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+metadata, and any other content or labor, has been confirmed to be
+in the PUBLIC DOMAIN IN THE UNITED STATES.
+
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+Project Gutenberg (https://www.gutenberg.org) public repository for
+eBook #55046 (https://www.gutenberg.org/ebooks/55046)
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-The Project Gutenberg EBook of First Principles, by Herbert Spencer
-
-This eBook is for the use of anyone anywhere in the United States and most
-other parts of the world at no cost and with almost no restrictions
-whatsoever. You may copy it, give it away or re-use it under the terms of
-the Project Gutenberg License included with this eBook or online at
-www.gutenberg.org. If you are not located in the United States, you'll have
-to check the laws of the country where you are located before using this ebook.
-
-Title: First Principles
-
-Author: Herbert Spencer
-
-Release Date: July 5, 2017 [EBook #55046]
-
-Language: English
-
-Character set encoding: UTF-8
-
-*** START OF THIS PROJECT GUTENBERG EBOOK FIRST PRINCIPLES ***
-
-
-
-
-Produced by Richard Tonsing and the Online Distributed
-Proofreading Team at http://www.pgdp.net (This file was
-produced from images generously made available by The
-Internet Archive)
-
-
-
-
-
-
-
-
-
- FIRST
- PRINCIPLES.
-
-
- BY
-
- HERBERT SPENCER,
-
- AUTHOR OF “SOCIAL STATICS,” “THE PRINCIPLES OF PSYCHOLOGY,” “ESSAYS:
- SCIENTIFIC, POLITICAL, AND SPECULATIVE,” “EDUCATION,” ETC.
-
-
- SECOND THOUSAND.
-
-
- LONDON:
- WILLIAMS AND NORGATE, 14, HENRIETTA STREET,
- COVENT GARDEN.
- 1863.
-
- _The Right of Translation is reserved._
-
-
-
-
- JOHN CHILDS AND SON, PRINTERS.
-
-------------------------------------------------------------------------
-
-
-
-
- PREFACE.
-
-
-This volume is the first of a series described in a prospectus
-originally distributed in March, 1860. Of that prospectus, the annexed
-is a reprint.
-
-
- A SYSTEM OF PHILOSOPHY.
-
-Mr. Herbert Spencer proposes to issue in periodical parts a connected
-series of works which he has for several years been preparing. Some
-conception of the general aim and scope of this series may be gathered
-from the following Programme.
-
-
- FIRST PRINCIPLES.
-
- PART I. THE UNKNOWABLE.—Carrying a step further the doctrine put
- into shape by Hamilton and Mansel; pointing out the various
- directions in which Science leads to the same conclusions; and
- showing that in this united belief in an Absolute that transcends
- not only human knowledge but human conception, lies the only
- possible reconciliation of Science and Religion.
-
- PART II. LAWS OF THE KNOWABLE.—A statement of the ultimate
- principles discernible throughout all manifestations of the
- Absolute—those highest generalizations now being disclosed by
- Science which are severally true not of one class of phenomena but
- of _all_ classes of phenomena; and which are thus the keys to all
- classes of phenomena.[1]
-
- [_In logical order should here come the application of these First
- Principles to Inorganic Nature. But this great division it is
- proposed to pass over: partly because, even without it, the scheme
- is too extensive; and partly because the interpretation of Organic
- Nature after the proposed method, is of more immediate importance.
- The second work of the series will therefore be_—]
-
-
- THE PRINCIPLES OF BIOLOGY.
-
-
- VOL. I.
-
- PART I. THE DATA OF BIOLOGY.—Including those general truths of
- Physics and Chemistry with which rational Biology must set out.
-
- II. THE INDUCTIONS OF BIOLOGY.—A statement of the leading
- generalizations which Naturalists, Physiologists, and Comparative
- Anatomists, have established.
-
- III. THE EVOLUTION OF LIFE.—Concerning the speculation commonly
- known as “The Development Hypothesis”—its _à priori_ and _à
- posteriori_ evidences.
-
-
- VOL. II.
-
- IV. MORPHOLOGICAL DEVELOPMENT.—Pointing out the relations that are
- everywhere traceable between organic forms and the average of the
- various forces to which they are subject; and seeking in the
- cumulative effects of such forces a theory of the forms.
-
- V. PHYSIOLOGICAL DEVELOPMENT.—The progressive differentiation of
- functions similarly traced; and similarly interpreted as
- consequent upon the exposure of different parts of organisms to
- different sets of conditions.
-
- VI. THE LAWS OF MULTIPLICATION.—Generalizations respecting the
- rates of reproduction of the various classes of plants and
- animals; followed by an attempt to show the dependence of these
- variations upon certain necessary causes.[2]
-
-
- THE PRINCIPLES OF PSYCHOLOGY.
-
-
- VOL. I.
-
- PART I. THE DATA OF PSYCHOLOGY.—Treating of the general connexions
- of Mind and Life and their relations to other modes of the
- Unknowable.
-
- II. THE INDUCTIONS OF PSYCHOLOGY.—A digest of such generalizations
- respecting mental phenomena as have already been empirically
- established.
-
- III. GENERAL SYNTHESIS.—A republication, with additional chapters,
- of the same part in the already-published _The Principles of
- Psychology_.
-
- IV. SPECIAL SYNTHESIS.—A republication, with extensive revisions
- and additions, of the same part, &c. &c.
-
- V. PHYSICAL SYNTHESIS.—An attempt to show the manner in which the
- succession of states of consciousness conforms to a certain
- fundamental law of nervous action that follows from the First
- Principles laid down at the outset.
-
-
- VOL. II.
-
- VI. SPECIAL ANALYSIS.—As at present published, but further
- elaborated by some additional chapters.
-
- VII. GENERAL ANALYSIS.—As at present published, with several
- explanations and additions.
-
- VIII. COROLLARIES.—Consisting in part of a number of derivative
- principles which form a necessary introduction to Sociology.[3]
-
-
- THE PRINCIPLES OF SOCIOLOGY.
-
-
- VOL. I.
-
- PART I. THE DATA OF SOCIOLOGY.—A statement of the several sets of
- factors entering into social phenomena—human ideas and feelings
- considered in their necessary order of evolution; surrounding
- natural conditions; and those ever complicating conditions to
- which Society itself gives origin.
-
- II. THE INDUCTIONS OF SOCIOLOGY.—General facts, structural and
- functional, as gathered from a survey of Societies and their
- changes: in other words, the empirical generalizations that are
- arrived at by comparing different societies, and successive phases
- of the same society.
-
- III. POLITICAL ORGANIZATION.—The evolution of governments, general
- and local, as determined by natural causes; their several types
- and metamorphoses; their increasing complexity and specialization;
- and the progressive limitation of their functions.
-
-
- VOL. II.
-
- IV. ECCLESIASTICAL ORGANIZATION.—Tracing the differentiation of
- religious government from secular; its successive complications
- and the multiplication of sects; the growth and continued
- modification of religious ideas, as caused by advancing knowledge
- and changing moral character; and the gradual reconciliation of
- these ideas with the truths of abstract science.
-
- V. CEREMONIAL ORGANIZATION.—The natural history of that third kind
- of government which, having a common root with the others, and
- slowly becoming separate from and supplementary to them, serves to
- regulate the minor actions of life.
-
- VI. INDUSTRIAL ORGANIZATION.—The development of productive and
- distributive agencies, considered, like the foregoing, in its
- necessary causes: comprehending not only the progressive division
- of labour, and the increasing complexity of each industrial
- agency, but also the successive forms of industrial government as
- passing through like phases with political government.
-
-
- VOL. III.
-
- VII. LINGUAL PROGRESS.—The evolution of Languages regarded as a
- psychological process determined by social conditions.
-
- VIII. INTELLECTUAL PROGRESS.—Treated from the same point of view:
- including the growth of classifications; the evolution of science
- out of common knowledge; the advance from qualitative to
- quantitative prevision, from the indefinite to the definite, and
- from the concrete to the abstract.
-
- IX. ÆSTHETIC PROGRESS.—The Fine Arts similarly dealt with: tracing
- their gradual differentiation from primitive institutions and from
- each other; their increasing varieties of development; and their
- advance in reality of expression and superiority of aim.
-
- X. MORAL PROGRESS.—Exhibiting the genesis of the slow emotional
- modifications which human nature undergoes in its adaptation to
- the social state.
-
- XI. THE CONSENSUS.—Treating of the necessary interdependence of
- structures and of functions in each type of society, and in the
- successive phases of social development.[4]
-
-
- THE PRINCIPLES OF MORALITY.
-
-
- VOL. I.
-
- PART I. THE DATA OF MORALITY.—Generalizations furnished by
- Biology, Psychology and Sociology, which underlie a true theory of
- right living: in other words, the elements of that equilibrium
- between constitution and conditions of existence, which is at once
- the moral ideal and the limit towards which we are progressing.
-
- II. THE INDUCTIONS OF MORALITY.—Those empirically-established
- rules of human action which are registered as essential laws by
- all civilized nations: that is to say—the generalizations of
- expediency.
-
- III. PERSONAL MORALS.—The principles of private conduct—physical,
- intellectual, moral and religious—that follow from the conditions
- to complete individual life: or, what is the same thing—those
- modes of private action which must result from the eventual
- equilibration of internal desires and external needs.
-
-
- VOL. II.
-
- IV. JUSTICE.—The mutual limitations of men’s actions necessitated
- by their co-existence as units of a society—limitations, the
- perfect observance of which constitutes that state of equilibrium
- forming the goal of political progress.
-
- V. NEGATIVE BENEFICENCE.—Those secondary limitations, similarly
- necessitated, which, though less important and not cognizable by
- law, are yet requisite to prevent mutual destruction of happiness
- in various indirect ways: in other words—those minor
- self-restraints dictated by what may be called passive sympathy.
-
- VI. POSITIVE BENEFICENCE.—Comprehending all modes of conduct,
- dictated by active sympathy, which imply pleasure in giving
- pleasure—modes of conduct that social adaptation has induced and
- must render ever more general; and which, in becoming universal,
- must fill to the full the possible measure of human happiness.[5]
-
- In anticipation of the obvious criticism that the scheme here
- sketched out is too extensive, it may be remarked that an
- exhaustive treatment of each topic is not intended; but simply the
- establishment of _principles_, with such illustrations as are
- needed to make their bearings fully understood. It may also be
- pointed out that, besides minor fragments, one large division
- (_The Principles of Psychology_) is already, in great part,
- executed. And a further reply is, that impossible though it may
- prove to execute the whole, yet nothing can be said against an
- attempt to set forth the First Principles and to carry their
- applications as far as circumstances permit.
-
- The price per Number to be half-a-crown; that is to say, the four
- Numbers yearly issued to be severally delivered, post free, to all
- annual subscribers of Ten Shillings.
-
- * * * * *
-
-This Programme I have thought well to reprint for two reasons:—the one
-being that readers may, from time to time, be able to ascertain what
-topics are next to be dealt with; the other being that an outline of the
-scheme may remain, in case it should never be completed.
-
-The successive instalments of which this volume consists, were issued to
-the subscribers at the following dates:—Part I. (pp. 1–80) in October,
-1860; Part II. (pp. 81–176) in January, 1861; Part III. (pp. 177–256) in
-April, 1861; Part IV. (pp. 257–334) in October, 1861; Part V. (pp.
-335–416) in March, 1862; and Part VI. (pp. 417–504) in June, 1862.
-
- _London, June 5th, 1862_
-
------
-
-Footnote 1:
-
- One of these generalizations is that currently known as “the
- Conservation of Force;” a second may be gathered from a published
- essay on “Progress: its Law and Cause;” a third is indicated in a
- paper on “Transcendental Physiology;” and there are several others.
-
-Footnote 2:
-
- The ideas to be developed in the second volume of the _Principles of
- Biology_ the writer has already briefly expressed in sundry
- Review-Articles. Part IV. will work out a doctrine suggested in a
- paper on “The Laws of Organic Form,” published in the
- _Medico-Chirurgical Review_ for January, 1859. The germ of Part V. is
- contained in the essay on “Transcendental Physiology:” See _Essays_,
- pp. 280–90. And in Part VI. will be unfolded certain views crudely
- expressed in a “Theory of Population,” published in the _Westminster
- Review_ for April, 1852.
-
-Footnote 3:
-
- Respecting the several additions to be made to the _Principles of
- Psychology_, it seems needful only to say that Part V. is the
- unwritten division named in the preface to that work—a division of
- which the germ is contained in a note on page 544, and of which the
- scope has since been more definitely stated in a paper in the
- _Medico-Chirurgical Review_ for Jan. 1859.
-
-Footnote 4:
-
- Of this treatise on Sociology a few small fragments may be found in
- already-published essays. Some of the ideas to be developed in Part
- II. are indicated in an article on “The Social Organism,” contained in
- the last number of the _Westminster Review_; those which Part V. will
- work out, may be gathered from the first half of a paper written some
- years since on “Manners and Fashion;” of Part VIII. the germs are
- contained in an article on the “Genesis of Science;” two papers on
- “The Origin and Function of Music” and “The Philosophy of Style,”
- contain some ideas to be embodied in Part IX.; and from a criticism of
- Mr. Bain’s work on “The Emotions and the Will,” in the last number of
- the _Medico-Chirurgical Review_, the central idea to be developed in
- Part X. may be inferred.
-
-Footnote 5:
-
- Part IV. of the _Principles of Morality_ will be co-extensive (though
- not identical) with the first half of the writer’s _Social Statics_.
-
-
-
-
- CONTENTS.
-
-
- PART I.—THE UNKNOWABLE.
-
- CHAP. PAGE
-
- I.— RELIGION AND SCIENCE 3
-
- II.— ULTIMATE RELIGIOUS IDEAS 25
-
- III.— ULTIMATE SCIENTIFIC IDEAS 47
-
- IV.— THE RELATIVITY OF ALL KNOWLEDGE 68
-
- V.— THE RECONCILIATION 98
-
-
- PART II.—LAWS OF THE KNOWABLE.
-
- I.— LAWS IN GENERAL 127
-
- II.— THE LAW OF EVOLUTION 146
-
- III.— THE LAW OF EVOLUTION (CONTINUED) 175
-
- IV.— THE CAUSES OF EVOLUTION 219
-
- V.— SPACE, TIME, MATTER, MOTION, AND FORCE 224
-
- VI.— THE INDESTRUCTIBILITY OF MATTER 238
-
- VII.— THE CONTINUITY OF MOTION 246
-
- VIII.— THE PERSISTENCE OF FORCE 251
-
- IX.— THE CORRELATION AND EQUIVALENCE OF FORCES 259
-
- X.— THE DIRECTION OF MOTION 286
-
- XI.— THE RHYTHM OF MOTION 313
-
- XII.— THE CONDITIONS ESSENTIAL TO EVOLUTION 335
-
- XIII.— THE INSTABILITY OF THE HOMOGENEOUS 358
-
- XIV.— THE MULTIPLICATION OF EFFECTS 388
-
- XV.— DIFFERENTIATION AND INTEGRATION 416
-
- VI.— EQUILIBRATION 440
-
- XVII.— SUMMARY AND CONCLUSION 487
-
-
-
-
- PART I.
-
- THE UNKNOWABLE.
-
-
-
-
- CHAPTER I.
- RELIGION AND SCIENCE.
-
-
-§ 1. We too often forget that not only is there “a soul of goodness in
-things evil,” but very generally also, a soul of truth in things
-erroneous. While many admit the abstract probability that a falsity has
-usually a nucleus of reality, few bear this abstract probability in
-mind, when passing judgment on the opinions of others. A belief that is
-finally proved to be grossly at variance with fact, is cast aside with
-indignation or contempt; and in the heat of antagonism scarcely any one
-inquires what there was in this belief which commended it to men’s
-minds. Yet there must have been something. And there is reason to
-suspect that this something was its correspondence with certain of their
-experiences: an extremely limited or vague correspondence perhaps; but
-still, a correspondence. Even the absurdest report may in nearly every
-instance be traced to an actual occurrence; and had there been no such
-actual occurrence, this preposterous misrepresentation of it would never
-have existed. Though the distorted or magnified image transmitted to us
-through the refracting medium of rumour, is utterly unlike the reality;
-yet in the absence of the reality there would have been no distorted or
-magnified image. And thus it is with human beliefs in general. Entirely
-wrong as they may appear, the implication is that they germinated out of
-actual experiences—originally contained, and perhaps still contain, some
-small amount of verity.
-
-More especially may we safely assume this, in the case of beliefs that
-have long existed and are widely diffused; and most of all so, in the
-case of beliefs that are perennial and nearly or quite universal. The
-presumption that any current opinion is not wholly false, gains in
-strength according to the number of its adherents. Admitting, as we
-must, that life is impossible unless through a certain agreement between
-internal convictions and external circumstances; admitting therefore
-that the probabilities are always in favour of the truth, or at least
-the partial truth, of a conviction; we must admit that the convictions
-entertained by many minds in common are the most likely to have some
-foundation. The elimination of individual errors of thought, must give
-to the resulting judgment a certain additional value. It may indeed be
-urged that many widely-spread beliefs are received on authority; that
-those entertaining them make no attempts at verification; and hence it
-may be inferred that the multitude of adherents adds but little to the
-probability of a belief. But this is not true. For a belief which gains
-extensive reception without critical examination, is thereby proved to
-have a general congruity with the various other beliefs of those who
-receive it; and in so far as these various other beliefs are based upon
-personal observation and judgment, they give an indirect warrant to one
-with which they harmonize. It may be that this warrant is of small
-value; but still it is of some value.
-
-Could we reach definite views on this matter, they would be extremely
-useful to us. It is important that we should, if possible, form
-something like a general theory of current opinions; so that we may
-neither over-estimate nor under-estimate their worth. Arriving at
-correct judgments on disputed questions, much depends on the attitude of
-mind we preserve while listening to, or taking part in, the controversy;
-and for the preservation of a right attitude, it is needful that we
-should learn how true, and yet how untrue, are average human beliefs. On
-the one hand, we must keep free from that bias in favour of received
-ideas which expresses itself in such dogmas as “What every one says must
-be true,” or “The voice of the people is the voice of God.” On the other
-hand, the fact disclosed by a survey of the past, that majorities have
-usually been wrong, must not blind us to the complementary fact, that
-majorities have usually not been _entirely_ wrong. And the avoidance of
-these extremes being a prerequisite to catholic thinking, we shall do
-well to provide ourselves with a safe-guard against them, by making a
-valuation of opinions in the abstract. To this end we must contemplate
-the kind of relation that ordinarily subsists between opinions and
-facts. Let us do so with one of those beliefs which under various forms
-has prevailed among all nations in all times.
-
- * * * * *
-
-§ 2. The earliest traditions represent rulers as gods or demigods. By
-their subjects, primitive kings were regarded as superhuman in origin,
-and superhuman in power. They possessed divine titles; received
-obeisances like those made before the altars of deities; and were in
-some cases actually worshipped. If there needs proof that the divine and
-half-divine characters originally ascribed to monarchs were ascribed
-literally, we have it in the fact that there are still existing savage
-races, among whom it is held that the chiefs and their kindred are of
-celestial origin, or, as elsewhere, that only the chiefs have souls. And
-of course along with beliefs of this kind, there existed a belief in the
-unlimited power of the ruler over his subjects—an absolute possession of
-them, extending even to the taking of their lives at will: as even still
-in Fiji, where a victim stands unbound to be killed at the word of his
-chief; himself declaring, “whatever the king says must be done.”
-
-In times and among races somewhat less barbarous, we find these beliefs
-a little modified. The monarch, instead of being literally thought god
-or demigod, is conceived to be a man having divine authority, with
-perhaps more or less of divine nature. He retains however, as in the
-East to the present day, titles expressing his heavenly descent or
-relationships; and is still saluted in forms and words as humble as
-those addressed to the Deity. While the lives and properties of his
-people, if not practically so completely at his mercy, are still in
-theory supposed to be his.
-
-Later in the progress of civilization, as during the middle ages in
-Europe, the current opinions respecting the relationship of rulers and
-ruled are further changed. For the theory of divine origin, there is
-substituted that of divine right. No longer god or demigod, or even
-god-descended, the king is now regarded as simply God’s vice-gerent. The
-obeisances made to him are not so extreme in their humility; and his
-sacred titles lose much of their meaning. Moreover his authority ceases
-to be unlimited. Subjects deny his right to dispose at will of their
-lives and properties; and yield allegiance only in the shape of
-obedience to his commands.
-
-With advancing political opinion has come still greater restriction of
-imperial power. Belief in the supernatural character of the ruler, long
-ago repudiated by ourselves for example, has left behind it nothing more
-than the popular tendency to ascribe unusual goodness, wisdom, and
-beauty to the monarch. Loyalty, which originally meant implicit
-submission to the king’s will, now means a merely nominal profession of
-subordination, and the fulfilment of certain forms of respect. Our
-political practice, and our political theory, alike utterly reject those
-regal prerogatives which once passed unquestioned. By deposing some, and
-putting others in their places, we have not only denied the divine
-rights of certain men to rule; but we have denied that they have any
-rights beyond those originating in the assent of the nation. Though our
-forms of speech and our state-documents still assert the subjection of
-the citizens to the ruler, our actual beliefs and our daily proceedings
-implicitly assert the contrary. We obey no laws save those of our own
-making. We have entirely divested the monarch of legislative power; and
-should immediately rebel against his or her exercise of such power, even
-in matters of the smallest concern. In brief, the aboriginal doctrine is
-all but extinct among us.
-
-Nor has the rejection of primitive political beliefs, resulted only in
-transferring the authority of an autocrat to a representative body. The
-views entertained respecting governments in general, of whatever form,
-are now widely different from those once entertained. Whether popular or
-despotic, governments were in ancient times supposed to have unlimited
-authority over their subjects. Individuals existed for the benefit of
-the State; not the State for the benefit of individuals. In our days,
-however, not only has the national will been in many cases substituted
-for the will of the king; but the exercise of this national will has
-been restricted to a much smaller sphere. In England, for instance,
-though there has been established no definite theory setting bounds to
-governmental authority; yet, in practice, sundry bounds have been set to
-it which are tacitly recognized by all. There is no organic law formally
-declaring that the legislature may not freely dispose of the citizens’
-lives, as early kings did when they sacrificed hecatombs of victims; but
-were it possible for our legislature to attempt such a thing, its own
-destruction would be the consequence, rather than the destruction of
-citizens. How entirely we have established the personal liberties of the
-subject against the invasions of State-power, would be quickly
-demonstrated, were it proposed by Act of Parliament forcibly to take
-possession of the nation, or of any class, and turn its services to
-public ends; as the services of the people were turned by primitive
-rulers. And should any statesman suggest a re-distribution of property
-such as was sometimes made in ancient democratic communities, he would
-be met by a thousand-tongued denial of imperial power over individual
-possessions. Not only in our day have these fundamental claims of the
-citizen been thus made good against the State, but sundry minor claims
-likewise. Ages ago, laws regulating dress and mode of living fell into
-disuse; and any attempt to revive them would prove the current opinion
-to be, that such matters lie beyond the sphere of legal control. For
-some centuries we have been asserting in practice, and have now
-established in theory, the right of every man to choose his own
-religious beliefs, instead of receiving such beliefs on State-authority.
-Within the last few generations we have inaugurated complete liberty of
-speech, in spite of all legislative attempts to suppress or limit it.
-And still more recently we have claimed and finally obtained under a few
-exceptional restrictions, freedom to trade with whomsoever we please.
-Thus our political beliefs are widely different from ancient ones, not
-only as to the proper depositary of power to be exercised over a nation,
-but also as to the extent of that power.
-
-Not even here has the change ended. Besides the average opinions which
-we have just described as current among ourselves, there exists a less
-widely-diffused opinion going still further in the same direction. There
-are to be found men who contend that the sphere of government should be
-narrowed even more than it is in England. The modern doctrine that the
-State exists for the benefit of citizens, which has now in a great
-measure supplanted the ancient doctrine that the citizens exist for the
-benefit of the State, they would push to its logical results. They hold
-that the freedom of the individual, limited only by the like freedom of
-other individuals, is sacred; and that the legislature cannot equitably
-put further restrictions upon it, either by forbidding any actions which
-the law of equal freedom permits, or taking away any property save that
-required to pay the cost of enforcing this law itself. They assert that
-the sole function of the State is the protection of persons against each
-other, and against a foreign foe. They urge that as, throughout
-civilization, the manifest tendency has been continually to extend the
-liberties of the subject, and restrict the functions of the State, there
-is reason to believe that the ultimate political condition must be one
-in which personal freedom is the greatest possible and governmental
-power the least possible: that, namely, in which the freedom of each has
-no limit but the like freedom of all; while the sole governmental duty
-is the maintenance of this limit.
-
-Here then in different times and places we find concerning the origin,
-authority, and functions of government, a great variety of
-opinions—opinions of which the leading genera above indicated subdivide
-into countless species. What now must be said about the truth or falsity
-of these opinions? Save among a few barbarous tribes the notion that a
-monarch is a god or demigod is regarded throughout the world as an
-absurdity almost passing the bounds of human credulity. In but few
-places does there survive a vague notion that the ruler possesses any
-supernatural attributes. Most civilized communities, which still admit
-the divine right of governments, have long since repudiated the divine
-right of kings. Elsewhere the belief that there is anything sacred in
-legislative regulations is dying out: laws are coming to be considered
-as conventional only. While the extreme school holds that governments
-have neither intrinsic authority, nor can have authority given to them
-by convention; but can possess authority only as the administrators of
-those moral principles deducible from the conditions essential to social
-life. Of these various beliefs, with their innumerable modifications,
-must we then say that some one alone is wholly right and all the rest
-wholly wrong; or must we say that each of them contains truth more or
-less completely disguised by errors? The latter alternative is the one
-which analysis will force upon us. Ridiculous as they may severally
-appear to those not educated under them, every one of these doctrines
-has for its vital element the recognition of an unquestionable fact.
-Directly or by implication, each of them insists on a certain
-subordination of individual actions to social requirements. There are
-wide differences as to the power to which this subordination is due;
-there are wide differences as to the motive for this subordination;
-there are wide differences as to its extent; but that there must be
-_some_ subordination all are agreed. From the oldest and rudest idea of
-allegiance, down to the most advanced political theory of our own day,
-there is on this point complete unanimity. Though, between the savage
-who conceives his life and property to be at the absolute disposal of
-his chief, and the anarchist who denies the right of any government,
-autocratic or democratic, to trench upon his individual freedom, there
-seems at first sight an entire and irreconcilable antagonism; yet
-ultimate analysis discloses in them this fundamental community of
-opinion; that there are limits which individual actions may not
-transgress—limits which the one regards as originating in the king’s
-will, and which the other regards as deducible from the equal claims of
-fellow-citizens.
-
-It may perhaps at first sight seem that we here reach a very unimportant
-conclusion; namely, that a certain tacit assumption is equally implied
-in all these conflicting political creeds—an assumption which is indeed
-of self-evident validity. The question, however, is not the value or
-novelty of the particular truth in this case arrived at. My aim has been
-to exhibit the more general truth, which we are apt to overlook, that
-between the most opposite beliefs there is usually something in
-common,—something taken for granted by each; and that this something, if
-not to be set down as an unquestionable verity, may yet be considered to
-have the highest degree of probability. A postulate which, like the one
-above instanced, is not consciously asserted but unconsciously involved;
-and which is unconsciously involved not by one man or body of men, but
-by numerous bodies of men who diverge in countless ways and degrees in
-the rest of their beliefs; has a warrant far transcending any that can
-be usually shown. And when, as in this case, the postulate is
-abstract—is not based on some one concrete experience common to all
-mankind, but implies an induction from a great variety of experiences,
-we may say that it ranks next in certainty to the postulates of exact
-science.
-
-Do we not thus arrive at a generalization which may habitually guide us
-when seeking for the soul of truth in things erroneous? While the
-foregoing illustration brings clearly home the fact, that in opinions
-seeming to be absolutely and supremely wrong something right is yet to
-be found; it also indicates the method we should pursue in seeking the
-something right. This method is to compare all opinions of the same
-genus; to set aside as more or less discrediting one another those
-various special and concrete elements in which such opinions disagree;
-to observe what remains after the discordant constituents have been
-eliminated; and to find for this remaining constituent that abstract
-expression which holds true throughout its divergent modifications.
-
- * * * * *
-
-§3. A candid acceptance of this general principle and an adoption of the
-course it indicates, will greatly aid us in dealing with those chronic
-antagonisms by which men are divided. Applying it not only to current
-ideas with which we are personally unconcerned, but also to our own
-ideas and those of our opponents, we shall be led to form far more
-correct judgments. We shall be ever ready to suspect that the
-convictions we entertain are not wholly right, and that the adverse
-convictions are not wholly wrong. On the one hand we shall not, in
-common with the great mass of the unthinking, let our beliefs be
-determined by the mere accident of birth in a particular age on a
-particular part of the Earth’s surface; and, on the other hand, we shall
-be saved from that error of entire and contemptuous negation, which is
-fallen into by most who take up an attitude of independent criticism.
-
-Of all antagonisms of belief, the oldest, the widest, the most profound
-and the most important, is that between Religion and Science. It
-commenced when the recognition of the simplest uniformities in
-surrounding things, set a limit to the previously universal fetishism.
-It shows itself everywhere throughout the domain of human knowledge:
-affecting men’s interpretations alike of the simplest mechanical
-accidents and of the most complicated events in the histories of
-nations. It has its roots deep down in the diverse habits of thought of
-different orders of minds. And the conflicting conceptions of nature and
-life which these diverse habits of thought severally generate, influence
-for good or ill the tone of feeling and the daily conduct.
-
-An unceasing battle of opinion like this which has been carried on
-throughout all ages under the banners of Religion and Science, has of
-course generated an animosity fatal to a just estimate of either party
-by the other. On a larger scale, and more intensely than any other
-controversy, has it illustrated that perennially significant fable
-concerning the knights who fought about the colour of a shield of which
-neither looked at more than one face. Each combatant seeing clearly his
-own aspect of the question, has charged his opponent with stupidity or
-dishonesty in not seeing the same aspect of it; while each has wanted
-the candour to go over to his opponent’s side and find out how it was
-that he saw everything so differently.
-
-Happily the times display an increasing catholicity of feeling, which we
-shall do well in carrying as far as our natures permit. In proportion as
-we love truth more and victory less, we shall become anxious to know
-what it is which leads our opponents to think as they do. We shall begin
-to suspect that the pertinacity of belief exhibited by them must result
-from a perception of something we have not perceived. And we shall aim
-to supplement the portion of truth we have found with the portion found
-by them. Making a more rational estimate of human authority, we shall
-avoid alike the extremes of undue submission and undue rebellion—shall
-not regard some men’s judgments as wholly good and others as wholly bad;
-but shall rather lean to the more defensible position that none are
-completely right and none are completely wrong.
-
-Preserving, as far as may be, this impartial attitude, let us then
-contemplate the two sides of this great controversy. Keeping guard
-against the bias of education and shutting out the whisperings of
-sectarian feeling, let us consider what are the _à priori_ probabilities
-in favour of each party.
-
- * * * * *
-
-§4. When duly realized, the general principle above illustrated must
-lead us to anticipate that the diverse forms of religious belief which
-have existed and which still exist, have all a basis in some ultimate
-fact. Judging by analogy the implication is, not that any one of them is
-altogether right; but that in each there is something right more or less
-disguised by other things wrong. It may be that the soul of truth
-contained in erroneous creeds is very unlike most, if not all, of its
-several embodiments; and indeed, if, as we have good reason to expect,
-it is much more abstract than any of them, its unlikeness necessarily
-follows. But however different from its concrete expressions, some
-essential verity must be looked for. To suppose that these multiform
-conceptions should be one and all _absolutely_ groundless, discredits
-too profoundly that average human intelligence from which all our
-individual intelligences are inherited.
-
-This most general reason we shall find enforced by other more special
-ones. To the presumption that a number of diverse beliefs of the same
-class have some common foundation in fact, must in this case be added a
-further presumption derived from the omnipresence of the beliefs.
-Religious ideas of one kind or other are almost if not quite universal.
-Even should it be true, as alleged, that there exist tribes of men who
-have nothing approaching to a theory of creation—even should it be true
-that only when a certain phase of intelligence is reached do the most
-rudimentary of such theories make their appearance; the implication is
-practically the same. Grant that among all races who have passed a
-certain stage of intellectual development there are found vague notions
-concerning the origin and hidden nature of surrounding things; and there
-arises the inference that such notions are necessary products of
-progressing intelligence. Their endless variety serves but to strengthen
-this conclusion: showing as it does a more or less independent
-genesis—showing how, in different places and times, like conditions have
-led to similar trains of thought, ending in analogous results. That
-these countless different, and yet allied, phenomena presented by all
-religions are accidental or factitious, is an untenable supposition. A
-candid examination of the evidence quite negatives the doctrine
-maintained by some, that creeds are priestly inventions. Even as a mere
-question of probabilities it cannot rationally be concluded that in
-every society, past and present, savage and civilized, certain members
-of the community have combined to delude the rest, in ways so analogous.
-To any who may allege that some primitive fiction was devised by some
-primitive priesthood, before yet mankind had diverged from a common
-centre, a reply is furnished by philology; for philology proves the
-dispersion of mankind to have commenced before there existed a language
-sufficiently organized to express religious ideas. Moreover, were it
-otherwise tenable, the hypothesis of artificial origin fails to account
-for the facts. It does not explain why, under all changes of form,
-certain elements of religious belief remain constant. It does not show
-us how it happens that while adverse criticism has from age to age gone
-on destroying particular theological dogmas, it has not destroyed the
-fundamental conception underlying these dogmas. It leaves us without any
-solution of the striking circumstance that when, from the absurdities
-and corruptions accumulated around them, national creeds have fallen
-into general discredit, ending in indifferentism or positive denial,
-there has always by and by arisen a re-assertion of them: if not the
-same in form, still the same in essence. Thus the universality of
-religious ideas, their independent evolution among different primitive
-races, and their great vitality, unite in showing that their source must
-be deep-seated instead of superficial. In other words, we are obliged to
-admit that if not supernaturally derived as the majority contend, they
-must be derived out of human experiences, slowly accumulated and
-organized.
-
-Should it be asserted that religious ideas are products of the religious
-sentiment, which, to satisfy itself, prompts imaginations that it
-afterwards projects into the external world, and by and by mistakes for
-realities; the problem is not solved, but only removed further back.
-Whether the wish is father to the thought, or whether sentiment and idea
-have a common genesis, there equally arises the question—Whence comes
-the sentiment? That it is a constituent in man’s nature is implied by
-the hypothesis; and cannot indeed be denied by those who prefer other
-hypotheses. And if the religious sentiment, displayed habitually by the
-majority of mankind, and occasionally aroused even in those seemingly
-devoid of it, must be classed among human emotions, we cannot rationally
-ignore it. We are bound to ask its origin and its function. Here is an
-attribute which, to say the least, has had an enormous influence—which
-has played a conspicuous part throughout the entire past as far back as
-history records, and is at present the life of numerous institutions,
-the stimulus to perpetual controversies, and the prompter of countless
-daily actions. Any Theory of Things which takes no account of this
-attribute, must, then, be extremely defective. If with no other view,
-still as a question in philosophy, we are called on to say what this
-attribute means; and we cannot decline the task without confessing our
-philosophy to be incompetent.
-
-Two suppositions only are open to us: the one that the feeling which
-responds to religious ideas resulted, along with all other human
-faculties, from an act of special creation; the other that it, in common
-with the rest, arose by a process of evolution. If we adopt the first of
-these alternatives, universally accepted by our ancestors and by the
-immense majority of our contemporaries, the matter is at once settled:
-man is directly endowed with the religious feeling by a creator; and to
-that creator it designedly responds. If we adopt the second alternative,
-then we are met by the questions—What are the circumstances to which the
-genesis of the religious feeling is due? and—What is its office? We are
-bound to entertain these questions; and we are bound to find answers to
-them. Considering all faculties, as we must on this supposition, to
-result from accumulated modifications caused by the intercourse of the
-organism with its environment, we are obliged to admit that there exist
-in the environment certain phenomena or conditions which have determined
-the growth of the feeling in question; and so are obliged to admit that
-it is as normal as any other faculty. Add to which that as, on the
-hypothesis of a development of lower forms into higher, the end towards
-which the progressive changes directly or indirectly tend, must be
-adaptation to the requirements of existence; we are also forced to infer
-that this feeling is in some way conducive to human welfare. Thus both
-alternatives contain the same ultimate implication. We must conclude
-that the religious sentiment is either directly created, or is created
-by the slow action of natural causes; and whichever of these conclusions
-we adopt, requires us to treat the religious sentiment with respect.
-
-One other consideration should not be overlooked—a consideration which
-students of Science more especially need to have pointed out. Occupied
-as such are with established truths, and accustomed to regard things not
-already known as things to be hereafter discovered, they are liable to
-forget that information, however extensive it may become, can never
-satisfy inquiry. Positive knowledge does not, and never can, fill the
-whole region of possible thought. At the uttermost reach of discovery
-there arises, and must ever arise, the question—What lies beyond? As it
-is impossible to think of a limit to space so as to exclude the idea of
-space lying outside that limit; so we cannot conceive of any explanation
-profound enough to exclude the question—What is the explanation of that
-explanation? Regarding Science as a gradually increasing sphere, we may
-say that every addition to its surface does but bring it into wider
-contact with surrounding nescience. There must ever remain therefore two
-antithetical modes of mental action. Throughout all future time, as now,
-the human mind may occupy itself, not only with ascertained phenomena
-and their relations, but also with that unascertained something which
-phenomena and their relations imply. Hence if knowledge cannot
-monopolize consciousness—if it must always continue possible for the
-mind to dwell upon that which transcends knowledge; then there can never
-cease to be a place for something of the nature of Religion; since
-Religion under all its forms is distinguished from everything else in
-this, that its subject matter is that which passes the sphere of
-experience.
-
-Thus, however untenable may be any or all the existing religious creeds,
-however gross the absurdities associated with them, however irrational
-the arguments set forth in their defence, we must not ignore the verity
-which in all likelihood lies hidden within them. The general probability
-that widely-spread beliefs are not absolutely baseless, is in this case
-enforced by a further probability due to the omnipresence of the
-beliefs. In the existence of a religious sentiment, whatever be its
-origin, we have a second evidence of great significance. And as in that
-nescience which must ever remain the antithesis to science, there is a
-sphere for the exercise of this sentiment, we find a third general fact
-of like implication. We may be sure therefore that religions, though
-even none of them be actually true, are yet all adumbrations of a truth.
-
- * * * * *
-
-§ 5. As, to the religious, it will seem absurd to set forth any
-justification for Religion; so, to the scientific, will it seem absurd
-to defend Science. Yet to do the last is certainly as needful as to do
-the first. If there exists a class who, in contempt of its follies and
-disgust at its corruptions, have contracted towards Religion a
-repugnance which makes them overlook the fundamental verity contained in
-it; so, too, is there a class offended to such a degree by the
-destructive criticisms men of science make on the religious tenets they
-regard as essential, that they have acquired a strong prejudice against
-Science in general. They are not prepared with any avowed reasons for
-their dislike. They have simply a remembrance of the rude shakes which
-Science has given to many of their cherished convictions, and a
-suspicion that it may perhaps eventually uproot all they regard as
-sacred; and hence it produces in them a certain inarticulate dread.
-
-What is Science? To see the absurdity of the prejudice against it, we
-need only remark that Science is simply a higher development of common
-knowledge; and that if Science is repudiated, all knowledge must be
-repudiated along with it. The extremest bigot will not suspect any harm
-in the observation that the sun rises earlier and sets later in the
-summer than in the winter; but will rather consider such an observation
-as a useful aid in fulfilling the duties of life. Well, Astronomy is an
-organized body of similar observations, made with greater nicety,
-extended to a larger number of objects, and so analyzed as to disclose
-the real arrangements of the heavens, and to dispel our false
-conceptions of them. That iron will rust in water, that wood will burn,
-that long kept viands become putrid, the most timid sectarian will teach
-without alarm, as things useful to be known. But these are chemical
-truths: Chemistry is a systematized collection of such facts,
-ascertained with precision, and so classified and generalized as to
-enable us to say with certainty, concerning each simple or compound
-substance, what change will occur in it under given conditions. And thus
-is it with all the sciences. They severally germinate out of the
-experiences of daily life; insensibly as they grow they draw in remoter,
-more numerous, and more complex experiences; and among these, they
-ascertain laws of dependence like those which make up our knowledge of
-the most familiar objects. Nowhere is it possible to draw a line and
-say—here Science begins. And as it is the function of common observation
-to serve for the guidance of conduct; so, too, is the guidance of
-conduct the office of the most recondite and abstract inquiries of
-Science. Through the countless industrial processes and the various
-modes of locomotion which it has given to us, Physics regulates more
-completely our social life than does his acquaintance with the
-properties of surrounding bodies regulate the life of the savage.
-Anatomy and Physiology, through their effects on the practice of
-medicine and hygiene, modify our actions almost as much as does our
-acquaintance with the evils and benefits which common environing
-agencies may produce on our bodies. All Science is prevision; and all
-prevision ultimately aids us in greater or less degree to achieve the
-good and avoid the bad. As certainly as the perception of an object
-lying in our path warns us against stumbling over it; so certainly do
-those more complicated and subtle perceptions which constitute Science,
-warn us against stumbling over intervening obstacles in the pursuit of
-our distant ends. Thus being one in origin and function, the simplest
-forms of cognition and the most complex must be dealt with alike. We are
-bound in consistency to receive the widest knowledge which our faculties
-can reach, or to reject along with it that narrow knowledge possessed by
-all. There is no logical alternative between accepting our intelligence
-in its entirety, or repudiating even that lowest intelligence which we
-possess in common with brutes.
-
-To ask the question which more immediately concerns our argument—whether
-Science is substantially true?—is much like asking whether the sun gives
-light. And it is because they are conscious how undeniably valid are
-most of its propositions, that the theological party regard Science with
-so much secret alarm. They know that during the two thousand years of
-its growth, some of its larger divisions—mathematics, physics,
-astronomy—have been subject to the rigorous criticism of successive
-generations; and have notwithstanding become ever more firmly
-established. They know that, unlike many of their own doctrines, which
-were once universally received but have age by age been more frequently
-called in question, the doctrines of Science, at first confined to a few
-scattered inquirers, have been slowly growing into general acceptance,
-and are now in great part admitted as beyond dispute. They know that men
-of science throughout the world subject each other’s results to the most
-searching examination; and that error is mercilessly exposed and
-rejected as soon as discovered. And, finally, they know that still more
-conclusive testimony is to be found in the daily verification of
-scientific predictions, and in the never-ceasing triumphs of those arts
-which Science guides.
-
-To regard with alienation that which has such high credentials is a
-folly. Though in the tone which many of the scientific adopt towards
-them, the defenders of Religion may find some excuse for this
-alienation; yet the excuse is a very insufficient one. On the side of
-Science, as on their own side, they must admit that short-comings in the
-advocates do not tell essentially against that which is advocated.
-Science must be judged by itself: and so judged, only the most perverted
-intellect can fail to see that it is worthy of all reverence. Be there
-or be there not any other revelation, we have a veritable revelation in
-Science—a continuous disclosure, through the intelligence with which we
-are endowed, of the established order of the Universe. This disclosure
-it is the duty of every one to verify as far as in him lies; and having
-verified, to receive with all humility.
-
- * * * * *
-
-§6. On both sides of this great controversy, then, truth must exist. An
-unbiassed consideration of its general aspects forces us to conclude
-that Religion, everywhere present as a weft running through the warp of
-human history, expresses some eternal fact; while it is almost a truism
-to say of Science that it is an organised mass of facts, ever growing,
-and ever being more completely purified from errors. And if both have
-bases in the reality of things, then between them there must be a
-fundamental harmony. It is an incredible hypothesis that there are two
-orders of truth, in absolute and everlasting opposition. Only on some
-Manichean theory, which among ourselves no one dares openly avow however
-much his beliefs may be tainted by it, is such a supposition even
-conceivable. That Religion is divine and Science diabolical, is a
-proposition which, though implied in many a clerical declamation, not
-the most vehement fanatic can bring himself distinctly to assert. And
-whoever does not assert this, must admit that under their seeming
-antagonism lies hidden an entire agreement.
-
-Each side, therefore, has to recognize the claims of the other as
-standing for truths that are not to be ignored. He who contemplates the
-Universe from the religious point of view, must learn to see that this
-which we call Science is one constituent of the great whole; and as such
-ought to be regarded with a sentiment like that which the remainder
-excites. While he who contemplates the universe from the scientific
-point of view, must learn to see that this which we call Religion is
-similarly a constituent of the great whole; and being such, must be
-treated as a subject of science with no more prejudice than any other
-reality. It behoves each party to strive to understand the other, with
-the conviction that the other has something worthy to be understood; and
-with the conviction that when mutually recognized this something will be
-the basis of a complete reconciliation.
-
-How to find this something—how to reconcile them, thus becomes the
-problem which we should perseveringly try to solve. Not to reconcile
-them in any makeshift way—not to find one of those compromises we hear
-from time to time proposed, which their proposers must secretly feel are
-artificial and temporary; but to arrive at the terms of a real and
-permanent peace between them. The thing we have to seek out, is that
-ultimate truth which both will avow with absolute sincerity—with not the
-remotest mental reservation. There shall be no concession—no yielding on
-either side of something that will by and by be reasserted; but the
-common ground on which they meet shall be one which each will maintain
-for itself. We have to discover some fundamental verity which Religion
-will assert, with all possible emphasis, in the absence of Science; and
-which Science, with all possible emphasis, will assert in the absence of
-Religion—some fundamental verity in the defence of which each will find
-the other its ally.
-
-Or, changing the point of view, our aim must be to co-ordinate the
-seemingly opposed convictions which Religion and Science embody. From
-the coalescence of antagonist ideas, each containing its portion of
-truth, there always arises a higher development. As in Geology when the
-igneous and aqueous hypotheses were united, a rapid advance took place;
-as in Biology we are beginning to progress through the fusion of the
-doctrine of types with the doctrine of adaptations; as in Psychology the
-arrested growth recommences now that the disciples of Kant and those of
-Locke have both their views recognized in the theory that organized
-experiences produce forms of thought; as in Sociology, now that it is
-beginning to assume a positive character, we find a recognition of both
-the party of progress and the party of order, as each holding a truth
-which forms a needful complement to that held by the other; so must it
-be on a grander scale with Religion and Science. Here too we must look
-for a conception which combines the conclusions of both; and here too we
-may expect important results from their combination. To understand how
-Science and Religion express opposite sides of the same fact—the one its
-near or visible side, and the other its remote or invisible side—this it
-is which we must attempt; and to achieve this must profoundly modify our
-general Theory of Things.
-
-Already in the foregoing pages the method of seeking such a
-reconciliation has been vaguely foreshadowed. Before proceeding further,
-however, it will be well to treat the question of method more
-definitely. To find that truth in which Religion and Science coalesce,
-we must know in what direction to look for it, and what kind of truth it
-is likely to be.
-
- * * * * *
-
-§ 7. We have found _à priori_ reason for believing that in all
-religions, even the rudest, there lies hidden a fundamental verity. We
-have inferred that this fundamental verity is that element common to all
-religions, which remains after their discordant peculiarities have been
-mutually cancelled. And we have further inferred that this element is
-almost certain to be more abstract than any current religious doctrine.
-Now it is manifest that only in some highly abstract proposition, can
-Religion and Science find a common ground. Neither such dogmas as those
-of the trinitarian and unitarian, nor any such idea as that of
-propitiation, common though it may be to all religions, can serve as the
-desired basis of agreement; for Science cannot recognize beliefs like
-these: they lie beyond its sphere. Hence we see not only that, judging
-by analogy, the essential truth contained in Religion is that most
-abstract element pervading all its forms; but also that this most
-abstract element is the only one in which Religion is likely to agree
-with Science.
-
-Similarly if we begin at the other end, and inquire what scientific
-truth can unite Science and Religion. It is at once manifest that
-Religion can take no cognizance of special scientific doctrines; any
-more than Science can take cognizance of special religious doctrines.
-The truth which Science asserts and Religion indorses cannot be one
-furnished by mathematics; nor can it be a physical truth; nor can it be
-a truth in chemistry: it cannot be a truth belonging to any particular
-science. No generalization of the phenomena of space, of time, of
-matter, or of force, can become a Religious conception. Such a
-conception, if it anywhere exists in Science, must be more general than
-any of these—must be one underlying all of them. If there be a fact
-which Science recognizes in common with Religion, it must be that fact
-from which the several branches of Science diverge, as from their common
-root.
-
-Assuming then, that since these two great realities are constituents of
-the same mind, and respond to different aspects of the same Universe,
-there must be a fundamental harmony between them; we see good reason to
-conclude that the most abstract truth contained in Religion and the most
-abstract truth contained in Science must be the one in which the two
-coalesce. The largest fact to be found within our mental range must be
-the one of which we are in search. Uniting these positive and negative
-poles of human thought, it must be the ultimate fact in our
-intelligence.
-
- * * * * *
-
-§ 8. Before proceeding in the search for this common datum let me
-bespeak a little patience. The next three chapters, setting out from
-different points and converging to the same conclusion, will be
-comparatively unattractive. Students of philosophy will find in them
-much that is more or less familiar; and to most of those who are
-unacquainted with the literature of modern metaphysics, they may prove
-somewhat difficult to follow.
-
-Our argument however cannot dispense with these chapters; and the
-greatness of the question at issue justifies even a heavier tax on the
-reader’s attention. The matter is one which concerns each and all of us
-more than any other matter whatever. Though it affects us little in a
-direct way, the view we arrive at must indirectly affect us in all our
-relations—must determine our conception of the Universe, of Life, of
-Human Nature—must influence our ideas of right and wrong, and so modify
-our conduct. To reach that point of view from which the seeming
-discordance of Religion and Science disappears, and the two merge into
-one, must cause a revolution of thought fruitful in beneficial
-consequences, and must surely be worth an effort.
-
-Here ending preliminaries, let us now address ourselves to this
-all-important inquiry.
-
-
-
-
- CHAPTER II.
- ULTIMATE RELIGIOUS IDEAS.
-
-
-§ 9. When, on the sea-shore, we note how the hulls of distant vessels
-are hidden below the horizon, and how, of still remoter vessels, only
-the uppermost sails are visible, we realize with tolerable clearness the
-slight curvature of that portion of the sea’s surface which lies before
-us. But when we seek in imagination to follow out this curved surface as
-it actually exists, slowly bending round until all its meridians meet in
-a point eight thousand miles below our feet, we find ourselves utterly
-baffled. We cannot conceive in its real form and magnitude even that
-small segment of our globe which extends a hundred miles on every side
-of us; much less the globe as a whole. The piece of rock on which we
-stand can be mentally represented with something like completeness: we
-find ourselves able to think of its top, its sides, and its under
-surface at the same time; or so nearly at the same time that they seem
-all present in consciousness together; and so we can form what we call a
-conception of the rock. But to do the like with the Earth we find
-impossible. If even to imagine the antipodes as at that distant place in
-space which it actually occupies, is beyond our power; much more beyond
-our power must it be at the same time to imagine all other remote points
-on the Earth’s surface as in their actual places. Yet we habitually
-speak as though we had an idea of the Earth—as though we could think of
-it in the same way that we think of minor objects.
-
-What conception, then, do we form of it? the reader may ask. That its
-name calls up in us some state of consciousness is unquestionable; and
-if this state of consciousness is not a conception, properly so called,
-what is it? The answer seems to be this:—We have learnt by indirect
-methods that the Earth is a sphere; we have formed models approximately
-representing its shape and the distribution of its parts; generally when
-the Earth is referred to, we either think of an indefinitely extended
-mass beneath our feet, or else, leaving out the actual Earth, we think
-of a body like a terrestrial globe; but when we seek to imagine the
-Earth as it really is, we join these two ideas as well as we can—such
-perception as our eyes give us of the Earth’s surface we couple with the
-conception of a sphere. And thus we form of the Earth, not a conception
-properly so called, but only a symbolic conception.[6]
-
-A large proportion of our conceptions, including all those of much
-generality, are of this order. Great magnitudes, great durations, great
-numbers, are none of them actually conceived, but are all of them
-conceived more or less symbolically; and so, too, are all those classes
-of objects of which we predicate some common fact. When mention is made
-of any individual man, a tolerably complete idea of him is formed. If
-the family he belongs to be spoken of, probably but a part of it will be
-represented in thought: under the necessity of attending to that which
-is said about the family, we realize in imagination only its most
-important or familiar members, and pass over the rest with a nascent
-consciousness which we know could, if requisite, be made complete.
-Should something be remarked of the class, say farmers, to which this
-family belongs, we neither enumerate in thought all the individuals
-contained in the class, nor believe that we could do so if required; but
-we are content with taking some few samples of it, and remembering that
-these could be indefinitely multiplied. Supposing the subject of which
-something is predicated be Englishmen, the answering state of
-consciousness is a still more inadequate representative of the reality.
-Yet more remote is the likeness of the thought to the thing, if
-reference be made to Europeans or to human beings. And when we come to
-propositions concerning the mammalia, or concerning the whole of the
-vertebrata, or concerning animals in general, or concerning all organic
-beings, the unlikeness of our conceptions to the objects named reaches
-its extreme. Throughout which series of instances we see, that as the
-number of objects grouped together in thought increases, the concept,
-formed of a few typical samples joined with the notion of multiplicity,
-becomes more and more a mere symbol; not only because it gradually
-ceases to represent the size of the group, but also because as the group
-grows more heterogeneous, the typical samples thought of are less like
-the average objects which the group contains.
-
-This formation of symbolic conceptions, which inevitably arises as we
-pass from small and concrete objects to large and to discrete ones, is
-mostly a very useful, and indeed necessary, process. When, instead of
-things whose attributes can be tolerably well united in a single state
-of consciousness, we have to deal with things whose attributes are too
-vast or numerous to be so united, we must either drop in thought part of
-their attributes, or else not think of them at all—either form a more or
-less symbolic conception, or no conception. We must predicate nothing of
-objects too great or too multitudinous to be mentally represented; or we
-must make our predications by the help of extremely inadequate
-representations of such objects—mere symbols of them.
-
-But while by this process alone we are enabled to form general
-propositions, and so to reach general conclusions, we are by this
-process perpetually led into danger, and very often into error. We
-habitually mistake our symbolic conceptions for real ones; and so are
-betrayed into countless false inferences. Not only is it that in
-proportion as the concept we form of any thing or class of things,
-misrepresents the reality, we are apt to be wrong in any assertion we
-make respecting the reality; but it is that we are led to suppose we
-have truly conceived a great variety of things which we have conceived
-only in this fictitious way; and further to confound with these certain
-things which cannot be conceived in any way. How almost unavoidably we
-fall into this error it will be needful here to observe.
-
-From objects readily representable in their totality, to those of which
-we cannot form even an approximate representation, there is an
-insensible transition. Between a pebble and the entire Earth a series of
-magnitudes might be introduced, each of which differed from the adjacent
-ones so slightly that it would be impossible to say at what point in the
-series our conceptions of them became inadequate. Similarly, there is a
-gradual progression from those groups of a few individuals which we can
-think of as groups with tolerable completeness, to those larger and
-larger groups of which we can form nothing like true ideas. Whence it is
-manifest that we pass from actual conceptions to symbolic ones by
-infinitesimal steps. Note next that we are led to deal with our symbolic
-conceptions as though they were actual ones, not only because we cannot
-clearly separate the two, but also because, in the great majority of
-cases, the first serve our purposes nearly or quite as well as the
-last—are simply the abbreviated signs we substitute for those more
-elaborate signs which are our equivalents for real objects. Those very
-imperfect representations of ordinary things which we habitually make in
-thinking, we know can be developed into adequate ones if needful. Those
-concepts of larger magnitudes and more extensive classes which we cannot
-make adequate, we still find can be verified by some indirect process of
-measurement or enumeration. And even in the case of such an utterly
-inconceivable object as the Solar System, we yet, through the fulfilment
-of predictions founded on our symbolic conception of it, gain the
-conviction that this symbolic conception stands for an actual existence,
-and, in a sense, truly expresses certain of its constituent relations.
-Thus our symbolic conceptions being in the majority of cases capable of
-development into complete ones, and in most other cases serving as steps
-to conclusions which are proved valid by their correspondence with
-observation, we acquire a confirmed habit of dealing with them as true
-conceptions—as real representations of actualities. Learning by long
-experience that they can, if needful, be verified, we are led habitually
-to accept them without verification. And thus we open the door to some
-which profess to stand for known things, but which really stand for
-things that cannot be known in any way.
-
-To sum up, we must say of conceptions in general, that they are complete
-only when the attributes of the object conceived are of such number and
-kind that they can be represented in consciousness so nearly at the same
-time as to seem all present together; that as the objects conceived
-become larger and more complex, some of the attributes first thought of
-fade from consciousness before the rest have been represented, and the
-conception thus becomes imperfect; that when the size, complexity, or
-discreteness of the object conceived becomes very great, only a small
-portion of its attributes can be thought of at once, and the conception
-formed of it thus becomes so inadequate as to be a mere symbol; that
-nevertheless such symbolic conceptions, which are indispensable in
-general thinking, are legitimate, provided that by some cumulative or
-indirect process of thought, or by the fulfilment of predictions based
-on them, we can assure ourselves that they stand for actualities; but
-that when our symbolic conceptions are such that no cumulative or
-indirect processes of thought can enable us to ascertain that there are
-corresponding actualities, nor any predictions be made whose fulfilment
-can prove this, then they are altogether vicious and illusive, and in no
-way distinguishable from pure fictions.
-
- * * * * *
-
-§ 10. And now to consider the bearings of this general truth on our
-immediate topic—Ultimate Religious Ideas.
-
-To the aboriginal man and to every civilized child the problem of the
-Universe suggests itself. What is it? and whence comes it? are questions
-that press for solution, when, from time to time, the imagination rises
-above daily trivialities. To fill the vacuum of thought, any theory that
-is proposed seems better than none. And in the absence of others, any
-theory that is proposed easily gains a footing and afterwards maintains
-its ground: partly from the readiness of mankind to accept proximate
-explanations; partly from the authority which soon accumulates round
-such explanations when given.
-
-A critical examination, however, will prove not only that no current
-hypothesis is tenable, but also that no tenable hypothesis can be
-framed.
-
- * * * * *
-
-§ 11. Respecting the origin of the Universe three verbally intelligible
-suppositions may be made. We may assert that it is self-existent; or
-that it is self-created; or that it is created by an external agency.
-Which of these suppositions is most credible it is not needful here to
-inquire. The deeper question, into which this finally merges, is,
-whether any one of them is even conceivable in the true sense of the
-word. Let us successively test them.
-
-When we speak of a man as self-supporting, of an apparatus as
-self-acting, or of a tree as self-developed, our expressions, however
-inexact, stand for things that can be realized in thought with tolerable
-completeness. Our conception of the self-development of a tree is
-doubtless symbolic. But though we cannot really represent in
-consciousness the entire series of complex changes through which the
-tree passes, yet we can thus represent the leading features of the
-series; and general experience teaches us that by long continued
-observation we could gain the power to realize in thought a series of
-changes more fully representing the actual series: that is, we know that
-our symbolic conception of self-development can be expanded into
-something like a real conception; and that it expresses, however
-inaccurately, an actual process in nature. But when we speak of
-self-existence, and, helped by the above analogies, form some vague
-symbolic conception of it, we delude ourselves in supposing that this
-symbolic conception is of the same order as the others. On joining the
-word _self_ to the word _existence_, the force of association makes us
-believe we have a thought like that suggested by the compound word
-self-acting. An endeavour to expand this symbolic conception, however,
-will undeceive us. In the first place, it is clear that by
-self-existence we especially mean, an existence independent of any
-other—not produced by any other: the assertion of self-existence is
-simply an indirect denial of creation. In thus excluding the idea of any
-antecedent cause, we necessarily exclude the idea of a beginning; for to
-admit the idea of a beginning—to admit that there was a time when the
-existence had not commenced—is to admit that its commencement was
-determined by something, or was caused; which is a contradiction.
-Self-existence, therefore, necessarily means existence without a
-beginning; and to form a conception of self-existence is to form a
-conception of existence without a beginning. Now by no mental effort can
-we do this. To conceive existence through infinite past-time, implies
-the conception of infinite past-time, which is an impossibility.
- To this let us add, that even were self-existence conceivable, it
-would not in any sense be an explanation of the Universe. No one will
-say that the existence of an object at the present moment is made easier
-to understand by the discovery that it existed an hour ago, or a day
-ago, or a year ago; and if its existence now is not made in the least
-degree more comprehensible by its existence during some previous finite
-period of time, then no accumulation of such finite periods, even could
-we extend them to an infinite period, would make it more comprehensible.
-Thus the Atheistic theory is not only absolutely unthinkable, but, even
-if it were thinkable, would not be a solution. The assertion that the
-Universe is self-existent does not really carry us a step beyond the
-cognition of its present existence; and so leaves us with a mere
-re-statement of the mystery.
-
-The hypothesis of self-creation, which practically amounts to what is
-called Pantheism, is similarly incapable of being represented in
-thought. Certain phenomena, such as the precipitation of invisible
-vapour into cloud, aid us in forming a symbolic conception of a
-self-evolved Universe; and there are not wanting indications in the
-heavens, and on the earth, which help us to render this conception
-tolerably definite. But while the succession of phases through which the
-Universe has passed in reaching its present form, may perhaps be
-comprehended as in a sense self-determined; yet the impossibility of
-expanding our symbolic conception of self-creation into a real
-conception, remains as complete as ever. Really to conceive
-self-creation, is to conceive potential existence passing into actual
-existence by some inherent necessity; which we cannot do. We
-cannot form any idea of a potential existence of the universe, as
-distinguished from its actual existence. If represented in thought at
-all, potential existence must be represented as _something_, that is as
-an actual existence; to suppose that it can be represented as nothing,
-involves two absurdities—that nothing is more than a negation, and can
-be positively represented in thought; and that one nothing is
-distinguished from all other nothings by its power to develope into
-something. Nor is this all. We have no state of consciousness answering
-to the words—an inherent necessity by which potential existence became
-actual existence. To render them into thought, existence, having for an
-indefinite period remained in one form, must be conceived as passing
-without any external or additional impulse, into another form; and this
-involves the idea of a change without a cause—a thing of which no idea
-is possible. Thus the terms of this hypothesis do not stand for real
-thoughts; but merely suggest the vaguest symbols incapable of any
-interpretation. Moreover, even were it true that potential
-existence is conceivable as a different thing from actual existence; and
-that the transition from the one to the other can be mentally realized
-as a self-determined change; we should still be no forwarder: the
-problem would simply be removed a step back. For whence the potential
-existence? This would just as much require accounting for as actual
-existence; and just the same difficulties would meet us. Respecting the
-origin of such a latent power, no other suppositions could be made than
-those above named—self-existence, self-creation, creation by external
-agency. The self-existence of a potential universe is no more
-conceivable than we have found the self-existence of the actual universe
-to be. The self-creation of such a potential universe would involve over
-again the difficulties here stated—would imply behind this potential
-universe a more remote potentiality; and so on in an infinite series,
-leaving us at last no forwarder than at first. While to assign as the
-source of this potential universe an external agency, would be to
-introduce the notion of a potential universe for no purpose whatever.
-
-There remains to be examined the commonly-received or theistic
-hypothesis—creation by external agency. Alike in the rudest creeds and
-in the cosmogony long current among ourselves, it is assumed that the
-genesis of the Heavens and the Earth is effected somewhat after the
-manner in which a workman shapes a piece of furniture. And this
-assumption is made not by theologians only, but by the immense
-majority of philosophers, past and present. Equally in the writings of
-Plato, and in those of not a few living men of science, we find it
-taken for granted that there is an analogy between the process of
-creation and the process of manufacture. Now in the first place,
-not only is this conception one that cannot by any cumulative process
-of thought, or the fulfilment of predictions based on it, be shown to
-answer to anything actual; and not only is it that in the absence of
-all evidence respecting the process of creation, we have no proof of
-correspondence even between this limited conception and some limited
-portion of the fact; but it is that the conception is not even
-consistent with itself—cannot be realized in thought, when all its
-assumptions are granted. Though it is true that the proceedings of a
-human artificer may vaguely symbolize to us a method after which the
-Universe might be shaped, yet they do not help us to comprehend the
-real mystery; namely, the origin of the material of which the Universe
-consists. The artizan does not make the iron, wood, or stone, he uses;
-but merely fashions and combines them. If we suppose suns, and
-planets, and satellites, and all they contain to have been similarly
-formed by a “Great Artificer,” we suppose merely that certain
-pre-existing elements were thus put into their present arrangement.
-But whence the pre-existing elements? The comparison helps us not in
-the least to understand that; and unless it helps us to understand
-that, it is worthless. The production of matter out of nothing is the
-real mystery, which neither this simile nor any other enables us to
-conceive; and a simile which does not enable us to conceive this, may
-just as well be dispensed with. Still more manifest does the
-insufficiency of this theory of creation become, when we turn from
-material objects to that which contains them—when instead of matter we
-contemplate space. Did there exist nothing but an immeasurable void,
-explanation would be needed as much as now. There would still arise
-the question—how came it so? If the theory of creation by external
-agency were an adequate one, it would supply an answer; and its answer
-would be—space was made in the same manner that matter was made. But
-the impossibility of conceiving this is so manifest, that no one dares
-to assert it. For if space was created, it must have been previously
-non-existent. The non-existence of space cannot, however, by any
-mental effort be imagined. It is one of the most familiar truths that
-the idea of space as surrounding us on all sides, is not for a moment
-to be got rid of—not only are we compelled to think of space as now
-everywhere present, but we are unable to conceive its absence either
-in the past or the future. And if the non-existence of space is
-absolutely inconceivable, then, necessarily, its creation is
-absolutely inconceivable. Lastly, even supposing that the
-genesis of the Universe could really be represented in thought as the
-result of an external agency, the mystery would be as great as ever;
-for there would still arise the question—how came there to be an
-external agency? To account for this only the same three hypotheses
-are possible—self-existence, self-creation, and creation by external
-agency. Of these the last is useless: it commits us to an infinite
-series of such agencies, and even then leaves us where we were. By the
-second we are practically involved in the same predicament; since, as
-already shown, self-creation implies an infinite series of potential
-existences. We are obliged therefore to fall back upon the first,
-which is the one commonly accepted and commonly supposed to be
-satisfactory. Those who cannot conceive a self-existent universe; and
-who therefore assume a creator as the source of the universe; take for
-granted that they can conceive a self-existent creator. The mystery
-which they recognize in this great fact surrounding them on every
-side, they transfer to an alleged source of this great fact; and then
-suppose that they have solved the mystery. But they delude themselves.
-As was proved at the outset of the argument, self-existence is
-rigorously inconceivable; and this holds true whatever be the nature
-of the object of which it is predicated. Whoever agrees that the
-atheistic hypothesis is untenable because it involves the impossible
-idea of self-existence, must perforce admit that the theistic
-hypothesis is untenable if it contains the same impossible idea.
-
-Thus these three different suppositions respecting the origin of things,
-verbally intelligible though they are, and severally seeming to their
-respective adherents quite rational, turn out, when critically examined,
-to be literally unthinkable. It is not a question of probability, or
-credibility, but of conceivability. Experiment proves that the elements
-of these hypotheses cannot even be put together in consciousness; and we
-can entertain them only as we entertain such pseud-ideas as a square
-fluid and a moral substance—only by abstaining from the endeavour to
-render them into actual thoughts. Or, reverting to our original mode of
-statement, we may say that they severally involve symbolic conceptions
-of the illegitimate and illusive kind. Differing so widely as they seem
-to do, the atheistic, the pantheistic, and the theistic hypotheses
-contain the same ultimate element. It is impossible to avoid making the
-assumption of self-existence somewhere; and whether that assumption be
-made nakedly, or under complicated disguises, it is equally vicious,
-equally unthinkable. Be it a fragment of matter, or some fancied
-potential form of matter, or some more remote and still less imaginable
-cause, our conception of its self-existence can be formed only by
-joining with it the notion of unlimited duration through past time. And
-as unlimited duration is inconceivable, all those formal ideas into
-which it enters are inconceivable; and indeed, if such an expression is
-allowable, are the more inconceivable in proportion as the other
-elements of the ideas are indefinite. So that in fact, impossible as it
-is to think of the actual universe as self-existing, we do but multiply
-impossibilities of thought by every attempt we make to explain its
-existence.
-
- * * * * *
-
-§ 12. If from the origin of the Universe we turn to its nature, the like
-insurmountable difficulties rise up before us on all sides—or rather,
-the same difficulties under new aspects. We find ourselves on the one
-hand obliged to make certain assumptions; and yet on the other hand we
-find these assumptions cannot be represented in thought.
-
-When we inquire what is the meaning of the various effects produced upon
-our senses—when we ask how there come to be in our consciousness
-impressions of sounds, of colours, of tastes, and of those various
-attributes which we ascribe to bodies; we are compelled to regard them
-as the effects of some cause. We may stop short in the belief that this
-cause is what we call matter. Or we may conclude, as some do, that
-matter is only a certain mode of manifestation of spirit; which is
-therefore the true cause. Or, regarding matter and spirit as proximate
-agencies, we may attribute all the changes wrought in our consciousness
-to immediate divine power. But be the cause we assign what it may, we
-are obliged to suppose _some_ cause. And we are not only obliged to
-suppose some cause, but also a first cause. The matter, or spirit, or
-whatever we assume to be the agent producing on us these various
-impressions, must either be the first cause of them or not. If it is the
-first cause, the conclusion is reached. If it is not the first cause,
-then by implication there must be a cause behind it; which thus becomes
-the real cause of the effect. Manifestly, however complicated the
-assumptions, the same conclusion must inevitably be reached. We cannot
-think at all about the impressions which the external world produces on
-us, without thinking of them as caused; and we cannot carry out an
-inquiry concerning their causation, without inevitably committing
-ourselves to the hypothesis of a First Cause.
-
-But now if we go a step further, and ask what is the nature of this
-First Cause, we are driven by an inexorable logic to certain further
-conclusions. Is the First Cause finite or infinite? If we say finite we
-involve ourselves in a dilemma. To think of the First Cause as finite,
-is to think of it as limited. To think of it as limited, necessarily
-implies a conception of something beyond its limits: it is absolutely
-impossible to conceive a thing as bounded without conceiving a region
-surrounding its boundaries. What now must we say of this region? If the
-First Cause is limited, and there consequently lies something outside of
-it, this something must have no First Cause—must be uncaused. But if we
-admit that there can be something uncaused, there is no reason to assume
-a cause for anything. If beyond that finite region over which the First
-Cause extends, there lies a region, which we are compelled to regard as
-infinite, over which it does not extend—if we admit that there is an
-infinite uncaused surrounding the finite caused; we tacitly abandon the
-hypothesis of causation altogether. Thus it is impossible to consider
-the First Cause as finite. And if it cannot be finite it must be
-infinite.
-
-Another inference concerning the First Cause is equally unavoidable. It
-must be independent. If it is dependent it cannot be the First Cause;
-for that must be the First Cause on which it depends. It is not enough
-to say that it is partially independent; since this implies some
-necessity which determines its partial dependence, and this necessity,
-be it what it may, must be a higher cause, or the true First Cause,
-which is a contradiction. But to think of the First Cause as totally
-independent, is to think of it as that which exists in the absence of
-all other existence; seeing that if the presence of any other existence
-is necessary, it must be partially dependent on that other existence,
-and so cannot be the First Cause. Not only however must the First Cause
-be a form of being which has no necessary relation to any other form of
-being, but it can have no necessary relation within itself. There can be
-nothing in it which determines change, and yet nothing which prevents
-change. For if it contains something which imposes such necessities or
-restraints, this something must be a cause higher than the First Cause,
-which is absurd. Thus the First Cause must be in every sense perfect,
-complete, total: including within itself all power, and transcending all
-law. Or to use the established word, it must be absolute.
-
-Here then respecting the nature of the Universe, we seem committed to
-certain unavoidable conclusions. The objects and actions surrounding us,
-not less than the phenomena of our own consciousness, compel us to ask a
-cause; in our search for a cause, we discover no resting place until we
-arrive at the hypothesis of a First Cause; and we have no alternative
-but to regard this First Cause as Infinite and Absolute. These are
-inferences forced upon us by arguments from which there appears no
-escape. It is hardly needful however to show those who have followed
-thus far, how illusive are these reasonings and their results. But that
-it would tax the reader’s patience to no purpose, it might easily be
-proved that the materials of which the argument is built, equally with
-the conclusions based on them, are merely symbolic conceptions of the
-illegitimate order. Instead, however, of repeating the disproof used
-above, it will be desirable to pursue another method; showing the
-fallacy of these conclusions by disclosing their mutual contradictions.
-
-Here I cannot do better than avail myself of the demonstration which Mr
-Mansel, carrying out in detail the doctrine of Sir William Hamilton, has
-given in his “Limits of Religious Thought.” And I gladly do this, not
-only because his mode of presentation cannot be improved, but also
-because, writing as he does in defence of the current Theology, his
-reasonings will be the more acceptable to the majority of readers.
-
- * * * * *
-
-§ 13. Having given preliminary definitions of the First Cause, of the
-Infinite, and of the Absolute, Mr Mansel says:—
-
-“But these three conceptions, the Cause, the Absolute, the Infinite, all
-equally indispensable, do they not imply contradiction to each other,
-when viewed in conjunction, as attributes of one and the same Being? A
-Cause cannot, as such, be absolute: the Absolute cannot, as such, be a
-cause. The cause, as such, exists only in relation to its effect: the
-cause is a cause of the effect; the effect is an effect of the cause. On
-the other hand, the conception of the Absolute implies a possible
-existence out of all relation. We attempt to escape from this apparent
-contradiction, by introducing the idea of succession in time. The
-Absolute exists first by itself, and afterwards becomes a Cause. But
-here we are checked by the third conception, that of the Infinite. How
-can the Infinite become that which it was not from the first? If
-Causation is a possible mode of existence, that which exists without
-causing is not infinite; that which becomes a cause has passed beyond
-its former limits.” * * *
-
-“Supposing the Absolute to become a cause, it will follow that it
-operates by means of freewill and consciousness. For a necessary cause
-cannot be conceived as absolute and infinite. If necessitated by
-something beyond itself, it is thereby limited by a superior power; and
-if necessitated by itself, it has in its own nature a necessary relation
-to its effect. The act of causation must therefore be voluntary; and
-volition is only possible in a conscious being. But consciousness again
-is only conceivable as a relation. There must be a conscious subject,
-and an object of which he is conscious. The subject is a subject to the
-object; the object is an object to the subject; and neither can exist by
-itself as the absolute. This difficulty, again, may be for the moment
-evaded, by distinguishing between the absolute as related to another and
-the absolute as related to itself. The Absolute, it may be said, may
-possibly be conscious, provided it is only conscious of itself. But this
-alternative is, in ultimate analysis, no less self-destructive than the
-other. For the object of consciousness, whether a mode of the subject’s
-existence or not, is either created in and by the act of consciousness,
-or has an existence independent of it. In the former case, the object
-depends upon the subject, and the subject alone is the true absolute. In
-the latter case, the subject depends upon the object, and the object
-alone is the true absolute. Or if we attempt a third hypothesis, and
-maintain that each exists independently of the other, we have no
-absolute at all, but only a pair of relatives; for coexistence, whether
-in consciousness or not, is itself a relation.”
-
-“The corollary from this reasoning is obvious. Not only is the Absolute,
-as conceived, incapable of a necessary relation to anything else; but it
-is also incapable of containing, by the constitution of its own nature,
-an essential relation within itself; as a whole, for instance, composed
-of parts, or as a substance consisting of attributes, or as a conscious
-subject in antithesis to an object. For if there is in the absolute any
-principle of unity, distinct from the mere accumulation of parts or
-attributes, this principle alone is the true absolute. If, on the other
-hand, there is no such principle, then there is no absolute at all, but
-only a plurality of relatives. The almost unanimous voice of philosophy,
-in pronouncing that the absolute is both one and simple, must be
-accepted as the voice of reason also, so far as reason has any voice in
-the matter. But this absolute unity, as indifferent and containing no
-attributes, can neither be distinguished from the multiplicity of finite
-beings by any characteristic feature, nor be identified with them in
-their multiplicity. Thus we are landed in an inextricable dilemma. The
-Absolute cannot be conceived as conscious, neither can it be conceived
-as unconscious: it cannot be conceived as complex, neither can it be
-conceived as simple: it cannot be conceived by difference, neither can
-it be conceived by the absence of difference: it cannot be identified
-with the universe, neither can it be distinguished from it. The One and
-the Many, regarded as the beginning of existence, are thus alike
-incomprehensible.”
-
-“The fundamental conceptions of Rational Theology being thus
-self-destructive, we may naturally expect to find the same antagonism
-manifested in their special applications. * * * How, for example, can
-Infinite Power be able to do all things, and yet Infinite Goodness be
-unable to do evil? How can Infinite Justice exact the utmost penalty for
-every sin, and yet Infinite Mercy pardon the sinner? How can Infinite
-Wisdom know all that is to come, and yet Infinite Freedom be at liberty
-to do or to forbear? How is the existence of Evil compatible with that
-of an infinitely perfect Being; for if he wills it, he is not infinitely
-good; and if he wills it not, his will is thwarted and his sphere of
-action limited?” * * *
-
-“Let us, however, suppose for an instant that these difficulties are
-surmounted, and the existence of the Absolute securely established on
-the testimony of reason. Still we have not succeeded in reconciling this
-idea with that of a Cause: we have done nothing towards explaining how
-the absolute can give rise to the relative, the infinite to the finite.
-If the condition of casual activity is a higher state than that of
-quiescence, the Absolute, whether acting voluntarily or involuntarily,
-has passed from a condition of comparative imperfection to one of
-comparative perfection; and therefore was not originally perfect. If the
-state of activity is an inferior state to that of quiescence, the
-Absolute, in becoming a cause, has lost its original perfection. There
-remains only the supposition that the two states are equal, and the act
-of creation one of complete indifference. But this supposition
-annihilates the unity of the absolute, or it annihilates itself. If the
-act of creation is real, and yet indifferent, we must admit the
-possibility of two conceptions of the absolute, the one as productive,
-the other as non-productive. If the act is not real, the supposition
-itself vanishes.” * * *
-
-“Again, how can the relative be conceived as coming into being? If it is
-a distinct reality from the absolute, it must be conceived as passing
-from non-existence into existence. But to conceive an object as
-non-existent, is again a self-contradiction; for that which is conceived
-exists, as an object of thought, in and by that conception. We may
-abstain from thinking of an object at all; but, if we think of it, we
-cannot but think of it as existing. It is possible at one time not to
-think of an object at all, and at another to think of it as already in
-being; but to think of it in the act of becoming, in the progress from
-not being into being, is to think that which, in the very thought,
-annihilates itself.” * * *
-
-“To sum up briefly this portion of my argument. The conception of the
-Absolute and Infinite, from whatever side we view it, appears
-encompassed with contradictions. There is a contradiction in supposing
-such an object to exist, whether alone or in conjunction with others;
-and there is a contradiction in supposing it not to exist. There is a
-contradiction in conceiving it as one; and there is a contradiction in
-conceiving it as many. There is a contradiction in conceiving it as
-personal; and there is a contradiction in conceiving it as impersonal.
-It cannot, without contradiction, be represented as active; nor, without
-equal contradiction, be represented as inactive. It cannot be conceived
-as the sum of all existence; nor yet can it be conceived as a part only
-of that sum.”
-
- * * * * *
-
-§ 14. And now what is the bearing of these results on the question
-before us? Our examination of Ultimate Religious Ideas has been carried
-on with the view of making manifest some fundamental verity contained in
-them. Thus far however we have arrived at negative conclusions only.
-Criticising the essential conceptions involved in the different orders
-of beliefs, we find no one of them to be logically defensible. Passing
-over the consideration of credibility, and confining ourselves to that
-of conceivability, we see that Atheism, Pantheism, and Theism, when
-rigorously analysed, severally prove to be absolutely unthinkable.
-Instead of disclosing a fundamental verity existing in each, our
-investigation seems rather to have shown that there is no fundamental
-verity contained in any. To carry away this conclusion, however, would
-be a fatal error; as we shall shortly see.
-
-Leaving out the accompanying moral code, which is in all cases a
-supplementary growth, every Religion may be defined as an _à priori_
-theory of the Universe. The surrounding facts being given, some form of
-agency is alleged which, in the opinion of those alleging it, accounts
-for these facts. Be it in the rudest Fetishism, which assumes a separate
-personality behind every phenomenon; be it in Polytheism, in which these
-personalities are partially generalized; be it in Monotheism, in which
-they are wholly generalized; or be it in Pantheism, in which the
-generalized personality becomes one with the phenomena; we equally find
-an hypothesis which is supposed to render the Universe comprehensible.
-Nay, even that which is commonly regarded as the negation of all
-Religion—even positive Atheism, comes within the definition; for it,
-too, in asserting the self-existence of Space, Matter, and Motion, which
-it regards as adequate causes of every appearance, propounds an _à
-priori_ theory from which it holds the facts to be deducible. Now every
-theory tacitly asserts two things: firstly, that there is something to
-be explained; secondly, that such and such is the explanation. Hence,
-however widely different speculators may disagree in the solutions they
-give of the same problem; yet by implication they agree that there is a
-problem to be solved. Here then is an element which all creeds have in
-common. Religions diametrically opposed in their overt dogmas, are yet
-perfectly at one in the tacit conviction that the existence of the world
-with all it contains and all which surrounds it, is a mystery ever
-pressing for interpretation. On this point, if on no other, there is
-entire unanimity.
-
-Thus we come within sight of that which we seek. In the last chapter,
-reasons were given for inferring that human beliefs in general, and
-especially the perennial ones, contain, under whatever disguises of
-error, some soul of truth; and here we have arrived at a truth
-underlying even the grossest superstitions. We saw further that this
-soul of truth was most likely to be some constituent common to
-conflicting opinions of the same order; and here we have a constituent
-which may be claimed alike by all religions. It was pointed out that
-this soul of truth would almost certainly be more abstract than any of
-the beliefs involving it; and the truth we have arrived at is one
-exceeding in abstractness the most abstract religious doctrines. In
-every respect, therefore, our conclusion answers to the requirements. It
-has all the characteristics which we inferred must belong to that
-fundamental verity expressed by religions in general.
-
-That this is the vital element in all religions is further proved by the
-fact, that it is the element which not only survives every change, but
-grows more distinct the more highly the religion is developed.
-Aboriginal creeds, though pervaded by the idea of personal agencies
-which are usually unseen, yet conceive these agencies under perfectly
-concrete and ordinary forms—class them with the visible agencies of men
-and animals; and so hide a vague perception of mystery in disguises as
-unmysterious as possible. The Polytheistic conceptions in their advanced
-phases, represent the presiding personalities in greatly idealized
-shapes, existing in a remote region, working in subtle ways, and
-communicating with men by omens or through inspired persons; that is,
-the ultimate causes of things are regarded as less familiar and
-comprehensible. The growth of a Monotheistic faith, accompanied as it is
-by a denial of those beliefs in which the divine nature is assimilated
-to the human in all its lower propensities, shows us a further step in
-the same direction; and however imperfectly this higher faith is at
-first realized, we yet see in altars “to the unknown and unknowable
-God,” and in the worship of a God that cannot by any searching be found
-out, that there is a clearer recognition of the inscrutableness of
-creation. Further developments of theology, ending in such assertions as
-that “a God understood would be no God at all,” and “to think that God
-is, as we can think him to be, is blasphemy,” exhibit this recognition
-still more distinctly; and it pervades all the cultivated theology of
-the present day. Thus while other constituents of religious creeds one
-by one drop away, this remains and grows even more manifest; and so is
-shown to be the essential constituent.
-
-Nor does the evidence end here. Not only is the omnipresence of
-something which passes comprehension, that most abstract belief which is
-common to all religions, which becomes the more distinct in proportion
-as they develope, and which remains after their discordant elements have
-been mutually cancelled; but it is that belief which the most unsparing
-criticism of each leaves unquestionable—or rather makes ever clearer. It
-has nothing to fear from the most inexorable logic; but on the contrary
-is a belief which the most inexorable logic shows to be more profoundly
-true than any religion supposes. For every religion, setting out though
-it does with the tacit assertion of a mystery, forthwith proceeds to
-give some solution of this mystery; and so asserts that it is not a
-mystery passing human comprehension. But an examination of the solutions
-they severally propound, shows them to be uniformly invalid. The
-analysis of every possible hypothesis proves, not simply that no
-hypothesis is sufficient, but that no hypothesis is even thinkable. And
-thus the mystery which all religions recognize, turns out to be a far
-more transcendent mystery than any of them suspect—not a relative, but
-an absolute mystery.
-
-Here, then, is an ultimate religious truth of the highest possible
-certainty—a truth in which religions in general are at one with each
-other, and with a philosophy antagonistic to their special dogmas. And
-this truth, respecting which there is a latent agreement among all
-mankind from the fetish-worshipper to the most stoical critic of human
-creeds, must be the one we seek. If Religion and Science are to be
-reconciled, the basis of reconciliation must be this deepest, widest,
-and most certain of all facts—that the Power which the Universe
-manifests to us is utterly inscrutable.
-
------
-
-Footnote 6:
-
- Those who may have before met with this term, will perceive that it is
- here used in quite a different sense.
-
-
-
-
- CHAPTER III.
- ULTIMATE SCIENTIFIC IDEAS.
-
-
-§ 15. What are Space and Time? Two hypotheses are current respecting
-them: the one that they are objective, and the other that they are
-subjective—the one that they are external to, and independent of,
-ourselves, the other that they are internal, and appertain to our own
-consciousness. Let us see what becomes of these hypotheses under
-analysis.
-
-To say that Space and Time exist objectively, is to say that they are
-entities. The assertion that they are non-entities is self-destructive:
-non-entities are non-existences; and to allege that non-existences exist
-objectively, is a contradiction in terms. Moreover, to deny that Space
-and Time are things, and so by implication to call them nothings,
-involves the absurdity that there are two kinds of nothing. Neither can
-they be regarded as attributes of some entity; seeing, not only that it
-is impossible really to conceive any entity of which they are
-attributes, but seeing further that we cannot think of them as
-disappearing, even if everything else disappeared; whereas attributes
-necessarily disappear along with the entities they belong to. Thus as
-Space and Time cannot be either non-entities, nor the attributes of
-entities, we have no choice but consider them as entities. But
-while, on the hypothesis of their objectivity, Space and Time must be
-classed as things, we find, on experiment, that to represent them in
-thought as things is impossible. To be conceived at all, a thing must be
-conceived as having attributes. We can distinguish something from
-nothing, only by the power which the something has to act on our
-consciousness; the several affections it produces on our consciousness
-(or else the hypothetical causes of them), we attribute to it, and call
-its attributes; and the absence of these attributes is the absence of
-the terms in which the something is conceived, and involves the absence
-of a conception. What now are the attributes of Space? The only one
-which it is possible for a moment to think of as belonging to it, is
-that of extension; and to credit it with this implies a confusion of
-thought. For extension and Space are convertible terms: by extension, as
-we ascribe it to surrounding objects, we mean occupancy of Space; and
-thus to say that Space is extended, is to say that Space occupies Space.
-How we are similarly unable to assign any attribute to Time, scarcely
-needs pointing out. Nor are Time and Space unthinkable as entities
-only from the absence of attributes; there is another peculiarity,
-familiar to readers of metaphysics, which equally excludes them from the
-category. All entities which we actually know as such, are limited; and
-even if we suppose ourselves either to know or to be able to conceive
-some unlimited entity, we of necessity in so classing it positively
-separate it from the class of limited entities. But of Space and Time we
-cannot assert either limitation or the absence of limitation. We find
-ourselves totally unable to form any mental image of unbounded Space;
-and yet totally unable to imagine bounds beyond which there is no Space.
-Similarly at the other extreme: it is impossible to think of a limit to
-the divisibility of Space; yet equally impossible to think of its
-infinite divisibility. And, without stating them, it will be seen that
-we labour under like impotencies in respect to Time. Thus we
-cannot conceive Space and Time as entities, and are equally disabled
-from conceiving them as either the attributes of entities or as
-non-entities. We are compelled to think of them as existing; and yet
-cannot bring them within those conditions under which existences are
-represented in thought.
-
-Shall we then take refuge in the Kantian doctrine? shall we say that
-Space and Time are forms of the intellect,—“_à priori_ laws or
-conditions of the conscious mind”? To do this is to escape from great
-difficulties by rushing into greater. The proposition with which Kant’s
-philosophy sets out, verbally intelligible though it is, cannot by any
-effort be rendered into thought—cannot be interpreted into an idea
-properly so called, but stands merely for a pseud-idea. In the
-first place, to assert that Space and Time, as we are conscious of them,
-are subjective conditions, is by implication to assert that they are not
-objective realities: if the Space and Time present to our minds belong
-to the _ego_, then of necessity they do not belong to the _non-ego_. Now
-it is absolutely impossible to think this. The very fact on which Kant
-bases his hypothesis—namely that our consciousness of Space and Time
-cannot be suppressed—testifies as much; for that consciousness of Space
-and Time which we cannot rid ourselves of, is the consciousness of them
-as existing objectively. It is useless to reply that such an inability
-must inevitably result if they are subjective forms. The question here
-is—What does consciousness directly testify? And the direct testimony of
-consciousness is, that Time and Space are not within but without the
-mind; and so absolutely independent of it that they cannot be conceived
-to become non-existent even were the mind to become non-existent.
- Besides being positively unthinkable in what it tacitly denies,
-the theory of Kant is equally unthinkable in what it openly affirms. It
-is not simply that we cannot combine the thought of Space with the
-thought of our own personality, and contemplate the one as a property of
-the other—though our inability to do this would prove the
-inconceivableness of the hypothesis—but it is that the hypothesis
-carries in itself the proof of its own inconceivableness. For if Space
-and Time are forms of thought, they can never be thought of; since it is
-impossible for anything to be at once the _form_ of thought and the
-_matter_ of thought. That Space and Time are objects of consciousness,
-Kant emphatically asserts by saying that it is impossible to suppress
-the consciousness of them. How then, if they are _objects_ of
-consciousness, can they at the same time be _conditions_ of
-consciousness? If Space and Time are the conditions under which we
-think, then when we think of Space and Time themselves, our thoughts
-must be unconditioned; and if there can thus be unconditioned thoughts,
-what becomes of the theory?
-
-It results therefore that Space and Time are wholly incomprehensible.
-The immediate knowledge which we seem to have of them, proves, when
-examined, to be total ignorance. While our belief in their objective
-reality is insurmountable, we are unable to give any rational account of
-it. And to posit the alternative belief (possible to state but
-impossible to realize) is merely to multiply irrationalities.
-
- * * * * *
-
-§ 16. Were it not for the necessities of the argument, it would be
-inexcusable to occupy the reader’s attention with the threadbare, and
-yet unended, controversy respecting the divisibility of matter. Matter
-is either infinitely divisible or it is not: no third possibility can be
-named. Which of the alternatives shall we accept? If we say that Matter
-is infinitely divisible, we commit ourselves to a supposition not
-realizable in thought. We can bisect and re-bisect a body, and
-continually repeating the act until we reduce its parts to a size no
-longer physically divisible, may then mentally continue the process
-without limit. To do this, however, is not really to conceive the
-infinite divisibility of matter, but to form a symbolic conception
-incapable of expansion into a real one, and not admitting of other
-verification. Really to conceive the infinite divisibility of matter, is
-mentally to follow out the divisions to infinity; and to do this would
-require infinite time. On the other hand, to assert that matter is not
-infinitely divisible, is to assert that it is reducible to parts which
-no conceivable power can divide; and this verbal supposition can no more
-be represented in thought than the other. For each of such ultimate
-parts, did they exist, must have an under and an upper surface, a right
-and a left side, like any larger fragment. Now it is impossible to
-imagine its sides so near that no plane of section can be conceived
-between them; and however great be the assumed force of cohesion, it is
-impossible to shut out the idea of a greater force capable of overcoming
-it. So that to human intelligence the one hypothesis is no more
-acceptable than the other; and yet the conclusion that one or other must
-agree with the fact, seems to human intelligence unavoidable.
-
-Again, leaving this insoluble question, let us ask whether substance
-has, in reality, anything like that extended solidity which it presents
-to our consciousness. The portion of space occupied by a piece of metal,
-seems to eyes and fingers perfectly filled: we perceive a homogeneous,
-resisting mass, without any breach of continuity. Shall we then say that
-Matter is as actually solid as it appears? Shall we say that whether it
-consists of an infinitely divisible element or of ultimate units
-incapable of further division, its parts are everywhere in actual
-contact? To assert as much entangles us in insuperable difficulties.
-Were Matter thus absolutely solid, it would be, what it is
-not—absolutely incompressible; since compressibility, implying the
-nearer approach of constituent parts, is not thinkable unless there is
-unoccupied space between the parts. Nor is this all. It is an
-established mechanical truth, that if a body, moving at a given
-velocity, strikes an equal body at rest in such wise that the two move
-on together, their joint velocity will be but half that of the striking
-body. Now it is a law of which the negation is inconceivable, that in
-passing from any one degree of magnitude to any other, all intermediate
-degrees must be passed through. Or, in the case before us, a body moving
-at velocity 4, cannot, by collision, be reduced to velocity 2, without
-passing through all velocities between 4 and 2. But were Matter truly
-solid—were its units absolutely incompressible and in absolute
-contact—this “law of continuity,” as it is called, would be broken in
-every case of collision. For when, of two such units, one moving at
-velocity 4 strikes another at rest, the striking unit must have its
-velocity 4 instantaneously reduced to velocity 2; must pass from
-velocity 4 to velocity 2 without any lapse of time, and without passing
-through intermediate velocities; must be moving with velocities 4 and 2
-at the same instant, which is impossible.
-
-The supposition that Matter is absolutely solid being untenable, there
-presents itself the Newtonian supposition, that it consists of solid
-atoms not in contact but acting on each other by attractive and
-repulsive forces, varying with the distances. To assume this, however,
-merely shifts the difficulty: the problem is simply transferred from the
-aggregated masses of matter to these hypothetical atoms. For granting
-that Matter, as we perceive it, is made up of such dense extended units
-surrounded by atmospheres of force, the question still arises—What is
-the constitution of these units? We have no alternative but to regard
-each of them as a small piece of matter. Looked at through a mental
-microscope, each becomes a mass of substance such as we have just been
-contemplating. Exactly the same inquiries may be made respecting the
-parts of which each atom consists; while exactly the same difficulties
-stand in the way of every answer. And manifestly, even were the
-hypothetical atom assumed to consist of still minuter ones, the
-difficulty would re-appear at the next step; nor could it be got rid of
-even by an infinite series of such assumptions.
-
-Boscovich’s conception yet remains to us. Seeing that Matter could not,
-as Leibnitz suggested, be composed of unextended monads (since the
-juxtaposition of an infinity of points having no extension, could not
-produce that extension which matter possesses); and perceiving
-objections to the view entertained by Newton; Boscovich proposed an
-intermediate theory, uniting, as he considered, the advantages of both
-and avoiding their difficulties. His theory is, that the constituents of
-Matter are centres of force—points without dimensions, which attract and
-repel each other in suchwise as to be kept at specific distances apart.
-And he argues, mathematically, that the forces possessed by such centres
-might so vary with the distances, that under given conditions the
-centres would remain in stable equilibrium with definite interspaces;
-and yet, under other conditions, would maintain larger or smaller
-interspaces. This speculation however, ingeniously as it is elaborated,
-and eluding though it does various difficulties, posits a proposition
-which cannot by any effort be represented in thought: it escapes all the
-inconceivabilities above indicated, by merging them in the one
-inconceivability with which it sets out. A centre of force absolutely
-without extension is unthinkable: answering to these words we can form
-nothing more than a symbolic conception of the illegitimate order. The
-idea of resistance cannot be separated in thought from the idea of an
-extended body which offers resistance. To suppose that central forces
-can reside in points not infinitesimally small but occupying no space
-whatever—points having position only, with nothing to mark their
-position—points in no respect distinguishable from the surrounding
-points that are not centres of force;—to suppose this, is utterly beyond
-human power.
-
-Here it may possibly be said, that though all hypotheses respecting the
-constitution of Matter commit us to inconceivable conclusions when
-logically developed, yet we have reason to think that one of them
-corresponds with the fact. Though the conception of Matter as consisting
-of dense indivisible units, is symbolic and incapable of being
-completely thought out, it may yet be supposed to find indirect
-verification in the truths of chemistry. These, it is argued,
-necessitate the belief that Matter consists of particles of specific
-weights, and therefore of specific sizes. The general law of definite
-proportions seems impossible on any other condition than the existence
-of ultimate atoms; and though the combining weights of the respective
-elements are termed by chemists their “equivalents,” for the purpose of
-avoiding a questionable assumption, we are unable to think of the
-combination of such definite weights, without supposing it to take place
-between definite numbers of definite particles. And thus it would appear
-that the Newtonian view is at any rate preferable to that of Boscovich.
- A disciple of Boscovich, however, may reply that his master’s
-theory is involved in that of Newton; and cannot indeed be escaped.
-“What,” he may ask, “is it that holds together the parts of these
-ultimate atoms?”. “A cohesive force,” his opponent must answer. “And
-what,” he may continue, “is it that holds together the parts of any
-fragments into which, by sufficient force, an ultimate atom might be
-broken?” Again the answer must be—a cohesive force. “And what,” he may
-still ask, “if the ultimate atom were, as we can imagine it to be,
-reduced to parts as small in proportion to it, as it is in proportion to
-a tangible mass of matter—what must give each part the ability to
-sustain itself, and to occupy space?” Still there is no answer but—a
-cohesive force. Carry the process in thought as far as we may, until the
-extension of the parts is less than can be imagined, we still cannot
-escape the admission of forces by which the extension is upheld; and we
-can find no limit until we arrive at the conception of centres of force
-without any extension.
-
-Matter then, in its ultimate nature, is as absolutely incomprehensible
-as Space and Time. Frame what suppositions we may, we find on tracing
-out their implications that they leave us nothing but a choice between
-opposite absurdities.
-
- * * * * *
-
-§ 17. A body impelled by the hand is clearly perceived to move, and to
-move in a definite direction: there seems at first sight no possibility
-of doubting that its motion is real, or that it is towards a given
-point. Yet it is easy to show that we not only may be, but usually are,
-quite wrong in both these judgments. Here, for instance, is a ship
-which, for simplicity’s sake, we will suppose to be anchored at the
-equator with her head to the West. When the captain walks from stem to
-stern, in what direction does he move? East is the obvious answer—an
-answer which for the moment may pass without criticism. But now the
-anchor is heaved, and the vessel sails to the West with a velocity equal
-to that at which the captain walks. In what direction does he now move
-when he goes from stem to stern? You cannot say East, for the vessel is
-carrying him as fast towards the West as he walks to the East; and you
-cannot say West for the converse reason. In respect to surrounding space
-he is stationary; though to all on board the ship he seems to be moving.
-But now are we quite sure of this conclusion?—Is he really stationary?
-When we take into account the Earth’s motion round its axis, we find
-that instead of being stationary he is travelling at the rate of 1000
-miles per hour to the East; so that neither the perception of one who
-looks at him, nor the inference of one who allows for the ship’s motion,
-is anything like the truth. Nor indeed, on further consideration, shall
-we find this revised conclusion to be much better. For we have forgotten
-to allow for the Earth’s motion in its orbit. This being some 68,000
-miles per hour, it follows that, assuming the time to be midday, he is
-moving, not at the rate of 1000 miles per hour to the East, but at the
-rate of 67,000 miles per hour to the West. Nay, not even now have we
-discovered the true rate and the true direction of his movement. With
-the Earth’s progress in its orbit, we have to join that of the whole
-Solar system towards the constellation Hercules; and when we do this, we
-perceive that he is moving neither East nor West, but in a line inclined
-to the plane of the Ecliptic, and at a velocity greater or less
-(according to the time of the year) than that above named. To which let
-us add, that were the dynamic arrangements of our sidereal system fully
-known to us, we should probably discover the direction and rate of his
-actual movement to differ considerably even from these. How
-illusive are our ideas of Motion, is thus made sufficiently manifest.
-That which seems moving proves to be stationary; that which seems
-stationary proves to be moving; while that which we conclude to be going
-rapidly in one direction, turns out to be going much more rapidly in the
-opposite direction. And so we are taught that what we are conscious of
-is not the real motion of any object, either in its rate or direction;
-but merely its motion as measured from an assigned position—either the
-position we ourselves occupy or some other. Yet in this very process of
-concluding that the motions we perceive are not the real motions, we
-tacitly assume that there are real motions. In revising our successive
-judgments concerning a body’s course or velocity, we take for granted
-that there is an actual course and an actual velocity—we take for
-granted that there are fixed points in space with respect to which all
-motions are absolute; and we find it impossible to rid ourselves of this
-idea. Nevertheless, absolute motion cannot even be imagined, much less
-known. Motion as taking place apart from those limitations of space
-which we habitually associate with it, is totally unthinkable. For
-motion is change of place; but in unlimited space, change of place is
-inconceivable, because place itself is inconceivable. Place can be
-conceived only by reference to other places; and in the absence of
-objects dispersed through space, a place could be conceived only in
-relation to the limits of space; whence it follows that in unlimited
-space, place cannot be conceived—all places must be equidistant from
-boundaries that do not exist. Thus while we are obliged to think that
-there is an absolute motion, we find absolute motion incomprehensible.
-
-Another insuperable difficulty presents itself when we contemplate the
-transfer of Motion. Habit blinds us to the marvelousness of this
-phenomenon. Familiar with the fact from childhood, we see nothing
-remarkable in the ability of a moving thing to generate movement in a
-thing that is stationary. It is, however, impossible to understand it.
-In what respect does a body after impact differ from itself before
-impact? What is this added to it which does not sensibly affect any of
-its properties and yet enables it to traverse space? Here is an object
-at rest and here is the same object moving. In the one state it has no
-tendency to change its place; but in the other it is obliged at each
-instant to assume a new position. What is it which will for ever go on
-producing this effect without being exhausted? and how does it dwell in
-the object? The motion you say has been communicated. But how?—What has
-been communicated? The striking body has not transferred a _thing_ to
-the body struck; and it is equally out of the question to say that it
-has transferred an _attribute_. What then has it transferred?
-
-Once more there is the old puzzle concerning the connexion between
-Motion and Rest. We daily witness the gradual retardation and final
-stoppage of things projected from the hand or otherwise impelled; and we
-equally often witness the change from Rest to Motion produced by the
-application of force. But truly to represent these transitions in
-thought, we find impossible. For a breach of the law of continuity seems
-necessarily involved; and yet no breach of it is conceivable. A body
-travelling at a given velocity cannot be brought to a state of rest, or
-no velocity, without passing through all intermediate velocities. At
-first sight nothing seems easier than to imagine it doing this. It is
-quite possible to think of its motion as diminishing insensibly until it
-becomes infinitesimal; and many will think equally possible to pass in
-thought from infinitesimal motion to no motion. But this is an error.
-Mentally follow out the decreasing velocity as long as you please, and
-there still remains _some_ velocity. Halve and again halve the rate of
-movement for ever, yet movement still exists; and the smallest movement
-is separated by an impassable gap from no movement. As something,
-however minute, is infinitely great in comparison with nothing; so is
-even the least conceivable motion, infinite as compared with rest.
- The converse perplexities attendant on the transition from Rest to
-Motion, need not be specified. These, equally with the foregoing, show
-us that though we are obliged to think of such changes as actually
-occurring, their occurrence cannot be realized.
-
-Thus neither when considered in connexion with Space, nor when
-considered in connexion with Matter, nor when considered in connexion
-with Rest, do we find that Motion is truly cognizable. All efforts to
-understand its essential nature do but bring us to alternative
-impossibilities of thought.
-
- * * * * *
-
-§ 18. On lifting a chair, the force exerted we regard as equal to that
-antagonistic force called the weight of the chair; and we cannot think
-of these as equal without thinking of them as like in kind; since
-equality is conceivable only between things that are connatural. The
-axiom that action and reaction are equal and in opposite directions,
-commonly exemplified by this very instance of muscular effort _versus_
-weight, cannot be mentally realized on any other condition. Yet,
-contrariwise, it is incredible that the force as existing in the chair
-really resembles the force as present to our minds. It scarcely needs to
-point out that the weight of the chair produces in us various feelings
-according as we support it by a single finger, or the whole hand, or the
-leg; and hence to argue that as it cannot be like all these sensations
-there is no reason to believe it like any. It suffices to remark that
-since the force as known to us is an affection of consciousness, we
-cannot conceive the force existing in the chair under the same form
-without endowing the chair with consciousness. So that it is absurd to
-think of Force as in itself like our sensation of it, and yet necessary
-so to think of it if we realize it in consciousness at all.
-
-How, again, can we understand the connexion between Force and Matter?
-Matter is known to us only through its manifestations of Force: our
-ultimate test of Matter is the ability to resist: abstract its
-resistance and there remains nothing but empty extension. Yet, on the
-other hand, resistance is equally unthinkable apart from Matter—apart
-from something extended. Not only, as pointed out some pages back, are
-centres of force devoid of extension unimaginable; but, as an inevitable
-corollary, we cannot imagine either extended or unextended centres of
-force to attract and repel other such centres at a distance, without the
-intermediation of some kind of matter. We have here to remark, what
-could not without anticipation be remarked when treating of Matter, that
-the hypothesis of Newton, equally with that of Boscovich, is open to the
-charge that it supposes one thing to act upon another through a space
-which is absolutely empty—a supposition which cannot be represented in
-thought. This charge is indeed met by the introduction of a hypothetical
-fluid existing between the atoms or centres. But the problem is not thus
-solved: it is simply shifted, and re-appears when the constitution of
-this fluid is inquired into. How impossible it is to elude the
-difficulty presented by the transfer of Force through space, is best
-seen in the case of astronomical forces. The Sim acts upon us in such
-way as to produce the sensations of light and heat; and we have
-ascertained that between the cause as existing in the Sun, and the
-effect as experienced on the Earth, a lapse of about eight minutes
-occurs: whence unavoidably result in us, the conceptions of both a force
-and a motion. So that for the assumption of a luminiferous ether, there
-is the defence, not only that the exercise of force through 95,000,000
-of miles of absolute vacuum is inconceivable, but also that it is
-impossible to conceive motion in the absence of something moved.
-Similarly in the case of gravitation. Newton described himself as unable
-to think that the attraction of one body for another at a distance,
-could be exerted in the absence of an intervening medium. But now let us
-ask how much the forwarder we are if an intervening medium be assumed.
-This ether whose undulations according to the received hypothesis
-constitute heat and light, and which is the vehicle of gravitation—how
-is it constituted? We must regard it, in the way that physicists do
-regard it, as composed of atoms which attract and repel each
-other—infinitesimal it may be in comparison with those of ordinary
-matter, but still atoms. And remembering that this ether is
-imponderable, we are obliged to conclude that the ratio between the
-interspaces of these atoms and the atoms themselves, is incommensurably
-greater than the like ratio in ponderable matter; else the densities
-could not be incommensurable. Instead then of a direct action by the Sun
-upon the Earth without anything intervening, we have to conceive the
-Sun’s action propagated through a medium whose molecules are probably as
-small relatively to their interspaces as are the Sun and Earth compared
-with the space between them: we have to conceive these infinitesimal
-molecules acting on each other through absolutely vacant spaces which
-are immense in comparison with their own dimensions. How is this
-conception easier than the other? We still have mentally to represent a
-body as acting where it is not, and in the absence of anything by which
-its action may be transferred; and what matters it whether this takes
-place on a large or a small scale? We see therefore that the
-exercise of Force is altogether unintelligible. We cannot imagine it
-except through the instrumentality of something having extension; and
-yet when we have assumed this something, we find the perplexity is not
-got rid of but only postponed. We are obliged to conclude that matter,
-whether ponderable or imponderable, and whether aggregated or in its
-hypothetical units, acts upon matter through absolutely vacant space;
-and yet this conclusion is positively unthinkable.
-
-Again, Light, Heat, Gravitation and all central forces, vary inversely
-as the squares of the distances; and physicists in their investigations
-assume that the units of matter act upon each other according to the
-same law—an assumption which indeed they are obliged to make; since this
-law is not simply an empirical one, but one deducible mathematically
-from the relations of space—one of which the negation is inconceivable.
-But now, in any mass of matter which is in internal equilibrium, what
-must follow? The attractions and repulsions of the constituent atoms are
-balanced. Being balanced, the atoms remain at their present distances;
-and the mass of matter neither expands nor contracts. But if the forces
-with which two adjacent atoms attract and repel each other both vary
-inversely as the squares of the distances, as they must; and if they are
-in equilibrium at their present distances, as they are; then,
-necessarily, they will be in equilibrium at all other distances. Let the
-atoms be twice as far apart, and their attractions and repulsions will
-both be reduced to one fourth of their present amounts. Let them be
-brought within half the distance, and their attractions and repulsions
-will both be quadrupled. Whence it follows that this matter will as
-readily as not assume any other density; and can offer no resistance to
-any external agents. Thus we are obliged to say that these antagonist
-molecular forces do not both vary inversely as the squares of the
-distances, which is unthinkable; or else that matter does not possess
-that attribute of resistance by which alone we distinguish it from empty
-space, which is absurd.
-
-While then it is impossible to form any idea of Force in itself, it is
-equally impossible to comprehend either its mode of exercise or its law
-of variation.
-
- * * * * *
-
-§ 19. Turning now from the outer to the inner world, let us contemplate,
-not the agencies to which we ascribe our subjective modifications, but
-the subjective modifications themselves. These constitute a series.
-Difficult as we find it distinctly to separate and individualize them,
-it is nevertheless beyond question that our states of consciousness
-occur in succession.
-
-Is this chain of states of consciousness infinite or finite? We cannot
-say infinite; not only because we have indirectly reached the conclusion
-that there was a period when it commenced, but also because all infinity
-is inconceivable—an infinite series included. We cannot say finite; for
-we have no knowledge of either of its ends. Go back in memory as far as
-we may, we are wholly unable to identify our first states of
-consciousness: the perspective of our thoughts vanishes in a dim
-obscurity where we can make out nothing. Similarly at the other extreme.
-We have no immediate knowledge of a termination to the series at a
-future time; and we cannot really lay hold of that temporary termination
-of the series reached at the present moment. For the state of
-consciousness recognized by us as our last, is not truly our last. That
-any mental affection may be contemplated as one of the series, it must
-be remembered—_represented_ in thought, not _presented_. The truly last
-state of consciousness is that which is passing in the very act of
-contemplating a state just past—that in which we are thinking of the one
-before as the last. So that the proximate end of the chain eludes us, as
-well as the remote end.
-
-“But,” it may be said, “though we cannot directly _know_ consciousness
-to be finite in duration, because neither of its limits can be actually
-reached; yet we can very well _conceive_ it to be so.” No: not even this
-is true. In the first place, we cannot _con_ceive the terminations of
-that consciousness which alone we really know—our own—any more than we
-can _per_ceive its terminations. For in truth the two acts are here one.
-In either case such terminations must be, as above said, not presented
-in thought, but represented; and they must be represented as in the act
-of occurring. Now to represent the termination of consciousness as
-occurring in ourselves, is to think of ourselves as contemplating the
-cessation of the last state of consciousness; and this implies a
-supposed continuance of consciousness after its last state, which is
-absurd. In the second place, if we regard the matter objectively—if we
-study the phenomena as occurring in others, or in the abstract, we are
-equally foiled. Consciousness implies perpetual change and the perpetual
-establishment of relations between its successive phases. To be known at
-all, any mental affection must be known as such or such—as like these
-foregoing ones or unlike those: if it is not thought of in connexion
-with others—not distinguished or identified by comparison with others,
-it is not recognized—is not a state of consciousness at all. A last
-state of consciousness, then, like any other, can exist only through a
-perception of its relations to previous states. But such perception of
-its relations must constitute a state later than the last, which is a
-contradiction. Or to put the difficulty in another form:—If ceaseless
-change of state is the condition on which alone consciousness exists,
-then when the supposed last state has been reached by the completion of
-the preceding change, change has ceased; therefore consciousness has
-ceased; therefore the supposed last state is not a state of
-consciousness at all; therefore there can be no last state of
-consciousness. In short, the perplexity is like that presented by the
-relations of Motion and Rest. As we found it was impossible really to
-conceive Rest becoming Motion or Motion becoming Rest; so here we find
-it is impossible really to conceive either the beginning or the ending
-of those changes which constitute consciousness.
-
-Hence, while we are unable either to believe or to conceive that the
-duration of consciousness is infinite, we are equally unable either to
-know it as finite, or to conceive it as finite.
-
- * * * * *
-
-§ 20. Nor do we meet with any greater success when, instead of the
-extent of consciousness, we consider its substance. The question—What is
-this that thinks? admits of no better solution than the question to
-which we have just found none but inconceivable answers.
-
-The existence of each individual as known to himself, has been always
-held by mankind at large, the most incontrovertible of truths. To say—“I
-am as sure of it as I am sure that I exist,” is, in common speech, the
-most emphatic expression of certainty. And this fact of personal
-existence, testified to by the universal consciousness of men, has been
-made the basis of sundry philosophies; whence may be drawn the
-inference, that it is held by thinkers, as well as by the vulgar, to be
-beyond all facts unquestionable.
-
-Belief in the reality of self, is, indeed, a belief which no hypothesis
-enables us to escape. What shall we say of these successive impressions
-and ideas which constitute consciousness? Shall we say that they are the
-affections of something called mind, which, as being the subject of
-them, is the real _ego_? If we say this, we manifestly imply that the
-_ego_ is an entity. Shall we assert that these impressions and ideas are
-not the mere superficial changes wrought on some thinking substance, but
-are themselves the very body of this substance—are severally the
-modified forms which it from moment to moment assumes? This hypothesis,
-equally with the foregoing, implies that the individual exists as a
-permanent and distinct being; since modifications necessarily involve
-something modified. Shall we then betake ourselves to the sceptic’s
-position, and argue that we know nothing more than our impressions and
-ideas themselves—that these are to us the only existences; and that the
-personality said to underlie them is a mere fiction? We do not even thus
-escape; since this proposition, verbally intelligible but really
-unthinkable, itself makes the assumption which it professes to
-repudiate. For how can consciousness be wholly resolved into impressions
-and ideas, when an impression of necessity implies something impressed?
-Or again, how can the sceptic who has decomposed his consciousness into
-impressions and ideas, explain the fact that he considers them as _his_
-impressions and ideas? Or once more, if, as he must, he admits that he
-has an impression of his personal existence, what warrant can he show
-for rejecting this impression as unreal while he accepts all his other
-impressions as real? Unless he can give satisfactory answers to these
-queries, which he cannot, he must abandon his conclusions; and must
-admit the reality of the individual mind.
-
-But now, unavoidable as is this belief—established though it is, not
-only by the assent of mankind at large, endorsed by divers philosophers,
-but by the suicide of the sceptical argument—it is yet a belief
-admitting of no justification by reason: nay, indeed, it is a belief
-which reason, when pressed for a distinct answer, rejects. One of the
-most recent writers who has touched upon this question—Mr Mansel—does
-indeed contend that in the consciousness of self, we have a piece of
-real knowledge. The validity of immediate intuition he holds in this
-case unquestionable: remarking that “let system-makers say what they
-will, the unsophisticated sense of mankind refuses to acknowledge that
-mind is but a bundle of states of consciousness, as matter is (possibly)
-a bundle of sensible qualities.” On which position the obvious comment
-is, that it does not seem altogether a consistent one for a Kantist, who
-pays but small respect to “the unsophisticated sense of mankind” when it
-testifies to the objectivity of space. Passing over this, however, it
-may readily be shown that a cognition of self, properly so called, is
-absolutely negatived by the laws of thought. The fundamental condition
-to all consciousness, emphatically insisted upon by Mr Mansel in common
-with Sir William Hamilton and others, is the antithesis of subject and
-object. And on this “primitive dualism of consciousness,” “from which
-the explanations of philosophy must take their start,” Mr Mansel founds
-his refutation of the German absolutists. But now, what is the corollary
-from this doctrine, as bearing on the consciousness of self? The mental
-act in which self is known, implies, like every other mental act, a
-perceiving subject and a perceived object. If, then, the object
-perceived is self, what is the subject that perceives? or if it is the
-true self which thinks, what other self can it be that is thought of?
-Clearly, a true cognition of self implies a state in which the knowing
-and the known are one—in which subject and object are identified; and
-this Mr Mansel rightly holds to be the annihilation of both.
-
-So that the personality of which each is conscious, and of which the
-existence is to each a fact beyond all others the most certain, is yet a
-thing which cannot truly be known at all: knowledge of it is forbidden
-by the very nature of thought.
-
- * * * * *
-
-§ 21. Ultimate Scientific Ideas, then, are all representative of
-realities that cannot be comprehended. After no matter how great a
-progress in the colligation of facts and the establishment of
-generalizations ever wider and wider—after the merging of limited and
-derivative truths in truths that are larger and deeper has been carried
-no matter how far; the fundamental truth remains as much beyond reach as
-ever. The explanation of that which is explicable, does but bring out
-into greater clearness the inexplicableness of that which remains
-behind. Alike in the external and the internal worlds, the man of
-science sees himself in the midst of perpetual changes of which he can
-discover neither the beginning nor the end. If, tracing back the
-evolution of things, he allows himself to entertain the hypothesis that
-the Universe once existed in a diffused form, he finds it utterly
-impossible to conceive how this came to be so; and equally, if he
-speculates on the future, he can assign no limit to the grand succession
-of phenomena ever unfolding themselves before him. In like manner if he
-looks inward, he perceives that both ends of the thread of consciousness
-are beyond his grasp; nay, even beyond his power to think of as having
-existed or as existing in time to come. When, again, he turns from the
-succession of phenomena, external or internal, to their intrinsic
-nature, he is just as much at fault. Supposing him in every case able to
-resolve the appearances, properties, and movements of things, into
-manifestations of Force in Space and Time; he still finds that Force,
-Space, and Time pass all understanding. Similarly, though the analysis
-of mental actions may finally bring him down to sensations, as the
-original materials out of which all thought is woven, yet he is little
-forwarder; for he can give no account either of sensations themselves or
-of that something which is conscious of sensations. Objective and
-subjective things he thus ascertains to be alike inscrutable in their
-substance and genesis. In all directions his investigations eventually
-bring him face to face with an insoluble enigma; and he ever more
-clearly perceives it to be an insoluble enigma. He learns at once the
-greatness and the littleness of the human intellect—its power in dealing
-with all that comes within the range of experience; its impotence in
-dealing with all that transcends experience. He realizes with a special
-vividness the utter incomprehensibleness of the simplest fact,
-considered in itself. He, more than any other, truly _knows_ that in its
-ultimate essence nothing can be known.
-
-
-
-
- CHAPTER IV.
- THE RELATIVITY OF ALL KNOWLEDGE.
-
-
-§ 22. The same conclusion is thus arrived at, from whichever point we
-set out. If, respecting the origin and nature of things, we make some
-assumption, we find that through an inexorable logic it inevitably
-commits us to alternative impossibilities of thought; and this holds
-true of every assumption that can be imagined. If, contrariwise, we make
-no assumption, but set out from the sensible properties of surrounding
-objects, and, ascertaining their special laws of dependence, go on to
-merge these in laws more and more general, until we bring them all under
-some most general laws; we still find ourselves as far as ever from
-knowing what it is which manifests these properties to us: clearly as we
-seem to know it, our apparent knowledge proves on examination to be
-utterly irreconcilable with itself. Ultimate religious ideas and
-ultimate scientific ideas, alike turn out to be merely symbols of the
-actual, not cognitions of it.
-
-The conviction, so reached, that human intelligence is incapable of
-absolute knowledge, is one that has been slowly gaining ground as
-civilization has advanced. Each new ontological theory, from time to
-time propounded in lieu of previous ones shown to be untenable, has been
-followed by a new criticism leading to a new scepticism. All possible
-conceptions have been one by one tried and found wanting; and so the
-entire field of speculation has been gradually exhausted without
-positive result: the only result arrived at being the negative one above
-stated—that the reality existing behind all appearances is, and must
-ever be, unknown. To this conclusion almost every thinker of note has
-subscribed. “With the exception,” says Sir William Hamilton, “of a few
-late Absolutist theorisers in Germany, this is, perhaps, the truth of
-all others most harmoniously re-echoed by every philosopher of every
-school.” And among these he names—Protagoras, Aristotle, St. Augustin,
-Boethius, Averroes, Albertus Magnus, Gerson, Leo Hebræus, Melancthon,
-Scaliger, Francis Piccolomini, Giordano Bruno, Campanella, Bacon,
-Spinoza, Newton, Kant.
-
-It yet remains to point out how this belief may be established
-rationally, as well as empirically. Not only is it that, as in the
-earlier thinkers above named, a vague perception of the inscrutableness
-of things in themselves results from discovering the illusiveness of
-sense-impressions; and not only is it that, as shown in the foregoing
-chapters, definite experiments evolve alternative impossibilities of
-thought out of every ultimate conception we can frame; but it is that
-the relativity of our knowledge is demonstrable analytically. The
-induction drawn from general and special experiences, may be confirmed
-by a deduction from the nature of our intelligence. Two ways of reaching
-such a deduction exist. Proof that our cognitions are not, and never can
-be, absolute, is obtainable by analyzing either the _product_ of
-thought, or the _process_ of thought. Let us analyze each.
-
- * * * * *
-
-§ 23. If, when walking through the fields some day in September, you
-hear a rustle a few yards in advance, and on observing the ditch-side
-where it occurs, see the herbage agitated, you will probably turn
-towards the spot to learn by what this sound and motion are produced. As
-you approach there flutters into the ditch, a partridge; on seeing which
-your curiosity is satisfied—you have what you call an _explanation_ of
-the appearances. The explanation, mark, amounts to this; that whereas
-throughout life you have had countless experiences of disturbance among
-small stationary bodies, accompanying the movement of other bodies among
-them, and have generalized the relation between such disturbances and
-such movements, you consider this particular disturbance explained, on
-finding it to present, an instance of the like relation. Suppose
-you catch the partridge; and, wishing to ascertain why it did not
-escape, examine it, and find at one spot, a slight trace of blood upon
-its feathers. You now _understand_, as you say, what has disabled the
-partridge. It has been wounded by a sportsman—adds another case to the
-many cases already seen by you, of birds being killed or injured by the
-shot discharged at them from fowling-pieces. And in assimilating this
-case to other such cases, consists your understanding of it. But
-now, on consideration, a difficulty suggests itself. Only a single shot
-has struck the partridge, and that not in a vital place: the wings are
-uninjured, as are also those muscles which move them; and the creature
-proves by its struggles that it has abundant strength. Why then, you
-inquire of yourself, does it not fly? Occasion favouring, you put the
-question to an anatomist, who furnishes you with _a solution_. He points
-out that this solitary shot has passed close to the place at which the
-nerve supplying the wing-muscles of one side, diverges from the spine;
-and that a slight injury to this nerve, extending even to the rupture of
-a few fibres, may, by preventing a perfect co-ordination in the actions
-of the two wings, destroy the power of flight. You are no longer
-puzzled. But what has happened?—what has changed your state from one of
-perplexity to one of _comprehension_? Simply the disclosure of a class
-of previously known cases, along with which you can include this case.
-The connexion between lesions of the nervous system and paralysis of
-limbs has been already many times brought under your notice; and you
-here find a relation of cause and effect that is essentially similar.
-
-Let us suppose you are led on to make further inquiries concerning
-organic actions, which, conspicuous and remarkable as they are, you had
-not before cared to understand. How is respiration effected? you ask—why
-does air periodically rush into the lungs? The answer is that in the
-higher vertebrata, as in ourselves, influx of air is caused by an
-enlargement of the thoracic cavity, due, partly to depression of the
-diaphragm, partly to elevation of the ribs. But how does elevation of
-the ribs enlarge the cavity? In reply the anatomist shows you that the
-plane of each pair of ribs makes an acute angle with the spine; that
-this angle widens when the moveable ends of the ribs are raised; and he
-makes you realize the consequent dilatation of the cavity, by pointing
-out how the area of a parallelogram increases as its angles approach to
-right angles—you understand this special fact when you see it to be an
-instance of a general geometrical fact. There still arises, however, the
-question—why does the air rush into this enlarged cavity? To which comes
-the answer that, when the thoracic cavity is enlarged, the contained
-air, partially relieved from pressure, expands, and so loses some of its
-resisting power; that hence it opposes to the pressure of the external
-air a less pressure; and that as air, like every other fluid, presses
-equally in all directions, motion must result along any line in which
-the resistance is less than elsewhere; whence follows an inward current.
-And this _interpretation_ you recognize as one, when a few facts of like
-kind, exhibited more plainly in a visible fluid such as water, are cited
-in illustration. Again, when it was pointed out that the limbs are
-compound levers acting in essentially the same way as levers of iron or
-wood, you might consider yourself as having obtained a partial
-_rationale_ of animal movements. The contraction of a muscle, seeming
-before utterly unaccountable, would seem less unaccountable were you
-shown how, by a galvanic current, a series of soft iron magnets could be
-made to shorten itself, through the attraction of each magnet for its
-neighbours:—an alleged analogy which especially answers the purpose of
-our argument; since, whether real or fancied, it equally illustrates the
-mental illumination that results on finding a class of cases within
-which a particular case may possibly be included. And it may be further
-noted how, in the instance here named, an additional feeling of
-comprehension arises on remembering that the influence conveyed through
-the nerves to the muscles, is, though not positively electric, yet a
-form of force nearly allied to the electric. Similarly when you
-learn that animal heat arises from chemical combination, and so is
-evolved as heat is evolved in other chemical combinations—when you learn
-that the absorption of nutrient fluids through the coats of the
-intestines, is an instance of osmotic action—when you learn that the
-changes undergone by food during digestion, are like changes
-artificially producible in the laboratory; you regard yourself as
-_knowing_ something about the natures of these phenomena.
-
-Observe now what we have been doing. Turning to the general question,
-let us note where these successive interpretations have carried us. We
-began with quite special and concrete facts. In explaining each, and
-afterwards explaining the more general facts of which they are
-instances, we have got down to certain highly general facts:—to a
-geometrical principle or property of space, to a simple law of
-mechanical action, to a law of fluid equilibrium—to truths in physics,
-in chemistry, in thermology, in electricity. The particular phenomena
-with which we set out, have been merged in larger and larger groups of
-phenomena; and as they have been so merged, we have arrived at solutions
-that we consider profound in proportion as this process has been carried
-far. Still deeper explanations are simply further steps in the same
-direction. When, for instance, it is asked why the law of action of the
-lever is what it is, or why fluid equilibrium and fluid motion exhibit
-the relations which they do, the answer furnished by mathematicians
-consists in the disclosure of the principle of virtual velocities—a
-principle holding true alike in fluids and solids—a principle under
-which the others are comprehended. And similarly, the insight obtained
-into the phenomena of chemical combination, heat, electricity, &c.,
-implies that a rationale of them, when found, will be the exposition of
-some highly general fact respecting the constitution of matter, of which
-chemical, electrical, and thermal facts, are merely different
-manifestations.
-
-Is this process limited or unlimited? Can we go on for ever explaining
-classes of facts by including them in larger classes; or must we
-eventually come to a largest class? The supposition that the process is
-unlimited, were any one absurd enough to espouse it, would still imply
-that an ultimate explanation could not be reached; since infinite time
-would be required to reach it. While the unavoidable conclusion that it
-is limited (proved not only by the finite sphere of observation open to
-us, but also by the diminution in the number of generalizations that
-necessarily accompanies increase of their breadth) equally implies that
-the ultimate fact cannot be understood. For if the successively deeper
-interpretations of nature which constitute advancing knowledge, are
-merely successive inclusions of special truths in general truths, and of
-general truths in truths still more general; it obviously follows that
-the most general truth, not admitting of inclusion in any other, does
-not admit of interpretation. Manifestly, as the _most_ general cognition
-at which we arrive cannot be reduced to a _more_ general one, it cannot
-be understood. Of necessity, therefore, explanation must eventually
-bring us down to the inexplicable. The deepest truth which we can get
-at, must be unaccountable. Comprehension must become something other
-than comprehension, before the ultimate fact can be comprehended.
-
- * * * * *
-
-§ 24. The inference which we thus find forced upon us when we analyze
-the product of thought, as exhibited objectively in scientific
-generalizations, is equally forced upon us by an analysis of the process
-of thought, as exhibited subjectively in consciousness. The
-demonstration of the necessarily relative character of our knowledge, as
-deduced from the nature of intelligence, has been brought to its most
-definite shape by Sir William Hamilton. I cannot here do better than
-extract from his essay on the “Philosophy of the Unconditioned,” the
-passage containing the substance of his doctrine.
-
-“The mind can conceive,” he argues, “and consequently can know,” only
-the _limited, and the conditionally limited_. The unconditionally
-unlimited, or the _Infinite_, the unconditionally limited, or the
-_Absolute_, cannot positively be construed to the mind; they can be
-conceived, only by a thinking away from, or abstraction of, those very
-conditions under which thought itself is realized; consequently, the
-notion of the Unconditioned is only negative,—negative of the
-conceivable itself. For example, on the one hand we can positively
-conceive, neither an absolute whole, that is, a whole so great, that we
-cannot also conceive it as a relative part of a still greater whole; nor
-an absolute part, that is, a part so small, that we cannot also conceive
-it as a relative whole, divisible into smaller parts. On the other hand,
-we cannot positively represent, or realize, or construe to the mind (as
-here understanding and imagination coincide), an infinite whole, for
-this could only be done by the infinite synthesis in thought of finite
-wholes, which would itself require an infinite time for its
-accomplishment; nor, for the same reason, can we follow out in thought
-an infinite divisibility of parts. The result is the same, whether we
-apply the process to limitation in _space_, in _time_, or in _degree_.
-The unconditional negation, and the unconditional affirmation of
-limitation; in other words, the _infinite_ and _absolute, properly so
-called_, are thus equally inconceivable to us.
-
-As the conditionally limited (which we may briefly call the
-_conditioned_) is thus the only possible object of knowledge and of
-positive thought—thought necessarily supposes conditions. To _think_ is
-to _condition_; and conditional limitation is the fundamental law of the
-possibility of thought. For, as the greyhound cannot outstrip his
-shadow, nor (by a more appropriate simile) the eagle outsoar the
-atmosphere in which he floats, and by which alone he may be supported;
-so the mind cannot transcend that sphere of limitation, within and
-through which exclusively the possibility of thought is realized.
-Thought is only of the conditioned; because, as we have said, to think
-is simply to condition. The _absolute_ is conceived merely by a negation
-of conceivability; and all that we know, is only known as
-
- ——‘won from the void and formless _infinite_.’
-
-How, indeed, it could ever be doubted that thought is only of the
-conditioned, may well be deemed a matter of the profoundest
-admiration. Thought cannot transcend consciousness; consciousness is
-only possible under the antithesis of a subject and object of thought,
-known only in correlation, and mutually limiting each other; while,
-independently of this, all that we know either of subject or object,
-either of mind or matter, is only a knowledge in each of the
-particular, of the plural, of the different, of the modified, of the
-phenomenal. We admit that the consequence of this doctrine is,—that
-philosophy, if viewed as more than a science of the conditioned, is
-impossible. Departing from the particular, we admit, that we can
-never, in our highest generalizations, rise above the finite; that our
-knowledge, whether of mind or matter, can be nothing more than a
-knowledge of the relative manifestations of an existence, which in
-itself it is our highest wisdom to recognize as beyond the reach of
-philosophy,—in the language of St Austin,—‘_cognoscendo ignorari, et
-ignorando cognosci_.’
-
-“The conditioned is the mean between two extremes,—two inconditionates,
-exclusive of each other, neither of which _can be conceived as
-possible_, but of which, on the principles of contradiction and excluded
-middle, one _must be admitted as necessary_. On this opinion, therefore,
-reason is shown to be weak, but not deceitful. The mind is not
-represented as conceiving two propositions subversive of each other, as
-equally possible; but only, as unable to understand as possible, either
-of two extremes; one of which, however, on the ground of their mutual
-repugnance, it is compelled to recognize as true. We are thus taught the
-salutary lesson, that the capacity of thought is not to be constituted
-into the measure of existence; and are warned from recognizing the
-domain of our knowledge as necessarily co-extensive with the horizon of
-our faith. And by a wonderful revelation, we are thus, in the very
-consciousness of our inability to conceive aught above the relative and
-finite, inspired with a belief in the existence of something
-unconditioned beyond the sphere of all comprehensible reality.”
-
-Clear and conclusive as this statement of the case appears when
-carefully studied, it is expressed in so abstract a manner as to be not
-very intelligible to the general reader. A more popular presentation of
-it, with illustrative applications, as given by Mr Mansel in his “Limits
-of Religious Thought,” will make it more fully understood. The following
-extracts, which I take the liberty of making from his pages, will
-suffice.
-
-“The very conception of consciousness, in whatever mode it may be
-manifested, necessarily implies _distinction between one object and
-another_. To be conscious, we must be conscious of something; and that
-something can only be known, as that which it is, by being distinguished
-from that which it is not. But distinction is necessarily limitation;
-for, if one object is to be distinguished from another, it must possess
-some form of existence which the other has not, or it must not possess
-some form which the other has. But it is obvious the Infinite cannot be
-distinguished, as such, from the Finite, by the absence of any quality
-which the Finite possesses; for such absence would be a limitation. Nor
-yet can it be distinguished by the presence of an attribute which the
-Finite has not; for, as no finite part can be a constituent of an
-infinite whole, this differential characteristic must itself be
-infinite; and must at the same time have nothing in common with the
-finite. We are thus thrown back upon our former impossibility; for this
-second infinite will be distinguished from the finite by the absence of
-qualities which the latter possesses. A consciousness of the Infinite as
-such thus necessarily involves a self-contradiction; for it implies the
-recognition, by limitation and difference, of that which can only be
-given as unlimited and indifferent. * * *
-
-“This contradiction, which is utterly inexplicable on the supposition
-that the infinite is a positive object of human thought, is at once
-accounted for, when it is regarded as the mere negation of thought. If
-all thought is limitation;—if whatever we conceive is, by the very act
-of conception, regarded as finite,—_the infinite_, from a human point of
-view, is merely a name for the absence of those conditions under which
-thought is possible. To speak of a _Conception of the Infinite_ is,
-therefore, at once to affirm those conditions and to deny them. The
-contradiction, which we discover in such a conception, is only that
-which we have ourselves placed there, by tacitly assuming the
-conceivability of the inconceivable. The condition of consciousness is
-distinction; and condition of distinction is limitation. We can have no
-consciousness of Being in general which is not some Being in particular:
-a _thing_, in consciousness, is one thing out of many. In assuming the
-possibility of an infinite object of consciousness, I assume, therefore,
-that it is at the same time limited and unlimited;—actually something,
-without which it could not be an object of consciousness, and actually
-nothing, without which it could not be infinite. * * *
-
-“A second characteristic of Consciousness is, that it is only possible
-in the form of a _relation_. There must be a Subject, or person
-conscious, and an Object, or thing of which he is conscious. There can
-be no consciousness without the union of these two factors; and, in that
-union, each exists only as it is related to the other. The subject is a
-subject, only in so far as it is conscious of an object: the object is
-an object, only in so far as it is apprehended by a subject: and the
-destruction of either is the destruction of consciousness itself. It is
-thus manifest that a consciousness of the Absolute is equally
-self-contradictory with that of the Infinite. To be conscious of the
-Absolute as such, we must know that an object, which is given in
-relation to our consciousness, is identical with one which exists in its
-own nature, out of all relation to consciousness. But to know this
-identity, we must be able to compare the two together; and such a
-comparison is itself a contradiction. We are in fact required to compare
-that of which we are conscious with that of which we are not conscious;
-the comparison itself being an act of consciousness, and only possible
-through the consciousness of both its objects. It is thus manifest that,
-even if we could be conscious of the absolute, we could not possibly
-know that it is the absolute: and, as we can be conscious of an object
-as such, only by knowing it to be what it is, this is equivalent to an
-admission that we cannot be conscious of the absolute at all. As an
-object of consciousness, every thing is necessarily relative; and what a
-thing may be out of consciousness, no mode of consciousness can tell us.
-
-“This contradiction, again, admits of the same explanation as the
-former. Our whole notion of existence is necessarily relative; for it is
-existence as conceived by us. But _Existence_, as we conceive it, is but
-a name for the several ways in which objects are presented to our
-consciousness,—a general term, embracing a variety of relations. _The
-Absolute_, on the other hand, is a term expressing no object of thought,
-but only a denial of the relation by which thought is constituted. To
-assume absolute existence as an object of thought, is thus to suppose a
-relation existing when the related terms exist no longer. An object of
-thought exists, as such, in and through its relation to a thinker; while
-the Absolute, as such, is independent of all relation. The _Conception
-of the Absolute_ thus implies at the same time the presence and absence
-of the relation by which thought is constituted; and our various
-endeavours to represent it are only so many modified forms of the
-contradiction involved in our original assumption. Here, too, the
-contradiction is one which we ourselves have made. It does not imply
-that the Absolute cannot exist; but it implies, most certainly, that we
-cannot conceive it as existing.”
-
-Here let me point out how the same general inference may be evolved from
-another fundamental condition of thought, omitted by Sir W. Hamilton,
-and not supplied by Mr Mansel;—a condition which, under its obverse
-aspect, we have already contemplated in the last section. Every complete
-act of consciousness, besides distinction and relation, also implies
-likeness. Before it can become an idea, or constitute a piece of
-knowledge, a mental state must not only be known as separate in kind
-from certain foregoing states to which it is known as related by
-succession; but it must further be known as of the same kind with
-certain other foregoing states. That organization of changes which
-constitutes thinking, involves continuous integration as well as
-continuous differentiation. Were each new affection of the mind
-perceived simply as an affection in some way contrasted with the
-preceding ones—were there but a chain of impressions, each of which as
-it arose was merely distinguished from its predecessors; consciousness
-would be an utter chaos. To produce that orderly consciousness which we
-call intelligence, there requires the assimilation of each impression to
-others, that occurred earlier in the series. Both the successive mental
-states, and the successive relations which they bear to each other, must
-be classified; and classification involves not only a parting of the
-unlike, but also a binding together of the like. In brief, a true
-cognition is possible only through an accompanying recognition.
- Should it be objected that if so, there cannot be a first
-cognition, and hence there can be no cognition; the reply is, that
-cognition proper arises gradually—that during the first stage of
-incipient intelligence, before the feelings produced by intercourse with
-the outer world have been put into order, there _are_ no cognitions,
-strictly so called; and that, as every infant shows us, these slowly
-emerge out of the confusion of unfolding consciousness as fast as the
-experiences are arranged into groups—as fast as the most frequently
-repeated sensations, and their relations to each other, become familiar
-enough to admit of their recognition as such or such, whenever they
-recur. Should it be further objected that if cognition pre-supposes
-recognition, there can be, no cognition, even by an adult, of an object
-never before seen; there is still the sufficient answer that in so far
-as it is not assimilated to previously-seen objects, it is _not_ known,
-and that it _is_ known in so far as it is assimilated to them. Of this
-paradox the interpretation is, that an object is classifiable in various
-ways, with various degrees of completeness. An animal hitherto _unknown_
-(mark the word), though not referable to any established species or
-genus, is yet _recognized_ as belonging to one of the larger
-divisions—mammals, birds, reptiles, or fishes; or should it be so
-anomalous that its alliance with any of these is not determinable, it
-may yet be classed as vertebrate or invertebrate; or if it be one of
-those organisms of which it is doubtful whether the animal or vegetal
-characteristics predominate, it is still known as a living body; even
-should it be questioned whether it is organic, it remains beyond
-question that it is a material object, and it is cognized by being
-recognized as such. Whence it is manifest that a thing is perfectly
-known only when it is in all respects like certain things previously
-observed; that in proportion to the number of respects in which it is
-unlike them, is the extent to which it is unknown; and that hence when
-it has absolutely no attribute in common with anything else, it must be
-absolutely beyond the bounds of knowledge.
-
-Observe the corollary which here concerns us. A cognition of the Real,
-as distinguished from the Phenomenal, must, if it exists, conform to
-this law of cognition in general. The First Cause, the Infinite, the
-Absolute, to be known at all, must be classed. To be positively thought
-of, it must be thought of as such or such—as of this or that kind. Can
-it be like in kind to anything of which we have sensible experience?
-Obviously not. Between the creating and the created, there must be a
-distinction transcending any of the distinctions existing between
-different divisions of the created. That which is uncaused cannot be
-assimilated to that which is caused: the two being, in the very naming,
-antithetically opposed. The Infinite cannot be grouped along with
-something that is finite; since, in being so grouped, it must be
-regarded as not-infinite. It is impossible to put the Absolute in the
-same category with anything relative, so long as the Absolute is defined
-as that of which no necessary relation can be predicated. Is it then
-that the Actual, though unthinkable by classification with the Apparent,
-is thinkable by classification with itself? This supposition is equally
-absurd with the other. It implies the plurality of the First Cause, the
-Infinite, the Absolute; and this implication is self-contradictory.
-There cannot be more than one First Cause; seeing that the existence of
-more than one would involve the existence of something necessitating
-more than one, which something would be the true First Cause. How
-self-destructive is the assumption of two or more Infinites, is manifest
-on remembering that such Infinites, by limiting each other, would become
-finite. And similarly, an Absolute which existed not alone but along
-with other Absolutes, would no longer be an absolute but a relative. The
-Unconditioned therefore, as class-able neither with any form of the
-conditioned nor with any other Unconditioned, cannot be classed at all.
-And to admit that it cannot be known as of such or such kind, is to
-admit that it is unknowable.
-
-Thus, from the very nature of thought, the relativity of our knowledge
-is inferable in three several ways. As we find by analyzing it, and as
-we see it objectively displayed in every proposition, a thought involves
-_relation_, _difference_, _likeness_. Whatever does not present each of
-these does not admit of cognition. And hence we may say that the
-Unconditioned, as presenting none of them, is trebly unthinkable.
-
- * * * * *
-
-§ 25. From yet another point of view we may discern the same great
-truth. If, instead of examining our intellectual powers directly as
-exhibited in the act of thought, or indirectly as exhibited in thought
-when expressed by words, we look at the connexion between the mind and
-the world, a like conclusion is forced upon us. In the very definition
-of Life, when reduced to its most abstract shape, this ultimate
-implication becomes visible.
-
-All vital actions, considered not separately but in their ensemble, have
-for their final purpose the balancing of certain outer processes by
-certain inner processes. There are unceasing external forces tending to
-bring the matter of which organic bodies consist, into that state of
-stable equilibrium displayed by inorganic bodies; there are internal
-forces by which this tendency is constantly antagonized; and the
-perpetual changes which constitute Life, may be regarded as incidental
-to the maintenance of the antagonism. To preserve the erect posture, for
-instance, we see that certain weights have to be neutralized by certain
-strains: each limb or other organ, gravitating to the Earth and pulling
-down the parts to which it is attached, has to be preserved in position
-by the tension of sundry muscles; or in other words, the group of forces
-which would if allowed bring the body to the ground, has to be
-counterbalanced by another group of forces. Again, to keep up the
-temperature at a particular point, the external process of radiation and
-absorption of heat by the surrounding medium, must be met by a
-corresponding internal process of chemical combination, whereby more
-heat may be evolved; to which add, that if from atmospheric changes the
-loss becomes greater or less, the production must become greater or
-less. And similarly throughout the organic actions in general.
-
-When we contemplate the lower kinds of life, we see that the
-correspondences thus maintained are direct and simple; as in a plant,
-the vitality of which mainly consists in osmotic and chemical actions
-responding to the co-existence of light, heat, water, and carbonic acid
-around it. But in animals, and especially in the higher orders of them,
-the correspondences become extremely complex. Materials for growth and
-repair not being, like those which plants require, everywhere present,
-but being widely dispersed and under special forms, have to be found, to
-be secured, and to be reduced to a fit state for assimilation. Hence the
-need for locomotion; hence the need for the senses; hence the need for
-prehensile and destructive appliances; hence the need for an elaborate
-digestive apparatus. Observe, however, that these successive
-complications are essentially nothing but aids to the maintenance of the
-organic balance in its integrity, in opposition to those physical,
-chemical, and other agencies which tend to overturn it. And observe,
-moreover, that while these successive complications subserve this
-fundamental adaptation of inner to outer actions, they are themselves
-nothing else but further adaptations of inner to outer actions. For what
-are those movements by which a predatory creature pursues its prey, or
-by which its prey seeks to escape, but certain changes in the organism
-fitted to meet certain changes in its environment? What is that compound
-operation which constitutes the perception of a piece of food, but a
-particular correlation of nervous modifications, answering to a
-particular correlation of physical properties? What is that process by
-which food when swallowed is reduced to a fit form for assimilation, but
-a set of mechanical and chemical actions responding to the mechanical
-and chemical actions which distinguish the food? Whence it becomes
-manifest, that while Life in its simplest form is the correspondence of
-certain inner physico-chemical actions with certain outer
-physico-chemical actions, each advance to a higher form of Life consists
-in a better preservation of this primary correspondence by the
-establishment of other correspondences.
-
-Divesting this conception of all superfluities and reducing it to its
-most abstract shape, we see that Life is definable as the continuous
-adjustment of internal relations to external relations. And when we so
-define it, we discover that the physical and the psychial life are
-equally comprehended by the definition. We perceive that this which we
-call Intelligence, shows itself when the external relations to which the
-internal ones are adjusted, begin to be numerous, complex, and remote in
-time or space; that every advance in Intelligence essentially consists
-in the establishment of more varied, more complete, and more involved
-adjustments; and that even the highest achievements of science are
-resolvable into mental relations of co-existence and sequence, so
-co-ordinated as exactly to tally with certain relations of co-existence
-and sequence that occur externally. A caterpillar, wandering at random
-and at length finding its way on to a plant having a certain odour,
-begins to eat—has inside of it an organic relation between a particular
-impression and a particular set of actions, answering to the relation
-outside of it, between scent and nutriment. The sparrow, guided by the
-more complex correlation of impressions which the colour, form, and
-movements of the caterpillar gave it; and guided also by other
-correlations which measure the position and distance of the caterpillar;
-adjusts certain correlated muscular movements in such way as to seize
-the caterpillar. Through a much greater distance in space is the hawk,
-hovering above, affected by the relations of shape and motion which the
-sparrow presents; and the much more complicated and prolonged series of
-related nervous and muscular changes, gone through in correspondence
-with the sparrow’s changing relations of position, finally succeed when
-they are precisely adjusted to these changing relations. In the fowler,
-experience has established a relation between the appearance and flight
-of a hawk and the destruction of other birds, including game; there is
-also in him an established relation between those visual impressions
-answering to a certain distance in space, and the range of his gun; and
-he has learned, too, by frequent observation, what relations of position
-the sights must bear to a point somewhat in advance of the flying bird,
-before he can fire with success. Similarly if we go back to the
-manufacture of the gun. By relations of co-existence between colour,
-density, and place in the earth, a particular mineral is known as one
-which yields iron; and the obtainment of iron from it, results when
-certain correlated acts of ours, are adjusted to certain correlated
-affinities displayed by ironstone, coal, and lime, at a high
-temperature. If we descend yet a step further, and ask a chemist to
-explain the explosion of gunpowder, or apply to a mathematician for a
-theory of projectiles, we still find that special or general relations
-of co-existence and sequence between properties, motions, spaces &c.,
-are all they can teach us. And lastly, let it be noted that what we call
-_truth_, guiding us to successful action and the consequent maintenance
-of life, is simply the accurate correspondence of subjective to
-objective relations; while _error_, leading to failure and therefore
-towards death, is the absence of such accurate correspondence.
-
-If, then, Life in all its manifestations, inclusive of Intelligence in
-its highest forms, consists in the continuous adjustment of internal
-relations to external relations, the necessarily relative character of
-our knowledge becomes obvious. The simplest cognition being the
-establishment of some connexion between subjective states, answering to
-some connexion between objective agencies; and each successively more
-complex cognition being the establishment of some more involved
-connexion of such states, answering to some more involved connexion of
-such agencies; it is clear that the process, no matter how far it be
-carried, can never bring within the reach of Intelligence, either the
-states themselves or the agencies themselves. Ascertaining which things
-occur along with which, and what things follow what, supposing it to be
-pursued exhaustively, must still leave us with co-existences and
-sequences only. If every act of knowing is the formation of a relation
-in consciousness parallel to a relation in the environment, then the
-relativity of knowledge is self-evident—becomes indeed a truism.
-Thinking being relationing, no thought can ever express more than
-relations.
-
-And here let us not omit to mark how that to which our intelligence is
-confined, is that with which alone our intelligence is concerned. The
-knowledge within our reach, is the only knowledge that can be of service
-to us. This maintenance of a correspondence between internal actions and
-external actions, which both constitutes our life at each moment and is
-the means whereby life is continued through subsequent moments, merely
-requires that the agencies acting upon us shall be known in their
-co-existences and sequences, and not that they shall be known in
-themselves. If _x_ and _y_ are two uniformly connected properties in
-some outer object, while _a_ and _b_ are the effects they produce in our
-consciousness; and if while the property _x_ produces in us the
-indifferent mental state _a_, the property _y_ produces in us the
-painful mental state _b_ (answering to a physical injury); then, all
-that is requisite for our guidance, is, that _x_ being the uniform
-accompaniment of _y_ externally, _a_ shall be the uniform accompaniment
-of _b_ internally; so that when, by the presence of _x_, _a_ is produced
-in consciousness, _b_, or rather the idea of _b_, shall follow it, and
-excite the motions by which the effect of _y_ may be escaped. The sole
-need is that _a_ and _b_ and the relation between them, shall always
-answer to _x_ and _y_ and the relation between them. It matters nothing
-to us if _a_ and _b_ are like _x_ and _y_ or not. Could they be exactly
-identical with them, we should not be one whit the better off; and their
-total dissimilarity is no disadvantage to us.
-
-Deep down then in the very nature of Life, the relativity of our
-knowledge is discernible. The analysis of vital actions in general,
-leads not only to the conclusion that things in themselves cannot be
-known to us; but also to the conclusion that knowledge of them, were it
-possible, would be useless.
-
- * * * * *
-
-§ 26. There still remains the final question—What must we say concerning
-that which transcends knowledge? Are we to rest wholly in the
-consciousness of phenomena?—is the result of inquiry to exclude utterly
-from our minds everything but the relative? or must we also believe in
-something beyond the relative?
-
-The answer of pure logic is held to be, that by the limits of our
-intelligence we are rigorously confined within the relative; and that
-anything transcending the relative can be thought of only as a pure
-negation, or as a non-existence. “The _absolute_ is conceived merely by
-a negation of conceivability,” writes Sir William Hamilton. “The
-_Absolute_ and the _Infinite_” says Mr Mansel, “are thus, like the
-_Inconceivable_ and the _Imperceptible_, names indicating, not an object
-of thought or of consciousness at all, but the mere absence of the
-conditions under which consciousness is possible.” From each of which
-extracts may be deduced the conclusion, that since reason cannot warrant
-us in affirming the positive existence of what is cognizable only as a
-negation, we cannot rationally affirm the positive existence of anything
-beyond phenomena.
-
-Unavoidable as this conclusion seems, it involves, I think, a grave
-error. If the premiss be granted, the inference must doubtless be
-admitted; but the premiss, in the form presented by Sir William
-Hamilton and Mr Mansel, is not strictly true. Though, in the foregoing
-pages, the arguments used by these writers to show that the Absolute
-is unknowable, have been approvingly quoted; and though these
-arguments have been enforced by others equally thoroughgoing; yet
-there remains to be stated a qualification, which saves us from that
-scepticism otherwise necessitated. It is not to be denied that so long
-as we confine ourselves to the purely logical aspect of the question,
-the propositions quoted above must be accepted in their entirety; but
-when we contemplate its more general, or psychological, aspect, we
-find that these propositions are imperfect statements of the truth:
-omitting, or rather excluding, as they do, an all-important fact. To
-speak specifically:—Besides that _definite_ consciousness of which
-Logic formulates the laws, there is also an _indefinite_ consciousness
-which cannot be formulated. Besides complete thoughts, and besides the
-thoughts which though incomplete admit of completion, there are
-thoughts which it is impossible to complete; and yet which are still
-real, in the sense that they are normal affections of the intellect.
-
-Observe in the first place, that every one of the arguments by which the
-relativity of our knowledge is demonstrated, distinctly postulates the
-positive existence of something beyond the relative. To say that we
-cannot know the Absolute, is, by implication, to affirm that there _is_
-an Absolute. In the very denial of our power to learn _what_ the
-Absolute is, there lies hidden the assumption _that_ it is; and the
-making of this assumption proves that the Absolute has been present to
-the mind, not as a nothing, but as a something. Similarly with every
-step in the reasoning by which this doctrine is upheld. The Noumenon,
-everywhere named as the antithesis of the Phenomenon, is throughout
-necessarily thought of as an actuality. It is rigorously impossible to
-conceive that our knowledge is a knowledge of Appearances only, without
-at the same time conceiving a Reality of which they are appearances; for
-appearance without reality is unthinkable. Strike out from the argument
-the terms Unconditioned, Infinite, Absolute, with their equivalents, and
-in place of them write, “negation of conceivability,” or “absence of the
-conditions under which consciousness is possible,” and you find that the
-argument becomes nonsense. Truly to realize in thought any one of the
-propositions of which the argument consists, the Unconditioned must be
-represented as positive and not negative. How then can it be a
-legitimate conclusion from the argument, that our consciousness of it is
-negative? An argument, the very construction of which assigns to a
-certain term a certain meaning, but which ends in showing that this term
-has no such meaning, is simply an elaborate suicide. Clearly, then, the
-very demonstration that a _definite_ consciousness of the Absolute is
-impossible to us, unavoidably presupposes an _indefinite_ consciousness
-of it.
-
-Perhaps the best way of showing that by the necessary conditions of
-thought, we are obliged to form a positive though vague consciousness of
-this which transcends distinct consciousness, is to analyze our
-conception of the antithesis between Relative and Absolute. It is a
-doctrine called in question by none, that such antinomies of thought as
-Whole and Part, Equal and Unequal, Singular and Plural, are necessarily
-conceived as correlatives: the conception of a part is impossible
-without the conception of a whole; there can be no idea of equality
-without one of inequality. And it is admitted that in the same manner,
-the Relative is itself conceivable as such, only by opposition to the
-Irrelative or Absolute. Sir William Hamilton however, in his
-trenchant (and in most parts unanswerable) criticism on Cousin,
-contends, in conformity with his position above stated, that one of
-these correlatives is nothing whatever beyond the negation of the other.
-“Correlatives” he says “certainly suggest each other, but correlatives
-may, or may not, be equally real and positive. In thought
-contradictories necessarily imply each other, for the knowledge of
-contradictories is one. But the reality of one contradictory, so far
-from guaranteeing the reality of the other, is nothing else than its
-negation. Thus every positive notion (the concept of a thing by what it
-is) suggests a negative notion (the concept of a thing by what it is
-not); and the highest positive notion, the notion of the conceivable, is
-not without its corresponding negative in the notion of the
-inconceivable. But though these mutually suggest each other, the
-positive alone is real; the negative is only an abstraction of the
-other, and in the highest generality, even an abstraction of thought
-itself.” Now the assertion that of such contradictories “the
-negative is _only_ an abstraction of the other”—“is _nothing_ else than
-its negation,”—is not true. In such correlatives as Equal and Unequal,
-it is obvious enough that the negative concept contains something
-besides the negation of the positive one; for the things of which
-equality is denied are not abolished from consciousness by the denial.
-And the fact overlooked by Sir William Hamilton, is, that the like holds
-even with those correlatives of which the negative is inconceivable, in
-the strict sense of the word. Take for example the Limited and the
-Unlimited. Our notion of the Limited is composed, firstly of a
-consciousness of some kind of being, and secondly of a consciousness of
-the limits under which it is known. In the antithetical notion of the
-Unlimited, the consciousness of limits is abolished; but not the
-consciousness of some kind of being. It is quite true that in the
-absence of conceived limits, this consciousness ceases to be a concept
-properly so called; but it is none the less true that it remains as a
-mode of consciousness. If, in such cases, the negative contradictory
-were, as alleged, “_nothing else_” than the negation of the other, and
-therefore a mere nonentity, then it would clearly follow that negative
-contradictories could be used interchangeably: the Unlimited might be
-thought of as antithetical to the Divisible; and the Indivisible as
-antithetical to the Limited. While the fact that they cannot be so used,
-proves that in consciousness the Unlimited and the Indivisible are
-qualitatively distinct, and therefore positive or real; since
-distinction cannot exist between nothings. The error, (very naturally
-fallen into by philosophers intent on demonstrating the limits and
-conditions of consciousness,) consists in assuming that consciousness
-contains _nothing but_ limits and conditions; to the entire neglect of
-that which is limited and conditioned. It is forgotten that there is
-something which alike forms the raw material of definite thought and
-remains after the definiteness which thinking gave to it has been
-destroyed. Now all this applies by change of terms to the last and
-highest of these antinomies—that between the Relative and the
-Non-relative. We are conscious of the Relative as existence under
-conditions and limits; it is impossible that these conditions and limits
-can be thought of apart from something to which they give the form; the
-abstraction of these conditions and limits, is, by the hypothesis, the
-abstraction of them _only_; consequently there must be a residuary
-consciousness of something which filled up their outlines; and this
-indefinite something constitutes our consciousness of the Non-relative
-or Absolute. Impossible though it is to give to this consciousness any
-qualitative or quantitative expression whatever, it is not the less
-certain that it remains with us as a positive and indestructible element
-of thought.
-
-Still more manifest will this truth become when it is observed that our
-conception of the Relative itself disappears, if our conception of the
-Absolute is a pure negation. It is admitted, or rather it is contended,
-by the writers I have quoted above, that contradictories can be known
-only in relation to each other—that Equality, for instance, is
-unthinkable apart from its correlative Inequality; and that thus the
-Relative can itself be conceived only by opposition to the Non-relative.
-It is also admitted, or rather contended, that the consciousness of a
-relation implies a consciousness of both the related members. If we are
-required to conceive the relation between the Relative and Non-relative
-without being conscious of both, “we are in fact” (to quote the words of
-Mr Mansel differently applied) “required to compare that of which we are
-conscious with that of which we are not conscious; the comparison itself
-being an act of consciousness, and only possible through the
-consciousness of both its objects.” What then becomes of the assertion
-that “the Absolute is conceived merely by a negation of conceivability,”
-or as “the mere absence of the conditions under which consciousness is
-possible?” If the Non-relative or Absolute, is present in thought only
-as a mere negation, then the relation between it and the Relative
-becomes unthinkable, because one of the terms of the relation is absent
-from consciousness. And if this relation is unthinkable, then is the
-Relative itself unthinkable, for want of its antithesis: whence results
-the disappearance of all thought whatever.
-
-Let me here point out that both Sir Wm Hamilton and Mr Mansel, do, in
-other places, distinctly imply that our consciousness of the Absolute,
-indefinite though it is, is positive and not negative. The very passage
-already quoted from Sir Wm Hamilton, in which he asserts that “the
-_absolute_ is conceived merely by a negation of conceivability,” itself
-ends with the remark that, “by a wonderful revelation, we are thus, in
-the very consciousness of our inability to conceive aught above the
-relative and finite, inspired with a belief in the existence of
-something unconditioned beyond the sphere of all comprehensible
-reality.” The last of these assertions practically admits that which the
-other denies. By the laws of thought as Sir Wm Hamilton has interpreted
-them, he finds himself forced to the conclusion that our consciousness
-of the Absolute is a pure negation. He nevertheless finds that there
-does exist in consciousness an irresistible conviction of the real
-“existence of something unconditioned.” And he gets over the
-inconsistency by speaking of this conviction as “a wonderful
-revelation”—“a belief” with which we are “inspired:” thus apparently
-hinting that it is supernaturally at variance with the laws of thought.
-Mr Mansel is betrayed into a like inconsistency. When he says that “we
-are compelled, by the constitution of our minds, to believe in the
-existence of an Absolute and Infinite Being,—a belief which appears
-forced upon us, as the complement of our consciousness of the relative
-and the finite;” he clearly says by implication that this consciousness
-is positive, and not negative. He tacitly admits that we are obliged to
-regard the Absolute as something more than a negation—that our
-consciousness of it is _not_ “the mere absence of the conditions under
-which consciousness is possible.”
-
-The supreme importance of this question must be my apology for taxing
-the reader’s attention a little further, in the hope of clearing up the
-remaining difficulties. The necessarily positive character of our
-consciousness of the Unconditioned, which, as we have seen, follows from
-an ultimate law of thought, will be better understood on contemplating
-the process of thought.
-
-One of the arguments used to prove the relativity of our knowledge, is,
-that we cannot conceive Space or Time as either limited or unlimited. It
-is pointed out that when we imagine a limit, there simultaneously arises
-the consciousness of a space or time existing beyond the limit. This
-remoter space or time, though not contemplated as definite, is yet
-contemplated as real. Though we do not form of it a conception proper,
-since we do not bring it within bounds, there is yet in our minds the
-unshaped material of a conception. Similarly with our consciousness of
-Cause. We are no more able to form a circumscribed idea of Cause, than
-of Space or Time; and we are consequently obliged to think of the Cause
-which transcends the limits of our thought as positive though
-indefinite. Just in the same manner that on conceiving any bounded
-space, there arises a nascent consciousness of space outside the bounds;
-so, when we think of any definite cause, there arises a nascent
-consciousness of a cause behind it: and in the one case as in the other,
-this nascent consciousness is in substance like that which suggests it,
-though without form. The momentum of thought inevitably carries us
-beyond conditioned existence to unconditioned existence; and this ever
-persists in us as the body of a thought to which we can give no shape.
-
-Hence our firm belief in objective reality—a belief which metaphysical
-criticisms cannot for a moment shake. When we are taught that a piece of
-matter, regarded by us as existing externally, cannot be really known,
-but that we can know only certain impressions produced on us, we are
-yet, by the relativity of our thought, compelled to think of these in
-relation to a positive cause—the notion of a real existence which
-generated these impressions becomes nascent. If it be proved to us that
-every notion of a real existence which we can frame, is utterly
-inconsistent with itself—that matter, however conceived by us, cannot be
-matter as it actually is, our conception, though transfigured, is not
-destroyed: there remains the sense of reality, dissociated as far as
-possible from those special forms under which it was before represented
-in thought. Though Philosophy condemns successively each attempted
-conception of the Absolute—though it proves to us that the Absolute is
-not this, nor that, nor that—though in obedience to it we negative, one
-after another, each idea as it arises; yet, as we cannot expel the
-entire contents of consciousness, there ever remains behind an element
-which passes into new shapes. The continual negation of each particular
-form and limit, simply results in the more or less complete abstraction
-of all forms and limits; and so ends in an indefinite consciousness of
-the unformed and unlimited.
-
-And here we come face to face with the ultimate difficulty—How can there
-possibly be constituted a consciousness of the unformed and unlimited,
-when, by its very nature, consciousness is possible only under forms and
-limits? If every consciousness of existence is a consciousness of
-existence as conditioned, then how, after the negation of conditions,
-can there be any residuum?. Though not directly withdrawn by the
-withdrawal of its conditions, must not the raw material of consciousness
-be withdrawn by implication? Must it not vanish when the conditions of
-its existence vanish? That there must be a solution of this
-difficulty is manifest; since even those who would put it, do, as
-already shown, admit that we have some such consciousness; and the
-solution appears to be that above shadowed forth. Such consciousness is
-not, and cannot be, constituted by any single mental act; but is the
-product of many mental acts. In each concept there is an element which
-persists. It is alike impossible for this element to be absent from
-consciousness, and for it to be present in consciousness alone: either
-alternative involves unconsciousness—the one from the want of the
-substance; the other from the want of the form. But the persistence of
-this element under successive conditions, _necessitates_ a sense of it
-as distinguished from the conditions, and independent of them. The sense
-of a something that is conditioned in every thought, cannot be got rid
-of, because the something cannot be got rid of. How then must the sense
-of this something be constituted? Evidently by combining successive
-concepts deprived of their limits and conditions. We form this
-indefinite thought, as we form many of our definite thoughts, by the
-coalescence of a series of thoughts. Let me illustrate this. A
-large complex object, having attributes too numerous to be represented
-at once, is yet tolerably well conceived by the union of several
-representations, each standing for part of its attributes. On thinking
-of a piano, there first rises in imagination its visual appearance, to
-which are instantly added (though by separate mental acts) the ideas of
-its remote side and of its solid substance. A complete conception,
-however, involves the strings, the hammers, the dampers, the pedals; and
-while successively adding these to the conception, the attributes first
-thought of lapse more or less completely out of consciousness.
-Nevertheless, the whole group constitutes a representation of the piano.
-Now as in this case we form a definite concept of a special existence,
-by imposing limits and conditions in successive acts; so, in the
-converse case, by taking away the limits and conditions in successive
-acts, we form an indefinite notion of general existence. By fusing a
-series of states of consciousness, in each of which, as it arises, the
-limitations and conditions are abolished, there is produced a
-consciousness of something unconditioned. To speak more
-rigorously:—this consciousness is not the abstract of any one group of
-thoughts, ideas, or conceptions; but it is the abstract of _all_
-thoughts, ideas, or conceptions. That which is common to them all, and
-cannot be got rid of, is what we predicate by the word existence.
-Dissociated as this becomes from each of its modes by the perpetual
-change of those modes, it remains as an indefinite consciousness of
-something constant under all modes—of being apart from its appearances.
-The distinction we feel between special and general existence, is the
-distinction between that which is changeable in us, and that which is
-unchangeable. The contrast between the Absolute and the Relative in our
-minds, is really the contrast between that mental element which exists
-absolutely, and those which exist relatively.
-
-By its very nature, therefore, this ultimate mental element is at once
-necessarily indefinite and necessarily indestructible. Our consciousness
-of the unconditioned being literally the unconditioned consciousness, or
-raw material of thought to which in thinking we give definite forms, it
-follows that an ever-present sense of real existence is the very basis
-of our intelligence. As we can in successive mental acts get rid of all
-particular conditions and replace them by others, but cannot get rid of
-that undifferentiated substance of consciousness which is conditioned
-anew in every thought; there ever remains with us a sense of that which
-exists persistently and independently of conditions. At the same time
-that by the laws of thought we are rigorously prevented from forming a
-conception of absolute existence; we are by the laws of thought equally
-prevented from ridding ourselves of the consciousness of absolute
-existence: this consciousness being, as we here see, the obverse of our
-self-consciousness. And since the only possible measure of relative
-validity among our beliefs, is the degree of their persistence in
-opposition to the efforts made to change them, it follows that this
-which persists at all times, under all circumstances, and cannot cease
-until consciousness ceases, has the highest validity of any.
-
-To sum up this somewhat too elaborate argument:—We have seen how in the
-very assertion that all our knowledge, properly so called, is Relative,
-there is involved the assertion that there exists a Non-relative. We
-have seen how, in each step of the argument by which this doctrine is
-established, the same assumption is made. We have seen how, from the
-very necessity of thinking in relations, it follows that the Relative is
-itself inconceivable, except as related to a real Non-relative. We have
-seen that unless a real Non-relative or Absolute be postulated, the
-Relative itself becomes absolute; and so brings the argument to a
-contradiction. And on contemplating the process of thought, we have
-equally seen how impossible it is to get rid of the consciousness of an
-actuality lying behind appearances; and how, from this impossibility,
-results our indestructible belief in that actuality.
-
-
-
-
- CHAPTER V.
- THE RECONCILIATION.
-
-
-§ 27. Thus do all lines of argument converge to the same conclusion. The
-inference reached _à priori_. in the last chapter, confirms the
-inferences which, in the two preceding chapters, were reached _à
-posteriori_. Those imbecilities of the understanding that disclose
-themselves when we try to answer the highest questions of objective
-science, subjective science proves to be necessitated by the laws of
-that understanding. We not only learn by the frustration of all our
-efforts, that the reality underlying appearances is totally and for ever
-inconceivable by us; but we also learn why, from the very nature of our
-intelligence, it must be so. Finally we discover that this conclusion,
-which, in its unqualified form, seems opposed to the instinctive
-convictions of mankind, falls into harmony with them when the missing
-qualification is supplied. Though the Absolute cannot in any manner or
-degree be known, in the strict sense of knowing, yet we find that its
-positive existence is a necessary datum of consciousness; that so long
-as consciousness continues, we cannot for an instant rid it of this
-datum; and that thus the belief which this datum constitutes, has a
-higher warrant than any other whatever.
-
-Here then is that basis of agreement we set out to seek. This conclusion
-which objective science illustrates, and subjective science shows to be
-unavoidable,—this conclusion which, while it in the main expresses the
-doctrine of the English school of philosophy, recognizes also a soul of
-truth in the doctrine of the antagonist German school—this conclusion
-which brings the results of speculation into harmony with those of
-common sense; is also the conclusion which reconciles Religion with
-Science. Common Sense asserts the existence of a reality; Objective
-Science proves that this reality cannot be what we think it; Subjective
-Science shows why we cannot think of it as it is, and yet are compelled
-to think of it as existing; and in this assertion of a Reality utterly
-inscrutable in nature, Religion finds an assertion essentially
-coinciding with her own. We are obliged to regard every phenomenon as a
-manifestation of some Power by which we are acted upon; phenomena being,
-so far as we can ascertain, unlimited in their diffusion, we are obliged
-to regard this Power as omnipresent; and criticism teaches us that this
-Power is wholly incomprehensible. In this consciousness of an
-Incomprehensible Omnipresent Power, we have just that consciousness on
-which Religion dwells. And so we arrive at the point where Religion and
-Science coalesce.
-
-To understand fully how real is the reconciliation thus reached, it will
-be needful to look at the respective attitudes that Religion and Science
-have all along maintained towards this conclusion. We must observe how,
-all along, the imperfections of each have been undergoing correction by
-the other; and how the final out-come of their mutual criticisms, can be
-nothing else than an entire agreement on this deepest and widest of all
-truths.
-
- * * * * *
-
-§ 28. In Religion let us recognize the high merit that from the
-beginning it has dimly discerned the ultimate verity, and has never
-ceased to insist upon it. In its earliest and crudest forms it
-manifested, however vaguely and inconsistently, an intuition forming the
-germ of this highest belief in which all philosophies finally unite. The
-consciousness of a mystery is traceable in the rudest fetishism. Each
-higher religious creed, rejecting those definite and simple
-interpretations of Nature previously given, has become more religious by
-doing this. As the quite concrete and conceivable agencies alleged as
-the causes of things, have been replaced by agencies less concrete and
-conceivable, the element of mystery has of necessity become more
-predominant. Through all its successive phases the disappearance of
-those positive dogmas by which the mystery was made unmysterious, has
-formed the essential change delineated in religious history. And so
-Religion has ever been approximating towards that complete recognition
-of this mystery which is its goal.
-
-For its essentially valid belief, Religion has constantly done battle.
-Gross as were the disguises under which it first espoused this belief,
-and cherishing this belief, though it still does, under disfiguring
-vestments, it has never ceased to maintain and defend it. It has
-everywhere established and propagated one or other modification of the
-doctrine that all things are manifestations of a Power that transcends
-our knowledge. Though from age to age, Science has continually defeated
-it wherever they have come in collision, and has obliged it to
-relinquish one or more of its positions; it has still held the remaining
-ones with undiminished tenacity. No exposure of the logical
-inconsistency of its conclusions—no proof that each of its particular
-dogmas was absurd, has been able to weaken its allegiance to that
-ultimate verity for which it stands. After criticism has abolished all
-its arguments and reduced it to silence, there has still remained with
-it the indestructible consciousness of a truth which, however faulty the
-mode in which it had been expressed, was yet a truth beyond cavil. To
-this conviction its adherence has been substantially sincere. And for
-the guardianship and diffusion of it, Humanity has ever been, and must
-ever be, its debtor.
-
-But while from the beginning, Religion has had the all-essential office
-of preventing men from being wholly absorbed in the relative or
-immediate, and of awakening them to a consciousness of something beyond
-it, this office has been but very imperfectly discharged. Religion has
-ever been more or less irreligious; and it continues to be partially
-irreligious even now. In the first place, as implied above, it has
-all along professed to have some knowledge of that which transcends
-knowledge; and has so contradicted its own teachings. While with one
-breath it has asserted that the Cause of all things passes
-understanding, it has, with the next breath, asserted that the Cause of
-all things possesses such or such attributes—can be in so far
-understood. In the second place, while in great part sincere in
-its fealty to the great truth it had had to uphold, it has often been
-insincere, and consequently irreligious, in maintaining the untenable
-doctrines by which it has obscured this great truth. Each assertion
-respecting the nature, acts, or motives of that Power which the Universe
-manifests to us, has been repeatedly called in question, and proved to
-be inconsistent with itself, or with accompanying assertions. Yet each
-of them has been age after age insisted on, in spite of a secret
-consciousness that it would not bear examination. Just as though unaware
-that its central position was impregnable, Religion has obstinately held
-every outpost long after it was obviously indefensible. And this
-naturally introduces us to the third and most serious form of irreligion
-which Religion has displayed; namely, an imperfect belief in that which
-it especially professes to believe. How truly its central position _is_
-impregnable, Religion has never adequately realized. In the devoutest
-faith as we habitually see it, there lies hidden an innermost core of
-scepticism; and it is this scepticism which causes that dread of inquiry
-displayed by Religion when face to face with Science. Obliged to abandon
-one by one the superstitions it once tenaciously held, and daily finding
-its cherished beliefs more and more shaken, Religion shows a secret fear
-that all things may some day be explained; and thus itself betrays a
-lurking doubt whether that Incomprehensible Cause of which it is
-conscious, is really incomprehensible.
-
-Of Religion then, we must always remember, that amid its many errors and
-corruptions it has asserted and diffused a supreme verity. From the
-first, the recognition of this supreme verity, in however imperfect a
-manner, has been its vital element; and its various defects, once
-extreme but gradually diminishing, have been so many failures to
-recognize in full that which it recognized in part. The truly religious
-element of Religion has always been good; that which has proved
-untenable in doctrine and vicious in practice, has been its irreligious
-element; and from this it has been ever undergoing purification.
-
- * * * * *
-
-§ 29. And now observe that all along, the agent which has effected the
-purification has been Science. We habitually overlook the fact that this
-has been one of its functions. Religion ignores its immense debt to
-Science; and Science is scarcely at all conscious how much Religion owes
-it. Yet it is demonstrable that every step by which Religion has
-progressed from its first low conception to the comparatively high one
-it has now reached, Science has helped it, or rather forced it, to take;
-and that even now, Science is urging further steps in the same
-direction.
-
-Using the word Science in its true sense, as comprehending all positive
-and definite knowledge of the order existing among surrounding
-phenomena, it becomes manifest that from the outset, the discovery of an
-established order has modified that conception of disorder, or
-undetermined order, which underlies every superstition. As fast as
-experience proves that certain familiar changes always happen in the
-same sequence, there begins to fade from the mind the conception of a
-special personality to whose variable will they were before ascribed.
-And when, step by step, accumulating observations do the like with the
-less familiar changes, a similar modification of belief takes place with
-respect to them.
-
-While this process seems to those who effect, and those who undergo it,
-an anti-religious one, it is really the reverse. Instead of the specific
-comprehensible agency before assigned, there is substituted a less
-specific and less comprehensible agency; and though this, standing in
-opposition to the previous one, cannot at first call forth the same
-feeling, yet, as being less comprehensible, it must eventually call
-forth this feeling more fully. Take an instance. Of old the Sun
-was regarded as the chariot of a god, drawn by horses. How far the idea
-thus grossly expressed, was idealized, we need not inquire. It suffices
-to remark that this accounting for the apparent motion of the Sun by an
-agency like certain visible terrestrial agencies, reduced a daily wonder
-to the level of the commonest intellect. When, many centuries after,
-Kepler discovered that the planets moved round the Sun in ellipses and
-described equal areas in equal times, he concluded that in each planet
-there must exist a spirit to guide its movements. Here we see that with
-the progress of Science, there had disappeared the idea of a gross
-mechanical traction, such as was first assigned in the case of the Sun;
-but that while for this there was substituted an indefinite and
-less-easily conceivable force, it was still thought needful to assume a
-special personal agent as a cause of the regular irregularity of motion.
-When, finally, it was proved that these planetary revolutions with all
-their variations and disturbances, conformed to one universal law—when
-the presiding spirits which Kepler conceived were set aside, and the
-force of gravitation put in their place; the change was really the
-abolition of an imaginable agency, and the substitution of an
-unimaginable one. For though the _law_ of gravitation is within our
-mental grasp, it is impossible to realize in thought the _force_ of
-gravitation. Newton himself confessed the force of gravitation to be
-incomprehensible without the intermediation of an ether; and, as we have
-already seen, (§ 18,) the assumption of an ether does not in the least
-help us. Thus it is with Science in general. Its progress in
-grouping particular relations of phenomena under laws, and these special
-laws under laws more and more general, is of necessity a progress to
-causes that are more and more abstract. And causes more and more
-abstract, are of necessity causes less and less conceivable; since the
-formation of an abstract conception involves the dropping of certain
-concrete elements of thought. Hence the most abstract conception, to
-which Science is ever slowly approaching, is one that merges into the
-inconceivable or unthinkable, by the dropping of all concrete elements
-of thought. And so is justified the assertion, that the beliefs which
-Science has forced upon Religion, have been intrinsically more religious
-than those which they supplanted.
-
-Science however, like Religion, has but very incompletely fulfilled its
-office. As Religion has fallen short of its function in so far as it has
-been irreligious; so has Science fallen short of its function in so far
-as it has been unscientific. Let us note the several parallelisms.
- In its earlier stages, Science, while it began to teach the
-constant relations of phenomena, and so discredited the belief in
-separate personalities as the causes of them, itself substituted the
-belief in causal agencies which, if not personal, were yet concrete.
-When certain facts were said to show “Nature’s abhorrence of a vacuum,”
-when the properties of gold were explained as due to some entity called
-“aureity,” and when the phenomena of life were attributed to “a vital
-principle;” there was set up a mode of interpreting the facts, which,
-while antagonistic to the religious mode, because assigning other
-agencies, was also unscientific, because it professed to know that about
-which nothing was known. Having abandoned these metaphysical
-agencies—having seen that they were not independent existences, but
-merely special combinations of general causes, Science has more recently
-ascribed extensive groups of phenomena to electricity, chemical
-affinity, and other like general powers. But in speaking of these as
-ultimate and independent entities, Science has preserved substantially
-the same attitude as before. Accounting thus for all phenomena, those of
-Life and Thought included, it has not only maintained its seeming
-antagonism to Religion, by alleging agencies of a radically unlike kind;
-but, in so far as it has tacitly assumed a knowledge of these agencies,
-it has continued unscientific. At the present time, however, the most
-advanced men of science are abandoning these later conceptions, as their
-predecessors abandoned the earlier ones. Magnetism, heat, light &c,
-which were awhile since spoken of as so many distinct imponderables,
-physicists are now beginning to regard as different modes of
-manifestation of some one universal force; and in so doing are ceasing
-to think of this force as comprehensible. In each phase of its
-progress, Science has thus stopped short with superficial solutions—has
-unscientifically neglected to ask what was the nature of the agents it
-so familiarly invoked. Though in each succeeding phase it has gone a
-little deeper, and merged its supposed agents in more general and
-abstract ones, it has still, as before, rested content with these as if
-they were ascertained realities. And this, which has all along been the
-unscientific characteristic of Science, has all along been a part cause
-of its conflict with Religion.
-
- * * * * *
-
-§ 30. We see then that from the first, the faults of both Religion and
-Science have been the faults of imperfect development. Originally a mere
-rudiment, each has been growing into a more complete form; the vice of
-each has in all times been its incompleteness; the disagreements between
-them have throughout been nothing more than the consequences of their
-incompleteness; and as they reach their final forms, they come into
-entire harmony.
-
-The progress of intelligence has throughout been dual. Though it has not
-seemed so to those who made it, every step in advance has been a step
-towards both the natural and the supernatural. The better interpretation
-of each phenomenon has been, on the one hand, the rejection of a cause
-that was relatively conceivable in its nature but unknown in the order
-of its actions, and, on the other hand, the adoption of a cause that was
-known in the order of its actions but relatively inconceivable in its
-nature. The first advance out of universal fetishism, manifestly
-involved the conception of agencies less assimilable to the familiar
-agencies of men and animals, and therefore less understood; while, at
-the same time, such newly-conceived agencies in so far as they were
-distinguished by their uniform effects, were better understood than
-those they replaced. All subsequent advances display the same double
-result. Every deeper and more general power arrived at as a cause of
-phenomena, has been at once less comprehensible than the special ones it
-superseded, in the sense of being less definitely representable in
-thought; while it has been more comprehensible in the sense that its
-actions have been more completely predicable. The progress has thus been
-as much towards the establishment of a positively unknown as towards the
-establishment of a positively known. Though as knowledge approaches its
-culmination, every unaccountable and seemingly supernatural fact, is
-brought into the category of facts that are accountable or natural; yet,
-at the same time, all accountable or natural facts are proved to be in
-their ultimate genesis unaccountable and supernatural. And so there
-arise two antithetical states of mind, answering to the opposite sides
-of that existence about which we think. While our consciousness of
-Nature under the one aspect constitutes Science, our consciousness of it
-under the other aspect constitutes Religion.
-
-Otherwise contemplating the facts, we may say that Religion and Science
-have been undergoing a slow differentiation; and that their ceaseless
-conflicts have been due to the imperfect separation of their spheres and
-functions. Religion has, from the first, struggled to unite more or less
-science with its nescience; Science has, from the first, kept hold of
-more or less nescience as though it were a part of science. Each has
-been obliged gradually to relinquish that territory which it wrongly
-claimed, while it has gained from the other that to which it had a
-right; and the antagonism between them has been an inevitable
-accompaniment of this process. A more specific statement will make this
-clear. Religion, though at the outset it asserted a mystery, also
-made numerous definite assertions respecting this mystery—professed to
-know its nature in the minutest detail; and in so far as it claimed
-positive knowledge, it trespassed upon the province of Science. From the
-times of early mythologies, when such intimate acquaintance with the
-mystery was alleged, down to our own days, when but a few abstract and
-vague propositions are maintained, Religion has been compelled by
-Science to give up one after another of its dogmas—of those assumed
-cognitions which it could not substantiate. In the mean time, Science
-substituted for the personalities to which Religion ascribed phenomena,
-certain metaphysical entities; and in doing this it trespassed on the
-province of Religion; since it classed among the things which it
-comprehended, certain forms of the incomprehensible. Partly by the
-criticisms of Religion, which has occasionally called in question its
-assumptions, and partly as a consequence of spontaneous growth, Science
-has been obliged to abandon these attempts to include within the
-boundaries of knowledge that which cannot be known; and has so yielded
-up to Religion that which of right belonged to it. So long as this
-process of differentiation is incomplete, more or less of antagonism
-must continue. Gradually as the limits of possible cognition are
-established, the causes of conflict will diminish. And a permanent peace
-will be reached when Science becomes fully convinced that its
-explanations are proximate and relative; while Religion becomes fully
-convinced that the mystery it contemplates is ultimate and absolute.
-
-Religion and Science are therefore necessary correlatives. As already
-hinted, they stand respectively for those two antithetical modes of
-consciousness which cannot exist asunder. A known cannot be thought of
-apart from an unknown; nor can an unknown be thought of apart from a
-known. And by consequence neither can become more distinct without
-giving greater distinctness to the other. To carry further a metaphor
-before used,—they are the positive and negative poles of thought; of
-which neither can gain in intensity without increasing the intensity of
-the other.
-
- * * * * *
-
-§ 31. Thus the consciousness of an Inscrutable Power manifested to us
-through all phenomena, has been growing ever clearer; and must
-eventually be freed from its imperfections. The certainty that on the
-one hand such a Power exists, while on the other hand its nature
-transcends intuition and is beyond imagination, is the certainty towards
-which intelligence has from the first been progressing. To this
-conclusion Science inevitably arrives as it reaches its confines; while
-to this conclusion Religion is irresistibly driven by criticism. And
-satisfying as it does the demands of the most rigorous logic at the same
-time that it gives the religious sentiment the widest possible sphere of
-action, it is the conclusion we are bound to accept without reserve or
-qualification.
-
-Some do indeed allege that though the Ultimate Cause of things cannot
-really be thought of by us as having specified attributes, it is yet
-incumbent upon us to assert these attributes. Though the forms of our
-consciousness are such that the Absolute cannot in any manner or degree
-be brought within them, we are nevertheless told that we must represent
-the Absolute to ourselves under these forms. As writes Mr Mansel, in the
-work from which I have already quoted largely—“It is our duty, then, to
-think of God as personal; and it is our duty to believe that He is
-infinite.”
-
-That this is not the conclusion here adopted, needs hardly be said. If
-there be any meaning in the foregoing arguments, duty requires us
-neither to affirm nor deny personality. Our duty is to submit ourselves
-with all humility to the established limits of our intelligence; and not
-perversely to rebel against them. Let those who can, believe that there
-is eternal war set between our intellectual faculties and our moral
-obligations. I for one, admit no such radical vice in the constitution
-of things.
-
-This which to most will seem an essentially irreligious position, is an
-essentially religious one—nay is _the_ religious one, to which, as
-already shown, all others are but approximations. In the estimate it
-implies of the Ultimate Cause, it does not fall short of the alternative
-position, but exceeds it. Those who espouse this alternative position,
-make the erroneous assumption that the choice is between personality and
-something lower than personality; whereas the choice is rather between
-personality and something higher. Is it not just possible that there is
-a mode of being as much transcending Intelligence and Will, as these
-transcend mechanical motion? It is true that we are totally unable to
-conceive any such higher mode of being. But this is not a reason for
-questioning its existence; it is rather the reverse. Have we not seen
-how utterly incompetent our minds are to form even an approach to a
-conception of that which underlies all phenomena? Is it not proved that
-this incompetency is the incompetency of the Conditioned to grasp the
-Unconditioned? Does it not follow that the Ultimate Cause cannot in any
-respect be conceived by us because it is in every respect greater than
-can be conceived? And may we not therefore rightly refrain from
-assigning to it any attributes whatever, on the ground that such
-attributes, derived as they must be from our own natures, are not
-elevations but degradations? Indeed it seems somewhat strange that men
-should suppose the highest worship to lie in assimilating the object of
-their worship to themselves. Not in asserting a transcendant difference,
-but in asserting a certain likeness, consists the element of their creed
-which they think essential. It is true that from the time when the
-rudest savages imagined the causes of all things to be creatures of
-flesh and blood like themselves, down to our own time, the degree of
-assumed likeness has been diminishing. But though a bodily form and
-substance similar to that of man, has long since ceased, among
-cultivated races, to be a literally-conceived attribute of the Ultimate
-Cause—though the grosser human desires have been also rejected as unfit
-elements of the conception—though there is some hesitation in ascribing
-even the higher human feelings, save in greatly idealized shapes; yet it
-is still thought not only proper, but imperative, to ascribe the most
-abstract qualities of our nature. To think of the Creative Power as in
-all respects anthropomorphous, is now considered impious by men who yet
-hold themselves bound to think of the Creative Power as in some respects
-anthropomorphous; and who do not see that the one proceeding is but an
-evanescent form of the other. And then, most marvellous of all, this
-course is persisted in even by those who contend that we are wholly
-unable to frame any conception whatever of the Creative Power. After it
-has been shown that every supposition respecting the genesis of the
-Universe commits us to alternative impossibilities of thought—after it
-has been shown that each attempt to conceive real existence ends in an
-intellectual suicide—after it has been shown why, by the very
-constitution of our minds, we are eternally debarred from thinking of
-the Absolute; it is still asserted that we ought to think of the
-Absolute thus and thus. In all imaginable ways we find thrust upon us
-the truth, that we are not permitted to know—nay are not even permitted
-to conceive—that Reality which is behind the veil of Appearance; and yet
-it is said to be our duty to believe (and in so far to conceive) that
-this Reality exists in a certain defined manner. Shall we call this
-reverence? or shall we call it the reverse?
-
-Volumes might be written upon the impiety of the pious. Through the
-printed and spoken thoughts of religious teachers, may almost everywhere
-be traced a professed familiarity with the ultimate mystery of things,
-which, to say the least of it, seems anything but congruous with the
-accompanying expressions of humility. And surprisingly enough, those
-tenets which most clearly display this familiarity, are those insisted
-upon as forming the vital elements of religious belief. The attitude
-thus assumed, can be fitly represented only by further developing a
-simile long current in theological controversies—the simile of the
-watch. If for a moment we made the grotesque supposition that the
-tickings and other movements of a watch constituted a kind of
-consciousness; and that a watch possessed of such a consciousness,
-insisted on regarding the watchmaker’s actions as determined like its
-own by springs and escapements; we should simply complete a parallel of
-which religious teachers think much. And were we to suppose that a watch
-not only formulated the cause of its existence in these mechanical
-terms, but held that watches were bound out of reverence so to formulate
-this cause, and even vituperated, as atheistic watches, any that did not
-venture so to formulate it; we should merely illustrate the presumption
-of theologians by carrying their own argument a step further. A
-few extracts will bring home to the reader the justice of this
-comparison. We are told, for example, by one of high repute among
-religious thinkers, that the Universe is “the manifestation and abode of
-a Free Mind, like our own; embodying His personal thought in its
-adjustments, realizing His own ideal in its phenomena, just as we
-express own inner faculty and character through the natural language of
-an external life. In this view, we interpret Nature by Humanity; we find
-the key to her aspects in such purposes and affections as our own
-consciousness enables us to conceive; we look everywhere for physical
-signals of an ever-living Will; and decipher the universe as the
-autobiography of an Infinite Spirit, repeating itself in miniature
-within our Finite Spirit.” The same writer goes still further. He not
-only thus parallels the assimilation of the watchmaker to the watch,—he
-not only thinks the created can “decipher” “the autobiography” of the
-Creating; but he asserts that the necessary limits of the one are
-necessary limits of the other. The primary qualities of bodies, he says,
-“belong eternally to the material datum objective to God” and control
-his acts; while the secondary ones are “products of pure Inventive
-Reason and Determining Will”—constitute “the realm of Divine
-originality.” * * * “While on this Secondary field His Mind and ours are
-thus contrasted, they meet in resemblance again upon the Primary: for
-the evolutions of deductive Reason there is but one track possible to
-all intelligences; no _merum arbitrium_ can interchange the false and
-true, or make more than one geometry, one scheme of pure Physics, for
-all worlds; and the Omnipotent Architect Himself, in realizing the
-Kosmical conception, in shaping the orbits out of immensity and
-determining seasons out of eternity, could but follow the laws of
-curvature, measure and proportion.” That is to say, the Ultimate Cause
-is like a human mechanic, not only as “shaping” the “material datum
-objective to” Him, but also as being obliged to conform to the necessary
-properties of that “datum.” Nor is this all. There follows some account
-of “the Divine psychology,” to the extent of saying that “we learn” “the
-character of God—the order of affections in Him” from “the distribution
-of authority in the hierarchy of our impulses.” In other words, it is
-alleged that the Ultimate Cause has desires that are to be classed as
-higher and lower like our own.[7] Every one has heard of the king
-who wished he had been present at the creation of the world, that he
-might have given good advice. He was humble however compared with those
-who profess to understand not only the relation of the Creating to the
-created, but also how the Creating is constituted. And yet this
-transcendant audacity, which claims to penetrate the secrets of the
-Power manifested to us through all existence—nay even to stand behind
-that Power and note the conditions to its action—this it is which passes
-current as piety! May we not without hesitation affirm that a sincere
-recognition of the truth that our own and all other existence is a
-mystery absolutely and for ever beyond our comprehension, contains more
-of true religion than all the dogmatic theology ever written?
-
-Meanwhile let us recognize whatever of permanent good there is in these
-persistent attempts to frame conceptions of that which cannot be
-conceived. From the beginning it has been only through the successive
-failures of such conceptions to satisfy the mind, that higher and higher
-ones have been gradually reached; and doubtless, the conceptions now
-current are indispensable as transitional modes of thought. Even more
-than this may be willingly conceded. It is possible, nay probable, that
-under their most abstract forms, ideas of this order will always
-continue to occupy the background of our consciousness. Very likely
-there will ever remain a need to give shape to that indefinite sense of
-an Ultimate Existence, which forms the basis of our intelligence. We
-shall always be under the necessity of contemplating it as _some_ mode
-of being; that is—of representing it to ourselves in _some_ form of
-thought, however vague. And we shall not err in doing this so long as we
-treat every notion we thus frame as merely a symbol, utterly without
-resemblance to that for which it stands. Perhaps the constant formation
-of such symbols and constant rejection of them as inadequate, may be
-hereafter, as it has hitherto been, a means of discipline. Perpetually
-to construct ideas requiring the utmost stretch of our faculties, and
-perpetually to find that such ideas must be abandoned as futile
-imaginations, may realize to us more fully than any other course, the
-greatness of that which we vainly strive to grasp. Such efforts and
-failures may serve to maintain in our minds a due sense of the
-incommensurable difference between the Conditioned and the
-Unconditioned. By continually seeking to know and being continually
-thrown back with a deepened conviction of the impossibility of knowing,
-we may keep alive the consciousness that it is alike our highest wisdom
-and our highest duty to regard that through which all things exist as
-The Unknowable.
-
- * * * * *
-
-§ 32. An immense majority will refuse with more or less of indignation,
-a belief seeming to them so shadowy and indefinite. Having always
-embodied the Ultimate Cause so far as was needful to its mental
-realization, they must necessarily resent the substitution of an
-Ultimate Cause which cannot be mentally realized at all. “You offer us,”
-they say, “an unthinkable abstraction in place of a Being towards whom
-we may entertain definite feelings. Though we are told that the Absolute
-is real, yet since we are not allowed to conceive it, it might as well
-be a pure negation. Instead of a Power which we can regard as having
-some sympathy with us, you would have us contemplate a Power to which no
-emotion whatever can be ascribed. And so we are to be deprived of the
-very substance of our faith.”
-
-This kind of protest of necessity accompanies every change from a lower
-creed to a higher. The belief in a community of nature between himself
-and the object of his worship, has always been to man a satisfactory
-one; and he has always accepted with reluctance those successively less
-concrete conceptions which have been forced upon him. Doubtless, in all
-times and places, it has consoled the barbarian to think of his deities
-as so exactly like himself in nature, that they could be bribed by
-offerings of food; and the assurance that deities could not be so
-propitiated, must have been repugnant, because it deprived him of an
-easy method of gaining supernatural protection. To the Greeks it was
-manifestly a source of comfort that on occasions of difficulty they
-could obtain, through oracles, the advice of their gods,—nay, might even
-get the personal aid of their gods in battle; and it was probably a very
-genuine anger which they visited upon philosophers who called in
-question these gross ideas of their mythology. A religion which teaches
-the Hindoo that it is impossible to purchase eternal happiness by
-placing himself under the wheel of Juggernaut, can scarcely fail to seem
-a cruel one to him; since it deprives him of the pleasurable
-consciousness that he can at will exchange miseries for joys. Nor is it
-less clear that to our Catholic ancestors, the beliefs that crimes could
-be compounded for by the building of churches, that their own
-punishments and those of their relatives could be abridged by the saying
-of masses, and that divine aid or forgiveness might be gained through
-the intercession of saints, were highly solacing ones; and that
-Protestantism, in substituting the conception of a God so comparatively
-unlike ourselves as not to be influenced by such methods, must have
-appeared to them hard and cold. Naturally, therefore, we must expect a
-further step in the same direction to meet with a similar resistance
-from outraged sentiments. No mental revolution can be accomplished
-without more or less of laceration. Be it a change of habit or a change
-of conviction, it must, if the habit or conviction be strong, do
-violence to some of the feelings; and these must of course oppose it.
-For long-experienced, and therefore definite, sources of satisfaction,
-have to be substituted sources of satisfaction that have not been
-experienced, and are therefore indefinite. That which is relatively well
-known and real, has to be given up for that which is relatively unknown
-and ideal. And of course such an exchange cannot be made without a
-conflict involving pain. Especially then must there arise a strong
-antagonism to any alteration in so deep and vital a conception as that
-with which we are here dealing. Underlying, as this conception does, all
-others, a modification of it threatens to reduce the superstructure to
-ruins. Or to change the metaphor—being the root with which are connected
-our ideas of goodness, rectitude, or duty, it appears impossible that it
-should be transformed without causing these to wither away and die. The
-whole higher part of the nature almost of necessity takes up arms
-against a change which, by destroying the established associations of
-thought, seems to eradicate morality.
-
-This is by no means all that has to be said for such protests. There is
-a much deeper meaning in them. They do not simply express the natural
-repugnance to a revolution of belief, here made specially intense by the
-vital importance of the belief to be revolutionized; but they also
-express an instinctive adhesion to a belief that is in one sense the
-best—the best for those who thus cling to it, though not abstractedly
-the best. For here let me remark that what were above spoken of as
-the imperfections of Religion, at first great but gradually diminishing,
-have been imperfections only as measured by an absolute standard; and
-not as measured by a relative one. Speaking generally, the religion
-current in each age and among each people, has been as near an
-approximation to the truth as it was then and there possible for men to
-receive: the more or less concrete forms in which it has embodied the
-truth, have simply been the means of making thinkable what would
-otherwise have been unthinkable; and so have for the time being served
-to increase its impressiveness. If we consider the conditions of
-the case, we shall find this to be an unavoidable conclusion. During
-each stage of evolution, men must think in such terms of thought as they
-possess. While all the conspicuous changes of which they can observe the
-origins, have men and animals as antecedents, they are unable to think
-of antecedents in general under any other shapes; and hence creative
-agencies are of necessity conceived by them in these shapes. If during
-this phase, these concrete conceptions were taken from them, and the
-attempt made to give them comparatively abstract conceptions, the result
-would be to leave their minds with none at all; since the substituted
-ones could not be mentally represented. Similarly with every successive
-stage of religious belief, down to the last. Though, as accumulating
-experiences slowly modify the earliest ideas of causal personalities,
-there grow up more general and vague ideas of them; yet these cannot be
-at once replaced by others still more general and vague. Further
-experiences must supply the needful further abstractions, before the
-mental void left by the destruction of such inferior ideas can be filled
-by ideas of a superior order. And at the present time, the refusal to
-abandon a relatively concrete notion for a relatively abstract one,
-implies the inability to frame the relatively abstract one; and so
-proves that the change would be premature and injurious. Still
-more clearly shall we see the injuriousness of any such premature
-change, on observing that the effects of a belief upon conduct must be
-diminished in proportion as the vividness with which it is realized
-becomes less. Evils and benefits akin to those which the savage has
-personally felt, or learned from those who have felt them, are the only
-evils and benefits he can understand; and these must be looked for as
-coming in ways, like those of which he has had experience. His deities
-must be imagined to have like motives and passions and methods with the
-beings around him; for motives and passions and methods of a higher
-character, being unknown to him, and in great measure unthinkable by
-him, cannot be so realized in thought as to influence his deeds. During
-every phase of civilization, the actions of the Unseen Reality, as well
-as the resulting rewards and punishments, being conceivable only in such
-forms as experience furnishes, to supplant them by higher ones before
-wider experiences have made higher ones conceivable, is to set up vague
-and uninfluential motives for definite and influential ones. Even now,
-for the great mass of men, unable through lack of culture to trace out
-with due clearness those good and bad consequences which conduct brings
-round through the established order of the Unknowable, it is needful
-that there should be vividly depicted future torments and future
-joys—pains and pleasures of a definite kind, produced in a manner direct
-and simple enough to be clearly imagined. Nay still more must be
-conceded. Few if any are as yet fitted wholly to dispense with such
-conceptions as are current. The highest abstractions take so great a
-mental power to realize with any vividness, and are so inoperative upon
-conduct unless they are vividly realized, that their regulative effects
-must for a long period to come be appreciable on but a small minority.
-To see clearly how a right or wrong act generates consequences, internal
-and external, that go on branching out more widely as years progress,
-requires a rare power of analysis. To mentally represent even a single
-series of these consequences, as it stretches out into the remote
-future, requires an equally rare power of imagination. And to estimate
-these consequences in their totality, ever multiplying in number while
-diminishing in intensity, requires a grasp of thought possessed by none.
-Yet it is only by such analysis, such imagination, and such grasp, that
-conduct can be rightly guided in the absence of all other control: only
-so can ultimate rewards and penalties be made to outweigh proximate
-pains and pleasures. Indeed, were it not that throughout the progress of
-the race, men’s experiences of the effects of conduct have been slowly
-generalized into principles—were it not that these principles have been
-from generation to generation insisted on by parents, upheld by public
-opinion, sanctified by religion, and enforced by threats of eternal
-damnation for disobedience—were it not that under these potent
-influences, habits have been modified, and the feelings proper to them
-made innate—were it not, in short, that we have been rendered in a
-considerable degree organically moral; it is certain that disastrous
-results would ensue from the removal of those strong and distinct
-motives which the current belief supplies. Even as it is, those who
-relinquish the faith in which they have been brought up, for this most
-abstract faith in which Science and Religion unite, may not uncommonly
-fail to act up to their convictions. Left to their organic morality,
-enforced only by general reasonings imperfectly wrought out and
-difficult to keep before the mind, their defects of nature will often
-come out more strongly than they would have done under their previous
-creed. The substituted creed can become adequately operative only when
-it becomes, like the present one, an element in early education, and has
-the support of a strong social sanction. Nor will men be quite ready for
-it until, through the continuance of a discipline which has already
-partially moulded them to the conditions of social existence, they are
-completely moulded to those conditions.
-
-We must therefore recognize the resistance to a change of theological
-opinion, as in great measure salutary. It is not simply that strong and
-deep-rooted feelings are necessarily excited to antagonism—it is not
-simply that the highest moral sentiments join in the condemnation of a
-change which seems to undermine their authority; but it is that a real
-adaptation exists between an established belief and the natures of those
-who defend it; and that the tenacity of the defence measures the
-completeness of the adaptation. Forms of religion, like forms of
-government, must be fit for those who live under them; and in the one
-case as in the other, that form which is fittest is that for which there
-is an instinctive preference. As certainly as a barbarous race needs a
-harsh terrestrial rule, and habitually shows attachment to a despotism
-capable of the necessary rigour; so certainly does such a race need a
-belief in a celestial rule that is similarly harsh, and habitually shows
-attachment to such a belief. And just in the same way that the sudden
-substitution of free institutions for tyrannical ones, is sure to be
-followed by a reaction; so, if a creed full of dreadful ideal penalties
-is all at once replaced by one presenting ideal penalties that are
-comparatively gentle, there will inevitably be a return to some
-modification of the old belief. The parallelism holds yet further.
-During those early stages in which there is an extreme incongruity
-between the relatively best and the absolutely best, both political and
-religious changes, when at rare intervals they occur, are necessarily
-violent; and necessarily entail violent retrogressions. But as the
-incongruity between that which is and that which should be, diminishes,
-the changes become more moderate, and are succeeded by more moderate
-retrogressions; until, as these movements and counter-movements decrease
-in amount and increase in frequency, they merge into an almost
-continuous growth. That adhesion to old institutions and beliefs, which,
-in primitive societies, opposes an iron barrier to any advance, and
-which, after the barrier has been at length burst through, brings back
-the institutions and beliefs from that too-forward position to which the
-momentum of change had carried them, and so helps to re-adapt social
-conditions to the popular character—this adhesion to old institution and
-beliefs, eventually becomes the constant check by which the constant
-advance is prevented from being too rapid. This holds true of religious
-creeds and forms, as of civil ones. And so we learn that theological
-conservatism, like political conservatism, has an all-important
-function.
-
- * * * * *
-
-§ 33. That spirit of toleration which is so marked a characteristic of
-modern times, and is daily growing more conspicuous, has thus a far
-deeper meaning than is supposed. What we commonly regard simply as a due
-respect for the right of private judgment, is really a necessary
-condition to the balancing of the progressive and conservative
-tendencies—is a means of maintaining the adaptation between men’s
-beliefs and their natures. It is therefore a spirit to be fostered; and
-it is a spirit which the catholic thinker, who perceives the functions
-of these various conflicting creeds, should above all other men display.
- Doubtless whoever feels the greatness of the error to which his
-fellows cling and the greatness of the truth which they reject, will
-find it hard to show a due patience. It is hard for him to listen calmly
-to the futile arguments used in support of irrational doctrines, and to
-the misrepresentation of antagonist doctrines. It is hard for him to
-bear the manifestation of that pride of ignorance which so far exceeds
-the pride of science. Naturally enough such a one will be indignant when
-charged with irreligion because he declines to accept the
-carpenter-theory of creation as the most worthy one. He may think it
-needless as it is difficult, to conceal his repugnance to a creed which
-tacitly ascribes to The Unknowable a love of adulation such as would be
-despised in a human being. Convinced as he is that all punishment, as we
-see it wrought out in the order of nature, is but a disguised
-beneficence, there will perhaps escape from him an angry condemnation of
-the belief that punishment is a divine vengeance, and that divine
-vengeance is eternal. He may be tempted to show his contempt when he is
-told that actions instigated by an unselfish sympathy or by a pure love
-of rectitude, are intrinsically sinful; and that conduct is truly good
-only when it is due to a faith whose openly-professed motive is
-other-worldliness. But he must restrain such feelings. Though he may be
-unable to do this during the excitement of controversy, or when
-otherwise brought face to face with current superstitions, he must yet
-qualify his antagonism in calmer moments; so that his mature judgment
-and resulting conduct may be without bias.
-
-To this end let him ever bear in mind three cardinal facts—two of them
-already dwelt upon, and one still to be pointed out. The first is
-that with which we set out; namely the existence of a fundamental verity
-under all forms of religion, however degraded. In each of them there is
-a soul of truth. Through the gross body of dogmas traditions and rites
-which contain it, it is always visible—dimly or clearly as the case may
-be. This it is which gives vitality even to the rudest creed; this it is
-which survives every modification; and this it is which we must not
-forget when condemning the forms under which it is presented. The
-second of these cardinal facts, set forth at length in the foregoing
-section, is, that while those concrete elements in which each creed
-embodies this soul of truth, are bad as measured by an absolute
-standard, they are good as measured by a relative standard. Though from
-higher perceptions they hide the abstract verity within them; yet to
-lower perceptions they render this verity more appreciable than it would
-otherwise be. They serve to make real and influential over men, that
-which would else be unreal and uninfluential. Or we may call them the
-protective envelopes, without which the contained truth would die.
- The remaining cardinal fact is, that these various beliefs are
-parts of the constituted order of things; and not accidental but
-necessary parts. Seeing how one or other of them is everywhere present;
-is of perennial growth; and when cut down, redevelops in a form but
-slightly modified; we cannot avoid the inference that they are needful
-accompaniments of human life, severally fitted to the societies in which
-they are indigenous. From the highest point of view, we must recognize
-them as elements in that great evolution of which the beginning and end
-are beyond our knowledge or conception—as modes of manifestation of The
-Unknowable; and as having this for their warrant.
-
-Our toleration therefore should be the widest possible. Or rather, we
-should aim at something beyond toleration, as commonly understood. In
-dealing with alien beliefs, our endeavour must be, not simply to refrain
-from injustice of word or deed; but also to do justice by an open
-recognition of positive worth. We must qualify our disagreement with as
-much as may be of sympathy.
-
- * * * * *
-
-§ 34. These admissions will perhaps be held to imply, that the current
-theology should be passively accepted; or, at any rate, should not be
-actively opposed. “Why,” it may be asked, “if all creeds have an average
-fitness to their times and places, should we not rest content with that
-to which we are born? If the established belief contains an essential
-truth—if the forms under which it presents this truth, though
-intrinsically bad, are extrinsically good—if the abolition of these
-forms would be at present detrimental to the great majority—nay, if
-there are scarcely any to whom the ultimate and most abstract belief can
-furnish an adequate rule of life; surely it is wrong, for the present at
-least, to propagate this ultimate and most abstract belief.”
-
-The reply is, that though existing religious ideas and institutions have
-an average adaptation to the characters of the people who live under
-them; yet, as these characters are ever changing, the adaptation is ever
-becoming imperfect; and the ideas and institutions need remodelling with
-a frequency proportionate to the rapidity of the change. Hence, while it
-is requisite that free play should be given to conservative thought and
-action, progressive thought and action must also have free play. Without
-the agency of both, there cannot be those continual re-adaptations which
-orderly progress demands.
-
-Whoever hesitates to utter that which he thinks the highest truth, lest
-it should be too much in advance of the time, may reassure himself by
-looking at his acts from an impersonal point of view. Let him duly
-realize the fact that opinion is the agency through which character
-adapts external arrangements to itself—that his opinion rightly forms
-part of this agency—is a unit of force, constituting, with other such
-units, the general power which works out social changes; and he will
-perceive that he may properly give full utterance to his innermost
-conviction: leaving it to produce what effect it may. It is not for
-nothing that he has in him these sympathies with some principles and
-repugnance to others. He, with all his capacities, and aspirations, and
-beliefs, is not an accident, but a product of the time. He must remember
-that while he is a descendant of the past, he is a parent of the future;
-and that his thoughts are as children born to him, which he may not
-carelessly let die. He, like every other man, may properly consider
-himself as one of the myriad agencies through whom works the Unknown
-Cause; and when the Unknown Cause produces in him a certain belief, he
-is thereby authorized to profess and act out that belief. For, to render
-in their highest sense the words of the poet—
-
- ——Nature is made better by no mean,
- But nature makes that mean: over that art
- Which you say adds to nature, is an art
- That nature makes.
-
-Not as adventitious therefore will the wise man regard the faith which
-is in him. The highest truth he sees he will fearlessly utter; knowing
-that, let what may come of it, he is thus playing his right part in the
-world—knowing that if he can effect the change he aims at—well: if
-not—well also; though not _so_ well.
-
------
-
-Footnote 7:
-
- These extracts are from an article entitled “Nature and God,”
- published in the _National Review_ for October, 1860.
-
-
-
-
- PART II.
-
- LAWS OF THE KNOWABLE.
-
-
-
-
- CHAPTER I.
- LAWS IN GENERAL.
-
-
-§ 35. We have seen that intellectual advance has been dual—has been
-towards the establishment of both a positively unknown and a positively
-known. In making ever more certain the inaccessibility of one kind of
-truth, experience has made ever more certain the accessibility of
-another kind. The differentiation of the knowable from the unknowable,
-is shown as much in the reduction of the one to perfect clearness, as in
-the reduction of the other to impenetrable mystery. Progressing
-enlightenment discloses a definite limit to human intelligence; and
-while all which lies on the other side of the limit, is, with increasing
-distinctness, seen to transcend our finite faculties, it grows more and
-more obvious that all which lies on this side of the limit may become an
-indisputable possession.
-
-To speak specifically—it has been shown that though we can never learn
-the _nature_ of that which is manifested to us, we are daily learning
-more completely the _order_ of its manifestations. We are conscious of
-effects produced in us by something separate from ourselves. The effects
-of which we are conscious—the changes of consciousness which make up our
-mental life, we ascribe to the forces of an external world. The
-intrinsic character of these forces—of this external world—of that which
-underlies all appearances, we find inscrutable; as is also the internal
-something whose changes constitute consciousness, but at the same time
-we find that among the changes of consciousness thus produced, there
-exist various constant relations; and we have no choice but to ascribe
-constancy to the relations which subsist among the inscrutable causes of
-these changes. Observation early discloses certain invariable connexions
-of coexistence and sequence among phenomena. Accumulating experiences
-tend continually to augment the number of invariable connexions
-recognized. When, as in the later stages of civilization, there arises
-not only a diligent gathering together of experiences but a critical
-comparison of them, more remote and complex connexions are added to the
-list. And gradually there grows up the habit of regarding these
-uniformities of relation as characterizing all manifestations of the
-Unknowable. Under the endless variety and seeming irregularity, there is
-ever more clearly discerned that “constant course of procedure” which we
-call Law.
-
-The growing belief in the universality of Law, is so conspicuous to all
-cultivated minds as scarcely to need illustration. None who read these
-pages will ask for proof that this has been the central element of
-intellectual progress. But though the fact is sufficiently familiar, the
-philosophy of the fact is not so; and it will be desirable now to
-consider it. Partly because the development of our conception of Law
-will so be rendered more comprehensible; but chiefly because our
-subsequent course will thus be facilitated; I propose here to enumerate
-the several conditions that determine the order in which the various
-relations among phenomena are discovered. Seeing, as we shall, the
-consequent necessity of this order; and enabled, as we shall also be, to
-estimate the future by inference from the past; we shall perceive how
-inevitable is our advance towards the ultimatum that has been indicated.
-
- * * * * *
-
-§ 36. The recognition of Law, being the recognition of uniformity of
-relations among phenomena, it follows that the order in which different
-groups of phenomena are reduced to law, must depend on the frequency and
-distinctness with which the uniform relations they severally present,
-are experienced. At any given stage of progress, those uniformities will
-be most recognized with which men’s minds have been oftenest and most
-strongly impressed. In proportion partly to the number of times a
-relation has been presented to consciousness (not merely to the senses);
-and in proportion partly to the vividness with which the terms of the
-relation have been cognized; will be the degree in which the constancy
-of connexion is perceived.
-
-The frequency and impressiveness with which different classes of
-relations are repeated in conscious experience, thus primarily
-determining the succession in which they are generalized, there result
-certain derivative principles to which this succession must more
-immediately and obviously conform. First in importance comes _the
-directness with which personal welfare is affected_. While, among
-surrounding things, many do not appreciably influence the body in any
-way, some act detrimentally and some beneficially, in various degrees;
-and manifestly, those things whose actions on the organism are most
-influential, will, cæteris paribus, be those whose laws of action are
-earliest observed. Second in order, is _the conspicuousness of one
-or both the phenomena between which a relation is to be perceived_. On
-every side are countless phenomena so concealed as to be detected only
-by close observation; others not obtrusive enough to attract notice;
-others which moderately solicit the attention; others so imposing or
-vivid as to force themselves upon consciousness; and supposing
-incidental conditions to be the same, these last will of course be among
-the first to have their relations generalized. In the third place,
-we have _the absolute frequency with which the relations occur_. There
-are coexistences and sequences of all degrees of commonness, from those
-which are ever present to those which are extremely rare; and it is
-clear that the rare coexistences and sequences, as well as the sequences
-which are very long in taking place, will not be reduced to law so soon
-as those which are familiar and rapid. Fourthly has to be added
-_the relative frequency of occurrence_. Many events and appearances are
-more or less limited to times and places; and as a relation which does
-not exist within the environment of an observer, cannot be cognized by
-him, however common it may be elsewhere or in another age, we have to
-take account of the surrounding physical circumstances, as well as the
-state of society, of the arts, and of the sciences—all of which affect
-the frequency with which certain groups of facts are exposed to
-observation. The fifth corollary to be noticed, is, that the
-succession in which different classes of phenomena are reduced to law,
-depends in part on their _simplicity_. Phenomena presenting great
-composition of causes or conditions, have their essential relations so
-masked, that it requires accumulated experiences to impress upon
-consciousness the true connexion of antecedents and consequents they
-involve. Hence, other things equal, the progress of generalization will
-be from the simple to the complex; and this it is which M. Comte has
-wrongly asserted to be the sole regulative principle of the progress.
- Sixth, and last, comes _the degree of abstractness_. Concrete
-relations are the earliest acquisitions. The colligation of any group of
-these into a general relation, which is the first step in abstraction,
-necessarily comes later than the discovery of the relations colligated.
-The union of a number of these lowest generalizations into a higher and
-more abstract generalization, is necessarily subsequent to the formation
-of such lowest generalizations. And so on continually, until the highest
-and most abstract generalizations have been reached.
-
-These then are the several derivative principles. The frequency and
-vividness with which uniform relations are repeated in conscious
-experience, determining the recognition of their uniformity; and this
-frequency and vividness depending on the above conditions; it follows
-that the order in which different classes of facts are generalized, must
-depend on the extent to which the above conditions are fulfilled in each
-class. Let us mark how the facts harmonize with this conclusion: taking
-first a few that elucidate the general truth, and afterwards some that
-are illustrative of the several special truths which we here see follow
-from it.
-
- * * * * *
-
-§ 37. The relations earliest known as uniformities, are those subsisting
-between the common physical properties of matter—tangibility,
-visibility, cohesion, weight &c. We have no trace of an era in human
-history when the resistance offered by every visible object, was
-regarded as caused by the will of the object; or when the pressure of a
-body on the hand supporting it, was ascribed to the direct agency of a
-living being. And accordingly, we see that these are the relations
-oftenest repeated in consciousness; being as they are, objectively
-frequent, conspicuous, simple, concrete, and of immediate personal
-concern.
-
-Similarly with respect to the ordinary phenomena of motion. The fall of
-a mass on the withdrawal of its support, is a sequence which directly
-affects bodily welfare, is conspicuous, simple, concrete, and very often
-repeated. Hence it is one of the uniformities recognized before the dawn
-of tradition. We know of no time when movements due to terrestrial
-gravitation were attributed to volition. Only when the relation is
-obscured—only, as in the case of an aerolite, where the antecedent of
-the descent is unperceived, do we find the fetishistic conception
-persistent. On the other hand, motions of intrinsically the same
-order as that of a falling stone—those of the heavenly bodies—long
-remain ungeneralized; and until their uniformity is seen, are construed
-as results of will. This difference is clearly not dependent on
-comparative complexity or abstractness; since the motion of a planet in
-an ellipse, is as simple and concrete a phenomenon as the motion of a
-projected arrow in a parabola. But the antecedents are not conspicuous;
-the sequences are of long duration; and they are infrequently repeated.
-Hence in a given period, there cannot be the same multiplied experiences
-of them. And that this is the chief cause of their slow reduction to
-law, we see in the fact that they are severally generalized in the order
-of their frequency and conspicuousness—the moon’s monthly cycle, the
-sun’s annual change, the periods of the inferior planets, the periods of
-the superior planets.
-
-While astronomical sequences were still ascribed to volition, certain
-terrestrial sequences of a different kind, but some of them equally
-without complication, were interpreted in like manner. The
-solidification of water at a low temperature, is a phenomenon that is
-simple, concrete, and of much personal concern. But it is neither so
-frequent as those which we saw are earliest generalized, nor is the
-presence of the antecedent so uniformly conspicuous. Though in all but
-tropical climates, mid-winter displays the relation between cold and
-freezing with tolerable constancy; yet, during the spring and autumn,
-the occasional appearance of ice in the mornings has no very manifest
-connexion with coldness of the weather. Sensation being so inaccurate a
-measure, it is not possible for the savage to experience the definite
-relation between a temperature of 32° and the congealing of water; and
-hence the long-continued conception of personal agency. Similarly, but
-still more clearly, with the winds. The absence of regularity and the
-inconspicuousness of the antecedents, allowed the mythological
-explanation to survive for a great period.
-
-During the era in which the uniformity of many quite simple inorganic
-relations was still unrecognized, certain classes of organic relations,
-intrinsically very complex and special, were generalized. The constant
-coexistence of feathers and a beak, of four legs with a bony internal
-framework, of a particular leaf with poisonous berries, are facts which
-were, and are, familiar to every savage. Did a savage find a bird with
-teeth, or a mammal clothed with feathers, he would be as much surprised
-as an instructed naturalist; and would probably make a fetish of the
-anomalous form: so showing that while the exceptional relation suggested
-the notion of a personal cause, the habitual relation did not. Now these
-uniformities of organic structure which are so early perceived, are of
-exactly the same class as those more numerous ones later established by
-biology. The constant coexistence of mammary glands with two occipital
-condyles in the skull, of vertebræ with teeth lodged in sockets, of
-frontal horns with the habit of rumination, are generalizations as
-purely empirical as those known to the aboriginal hunter. The vegetal
-physiologist cannot in the least understand the complex relation between
-the kind of leaf and the kind of fruit borne by a particular plant: he
-knows these and like connexions simply in the same manner that the
-barbarian knows them. But the fact that sundry of the uniform relations
-which chiefly make up the organic sciences, were very early recognized,
-is due to the high degree of vividness and frequency with which they
-were presented to consciousness. Though the connexion between the form
-of a given creature and the sound it makes, or the quality of its fur,
-or the nature of its flesh, is extremely involved; yet the two terms of
-the relation are conspicuous; are usually observed in close
-juxtaposition in time and space; are so observed perhaps daily, or many
-times a day; and above all a knowledge of their connexion has a direct
-and obvious bearing on personal welfare. Meanwhile, we see that
-innumerable other relations of exactly the same order, which are
-displayed with even greater frequency by surrounding plants and animals,
-remain for thousands of years unrecognized, if they are unobtrusive or
-of no apparent moment.
-
-When, passing from this primitive stage to a more advanced stage, we
-trace the discovery of those less familiar uniformities which constitute
-what is technically distinguished as Science, we find the order of
-discovery to be still determined in the same manner. We shall most
-clearly see this in contemplating separately the influence of each
-derivative condition; as was proposed in the last section.
-
- * * * * *
-
-§ 38. How relations that have an immediate bearing on the maintenance of
-life, are, other things equal, necessarily fixed in the mind before
-those which have no such immediate bearing, is abundantly illustrated in
-the history of Science. The habits of existing uncivilized races, who
-fix times by moons and barter so many of one article for so many of
-another, show us that numeration, which is the germ of mathematical
-science, commenced under the immediate pressure of personal wants; and
-it can scarcely be doubted that those laws of numerical relations which
-are embodied in the rules of arithmetic, were first brought to light
-through the practice of mercantile exchange. Similarly with Geometry.
-The derivation shows us that it originally included only certain methods
-of partitioning ground and laying out buildings. The properties of the
-scales and the lever, involving the first principle in mechanics, were
-early generalized under the stimulus of commercial and architectural
-needs. To fix the times of religious festivals and agricultural
-operations, were the motives which led to the establishment of the
-simpler astronomic periods. Such small knowledge of chemical relations
-as was involved in ancient metallurgy, was manifestly obtained in
-seeking how to improve tools and weapons. In the alchemy of later times,
-we see how greatly an intense hope of private benefit contributed to the
-disclosure of a certain class of uniformities. Nor is our own age barren
-of illustrations. “Here,” says Humboldt when in Guiana, “as in many
-parts of Europe, the sciences are thought worthy to occupy the mind,
-only so far as they confer some immediate and practical benefit on
-society.” “How is it possible to believe,” said a missionary to him,
-“that you have left your country to come and be devoured by mosquitoes
-on this river, and to measure lands that are not your own.” Our coasts
-furnish like instances. Every sea-side naturalist knows how great is the
-contempt with which fishermen regard the collection of objects for the
-microscope or aquarium: their incredulity as to the possible value of
-such things, being so great, that they can scarcely be induced even by
-bribes to preserve the refuse of their nets. Nay, we need not go for
-evidence beyond daily table-talk. The demand for “practical science”—for
-a knowledge that can be brought to bear on the business of life; joined
-to the ridicule commonly vented on pursuits that have no obvious use;
-suffice to show that the order in which different coexistences and
-sequences are discovered, greatly depends on the directness with which
-they affect our welfare.
-
-That, when all other conditions are the same, obtrusive relations will
-be generalized before unobtrusive ones, is so nearly a truism that
-examples appear almost superfluous. If it be admitted that by the
-aboriginal man, as by the child, the co-existent properties of large
-surrounding objects are noticed before those of minute objects; and that
-the external relations which bodies present are generalized before their
-internal ones; it must be admitted that in all subsequent stages of
-progress, the comparative conspicuousness of relations has greatly
-affected the order in which they were recognized as uniform. Hence it
-happened that after the establishment of those very manifest sequences
-constituting a lunation, and those less manifest ones marking a year,
-and those still less manifest ones marking the planetary periods,
-Astronomy occupied itself with such inconspicuous sequences as those
-displayed in the repeating cycle of lunar eclipses, and those which
-suggested the theory of epicycles and eccentrics; while modern Astronomy
-deals with still more inconspicuous sequences: some of which, as the
-planetary rotations, are nevertheless the simplest which the heavens
-present. In Physics, the early use of canoes implied an empirical
-knowledge of certain hydrostatic relations that are intrinsically more
-complex than sundry static relations then unknown; but these hydrostatic
-relations were thrust upon observation. Or if we compare the solution of
-the problem of specific gravity by Archimedes, with the discovery of
-atmospheric pressure by Torricelli, (the two involving mechanical
-relations of exactly the same kind,) we perceive that the much earlier
-occurrence of the first than the last, was determined neither by a
-difference in their bearings on personal welfare, nor by a difference in
-the frequency with which illustrations of them come under observation,
-nor by relative simplicity; but solely by the greater obtrusiveness of
-the connexion between antecedent and consequent in the one case than in
-the other. Similarly with Chemistry. The burning of wood, the rusting of
-iron, the putrefaction of dead bodies, were early known as consequents
-uniformly related to certain antecedents; but not until long after was
-there reached a like empirical knowledge of the effect produced by air
-in the decomposition of soil: a phenomenon of equal simplicity, equal or
-greater importance, and greater frequency; but one that is extremely
-unobtrusive. Among miscellaneous illustrations, it may be pointed out
-that the connexions between lightning and thunder and between rain and
-clouds, were established long before others of the same order; simply
-because they thrust themselves on the attention. Or the long-delayed
-discovery of the microscopic forms of life, with all the phenomena they
-present, may be named as very clearly showing how certain groups of
-relations that are not ordinarily perceptible, though in all other
-respects like long-familiar relations, have to wait until changed
-conditions render them perceptible. But, without further details, it
-needs only to consider the inquiries which now occupy the electrician,
-the chemist, the physiologist, to see that Science has advanced and is
-advancing from the more conspicuous phenomena to the less conspicuous
-ones.
-
-How the degree of absolute frequency of a relation affects the
-recognition of its uniformity, we see in contrasting certain biological
-facts. Death and disease are near akin in most of their relations to us;
-while in respect of complexity, conspicuousness, and the directness with
-which they personally concern us, diseases in general may be put pretty
-nearly on a level with each other. But there are great differences in
-the times at which the natural sequences they severally exhibit are
-recognized as such. The connexion between death and bodily injury,
-constantly displayed not only in men but in all inferior creatures, was
-known as an established uniformity while yet diseases were thought
-supernatural. Among diseases themselves, it is observable that
-comparatively unusual ones were regarded as of demoniacal origin during
-ages when the more frequent were ascribed to ordinary causes: a truth
-paralleled indeed among our own peasantry, who by the use of charms show
-a lingering superstition with respect to rare disorders, which they do
-not show with respect to common ones, such as colds. Passing to physical
-illustrations, we may note that within the historic period, whirlpools
-were accounted for by the agency of water-spirits; but we do not find
-that within the same period the disappearance of water on exposure
-either to the sun or to artificial heat was interpreted in an analogous
-way: though a much more marvellous occurrence, and a much more complex
-one, its great frequency led to the early establishment of it as a
-natural uniformity. Rainbows and comets do not differ greatly in
-conspicuousness, and a rainbow is intrinsically the more involved
-phenomenon; but chiefly because of their far greater commonness,
-rainbows were perceived to have a direct dependence on sun and rain
-while yet comets were regarded as supernatural appearances.
-
-That races living inland must long have remained ignorant of the daily
-and monthly sequences of the tides, and that intertropical races could
-not early have comprehended the phenomena of northern winters, are
-extreme illustrations of the influence which relative frequency has on
-the recognition of uniformities. Animals which, where they are
-indigenous, call forth no surprise by their structure or habits, because
-these are so familiar, when taken to a part of the earth where they have
-never been seen, are looked at with an astonishment approaching to
-awe—are even thought supernatural: a fact which will suggest numerous
-others that show how the localization of phenomena, in part controls the
-order in which they are reduced to law. Not only however does their
-localization in space affect the progression, but also their
-localization in time. Facts which are rarely if ever manifested during
-one era, are rendered very frequent in another, simply through the
-changes wrought by civilization. The lever, of which the properties are
-illustrated in the use of sticks and weapons, is vaguely understood by
-every savage—on applying it in a certain way he rightly anticipates
-certain effects; but the action of the equally simple wedge, which is
-not commonly displayed till tool-making has made some progress, is less
-early generalized; while the wheel and axle, pulley, and screw, cannot
-have their powers either empirically or rationally known till the
-advance of the arts has more or less familiarized them. Through those
-various means of exploration which we have inherited and are ever
-increasing, we have become acquainted with a vast range of chemical
-relations that were relatively non-existent to the primitive man: to
-highly developed industries we owe both the substances and the apparatus
-that have disclosed to us countless uniformities which our ancestors had
-no opportunity of seeing, and therefore could not recognize. These and
-sundry like instances that will occur to the reader, show that the
-accumulated materials, and processes, and appliances, and products,
-which characterize the environments of complex societies, greatly
-increase the accessibility of various classes of relations; and by so
-multiplying the experiences of them, or making them relatively frequent,
-facilitate their generalization. To which add, that various classes of
-phenomena presented by society itself, as for instance those which
-political economy formulates, become relatively frequent and therefore
-recognizable in advanced social states; while in less advanced ones they
-are too rarely displayed to have their relations perceived, or, as in
-the least advanced ones, are not displayed at all.
-
-That, where no other circumstances interfere, the order in which
-different uniformities are established varies as their complexity, is
-manifest. The geometry of straight lines was understood before the
-geometry of curved lines; the properties of the circle before the
-properties of the ellipse, parabola and hyperbola; and the equations of
-curves of single curvature were ascertained before those of curves of
-double curvature. Plane trigonometry comes in order of time and
-simplicity before spherical trigonometry; and the mensuration of plane
-surfaces and solids before the mensuration of curved surfaces and
-solids. Similarly with mechanics: the laws of simple motion were
-generalized before those of compound motion; and those of rectilinear
-motion before those of curvilinear motion. The properties of equal-armed
-levers, or scales, were understood before those of the lever with
-unequal arms; and the law of the inclined plane was formulated earlier
-than that of the screw, which involves it. In chemistry, the progress
-has been from the simple inorganic compounds, to the more involved
-organic ones. And where, as in most of the other sciences, the
-conditions of the exploration are more complicated, we still may clearly
-trace relative complexity as one of the determining circumstances.
-
-The progression from concrete relations to abstract ones, and from the
-less abstract to the more abstract, is equally obvious. Numeration,
-which in its primary form concerned itself only with groups of actual
-objects, came earlier than simple arithmetic: the rules of which deal
-with numbers apart from objects. Arithmetic, limited in its sphere to
-concrete numerical relations, is alike earlier and less abstract than
-Algebra, which deals with the relations of these relations. And in like
-manner, the Infinitesimal Calculus comes after Algebra, both in order of
-evolution and in order of abstractness. In Astronomy, the progress has
-been from special generalizations, each expressing the motions of a
-particular planet, to the generalizations of Kepler, expressing the
-motions of the planets at large; and then to Newton’s generalization,
-expressing the motions of all heavenly bodies whatever. Similarly with
-Physics, Chemistry and Biology, there has ever been an advance from the
-relations of particular facts and particular classes of facts, to the
-relations presented by still wider classes—to truths of a high
-generality or greater abstractness.
-
-Brief and rude as is this sketch of a mental development that has been
-long and complicated, it fulfils its end if it displays the several
-conditions that have regulated the course of the development. I venture
-to think it shows inductively, what was deductively inferred, that the
-order in which separate groups of uniformities are recognized, depends
-not on one circumstance but on several circumstances. A survey of the
-facts makes it manifest that the various classes of relations are
-generalized in a certain succession, not solely because of one
-particular kind of difference in their natures; but also because they
-are variously placed with respect to time, space, other relations, and
-our own constitutions: our perception of them being influenced by all
-these conditions in endless combinations. The comparative degrees of
-importance, of obtrusiveness, of absolute frequency, of relative
-frequency, of simplicity, of concreteness, are every one of them
-factors; and from their union in proportions that are more or less
-different in every case, there results a highly complex process of
-mental evolution. But while it thus becomes manifest that the proximate
-causes of the succession in which relations are reduced to law, are
-numerous and involved; it also becomes manifest that there is one
-ultimate cause to which these proximate ones are subordinate. As the
-several circumstances that determine the early or late recognition of
-uniformities, are circumstances that determine the number and strength
-of the impressions which these uniformities make on the mind; it follows
-that the progression conforms to a certain fundamental principle of
-psychology. We see _à posteriori_, what we concluded _à priori_, that
-the order in which relations are generalized, depends on the frequency
-and impressiveness with which they are repeated in conscious experience.
-
- * * * * *
-
-§ 39. And now to observe the bearings of these truths on our general
-argument. Having roughly analyzed the progress of the past, let us take
-advantage of the light thus thrown on the present, and consider what is
-implied respecting the future.
-
-Note first that the likelihood of the universality of Law, has been ever
-growing greater. Out of the countless coexistences and sequences with
-which mankind are environed, they have been continually transferring
-some from the group whose order was supposed to be arbitrary, to the
-group whose order is known to be uniform. Age by age, the number of
-recognized connexions of phenomena has been increasing; and that of
-unrecognized connexions decreasing. And manifestly, as fast as the class
-of ungeneralized relations becomes smaller, the probability that among
-them there may be some that do not conform to law, becomes less. To put
-the argument numerically—It is clear that when out of surrounding
-phenomena a hundred of several kinds have been found to occur in
-constant connexions, there arises a slight presumption that all
-phenomena occur in constant connexions. When uniformity has been
-established in a thousand cases, more varied in their kinds, the
-presumption gains strength. And when the established cases of uniformity
-mount to myriads, including many of each variety, it becomes an ordinary
-induction that uniformity exists everywhere. Just as from the numerous
-observed cases in which heavenly bodies have been found to move in
-harmony with the law of gravitation, it is inferred that all heavenly
-bodies move in harmony with the law of gravitation; so, from the
-innumerable observed cases in which phenomena are found to stand in
-invariable connexions, it is inferred that in all cases phenomena stand
-in invariable connexions.
-
-Silently and insensibly their experiences have been pressing men on
-towards the conclusion thus drawn. Not out of a conscious regard for
-these abstract reasons, but from a habit of thought which these abstract
-reasons formulate and justify, all minds have been advancing towards a
-belief in the constancy of surrounding coexistences and sequences.
-Familiarity with special uniformities, has generated the abstract
-conception of uniformity—the idea of _Law_; and this idea has been in
-successive generations slowly gaining fixity and clearness. Especially
-has it been thus among those whose knowledge of natural phenomena is the
-most extensive—men of science. The Mathematician, the Physicist, the
-Astronomer, the Chemist, severally acquainted with the vast
-accumulations of uniformities established by their predecessors, and
-themselves daily adding new ones as well as verifying the old, acquire a
-far stronger faith in Law than is ordinarily possessed. With them this
-faith, ceasing to be merely passive, becomes an active stimulus to
-inquiry. Wherever there exist phenomena of which the dependence is not
-yet ascertained, these most cultivated intellects, impelled by the
-conviction that here too there is some invariable connexion, proceed to
-observe, compare, and experiment; and when they discover the law to
-which the phenomena conform, as they eventually do, their general belief
-in the universality of law is further strengthened. So overwhelming is
-the evidence, and such the effect of this discipline, that to the
-advanced student of nature, the proposition that there are lawless
-phenomena, has become not only incredible but almost inconceivable.
-
-Hence we may see how inevitably there must spread among mankind at
-large, this habitual recognition of law which already distinguishes
-modern thought from ancient thought. Not only is it that each conquest
-of generalization over a region of fact hitherto ungeneralized, and each
-merging of lower generalizations in a higher one, adds to the
-distinctness of this recognition among those immediately concerned—not
-only is it that the fulfilment of the predictions made possible by every
-new step, and the further command so gained of nature’s forces, prove to
-the uninitiated the validity of these generalizations and the doctrine
-they illustrate; but it is that widening education is daily diffusing
-among the mass of men, that knowledge of generalizations which has been
-hitherto confined to the few. And as fast as this diffusion goes on,
-must the belief of the scientific become the belief of the world at
-large. The simple accumulation of instances, must inevitably establish
-in the general mind, a conviction of the universality of law; even were
-the influence of this accumulation to be aided by no other.
-
- * * * * *
-
-§ 40. But it will be aided by another. From the evidence above set
-forth, it may be inferred that a secondary influence will by and by
-enforce this primary one. That law is universal, will become an
-irresistible conclusion when it is perceived that _the progress in the
-discovery of laws itself conforms to law_; and when it is hence
-understood why certain groups of phenomena have been reduced to law,
-while other groups are still unreduced. When it is seen that the order
-in which uniformities are recognized, must depend upon the frequency and
-vividness with which they are repeated in conscious experience; when it
-is seen that, as a matter of fact, the most common, important,
-conspicuous, concrete and simple uniformities were the earliest
-recognized, because they were experienced oftenest and most distinctly;
-when it is further seen that from the beginning the advance has been to
-the recognition of uniformities which, from one or other circumstance,
-were less often experienced; it will by implication be seen that long
-after the great mass of phenomena have been generalized, there must
-remain phenomena which, from their rareness, or unobtrusiveness, or
-seeming unimportance, or complexity, or abstractness, are still
-ungeneralized. Thus will be furnished a solution to a difficulty
-sometimes raised. When it is asked why the universality of law is not
-already fully established, there will be the answer that the directions
-in which it is not yet established are those in which its establishment
-must necessarily be latest. That state of things which is inferable
-beforehand, is just the state which we find to exist. If such
-coexistences and sequences as those of Biology and Sociology are not yet
-reduced to law, the presumption is not that they are irreducible to law,
-but that their laws elude our present means of analysis. Having long ago
-proved uniformity throughout all the lower classes of relations; and
-having been step by step proving uniformity throughout classes of
-relations successively higher and higher; if we have not at present
-succeeded with the highest classes, it may be fairly concluded that our
-powers are at fault, rather than that the uniformity does not exist. And
-unless we make the absurd assumption that the process of generalization,
-now going on with unexampled rapidity, has reached its limit, and will
-suddenly cease, we must infer that ultimately mankind will discover a
-constant order of manifestation even in the most involved, obscure, and
-abstract phenomena.
-
- * * * * *
-
-§ 41. Not even yet, however, have we exhausted the evidence. The
-foregoing arguments have to be merged in another, still more cogent,
-which fuses all fragmentary proofs into one general proof.
-
-Thus far we have spoken of laws that are more or less special; and from
-the still-continuing disclosure of special laws, each formulating some
-new class of phenomena, have inferred that eventually all classes of
-phenomena will be formulated. If, now, we find that there are laws of
-far higher generality, to which those constituting the body of Science
-are subordinate; the fact must greatly strengthen the proof that Law is
-universal. If, underneath different groups of concrete phenomena,
-Mechanical, Chemical, Thermal, Electric, &c., we discern certain
-uniformities of action common to them all; we have a new and weighty
-reason for believing that uniformity of action pervades the whole of
-nature. And if we also see that these most general laws hold not only of
-the inorganic but of the organic worlds—if we see that the phenomena of
-Life, of Mind, of Society, whose special laws are yet unestablished,
-nevertheless conform to these most general laws; the proof of the
-universality of Law amounts to demonstration.
-
-That there are laws of this transcendant generality, has now to be
-shown. To specify and illustrate them, will be the purpose of the
-succeeding chapters. And while, in contemplating them, we shall perceive
-how irresistible is the conclusion that the workings of the Unknowable
-are distinguished from those of finite agents by their absolute
-uniformity; we shall at the same time familiarize ourselves with those
-primary facts through which all other facts are to be interpreted.
-
-
-
-
- CHAPTER II.
- THE LAW OF EVOLUTION.[8]
-
-
-§ 42. The class of phenomena to be considered under the title of
-Evolution, is in a great measure co-extensive with the class commonly
-indicated by the word Progress. But the word Progress is here
-inappropriate, for several reasons. To specify these reasons will
-perhaps be the best way of showing what is to be understood by
-Evolution.
-
-In the first place, the current conception of Progress is shifting and
-indefinite. Sometimes it comprehends little more than simple growth—as
-of a nation in the number of its members and the extent of territory
-over which it has spread. At other times it has reference to quantity of
-material products—as when the advance of agriculture and manufactures is
-the topic. Now the superior quality of these products is contemplated;
-and then the new or improved appliances by which they are produced.
-When, again, we speak of moral or intellectual progress, we refer to the
-state of the individual or people exhibiting it; while, when the
-progress of Knowledge, of Science, of Art, is commented upon, we have in
-view certain abstract results of human thought and action. In the
-second place, besides being more or less vague, the ordinary idea of
-Progress is in great measure erroneous. It takes in not so much the
-reality as its accompaniments—not so much the substance as the shadow.
-That progress in intelligence seen during the growth of the child into
-the man, or the savage into the philosopher, is commonly regarded as
-consisting in the greater number of facts known and laws understood;
-whereas the actual progress consists in those internal modifications of
-which this increased knowledge is the expression. Social progress is
-supposed to consist in the produce of a greater quantity and variety of
-the articles required for satisfying men’s wants—in the increasing
-security of person and property—in widening freedom of action; whereas,
-rightly understood, social progress consists in those changes of
-structure in the social organism which have entailed these consequences.
-The interpretation is a teleological one. The phenomena are contemplated
-solely as bearing on human happiness. Only those changes are held to
-constitute progress, which directly or indirectly tend to heighten human
-happiness. And they are thought to constitute progress simply _because_
-they tend to heighten human happiness. In the third place, in
-consequence of its teleological implications, the term Progress is
-rendered scarcely applicable to a wide range of phenomena which are
-intrinsically of the same nature as those included under it. The
-metamorphoses of an insect are only by analogy admitted within the scope
-of the word, as popularly accepted; though, considered in themselves,
-they have as much right there as the changes which constitute
-civilization. Having no apparent bearing on human interests, an
-increasing complication in the arrangement of ocean-currents, would not
-ordinarily be regarded as progress; though really of the same character
-as phenomena which are so regarded.
-
-Hence the need for another word. Our purpose here is to analyze the
-various class of changes usually considered as Progress, together with
-others like them which are not so considered; and to see what is their
-intrinsic peculiarity—what is their essential nature apart from their
-bearings on our welfare. And that we may avoid the confusion of thought
-likely to result from pre-established associations, it will be best to
-substitute for the term Progress, the term Evolution. Our question is
-then—what is Evolution?
-
- * * * * *
-
-§ 43. In respect to that evolution which individual organisms display,
-this question has been answered. Pursuing an idea which Harvey set
-afloat, Wolff, Goethe, and Von Baer, have established the truth that the
-series of changes gone through during the development of a seed into a
-tree, or an ovum into an animal, constitute an advance from homogeneity
-of structure to heterogeneity of structure. In its primary stage, every
-germ consists of a substance that is uniform throughout, both in texture
-and chemical composition. The first step is the appearance of a
-difference between two parts of this substance; or, as the phenomenon is
-called in physiological language, a differentiation. Each of these
-differentiated divisions presently begins itself to exhibit some
-contrast of parts; and by and by these secondary differentiations become
-as definite as the original one. This process is continuously
-repeated—is simultaneously going on in all parts of the growing embryo;
-and by endless such differentiations there is finally produced that
-complex combination of tissues and organs, constituting the adult animal
-or plant. This is the history of all organisms whatever. It is settled
-beyond dispute that organic evolution consists in a change from the
-homogeneous to the heterogeneous.
-
-Now I propose in the first place to show, that this law of organic
-evolution is the law of all evolution. Whether it be in the development
-of the Earth, in the development of Life upon its surface, in the
-development of Society, of Government, of Manufactures, of Commerce, of
-Language, Literature, Science, Art, this same advance from the simple to
-the complex, through successive differentiations, holds uniformly. From
-the earliest traceable cosmical changes down to the latest results of
-civilization, we shall find that the transformation of the homogeneous
-into the heterogeneous, is that in which Evolution essentially consists.
-
- * * * * *
-
-§ 44. With the view of showing that _if_ the Nebular Hypothesis be true,
-the genesis of the solar system supplies one illustration of this law,
-let us assume that the matter of which the sun and planets consist was
-once in a diffused form; and that from the gravitation of its atoms
-there resulted a gradual concentration. By the hypothesis, the solar
-system in its nascent state existed as an indefinitely extended and
-nearly homogeneous medium—a medium almost homogeneous in density, in
-temperature, and in other physical attributes. The first advance towards
-consolidation resulted in a differentiation between the occupied space
-which the nebulous mass still filled, and the unoccupied space which it
-previously filled. There simultaneously resulted a contrast in density
-and a contrast in temperature, between the interior and the exterior of
-this mass. And at the same time there arose throughout it, rotatory
-movements, whose velocities varied according to their distances from its
-centre. These differentiations increased in number and degree until
-there was evolved the organized group of sun, planets, and satellites,
-which we now know—a group which presents numerous contrasts of structure
-and action among its members. There are the immense contrasts between
-the sun and the planets, in bulk and in weight; as well as the
-subordinate contrasts between one planet and another, and between the
-planets and their satellites. There is the similarly marked contrast
-between the sun as almost stationary, and the planets as moving round
-him with great velocity; while there are the secondary contrasts between
-the velocities and periods of the several planets, and between their
-simple revolutions and the double ones of their satellites, which have
-to move round their primaries while moving round the sun. There is the
-yet further strong contrast between the sun and the planets in respect
-of temperature; and there is reason to suppose that the planets and
-satellites differ from each other in their proper heat, as well as in
-the heat they receive from the sun. When we bear in mind that, in
-addition to these various contrasts, the planets and satellites also
-differ in respect to their distances from each other and their primary;
-in respect to the inclinations of their orbits, the inclinations of
-their axes, their times of rotation on their axes, their specific
-gravities, and their physical constitutions; we see what a high degree
-of heterogeneity the solar system exhibits, when compared with the
-almost complete homogeneity of the nebulous mass out of which it is
-supposed to have originated.
-
- * * * * *
-
-§ 45. Passing from this hypothetical illustration, which must be taken
-for what it is worth, without prejudice to the general argument, let us
-descend to a more certain order of evidence.
-
-It is now generally agreed among geologists that the Earth was at first
-a mass of molten matter; and that it is still fluid and incandescent at
-the distance of a few miles beneath its surface. Originally, then, it
-was homogeneous in consistence, and, because of the circulation that
-takes place in heated fluids, must have been comparatively homogeneous
-in temperature; and it must have been surrounded by an atmosphere
-consisting partly of the elements of air and water, and partly of those
-various other elements which assume a gaseous form at high temperatures.
-That slow cooling by radiation which is still going on at an
-inappreciable rate, and which, though originally far more rapid than
-now, necessarily required an immense time to produce any decided change,
-must ultimately have resulted in the solidification of the portion most
-able to part with its heat; namely, the surface. In the thin crust thus
-formed, we have the first marked differentiation. A still further
-cooling, a consequent thickening of this crust, and an accompanying
-deposition of all solidifiable elements contained in the atmosphere,
-must finally have been followed by the condensation of the water
-previously existing as vapour. A second marked differentiation must thus
-have arisen; and as the condensation must have taken place on the
-coolest parts of the surface—namely, about the poles—there must thus
-have resulted the first geographical distinction of parts.
-
-To these illustrations of growing heterogeneity, which, though deduced
-from the known laws of matter, may be regarded as more or less
-hypothetical, Geology adds an extensive series that have been
-inductively established. Its investigations show that the Earth has been
-continually becoming more heterogeneous through the multiplication of
-the strata which form its crust; further, that it has been becoming more
-heterogeneous in respect of the composition of these strata, the latter
-of which, being made from the detritus of the older ones, are many of
-them rendered highly complex by the mixture of materials they contain;
-and that this heterogeneity has been vastly increased by the action of
-the Earth’s still molten nucleus upon its envelope: whence have resulted
-not only a great variety of igneous rocks, but the tilting up of
-sedimentary strata at all angles, the formation of faults and metallic
-veins, the production of endless dislocations and irregularities. Yet
-again, geologists teach us that the Earth’s surface has been growing
-more varied in elevation—that the most ancient mountain systems are the
-smallest, and the Andes and Himalayas the most modern; while, in all
-probability, there have been corresponding changes in the bed of the
-ocean. As a consequence of these ceaseless differentiations, we now find
-that no considerable portion of the Earth’s exposed surface is like any
-other portion, either in contour, in geologic structure, or in chemical
-composition; and that in most parts it changes from mile to mile in all
-these characteristics.
-
-Moreover, it must not be forgotten that there has been simultaneously
-going on a gradual differentiation of climates. As fast as the Earth
-cooled and its crust solidified, there arose appreciable differences in
-temperature between those parts of its surface most exposed to the sun
-and those less exposed. Gradually, as the cooling progressed, these
-differences became more pronounced; until there finally resulted the
-marked contrasts between regions of perpetual ice and snow, regions
-where winter and summer alternately reign for periods varying according
-to the latitude, and regions where summer follows summer with scarcely
-an appreciable variation. At the same time, the successive elevations
-and subsidences of different portions of the Earth’s crust, tending as
-they have done to the present irregular distribution of land and sea,
-have entailed various modifications of climate beyond those dependent on
-latitude; while a yet further series of such modifications have been
-produced by increasing differences of elevation in the land, which have
-in sundry places brought arctic, temperate, and tropical climates to
-within a few miles of each other. And the general result of these
-changes is, that not only has every extensive region its own
-meteorologic conditions, but that every locality in each region differs
-more or less from others in those conditions: as in its structure, its
-contour, its soil.
-
-Thus, between our existing Earth, the phenomena of whose varied crust
-neither geographers, geologists, mineralogists nor meteorologists have
-yet enumerated, and the molten globe out of which it was evolved, the
-contrast in heterogeneity is sufficiently striking.
-
- * * * * *
-
-§ 46. When from the Earth itself we turn to the plants and animals that
-have lived, or still live, upon its surface, we find ourselves in some
-difficulty from lack of facts. That every existing organism has been
-developed out of the simple into the complex, is indeed the first
-established truth of all; and that every organism which has existed was
-similarly developed, is an inference that no physiologist will hesitate
-to draw. But when we pass from individual forms of life to Life in
-general, and inquire whether the same law is seen in the _ensemble_ of
-its manifestations,—whether modern plants and animals are of more
-heterogeneous structure than ancient ones, and whether the Earth’s
-present Flora and Fauna are more heterogeneous than the Flora and Fauna
-of the past,—we find the evidence so fragmentary, that every conclusion
-is open to dispute. Two-thirds of the Earth’s surface being covered by
-water; a great part of the exposed land being inaccessible to, or
-untravelled by, the geologist; the greater part of the remainder having
-been scarcely more than glanced at; and even the most familiar portions,
-as England, having been so imperfectly explored, that a new series of
-strata has been added within these few years,—it is manifestly
-impossible for us to say with any certainty what creatures have, and
-what have not, existed at any particular period. Considering the
-perishable nature of many of the lower organic forms, the metamorphosis
-of many sedimentary strata, and the gaps that occur among the rest, we
-shall see further reason for distrusting our deductions. On the one
-hand, the repeated discovery of vertebrate remains in strata previously
-supposed to contain none,—of reptiles where only fish were thought to
-exist,—of mammals where it was believed there were no creatures higher
-than reptiles; renders it daily more manifest how small is the value of
-negative evidence. On the other hand, the worthlessness of the
-assumption that we have discovered the earliest, or anything like the
-earliest, organic remains, is becoming equally clear. That the oldest
-known aqueous formations have been greatly changed by igneous action,
-and that still older ones have been totally transformed by it, is
-becoming undeniable. And the fact that sedimentary strata earlier than
-any we know, have been melted up, being admitted, it must also be
-admitted that we cannot say how far back in time this destruction of
-sedimentary strata has been going on. Thus it is manifest that the title
-_Palæozoic_, as applied to the earliest known fossiliferous strata,
-involves a _petitio principii_; and that, for aught we know to the
-contrary, only the last few chapters of the Earth’s biological history
-may have come down to us.
-
-All inferences drawn from such scattered facts as we find, must thus be
-extremely questionable. If, looking at the general aspect of evidence, a
-progressionist argues that the earliest known vertebrate remains are
-those of Fishes, which are the most homogeneous of the vertebrata; that
-Reptiles, which are more heterogeneous, are later; and that later still,
-and more heterogeneous still, are Mammals and Birds; it may be replied
-that the Palæozoic deposits, not being estuary deposits, are not likely
-to contain the remains of terrestrial vertebrata, which may nevertheless
-have existed at that era. The same answer may be made to the argument
-that the vertebrate fauna of the Palæozoic period, consisting so far as
-we know, entirely of Fishes, was less heterogeneous than the modern
-vertebrate fauna, which includes Reptiles, Birds and Mammals, of
-multitudinous genera; or the uniformitarian may contend with great show
-of truth, that this appearance of higher and more varied forms in later
-geologic eras, was due to progressive immigration—that a continent
-slowly upheaved from the ocean at a point remote from pre-existing
-continents, would necessarily be peopled from them in a succession like
-that which our strata display. At the same time the
-counter-arguments may be proved equally inconclusive. When, to show that
-there cannot have been a continuous evolution of the more homogeneous
-organic forms into the more heterogeneous ones, the uniformitarian
-points to the breaks that occur in the succession of these forms; there
-is the sufficient answer that current geological changes show us why
-such breaks must occur, and why, by subsidences and elevations of large
-area, there must be produced such marked breaks as those which divide
-the three great geologic epochs. Or again, if the opponent of the
-development hypothesis cites the facts set forth by Professor Huxley in
-his lecture on “Persistent Types”—if he points out that “of some two
-hundred known orders of plants, not one is exclusively fossil,” while
-“among animals, there is not a single totally extinct class; and of the
-orders, at the outside not more than seven per cent. are unrepresented
-in the existing creation”—if he urges that among these some have
-continued from the Silurian epoch to our own day with scarcely any
-change—and if he infers that there is evidently a much greater average
-resemblance between the living forms of the past and those of the
-present, than consists with this hypothesis; there is still a
-satisfactory reply, on which in fact Prof. Huxley insists; namely, that
-we have evidence of a “pre-geologic era” of unknown duration. And
-indeed, when it is remembered, that the enormous subsidences of the
-Silurian period show the Earth’s crust to have been approximately as
-thick then as it is now—when it is concluded that the time taken to form
-so thick a crust, must have been immense as compared with the time which
-has since elapsed—when it is assumed, as it must be, that during this
-comparatively immense time the geologic and biologic changes went on at
-their usual rates; it becomes manifest, not only that the
-palæontological records which we find, do not negative the theory of
-evolution, but that they are such as might rationally be looked for.
-
-Moreover, it must not be forgotten that though the evidence suffices
-neither for proof nor disproof, yet some of its most conspicuous facts
-support the belief, that the more heterogeneous organisms and groups of
-organisms, have been evolved from the less heterogeneous ones. The
-average community of type between the fossils of adjacent strata, and
-still more the community that is found between the latest tertiary
-fossils and creatures now existing, is one of these facts. The discovery
-in some modern deposits of such forms as the Palæotherium and
-Anaplotherium, which, if we may rely on Prof. Owen, had a type of
-structure intermediate between some of the types now existing, is
-another of these facts. And the comparatively recent appearance of Man,
-is a third fact of this kind, which possesses still greater
-significance. Hence we may say, that though our knowledge of past life
-upon the Earth, is too scanty to justify us in asserting an evolution of
-the simple into the complex, either in individual forms or in the
-aggregate of forms; yet the knowledge we have, not only consists with
-the belief that there has been such an evolution, but rather supports it
-than otherwise.
-
- * * * * *
-
-§ 47. Whether an advance from the homogeneous to the heterogeneous is or
-is not displayed in the biological history of the globe, it is clearly
-enough displayed in the progress of the latest and most heterogeneous
-creature—Man. It is alike true that, during the period in which the
-Earth has been peopled, the human organism has grown more heterogeneous
-among the civilized divisions of the species; and that the species, as a
-whole, has been made more heterogeneous by the multiplication of races
-and the differentiation of these races from each other. In proof
-of the first of these positions, we may cite the fact that, in the
-relative development of the limbs, the civilized man departs more widely
-from the general type of the placental mammalia, than do the lower human
-races. Though often possessing well-developed body and arms, the Papuan
-has extremely small legs: thus reminding us of the quadrumana, in which
-there is no great contrast in size between the hind and fore limbs. But
-in the European, the greater length and massiveness of the legs has
-become very marked—the fore and hind limbs are relatively more
-heterogeneous. Again, the greater ratio which the cranial bones bear to
-the facial bones, illustrates the same truth. Among the vertebrata in
-general, evolution is marked by an increasing heterogeneity in the
-vertebral column, and more especially in the segments constituting the
-skull: the higher forms being distinguished by the relatively larger
-size of the bones which cover the brain, and the relatively smaller size
-of those which form the jaws, &c. Now, this characteristic, which is
-stronger in Man than in any other creature, is stronger in the European
-than in the savage. Moreover, judging from the greater extent and
-variety of faculty he exhibits, we may infer that the civilized man has
-also a more complex or heterogeneous nervous system than the uncivilized
-man; and indeed the fact is in part visible in the increased ratio which
-his cerebrum bears to the subjacent ganglia. If further elucidation be
-needed, we may find it in every nursery. The infant European has sundry
-marked points of resemblance to the lower human races; as in the
-flatness of the alæ of the nose, the depression of its bridge, the
-divergence and forward opening of the nostrils, the form of the lips,
-the absence of a frontal sinus, the width between the eyes, the
-smallness of the legs. Now, as the developmental process by which these
-traits are turned into those of the adult European, is a continuation of
-that change from the homogeneous to the heterogeneous displayed during
-the previous evolution of the embryo, which every physiologist will
-admit; it follows that the parallel developmental process by which the
-like traits of the barbarous races have been turned into those of the
-civilized races, has also been a continuation of the change from the
-homogeneous to the heterogeneous. The truth of the second
-position—that Mankind, as a whole, have become more heterogeneous—is so
-obvious as scarcely to need illustration. Every work on Ethnology, by
-its divisions and subdivisions of races, bears testimony to it. Even
-were we to admit the hypothesis that Mankind originated from several
-separate stocks, it would still remain true that as, from each of these
-stocks, there have sprung many now widely different tribes, which are
-proved by philological evidence to have had a common origin, the race as
-a whole is far less homogeneous than it once was. Add to which, that we
-have, in the Anglo-Americans, an example of a new variety arising within
-these few generations; and that, if we may trust to the descriptions of
-observers, we are likely soon to have another such example in Australia.
-
- * * * * *
-
-§ 48. On passing from Humanity under its individual form, to Humanity as
-socially embodied, we find the general law still more variously
-exemplified. The change from the homogeneous to the heterogeneous, is
-displayed equally in the progress of civilization as a whole, and in the
-progress of every tribe or nation; and is still going on with increasing
-rapidity.
-
-As we see in existing barbarous tribes, society in its first and lowest
-form is a homogeneous aggregation of individuals having like powers and
-like functions: the only marked difference of function being that which
-accompanies difference of sex. Every man is warrior, hunter, fisherman,
-tool-maker, builder; every woman performs the same drudgeries; every
-family is self-sufficing, and, save for purposes of aggression and
-defence, might as well live apart from the rest. Very early, however, in
-the process of social evolution, we find an incipient differentiation
-between the governing and the governed. Some kind of chieftainship seems
-coeval with the first advance from the state of separate wandering
-families to that of a nomadic tribe. The authority of the strongest
-makes itself felt among a body of savages, as in a herd of animals, or a
-posse of school-boys. At first, however, it is indefinite, uncertain; is
-shared by others of scarcely inferior power; and is unaccompanied by any
-difference in occupation or style of living: the first ruler kills his
-own game, makes his own weapons, builds his own hut, and, economically
-considered, does not differ from others of his tribe. Gradually, as the
-tribe progresses, the contrast between the governing and the governed
-grows more decided. Supreme power becomes hereditary in one family; the
-head of that family, ceasing to provide for his own wants, is served by
-others; and he begins to assume the sole office of ruling. At the
-same time there has been arising a co-ordinate species of
-government—that of Religion. As all ancient records and traditions
-prove, the earliest rulers are regarded as divine personages. The maxims
-and commands they uttered during their lives are held sacred after their
-deaths, and are enforced by their divinely-descended successors; who in
-their turns are promoted to the pantheon of the race, there to be
-worshipped and propitiated along with their predecessors: the most
-ancient of whom is the supreme god, and the rest subordinate gods. For a
-long time these connate forms of government—civil and religious—continue
-closely associated. For many generations the king continues to be the
-chief priest, and the priesthood to be members of the royal race. For
-many ages religious law continues to contain more or less of civil
-regulation, and civil law to possess more or less of religious sanction;
-and even among the most advanced nations these two controlling agencies
-are by no means completely differentiated from each other. Having
-a common root with these, and gradually diverging from them, we find yet
-another controlling agency—that of Manners or ceremonial usages. All
-titles of honour are originally the names of the god-king; afterwards of
-God and the king; still later of persons of high rank; and finally come,
-some of them, to be used between man and man. All forms of complimentary
-address were at first the expressions of submission from prisoners to
-their conqueror, or from subjects to their ruler, either human or
-divine—expressions that were afterwards used to propitiate subordinate
-authorities, and slowly descended into ordinary intercourse. All modes
-of salutation were once obeisances made before the monarch and used in
-worship of him after his death. Presently others of the god-descended
-race were similarly saluted; and by degrees some of the salutations have
-become the due of all.[9] Thus, no sooner does the originally
-homogeneous social mass differentiate into the governed and the
-governing parts, than this last exhibits an incipient differentiation
-into religious and secular—Church and State; while at the same time
-there begins to be differentiated from both, that less definite species
-of government which rides our daily intercourse—a species of government
-which, as we may see in heralds’ colleges, in books of the peerage, in
-masters of ceremonies, is not without a certain embodiment of its own.
- Each of these kinds of government is itself subject to successive
-differentiations. In the course of ages, there arises, as among
-ourselves, a highly complex political organization of monarch,
-ministers, lords and commons, with their subordinate administrative
-departments, courts of justice, revenue offices, &c., supplemented in
-the provinces by municipal governments, county governments, parish or
-union governments—all of them more or less elaborated. By its side there
-grows up a highly complex religious organization, with its various
-grades of officials from archbishops down to sextons, its colleges,
-convocations, ecclesiastical courts, &c.; to all which must be added the
-ever-multiplying independent sects, each with its general and local
-authorities. And at the same time there is developed a highly complex
-aggregation of customs, manners, and temporary fashions, enforced by
-society at large, and serving to control those minor transactions
-between man and man which are not regulated by civil and religious law.
-Moreover, it is to be observed that this ever-increasing heterogeneity
-in the governmental appliances of each nation, has been accompanied by
-an increasing heterogeneity in the governmental appliances of different
-nations: all of which are more or less unlike in their political systems
-and legislation, in their creeds and religious institutions, in their
-customs and ceremonial usages.
-
-Simultaneously there has been going on a second differentiation of a
-more familiar kind; that, namely, by which the mass of the community
-has been segregated into distinct classes and orders of workers. While
-the governing part has undergone the complex development above
-detailed, the governed part has undergone an equally complex
-development; which has resulted in that minute division of labour
-characterizing advanced nations. It is needless to trace out
-this progress from its first stages, up through the caste divisions of
-the East and the incorporated guilds of Europe, to the elaborate
-producing and distributing organization existing among ourselves.
-Political economists have long since indicated the evolution which,
-beginning with a tribe whose members severally perform the same
-actions, each for himself ends with a civilized community whose
-members severally perform different actions for each other; and they
-have further pointed out the changes through which the solitary
-producer of any one commodity, is transformed into a combination of
-producers who, united under a master, take separate parts in the
-manufacture of such commodity. But there are yet other and
-higher phases of this advance from the homogeneous to the
-heterogeneous in the industrial organization of society. Long after
-considerable progress has been made in the division of labour among
-the different classes of workers, there is still little or no division
-of labour among the widely separated parts of the community: the
-nation continues comparatively homogeneous in the respect that in each
-district the same occupations are pursued. But when roads and other
-means of transit become numerous and good, the different districts
-begin to assume different functions, and to become mutually dependent.
-The calico-manufacture locates itself in this county, the
-woollen-manufacture in that; silks are produced here, lace there;
-stockings in one place, shoes in another; pottery, hardware, cutlery,
-come to have their special towns; and ultimately every locality grows
-more or less distinguished from the rest by the leading occupation
-carried on in it. Nay, more, this subdivision of functions shows
-itself not only among the different parts of the same nation, but
-among different nations. That exchange of commodities which free-trade
-promises so greatly to increase, will ultimately have the effect of
-specializing, in a greater or less degree, the industry of each
-people. So that beginning with a barbarous tribe, almost if not
-quite homogeneous in the functions of its members, the progress has
-been, and still is, towards an economic aggregation of the whole human
-race; growing ever more heterogeneous in respect of the separate
-functions assumed by separate nations, the separate functions assumed
-by the local sections of each nation, the separate functions assumed
-by the many kinds of makers and traders in each town, and the separate
-functions assumed by the workers united in producing each commodity.
-
- * * * * *
-
-§ 49. Not only is the law thus clearly exemplified in the evolution of
-the social organism, but it is exemplified with equal clearness in the
-evolution of all products of human thought and action; whether concrete
-or abstract, real or ideal. Let us take Language as our first
-illustration.
-
-The lowest form of language is the exclamation, by which an entire idea
-is vaguely conveyed through a single sound; as among the lower animals.
-That human language ever consisted solely of exclamations, and so was
-strictly homogeneous in respect of its parts of speech, we have no
-evidence. But that language can be traced down to a form in which nouns
-and verbs are its only elements, is an established fact. In the gradual
-multiplication of parts of speech out of these primary ones—in the
-differentiation of verbs into active and passive, of nouns into abstract
-and concrete—in the rise of distinctions of mood, tense, person, of
-number and case—in the formation of auxiliary verbs, of adjectives,
-adverbs, pronouns, prepositions, articles—in the divergence of those
-orders, genera, species, and varieties of parts of speech by which
-civilized races express minute modifications of meaning—we see a change
-from the homogeneous to the heterogeneous. And it may be remarked, in
-passing, that it is more especially in virtue of having carried this
-subdivision of functions to a greater extent and completeness, that the
-English language is superior to all others. Another aspect under
-which we may trace the development of language, is the differentiation
-of words of allied meanings. Philology early disclosed the truth that in
-all languages words may be grouped into families having a common
-ancestry. An aboriginal name, applied indiscriminately to each of an
-extensive and ill-defined class of things or actions, presently
-undergoes modifications by which the chief divisions of the class are
-expressed. These several names springing from the primitive root,
-themselves become the parents of other names still further modified. And
-by the aid of those systematic modes which presently arise, of making
-derivatives and forming compound terms expressing still smaller
-distinctions, there is finally developed a tribe of words so
-heterogeneous in sound and meaning, that to the uninitiated it seems
-incredible they should have had a common origin. Meanwhile, from other
-roots there are being evolved other such tribes, until there results a
-language of some sixty thousand or more unlike words, signifying as many
-unlike objects, qualities, acts. Yet another way in which language
-in general advances from the homogeneous to the heterogeneous, is in the
-multiplication of languages. Whether, as Max Müller and Bunsen think,
-all languages have grown from one stock, or whether, as some
-philologists say, they have grown from two or more stocks, it is clear
-that since large families of languages, as the Indo-European, are of one
-parentage, they have become distinct through a process of continuous
-divergence. The same diffusion over the Earth’s surface which has led to
-the differentiation of the race, has simultaneously led to a
-differentiation of their speech: a truth which we see further
-illustrated in each nation by the peculiarities of dialect found in
-separate districts. Thus the progress of Language conforms to the
-general law, alike in the evolution of languages, in the evolution of
-families of words, and in the evolution of parts of speech.
-
-On passing from spoken to written language, we come upon several classes
-of facts, all having similar implications. Written language is connate
-with Painting and Sculpture; and at first all three are appendages of
-Architecture, and have a direct connexion with the primary form of all
-Government—the theocratic. Merely noting by the way the fact that sundry
-wild races, as for example the Australians and the tribes of South
-Africa, are given to depicting personages and events upon the walls of
-caves, which are probably regarded as sacred places, let us pass to the
-case of the Egyptians. Among them, as also among the Assyrians, we find
-mural paintings used to decorate the temple of the god and the palace of
-the king (which were, indeed, originally identical); and as such they
-were governmental appliances in the same sense that state-pageants and
-religious feasts were. Further, they were governmental appliances in
-virtue of representing the worship of the god, the triumphs of the
-god-king, the submission of his subjects, and the punishment of the
-rebellious. And yet again they were governmental, as being the products
-of an art reverenced by the people as a sacred mystery. From the
-habitual use of this pictorial representation, there naturally grew up
-the but slightly-modified practice of picture-writing—a practice which
-was found still extant among the Mexicans at the time they were
-discovered. By abbreviations analogous to those still going on in our
-own written and spoken language, the most familiar of these pictured
-figures were successively simplified; and ultimately there grew up a
-system of symbols, most of which had but a distant resemblance to the
-things for which they stood. The inference that the hieroglyphics of the
-Egyptians were thus produced, is confirmed by the fact that the
-picture-writing of the Mexicans was found to have given birth to a like
-family of ideographic forms; and among them, as among the Egyptians,
-these had been partially differentiated into the _kuriological_ or
-imitative, and the _tropical_ or symbolic: which were, however, used
-together in the same record. In Egypt, written language underwent a
-further differentiation; whence resulted the _hieratic_ and the
-_epistolographic_ or _enchorial_: both of which are derived from the
-original hieroglyphic. At the same time we find that for the expression
-of proper names, which could not be otherwise conveyed, phonetic symbols
-were employed; and though it is alleged that the Egyptians never
-actually achieved complete alphabetic writing, yet it can scarcely be
-doubted that these phonetic symbols occasionally used in aid of their
-ideographic ones, were the germs out of which alphabetic writing grew.
-Once having become separate from hieroglyphics, alphabetic writing
-itself underwent numerous differentiations—multiplied alphabets were
-produced: between most of which, however, more or less connexion can
-still be traced. And in each civilized nation there has now grown up,
-for the representation of one set of sounds, several sets of written
-signs, used for distinct purposes. Finally, through a yet more important
-differentiation came printing; which, uniform in kind as it was at
-first, has since become multiform.
-
- * * * * *
-
-§ 50. While written language was passing through its earlier stages of
-development, the mural decoration which formed its root was being
-differentiated into Painting and Sculpture. The gods, kings, men, and
-animals represented, were originally marked by indented outlines and
-coloured. In most cases these outlines were of such depth, and the
-object they circumscribed so far rounded and marked out in its leading
-parts, as to form a species of work intermediate between intaglio and
-bas-relief. In other cases we see an advance upon this: the raised
-spaces between the figures being chiselled off, and the figures
-themselves appropriately tinted, a painted bas-relief was produced. The
-restored Assyrian architecture at Sydenham, exhibits this style of art
-carried to greater perfection—the persons and things represented, though
-still barbarously coloured, are carved out with more truth and in
-greater detail; and in the winged lions and bulls used for the angles of
-gateways, we may see a considerable advance towards a completely
-sculptured figure; which, nevertheless, is still coloured, and still
-forms part of the building. But while in Assyria the production of a
-statue proper, seems to have been little, if at all, attempted, we may
-trace in Egyptian art the gradual separation of the sculptured figure
-from the wall. A walk through the collection in the British Museum will
-clearly show this; while it will at the same time afford an opportunity
-of observing the evident traces which the independent statues bear of
-their derivation from bas-relief: seeing that nearly all of them not
-only display that union of the limbs with the body which is the
-characteristic of bas-relief, but have the back of the statue united
-from head to foot with a block which stands in place of the original
-wall. Greece repeated the leading stages of this progress. As in
-Egypt and Assyria, these twin arts were at first united with each other
-and with their parent, Architecture; and were the aids of Religion and
-Government. On the friezes of Greek temples, we see coloured bas-reliefs
-representing sacrifices, battles, processions, games—all in some sort
-religious. On the pediments we see painted sculptures more or less
-united with the tympanum, and having for subjects the triumphs of gods
-or heroes. Even when we come to statues that are definitely separated
-from the buildings to which they pertain, we still find them coloured;
-and only in the later periods of Greek civilization, does the
-differentiation of sculpture from painting appear to have become
-complete. In Christian art we may clearly trace a parallel
-re-genesis. All early paintings and sculptures throughout Europe, were
-religious in subject—represented Christs, crucifixions, virgins, holy
-families, apostles, saints. They formed integral parts of church
-architecture, and were among the means of exciting worship: as in Roman
-Catholic countries they still are. Moreover, the early sculptures of
-Christ on the cross, of virgins, of saints, were coloured; and it needs
-but to call to mind the painted madonnas and crucifixes still abundant
-in continental churches and highways, to perceive the significant fact
-that painting and sculpture continue in closest connexion with each
-other, where they continue in closest connexion with their parent. Even
-when Christian sculpture was pretty clearly differentiated from
-painting, it was still religious and governmental in its subjects—was
-used for tombs in churches and statues of kings; while, at the same
-time, painting, where not purely ecclesiastical, was applied to the
-decoration of palaces, and besides representing royal personages, was
-almost wholly devoted to sacred legends. Only in quite recent times have
-painting and sculpture become entirely secular arts. Only within these
-few centuries has painting been divided into historical, landscape,
-marine, architectural, genre, animal, still-life, &c., and sculpture
-grown heterogeneous in respect of the variety of real and ideal subjects
-with which it occupies itself.
-
-Strange as it seems then, we find it no less true, that all forms of
-written language, of painting, and of sculpture, have a common root in
-the politico-religious decorations of ancient temples and palaces.
-Little resemblance as they now have, the bust that stands on the
-console, the landscape that hangs against the wall, and the copy of the
-_Times_ lying upon the table, are remotely akin; not only in nature, but
-by extraction. The brazen face of the knocker which the postman has just
-lifted, is related not only to the woodcuts of the _Illustrated London
-News_ which he is delivering, but to the characters of the _billet-doux_
-which accompanies it. Between the painted window, the prayer-book on
-which its light falls, and the adjacent monument, there is
-consanguinity. The effigies on our coins, the signs over shops, the
-figures that fill every ledger, the coat of arms outside the
-carriage-panel, and the placards inside the omnibus, are, in common with
-dolls, blue-books and paper-hangings, lineally descended from the rude
-sculpture-paintings in which the Egyptians represented the triumphs and
-worship of their god-kings. Perhaps no example can be given which more
-vividly illustrates the multiplicity and heterogeneity of the products
-that in course of time may arise by successive differentiations from a
-common stock.
-
-Before passing to other classes of facts, it should be observed that the
-evolution of the homogeneous into the heterogeneous is displayed not
-only in the separation of Painting and Sculpture from Architecture and
-from each other, and in the greater variety of subjects they embody; but
-it is further shown in the structure of each work. A modern picture or
-statue is of far more heterogeneous nature than an ancient one. An
-Egyptian sculpture-fresco represents all its figures as on one
-plane—that is, at the same distance from the eye; and so is less
-heterogeneous than a painting that represents them as at various
-distances from the eye. It exhibits all objects as exposed to the same
-degree of light; and so is less heterogeneous than a painting which
-exhibits different objects, and different parts of each object, as in
-different degrees of light. It uses scarcely any but the primary
-colours, and these in their full intensity; and so is less heterogeneous
-than a painting which, introducing the primary colours but sparingly,
-employs an endless variety of intermediate tints, each of heterogeneous
-composition, and differing from the rest not only in quality but in
-intensity. Moreover, we see in these earliest works a great
-uniformity of conception. The same arrangement of figures is perpetually
-reproduced—the same actions, attitudes, faces, dresses. In Egypt the
-modes of representation were so fixed that it was sacrilege to introduce
-a novelty; and indeed it could have been only in consequence of a fixed
-mode of representation that a system of hieroglyphics became possible.
-The Assyrian bas-reliefs display parallel characters. Deities, kings,
-attendants, winged-figures and animals, are severally depicted in like
-positions, holding like implements, doing like things, and with like
-expression or non-expression of face. If a palm-grove is introduced, all
-the trees are of the same height, have the same number of leaves, and
-are equidistant. When water is imitated, each wave is a counterpart of
-the rest; and the fish, almost always of one kind, are evenly
-distributed over the surface. The beards of the kings, the gods, and the
-winged-figures, are everywhere similar; as are the manes of the lions,
-and equally so those of the horses. Hair is represented throughout by
-one form of curl. The king’s beard is quite architecturally built up of
-compound tiers of uniform curls, alternating with twisted tiers placed
-in a transverse direction, and arranged with perfect regularity; and the
-terminal tufts of the bulls’ tails are represented in exactly the same
-manner. Without tracing out analogous facts in early Christian
-art, in which, though less striking, they are still visible, the advance
-in heterogeneity will be sufficiently manifest on remembering that in
-the pictures of our own day the composition is endlessly varied; the
-attitudes, faces, expressions, unlike; the subordinate objects different
-in size, form, position, texture; and more or less of contrast even in
-the smallest details. Or, if we compare an Egyptian statue, seated bolt
-upright on a block, with hands on knees, fingers outspread and parallel,
-eyes looking straight forward, and the two sides perfectly symmetrical
-in every particular, with a statue of the advanced Greek or the modern
-school, which is asymmetrical in respect of the position of the head,
-the body, the limbs, the arrangement of the hair, dress, appendages, and
-in its relations to neighbouring objects, we shall see the change from
-the homogeneous to the heterogeneous clearly manifested.
-
- * * * * *
-
-§ 51. In the co-ordinate origin and gradual differentiation of Poetry,
-Music, and Dancing, we have another series of illustrations. Rhythm in
-speech, rhythm in sound, and rhythm in motion, were in the beginning,
-parts of the same thing; and have only in process of time become
-separate things. Among various existing barbarous tribes we find them
-still united. The dances of savages are accompanied by some kind of
-monotonous chant, the clapping of hands, the striking of rude
-instruments: there are measured movements, measured words, and measured
-tones; and the whole ceremony, usually having reference to war or
-sacrifice, is of governmental character. In the early records of the
-historic races we similarly find these three forms of metrical action
-united in religious festivals. In the Hebrew writings we read that the
-triumphal ode composed by Moses on the defeat of the Egyptians, was sung
-to an accompaniment of dancing and timbrels. The Israelites danced and
-sung “at the inauguration of the golden calf. And as it is generally
-agreed that this representation of the Deity was borrowed from the
-mysteries of Apis, it is probable that the dancing was copied from that
-of the Egyptians on those occasions.” There was an annual dance in
-Shiloh on the sacred festival; and David danced before the ark. Again,
-in Greece the like relation is everywhere seen: the original type being
-there, as probably in other cases, a simultaneous chanting and mimetic
-representation of the life and adventures of the god. The Spartan dances
-were accompanied by hymns and songs; and in general the Greeks had “no
-festivals or religious assemblies but what were accompanied with songs
-and dances”—both of them being forms of worship used before altars.
-Among the Romans, too, there were sacred dances: the Salian and
-Lupercalian being named as of that kind. And even in Christian
-countries, as at Limoges in comparatively recent times, the people have
-danced in the choir in honour of a saint. The incipient separation
-of these once united arts from each other and from religion, was early
-visible in Greece. Probably diverging from dances partly religious,
-partly warlike, as the Corybantian, came the war-dances proper, of which
-there were various kinds; and from these resulted secular dances.
-Meanwhile Music and Poetry, though still united, came to have an
-existence separate from dancing. The aboriginal Greek poems, religious
-in subject, were not recited but chanted; and though at first the chant
-of the poet was accompanied by the dance of the chorus, it ultimately
-grew into independence. Later still, when the poem had been
-differentiated into epic and lyric—when it became the custom to sing the
-lyric and recite the epic—poetry proper was born. As during the same
-period musical instruments were being multiplied, we may presume that
-music came to have an existence apart from words. And both of them were
-beginning to assume other forms besides the religious. Facts
-having like implications might be cited from the histories of later
-times and peoples; as the practices of our own early minstrels, who sang
-to the harp heroic narratives versified by themselves to music of their
-own composition: thus uniting the now separate offices of poet,
-composer, vocalist, and instrumentalist. But, without further
-illustration, the common origin and gradual differentiation of Dancing,
-Poetry, and Music will be sufficiently manifest.
-
-The advance from the homogeneous to the heterogeneous is displayed not
-only in the separation of these arts from each other and from religion,
-but also in the multiplied differentiations which each of them
-afterwards undergoes. Not to dwell upon the numberless kinds of dancing
-that have, in course of time, come into use; and not to occupy space in
-detailing the progress of poetry, as seen in the development of the
-various forms of metre, of rhyme, and of general organization; let us
-confine our attention to music as a type of the group. As argued
-by Dr. Burney, and as implied by the customs of still extant barbarous
-races, the first musical instruments were, without doubt,
-percussive—sticks, calabashes, tom-toms—and were used simply to mark the
-time of the dance; and in this constant repetition of the same sound, we
-see music in its most homogeneous form. The Egyptians had a lyre with
-three strings. The early lyre of the Greeks had four, constituting their
-tetrachord. In course of some centuries lyres of seven and eight strings
-were employed. And, by the expiration of a thousand years, they had
-advanced to their “great system” of the double octave. Through all which
-changes there of course arose a greater heterogeneity of melody.
-Simultaneously there came into use the different modes—Dorian, Ionian,
-Phrygian, Æolian, and Lydian—answering to our keys: and of these there
-were ultimately fifteen. As yet, however, there was but little
-heterogeneity in the time of their music. Instrumental music during this
-period being merely the accompaniment of vocal music, and vocal music
-being completely subordinated to words,—the singer being also the poet,
-chanting his own compositions and making the lengths of his notes agree
-with the feet of his verses; there unavoidably arose a tiresome
-uniformity of measure, which, as Dr Burney says, “no resources of melody
-could disguise.” Lacking the complex rhythm obtained by our equal bars
-and unequal notes, the only rhythm was that produced by the quantity of
-the syllables, and was of necessity comparatively monotonous. And
-further, it may be observed that the chant thus resulting, being like
-recitative, was much less clearly differentiated from ordinary speech
-than is our modern song. Nevertheless, considering the extended range of
-notes in use, the variety of modes, the occasional variations of time
-consequent on changes of metre, and the multiplication of instruments,
-we see that music had, towards the close of Greek civilization, attained
-to considerable heterogeneity: not indeed as compared with our music,
-but as compared with that which preceded it. As yet, however,
-there existed nothing but melody: harmony was unknown. It was not until
-Christian church-music had reached some development, that music in parts
-was evolved; and then it came into existence through a very unobtrusive
-differentiation. Difficult as it may be to conceive, _à priori_, how the
-advance from melody to harmony could take place without a sudden leap,
-it is none the less true that it did so. The circumstance which prepared
-the way for it, was the employment of two choirs singing alternately the
-same air. Afterwards it became the practice (very possibly first
-suggested by a mistake) for the second choir to commence before the
-first had ceased; thus producing a fugue. With the simple airs then in
-use, a partially harmonious fugue might not improbably thus result; and
-a very partially harmonious fugue satisfied the ears of that age, as we
-know from still preserved examples. The idea having once been given, the
-composing of airs productive of fugal harmony would naturally grow up;
-as in some way it _did_ grow up out of this alternate choir-singing. And
-from the fugue to concerted music of two, three, four, and more parts,
-the transition was easy. Without pointing out in detail the
-increasing complexity that resulted from introducing notes of various
-lengths, from the multiplication of keys, from the use of accidentals,
-from varieties of time, from modulations and so forth, it needs but to
-contrast music as it is, with music as it was, to see how immense is the
-increase of heterogeneity. We see this if, looking at music in its
-_ensemble_, we enumerate its many different genera and species—if we
-consider the divisions into vocal, instrumental, and mixed; and their
-subdivisions into music for different voices and different
-instruments—if we observe the many forms of sacred music, from the
-simple hymn, the chant, the canon, motet, anthem, &c., up to the
-oratorio; and the still more numerous forms of secular music, from the
-ballad up to the serenata, from the instrumental solo up to the
-symphony. Again, the same truth is seen on comparing any one sample of
-aboriginal music with a sample of modern music—even an ordinary song for
-the piano; which we find to be relatively highly heterogeneous, not only
-in respect of the varieties in the pitch and in the length of the notes,
-the number of different notes sounding at the same instant in company
-with the voice, and the variations of strength with which they are
-sounded and sung, but in respect of the changes of key, the changes of
-time, the changes of _timbre_ of the voice, and the many other
-modifications of expression. While between the old monotonous
-dance-chant and a grand opera of our own day, with its endless
-orchestral complexities and vocal combinations, the contrast in
-heterogeneity is so extreme that it seems scarcely credible that the one
-should have been the ancestor of the other.
-
- * * * * *
-
-§ 52. Were they needed, many further illustrations might be cited. Going
-back to the early time when the deeds of the god-king, chanted and
-mimetically represented in dances round his altar, were further narrated
-in picture-writings on the walls of temples and palaces, and so
-constituted a rude literature, we might trace the development of
-Literature through phases in which, as in the Hebrew Scriptures it
-presents in one work, theology, cosmogony, history, biography, civil
-law, ethics, poetry; through other phases in which, as in the Iliad, the
-religious, martial, historical, the epic, dramatic, and lyric elements
-are similarly commingled; down to its present heterogeneous development,
-in which its divisions and subdivisions are so numerous and varied as to
-defy complete classification. Or we might track the evolution of
-Science: beginning with the era in which it was not yet differentiated
-from Art, and was, in union with Art, the handmaid of Religion; passing
-through the era in which the sciences were so few and rudimentary, as to
-be simultaneously cultivated by the same philosophers; and ending with
-the era in which the genera and species are so numerous that few can
-enumerate them, and no one can adequately grasp even one genus. Or we
-might do the like with Architecture, with the Drama, with Dress. But
-doubtless the reader is already weary of illustrations; and my promise
-has been amply fulfilled. I believe it has been shown beyond question,
-that that which the German physiologists have found to be the law of
-organic development, is the law of all development. The advance from the
-simple to the complex, through a process of successive differentiations,
-is seen alike in the earliest changes of the Universe to which we can
-reason our way back, and in the earliest changes which we can
-inductively establish; it is seen in the geologic and climatic evolution
-of the Earth, and of every single organism on its surface; it is seen in
-the evolution of Humanity, whether contemplated in the civilized
-individual, or in the aggregation of races; it is seen in the evolution
-of Society, in respect alike of its political, its religious, and its
-economical organization; and it is seen in the evolution of all those
-endless concrete and abstract products of human activity, which
-constitute the environment of our daily life. From the remotest past
-which Science can fathom, up to the novelties of yesterday, that in
-which Evolution essentially consists, is the transformation of the
-homogeneous into the heterogeneous.
-
------
-
-Footnote 8:
-
- The substance of this chapter is nearly identical with the first half
- of an essay on “Progress: its Law and Cause,” which was originally
- published in the _Westminster Review_ for April 1857: only a few
- unimportant additions and alterations have been made. The succeeding
- chapter, however, in which the subject is continued, is, with the
- exception of a fragment embodied in it, wholly new.
-
-Footnote 9:
-
- For detailed proof of these assertions see essay on _Manners and
- Fashion_.
-
-
-
-
- CHAPTER III.
- THE LAW OF EVOLUTION, CONTINUED.
-
-
-§ 53. But now, does this generalization express the whole truth? Does it
-include all the phenomena of Evolution? and does it exclude all other
-phenomena? A careful consideration of the facts, will show that it does
-neither.
-
-That there are changes from the less heterogeneous to the more
-heterogeneous, which do not come within what we call Evolution, is
-proved in every case of local disease. A portion of the body in which
-there arises a cancer, or other morbid growth, unquestionably displays a
-new differentiation. Whether this morbid growth be, or be not, more
-heterogeneous than the tissues in which it is seated, is not the
-question. The question is, whether the structure of the organism as a
-whole, is, or is not, rendered more heterogeneous by the addition of a
-part unlike every pre-existing part, both in form and composition. And
-to this question there can be none but an affirmative answer.
- Again, it might with apparent truth be contended, that the earlier
-stages of decomposition in a dead body, similarly involve an increase of
-heterogeneity. Supposing the chemical changes to commence in some parts
-of the body earlier than in other parts, as they commonly do; and to
-affect different tissues in different, ways, as they must; it seems to
-be a necessary admission that the entire body, made up of undecomposed
-parts and parts decomposed in different ways and degrees, has become
-more heterogeneous than it was. Though greater homogeneity will be the
-eventual result, the immediate result is the opposite. And yet this
-immediate result is certainly not evolution. But perhaps of all
-illustrations the least debatable are those furnished by social
-disorders and disasters. When in any nation there occurs a rebellion,
-which, while leaving some provinces undisturbed, developes itself here
-in secret societies, there in public demonstrations, and elsewhere in
-actual appeal to arms, leading probably to conflict and bloodshed; it
-must be admitted that the society, regarded as a whole, has so been
-rendered more heterogeneous. Or when a dearth causes commercial panic
-with its entailed bankruptcies, closed factories, discharged operatives,
-political agitations, food riots, incendiarisms; it is manifest that as,
-throughout the rest of society, there still exists the ordinary
-organization displaying the usual phenomena, these new phenomena must be
-regarded as adding to the complexity previously existing. Nevertheless,
-it is clear that such changes so far from constituting a further stage
-of evolution, are steps towards dissolution.
-
-There is good reason to think then, that the definition arrived at in
-the last chapter, is an imperfect one. We may suspect, not that the
-process of evolution is different from the process there described; but
-that the description did not contain all that it should. The changes
-above instanced as coming within the formula as it now stands, are so
-obviously different from the rest, that the inclusion of them implies
-some oversight—some distinction hitherto overlooked. Such further
-distinction we shall find really exists.
-
- * * * * *
-
-§ 54. At the same time that all evolution is a change from the
-homogeneous to the heterogeneous, it is also a change from the
-indefinite to the definite. As well as an advance from simplicity to
-complexity, there is an advance from confusion to order—from
-undetermined arrangement to determined arrangement. In the process of
-development, no matter what sphere it is displayed in, there is not only
-a gradual multiplication of unlike parts; but there is a gradual
-increase in the distinctness with which these parts are marked off from
-each other. And so is that increase of heterogeneity which characterizes
-Evolution, distinguished from that increase of heterogeneity which does
-not. For proof of this, it needs only to reconsider the instances
-given above. The structural changes constituting a disease, have no such
-definiteness, either in locality, extent, or outline, as the structural
-changes constituting development. Though certain morbid growths arise
-much more commonly in some parts of the body than in others (as warts on
-the hands, cancer on the breasts, tubercle in the lungs), yet they are
-not confined to these parts; nor, when found on them, are they anything
-like so precise in their relative positions as are the normal parts
-around them. In size, again, they are extremely variable—they bear no
-such constant proportion to the body as organs do. Their forms, too, are
-far less specific than organic forms. And they are extremely irregular
-or confused in their internal structures. That is to say, they are in
-all respects comparatively indefinite. The like peculiarity may be
-traced in decomposition. That state of total indefiniteness to which a
-dead body is finally reduced, is a state towards which the putrefactive
-changes have tended from their commencement. Each step in the
-destruction of the organic compounds, is accompanied by a blurring of
-the minute structure—diminishes its distinctness. From the portions that
-have undergone most decomposition, there is a gradual transition to the
-less decomposed portions. And step by step the lines of organization,
-once so precise, disappear. Similarly with social changes of an
-abnormal kind. A political outbreak rising finally to a rebellion, tends
-from the very first to obliterate the specializations, governmental and
-industrial, which previously existed. The disaffection which originates
-such an outbreak, itself implies a loosening of those ties by which the
-citizens are bound up into distinct classes and sub-classes. Agitation,
-growing into revolutionary meetings, shows us a decided tendency towards
-the fusion of ranks that are usually separated. Acts of open
-insubordination exhibit a breaking through of those definite limits to
-individual conduct which were previously observed; and a disappearance
-of the lines previously existing between those in authority and those
-beneath them. At the same time, by the arrest of trade, artizans and
-others lose their occupations; and in so ceasing to be functionally
-distinguished, become fused into a mass from which the demarcations in
-great part vanish. And when at last there comes positive insurrection,
-all magisterial and official powers, all class distinctions, and all
-industrial differences, at once cease: organized society lapses into an
-unorganized aggregation of social units. How the like holds true of such
-social disasters as are entailed by famine, needs not be pointed out. On
-calling to mind that in cases of this kind the changes are from order
-towards disorder, it will at once be seen that like the foregoing they
-are changes from definite arrangements to indefinite arrangements.
-
-Thus then is that increase of heterogeneity which constitutes Evolution,
-distinguished from that increase of heterogeneity which does not do so.
-Though in disease and death, individual or social, the earliest
-modifications may be construed as additions to the heterogeneity
-previously existing; yet they cannot be construed as additions to the
-definiteness previously existing. They begin from the very outset to
-destroy this definiteness; and so, gradually produce a heterogeneity
-that is indeterminate instead of determinate. Just in the same way that
-a city, already multiform in its variously arranged structures of
-various architecture, may be made more multiform by an earthquake, which
-leaves part of it standing and overthrows other parts in different ways
-and degrees, and yet is at the same time reduced from definite
-arrangement to indefinite arrangement; so may organized bodies be made
-for a time more multiform by changes which are nevertheless
-disorganizing changes. And in the one case as in the other, it is the
-absence of definiteness which distinguishes the multiformity of
-regression from the multiformity of progression.
-
-If the advance from the indefinite to the definite is an essential
-characteristic of Evolution, we shall of course find it everywhere
-displayed; as in the last Chapter we found the advance from the
-homogeneous to the heterogeneous. With a view of showing that it is so,
-let us now briefly reconsider the same several classes of facts.
-
- * * * * *
-
-§ 55. Beginning as before with a hypothetical illustration, we have to
-note that each further stage in the evolution of the Solar System,
-supposing it to have originated from diffused matter, was an advance
-towards more definite forms, and times, and forces. At first irregular
-in shape and with indistinct margins, the attenuated substance, as it
-concentrated and acquired a rotatory motion, must have assumed the shape
-of an oblate spheroid; which, with every increase of density, became
-more specific in general outline, and had its surface more sharply
-marked off from the surrounding void. At the same time, the constituent
-portions of nebulous matter, instead of independently moving towards
-their common centre of gravity from all points, and tending to revolve
-round it in various planes, as they would at first do, must have had
-these planes more and more merged into a single plane; and this plane
-must have gained greater precision as the concentration progressed. To
-which add that in the gradual establishment of a common and determinate
-angular velocity, instead of the various and conflicting angular
-velocities of different parts, we have a further change of like nature.
- According to the hypothesis, change from indistinct
-characteristics to distinct ones, was repeated in the evolution of each
-planet and satellite; and may in them be traced to a much greater
-extent. A gaseous spheroid is less definitely marked off from the space
-around it than a fluid spheroid, since it is subject to larger and more
-rapid undulations of surface, and to much greater distortions of general
-form; and similarly a fluid spheroid, covered as it must be with waves
-of various magnitudes, is less definite than a solid spheroid. Nor is it
-only in greater fixity of surface that a planet in its last stage, is
-distinguished from a planet in its earlier stages. Its general form,
-too, is more precise. The sphere, to which in the end it very closely
-approximates, is a perfectly specific figure; while the spheroid, under
-which figure it previously existed, being infinitely variable in
-oblateness, is an imperfectly specific figure. And further, a planet
-having an axis inclined to the plane of its orbit, must, while its form
-is very oblate, have its plane of rotation greatly disturbed by the
-attraction of external bodies; whereas its approach to a spherical form,
-involving a less extreme precessional motion, implies less marked
-variations in the direction of its axis. Nor is it only in respect
-of space-relations that the Solar System in general and in detail has
-become more precise. The like is true of time-relations. During the
-process of concentration the various portions of the nebulous mass must
-not only differ more or less from each other in their angular
-velocities, but each of them must gradually change the period in which
-it moves round the general axis. In every detached ring however, and in
-the resulting planet, this progressive alteration ceases: there results
-a determinate period of revolution. And similarly the time of axial
-rotation, which, during the formation of each planet, is continually
-diminishing, becomes at last practically fixed: as in the case of the
-Earth, whose day is not a second less than it was 2000 years ago.
- It is scarcely needful to point out that the force-relations have
-simultaneously become more and more settled. The exact calculations of
-physical astronomy, show us how definite these force-relations now are;
-while the great indefiniteness which once characterized them, is implied
-in the extreme difficulty, if not impossibility, of subjecting the
-nebular hypothesis to mathematical treatment.
-
-From that originally molten state of the Earth inferable from
-established geological data—a state in harmony with the nebular
-hypothesis but inexplicable on any other—the transition to its existing
-state has been through stages in which the characters became more
-determinate. Besides being, as above pointed out, comparatively unstable
-in surface and contour, a fluid spheroid is less definite than a solid
-spheroid in having no fixed distribution of parts. Currents of molten
-matter, though kept to certain general circuits by the conditions of
-equilibrium, cannot in the absence of solid boundaries be precise or
-permanent in direction: all parts must be in motion with respect to
-other parts. But a solidification of the surface, even though but
-partial, is manifestly a step towards the establishment of definite
-relations of position. In a thin crust however, frequently ruptured as
-it must be by disturbing forces, and moved by every tidal undulation,
-such fixity of relative position can be but temporary. Only as the crust
-slowly increases in thickness, can there arise distinct and settled
-geographical relations. Observe too that when, on a crust that has
-cooled to the requisite degree, there begins to precipitate the water
-floating above as vapour, the water which is precipitated cannot
-maintain any definiteness either of state or place. Falling on a surface
-not thick enough to preserve anything beyond slight variations of level,
-it must form small shallow deposits over areas sufficiently cool to
-permit condensation; which areas must not only pass insensibly into
-others that are too hot for this, but must themselves from time to time
-be so raised in temperature as to drive off the water lying on them.
-With progressive refrigeration, however,—with an increasing thickness of
-crust, a consequent formation of larger elevations and depressions, and
-the condensation of more atmospheric water, there comes an arrangement
-of parts that is comparatively fixed in both time and space; and the
-definiteness of state and position increases, until there results such a
-distribution of continents and oceans as we now see—a distribution that
-is not only topographically precise, but also in its cliff-marked
-coast-lines presents a more definite division of land from water than
-could have existed during the period when islands of low elevation had
-shelving beaches up which the tide ebbed and flowed to great distances.
- Respecting the characteristics technically classed as geological,
-we may draw parallel inferences. While the Earth’s crust was thin,
-mountain-chains were impossibilities: there could not have been long and
-well-defined axes of elevation, with distinct water-sheds and areas of
-drainage. Moreover, from small islands admitting of but small rivers,
-and tidal streams both feeble and narrow, there would result no
-clearly-marked sedimentary strata. Confused and varying masses of
-detritus, such as those now found at the mouths of brooks, must have
-been the prevailing formations. And these could give place to distinct
-strata, only as there arose continents and oceans, with their great
-rivers, long coast-lines, and wide-spreading marine currents. How
-there must simultaneously have resulted more definite meteorological
-characters, need not be pointed out in detail. That differences of
-climates and seasons must have grown relatively decided as the heat of
-the Sun became distinguishable from the proper heat of the Earth; that
-the establishment through this cause of comparatively constant
-atmospheric currents, must have similarly produced more specific
-conditions in each locality; and that these effects must have been aided
-by increasing permanence in the distribution of land and sea and of
-ocean currents; are conclusions which are sufficiently obvious.
-
-Let us turn now to the evidence furnished by organic bodies. In place of
-deductive illustrations like the foregoing, we shall here find numerous
-illustrations which, as being inductively established, are less open to
-criticism. The process of mammalian development, for example, will
-supply us with numerous proofs ready-described by embryologists.
- The first change which the ovum of a mammal undergoes, after
-continued segmentation has reduced its yelk to a mulberry-like mass, is
-the appearance of a greater definiteness in the peripheral cells of this
-mass: each of which acquires a distinct enveloping membrane. These
-peripheral cells, vaguely distinguished from the internal ones both by
-their greater completeness and by their minuter subdivision, coalesce to
-form the blastoderm or germinal membrane. One portion of the blastoderm
-presently becomes contrasted with the rest, through the accumulation of
-cells still more subdivided, which, together, form an opaque roundish
-spot. This _area germinativa_, as it is called, is not sharply
-delineated, but shades off gradually into the surrounding parts of the
-blastoderm; and the _area pellucida_, subsequently formed in the midst
-of this germinal area, is similarly without any precise margin. The
-“primitive trace,” which makes its appearance in the centre of the _area
-pellucida_, and is the rudiment of that vertebrate axis which is to be
-the fundamental characteristic of the mature animal, is shown by its
-name to be at first indefinite—a mere trace. Beginning as a shallow
-groove, this becomes slowly more pronounced: its sides grow higher,
-their summits overlap, and at last unite; and so the indefinite groove
-passes into a definite tube, forming the vertebral canal. In this
-vertebral canal the leading divisions of the brain are at first
-discernible only as slight bulgings; while the vertebræ commence as
-indistinct modifications of the tissue bounding the canal.
-Simultaneously, the outer portion of the blastoderm has been undergoing
-separation from the inner portion: there has been a division into the
-serous and mucous layers—a division at the outset indistinct, and
-traceable only about the germinal area, but which insensibly spreads
-throughout nearly the whole germinal membrane, and becomes definite.
-From the mucous layer, the development of the alimentary canal proceeds
-as that of the vertebral canal does from the serous layer. Originally a
-simple channel along the under surface of the embryonic mass, the
-intestine is rendered step by step more distinct by the bending down, on
-each side, of ridges which finally join to form a tube—the permanent
-absorbing surface is by degrees clearly cut off from that temporary
-absorbing surface of which it was at first a part like all the rest. And
-in an analogous manner the entire embryo, which at first lies outspread
-upon the surface of the yelk-sack, gradually rises up from it, and, by
-the infolding of its ventral surface, becomes a separate mass, connected
-with the yelk-sack only by a narrow duct. These changes through
-which the general structure of the embryo is marked out with
-slowly-increasing precision, are paralleled in the evolution of each
-organ. The heart is at first a mere aggregation of cells, of which the
-inner liquify to form the cavity, while the outer are transformed into
-the walls; and when thus sketched out, the heart is indefinite not only
-as being unlined by limiting membrane, but also as being but vaguely
-distinguishable from the great blood-vessels: of which it is little more
-than a dilatation. By and by the receiving portion of the cavity becomes
-distinct from the propelling portion. Afterwards there begins to be
-formed across the ventricle, a septum, which, however, is some time
-before it completely shuts off the two halves from each other; while the
-later-formed septum of the auricle remains incomplete during the whole
-of fœtal life. Again, the liver commences as a multiplication of certain
-cells in the wall of the intestine. The thickening produced by this
-multiplication “increases so as to form a projection upon the exterior
-of the canal;” and at the same time that the organ grows and becomes
-distinct from the intestine, the channels which permeate it are
-transformed into ducts having clearly-marked walls. Similarly, by the
-increase of certain cells of the external coat of the alimentary canal
-at its upper portion, are produced buds from which the lungs are
-developed; and these, in their general outlines and detailed structure,
-acquire distinctness step by step. Changes of this order continue
-long after birth; and, in the human being, are some of them not
-completed till middle life. During youth, most of the articular surfaces
-of the bones remain rough and fissured—the calcareous deposit ending
-irregularly in the surrounding cartilage. But between puberty and the
-age of thirty, the articular surfaces are finished off by the addition
-of smooth, hard, sharply-cut “epiphyses.” Thus we may say that during
-Evolution, an increase of definiteness continues long after there ceases
-to be any appreciable increase of heterogeneity. And, indeed, there is
-reason to think that those structural modifications which take place
-after maturity, ending in old age and death, are modifications of this
-nature; since they result in a growing rigidity of structure, a
-consequent restriction of movement and of functional pliability, a
-gradual narrowing of the limits within which the vital processes go on,
-ending at length in an organic adjustment too precise—too narrow in its
-margin of possible variation to permit the requisite adaptation to
-external changes of condition.
-
-To demonstrate that the Earth’s Flora and Fauna, regarded either as
-wholes or in their separate species, have progressed in definiteness, is
-of course no more possible than it was to demonstrate that they have
-progressed in heterogeneity: lack of facts being an obstacle to the one
-conclusion as to the other. If, however, we allow ourselves to reason
-from the hypothesis, now daily rendered more probable, that every
-species of organic form up to the most complex, has arisen out of the
-simplest through the accumulation of modifications upon modifications,
-just as every individual organic form arises; we shall see that in such
-case there must have been a progress from the indeterminate to the
-determinate, both in the particular forms and in the groups of forms.
- We may set out with the significant fact that many of the lowest
-living organisms (which are analogous in structure to the germs of all
-higher ones) are so indefinite in character that it is difficult, if not
-impossible, to decide whether they are plants or animals. Respecting
-sundry of them there are unsettled disputes between zoologists and
-botanists; and it has even been proposed to group them into a separate
-kingdom, forming a common basis to the animal and vegetal kingdoms. Note
-next that among the _Protozoa_, extreme indefiniteness of shape is very
-general. In the shell-less Rhizopods and their allies, not only is the
-form so irregular as to admit of no description, but it is neither alike
-in any two individuals nor in the same individual at successive moments.
-By the aggregation of such creatures, are produced, among other
-indefinite bodies, the sponges—bodies that are indefinite in size, in
-contour, in internal arrangement, and in the absence of an external
-limiting membrane. As further showing the relatively indeterminate
-character of the simplest organisms, it may be mentioned that their
-structures vary very greatly with surrounding conditions: so much so
-that, among the _Protozoa_ and _Protophyta_, many forms which were once
-classed as distinct species, and even as distinct genera, are found to
-be merely varieties of one species. If now we call to mind how precise
-in their attributes are the highest organisms—how sharply cut their
-outlines, how invariable their proportions, and how comparatively
-constant their structures under changed conditions, we cannot deny that
-greater definiteness is one of their characteristics; and that if they
-have been evolved out of lower organisms, an increase of definiteness
-has been an accompaniment of their evolution. That in course of
-time, species have become more sharply marked off from other species,
-genera from genera, and orders from orders, is a conclusion not
-admitting of a more positive establishment than the foregoing; and must,
-indeed, stand or fall with it. If, however, species and genera and
-orders have resulted from the process of “natural selection,” then, as
-Mr. Darwin shows, there must have been a tendency to divergence, causing
-the contrasts between groups to become more and more pronounced. By the
-disappearance of intermediate forms, less fitted for special spheres of
-existence than the extreme forms they connected, the differences between
-the extreme forms must be rendered more decided; and so, from indistinct
-and unstable varieties, must slowly be produced distinct and stable
-species. Of which inference it may be remarked, not only that it follows
-from a process to which the organic creation is of necessity ever
-subject, but also that it is in harmony with what we know respecting
-races of men and races of domestic animals.
-
-Evidence that in the course of psychial development, there is a change
-from the vague to the distinct, may be seen in every nursery. The
-confusion of the infant’s perceptions is shown by its inability to
-distinguish persons. The dimness of its ideas of direction and distance,
-may be inferred from the ill-guided movements of its hands, and from its
-endeavours to grasp objects far out of reach. Only by degrees does the
-sense of equilibrium, needful for safe standing and moving, gain the
-requisite precision. Through the insensible steps that end in
-comprehensible speech, we may trace an increase in the accuracy with
-which sounds are discriminated and in the nicety with which they are
-imitated. And similarly during education, the change is towards the
-establishment of internal relations more perfectly corresponding to
-external ones—to exactness in calculations, to a better representation
-of objects drawn, to a more correct spelling, to a completer conformity
-to the rules of speech, to clearer ideas respecting the affairs of life.
- How in the further progress to maturity the law still holds, needs
-not here be pointed out; more especially as it will presently be shown
-in treating of the evolution of intelligence during the advance of
-civilization. The only further fact calling for remark, is, that this
-increase of mental definiteness is, in some ways, manifested even during
-the advance from maturity to old age. The habits of life grow more and
-more fixed; the character becomes less capable of change; the quantity
-of knowledge previously acquired ceases to have its limits alterable by
-additions; and the opinions upon every point admit of no modification.
-
-Still more manifestly do the successive phases through which societies
-pass, display the progress from indeterminate arrangement to determinate
-arrangement. A wandering tribe of savages, as being fixed neither in its
-locality nor in the relative positions of its parts, is far less
-definite than a nation, covering a territory clearly marked out, and
-formed of individuals grouped together in towns and villages. In such a
-tribe the social relations are similarly confused and unsettled.
-Political authority is neither well established nor precise.
-Distinctions of rank are neither clearly marked nor impassable.
-“Medicine-men” and “rain-makers” form a class by no means as distinct
-from the rest of the community as eventually becomes the priesthood they
-foreshadow. And save in the different occupations of men and women,
-there are no complete industrial divisions. Only in tribes of
-considerable size, which have enslaved other tribes, is the economical
-differentiation decided. Any one of these primitive societies
-however that developes, becomes step by step more specific. Increasing
-in size, consequently ceasing to be so nomadic, and restricted in its
-range by neighbouring tribes, it acquires, after prolonged border
-warfare, a more settled territorial boundary. The distinction between
-the royal race and the people, grows so extreme as to amount in the
-popular apprehension to a difference of nature. The warrior-class
-attains a perfect separation from classes devoted to the cultivation of
-the soil or other occupations regarded as servile. And there arises a
-priesthood that is defined in its rank, its functions, its privileges.
-This sharpness of definition, growing both greater and more variously
-exemplified as societies advance to maturity, is extremest in those that
-have reached their full development or are declining. Of ancient Egypt
-we read that its social divisions were strongly-marked and its customs
-rigid. Recent investigations make it more than ever clear, that among
-the Assyrians and surrounding peoples, not only were the laws
-unalterable, but even the minor habits, down to those of domestic
-routine, possessed a sacredness which insured their permanence. In India
-at the present day, the unchangeable distinctions of caste, not less
-than the constancy in modes of dress, industrial processes, and
-religious observances, show us how fixed are the arrangements where the
-antiquity is great. Nor does China with its long-settled political
-organization, its elaborate and precise conventions, and its
-unprogressive literature, fail to exemplify the same truth. The
-successive phases of our own and neighbouring societies, furnish facts
-somewhat different in kind but similar in meaning. After our leading
-class-divisions had become tolerably well-established, it was long
-before they acquired their full precision. Originally, monarchical
-authority was more baronial, and baronial authority more monarchical,
-than they afterwards became. Between modern priests and the priests of
-old times, who while officially teachers of religion were also warriors,
-judges, architects, there is a marked difference in definiteness of
-function. And among the people engaged in productive occupations, the
-like contrast would be found to hold: the industrial office has become
-more distinct from the military; and its various divisions from each
-other. A history of our constitution, reminding us how, after prolonged
-struggles, the powers of King, Lords, and Commons, have been gradually
-settled, would clearly exhibit analogous changes. Countless facts
-bearing the like construction would meet us, were we to trace the
-development of legislation: in the successive stages of which, we should
-find statutes made more precise in their provisions—more specific in
-their applications to particular cases. Even at the present time we see
-that each new law, beginning as a vague proposition, is, in the course
-of enactment, elaborated into specific clauses; and further that only
-after its interpretation has been established by judges’ decisions in
-courts of justice, does it reach its final definiteness. From the
-history of minor institutions like evidence may be gathered. Religious,
-charitable, literary, and all other societies, beginning with ends and
-methods roughly sketched out and easily modifiable, show us how, by the
-accumulation of rules and precedents, the purposes become more distinct
-and the modes of action more restricted; until at last death often
-results from a fixity which admits of no adaptation to new conditions.
-Should it be objected that among civilized nations there are examples of
-decreasing definiteness, (instance the breaking down of limits between
-ranks,) the reply is, that such apparent exceptions are the
-accompaniments of a social metamorphosis—a change from the military or
-predatory type of social structure, to the industrial or mercantile
-type, during which the old lines of organization are disappearing and
-the new ones becoming more marked.
-
-That all organized results of social action, pass in the course of
-civilization through parallel phases, is demonstrable. Being, as they
-are, objective products of subjective processes, they must display
-corresponding changes; and that they do this, the cases of Language, of
-Science, of Art, clearly prove.
-
-If we strike out from our sentences everything but nouns and verbs, we
-shall perceive how extremely vague is the expression of ideas in
-undeveloped tongues. When we note how each inflection of a verb or
-addition by which the case of a noun is marked, serves to limit the
-conditions of action or of existence, we see that these constituents of
-speech enable men more precisely to communicate their thoughts. That the
-application of an adjective to a noun or an adverb to a verb, narrows
-the class of things or changes indicated, implies that these additional
-words serve further to define the meaning. And similarly with other
-parts of speech. The like effect results from the multiplication
-of words of each order. When the names for objects, and acts, and
-qualities, are but few, the range of each is proportionately wide, and
-its meaning therefore unspecific. The similes and metaphors so
-abundantly used by aboriginal races, are simply vehicles for indirectly
-and imperfectly conveying ideas, which lack of words disables them from
-conveying directly and perfectly. In contrasting these figurative
-expressions, interpretable in various senses, with the expressions which
-we should use in place of them, the increase of exactness which wealth
-of language gives, is rendered very obvious. Or to take a case from
-ordinary life, if we compare the speech of the peasant, who, out of his
-limited vocabulary, can describe the contents of the bottle he carries,
-only as “doctor’s-stuff” which he has got for his “sick” wife, with the
-speech of the physician, who tells those educated like himself the
-particular composition of the medicine, and the particular disorder for
-which he has prescribed it; we have vividly brought home to us, the
-precision which language gains by the multiplication of terms.
- Again, in the course of its evolution, each tongue acquires a
-further accuracy through processes which fix the meaning of each word.
-Intellectual intercourse tends gradually to diminish laxity of
-expression. By and by dictionaries give definitions. And eventually,
-among the most cultivated, indefiniteness is not tolerated, either in
-the terms used or in their grammatical combinations. Once more,
-languages considered as wholes, become gradually more distinct from each
-other, and from their common parent: as witness in early times the
-divergence from the same root of two languages so unlike as Greek and
-Latin, and in later times the development of three Latin dialects into
-Italian, French, and Spanish.
-
-In his “History of the Inductive Sciences,” Dr. Whewell says that the
-Greeks failed in physical philosophy because their “ideas were not
-distinct, and appropriate to the facts.” I do not quote this remark for
-its luminousness; since it would be equally proper to ascribe the
-indistinctness and inappropriateness of their ideas to the imperfection
-of their physical philosophy; but I quote it because it serves as good
-evidence of the indefiniteness of primitive science. The same work and
-its fellow on “The Philosophy of the Inductive Sciences,” supply other
-evidences equally good, because equally independent of any such
-hypothesis as is here to be established. Respecting mathematics we have
-the fact that geometrical theorems grew out of empirical methods; and
-that these theorems, at first isolated, did not acquire the clearness
-which complete demonstration gives, until they were arranged by Euclid
-into a series of dependent propositions. At a later period the same
-general truth was exemplified in the progress from the “method of
-exhaustions” and the “method of indivisibles” to the “method of limits;”
-which is the central idea of the infinitesimal calculus. In early
-mechanics, too, may be traced a dim perception that action and re-action
-are equal and opposite; though for ages after, this truth remained
-unformulated. And similarly, the property of inertia, though not
-distinctly comprehended until Kepler lived, was vaguely recognized long
-previously. “The conception of statical force,” “was never presented in
-a distinct form till the works of Archimedes appeared;” and “the
-conception of accelerating force was confused, in the mind of Kepler and
-his contemporaries, and did not become clear enough for purposes of
-sound scientific reasoning before the succeeding century.” To which
-specific assertions may be added the general remark, that “terms which
-originally, and before the laws of motion were fully known, were used in
-a very vague and fluctuating sense, were afterwards limited and rendered
-precise.” When we turn from abstract scientific conceptions to the
-concrete previsions of science, of which astronomy furnishes us with
-numerous examples, the like contrast is visible. The times at which
-celestial phenomena will occur, have been predicted with ever-increasing
-accuracy: errors once amounting to days, have been reduced down to
-seconds. The correspondence between the real and supposed forms of
-orbits, has been growing gradually more precise. Originally thought
-circular, then epicyclical, then elliptical, orbits are now ascertained
-to be curves which always deviate more or less from perfect ellipses,
-and which are ever undergoing change. But the general advance of
-Science in definiteness, is best shown by the contrast between its
-qualitative stage, and its quantitative stage. At first, the facts
-ascertained were, that between such and such phenomena some connexion
-existed—that the appearances _a_ and _b_ always occurred together or in
-succession; but it was neither known what was the nature of the relation
-between _a_ and _b_, nor how much of _a_ accompanied so much of _b_. The
-development of Science has in part been the reduction of these vague
-connexions to distinct ones. Most relations have been determined as
-belonging to the classes mechanical, chemical, thermal, electric,
-magnetic, &c.; and we have learnt to infer the amounts of the
-antecedents and consequents from each other with an exactness that
-becomes ever greater. Were there space to state them, illustrations of
-this truth might be cited from all departments of physics; but it must
-suffice here to instance the general progress of chemistry. Besides the
-conspicuous fact that we have positively ascertained the constituent
-elements of an immense number of compounds which our ancestors could not
-analyze, and of a far greater number which they never even saw, there is
-the still more conspicuous fact that the combining equivalents of these
-elements are accurately calculated. The beginnings of a like advance
-from qualitative to quantitative prevision, may be traced even in some
-of the higher sciences. Physiology shows it in the weighing and
-measuring of organic products, and of the materials consumed. By
-Pathology it is displayed in the use of the statistical method of
-determining the sources of diseases, and the effects of treatment. In
-Zoology and Botany, the numerical comparisons of Floras and Faunas,
-leading to specific conclusions respecting their sources and
-distributions, illustrate it. And in Sociology, questionable as are the
-conclusions usually drawn from the classified sum-totals of the census,
-from Board-of-Trade tables, and from criminal returns, it must be
-admitted that these imply a progress towards more accurate conceptions
-of social phenomena. That an essential characteristic of advancing
-Science is increase in definiteness, appears indeed almost a truism,
-when we remember that Science may be described as definite knowledge, in
-contradistinction to that indefinite knowledge possessed by the
-uncultured. And if, as we cannot question, Science has, in the slow
-course of ages, been evolved out of this indefinite knowledge of the
-uncultured; then, the gradual acquirement of that great definiteness
-which now distinguishes it, must have been a leading trait in its
-evolution.
-
-The Arts, industrial and æsthetic, furnish illustrations perhaps still
-more striking. Flint implements of the kind recently found in certain of
-the later geologic deposits—implements so rude that some have held them
-to be of natural rather than of artificial origin—show the extreme want
-of precision in men’s first handyworks. Though a great advance on these
-is seen in the tools and weapons of existing savage tribes, yet an
-inexactness in forms and fittings, more than anything else distinguishes
-such tools and weapons from those of civilized races. In a less degree,
-the productions of semi-barbarous nations are characterized by like
-defects. A Chinese junk with all its contained furniture and appliances,
-nowhere presents a perfectly straight line, a uniform curve, or a true
-surface. Nor do the utensils and machines of our ancestors fail to
-exhibit a similar inferiority to our own. An antique chair, an old
-fireplace, a lock of the last century, or almost any article of
-household use that has been preserved for a few generations, will prove
-by contrast how greatly the industrial products of our time excel those
-of the past in their accuracy. Since planing machines have been
-invented, it has become possible to produce absolutely straight lines,
-and surfaces so truly level as to be air-tight when applied to each
-other. While in the dividing-engine of Troughton, in the micrometer of
-Whitworth, and in microscopes that show fifty thousand divisions to the
-inch, we have an exactness as far exceeding that reached in the works of
-our great-grandfathers, as theirs exceeded that of the aboriginal
-celt-makers. In the Fine Arts there has been a parallel process.
-From the rudely carved and painted idols of savages, through the early
-sculptures characterized by limbs having no muscular detail,
-wooden-looking drapery, and faces devoid of individuality, up to the
-later statues of the Greeks or some of those now produced, the increased
-accuracy of representation is conspicuous. Compare the mural paintings
-of the Egyptians with the paintings of medieval Europe, or these with
-modern paintings, and the more precise rendering of the appearances of
-objects is manifest. So too is it with the delineations of fiction and
-the drama. In the marvellous tales current among Eastern nations, in the
-romantic legends of feudal Europe, as well as in the mystery-plays and
-those immediately succeeding them, we see great want of correspondence
-to the realities of life; not only in the predominance of supernatural
-events and extremely improbable coincidences, but also in the
-vaguely-indicated personages, who are nothing more than embodiments of
-virtue and vice in general, or at best of particular virtues and vices.
-Through transitions that need not be specified, there has been a
-progressive diminution, in both fiction and the drama, of whatever is
-unnatural—whatever does not answer to real life. And now, novels and
-plays are applauded in proportion to the fidelity with which they
-exhibit individual characters with their motives and consequent actions;
-improbabilities, like the impossibilities which preceded them, are
-disallowed; and there is even an incipient abandonment of those
-elaborate plots which the realities of life rarely if ever furnish.
-
-Were it needful, it would be easy to accumulate evidences of various
-other kinds. The progress from myths and legends, extreme in their
-misrepresentations, to a history that has slowly become, and is still
-becoming, more accurate; the establishment of settled systematic methods
-of doing things, instead of the indeterminate ways at first pursued; and
-the great increase in the number of points on which conflicting opinion
-has settled down into exact knowledge; might severally be used further
-to exemplify the general truth enunciated. The basis of induction is,
-however, already sufficiently wide. Proof that all Evolution is from the
-indefinite to the definite, we find to be not less abundant than proof
-that all Evolution is from the homogeneous to the heterogeneous. The one
-kind of change is co-extensive with the other—is equally with it
-exhibited throughout Nature.
-
- * * * * *
-
-§ 56. To form a complete conception of Evolution, we have to contemplate
-it under yet another aspect. This advance from the indefinite to the
-definite, is obviously not primary but secondary—is an incidental result
-attendant on the finishing of certain changes. The transformation of a
-whole that was originally uniform, into a combination of multiform
-parts, implies a progressive separation. While this is going on there
-must be indistinctness. Only as each separated division draws into its
-general mass those diffused peripheral portions which are at first
-imperfectly disunited from the peripheral portions of neighbouring
-divisions, can it acquire anything like a precise outline. And it cannot
-become perfectly definite until its units are aggregated into a compact
-whole. That is to say, the acquirement of definiteness is simply a
-concomitant of complete union of the elements constituting each
-component division. Thus, Evolution is characterized not only by a
-continuous multiplication of parts, but also by a growing oneness in
-each part. And while an advance in heterogeneity results from
-progressive differentiation, an advance in definiteness results from
-progressive integration. The two changes are simultaneous; or are rather
-opposite aspects of the same change. This change, however, cannot be
-rightly comprehended without looking at both its sides. Let us then once
-more consider Evolution under its several manifestations; for the
-purpose of noting how it is throughout a process of integration.
-
-The illustrations furnished by the Solar System, supposing it to have
-had a nebular origin, are so obvious as scarcely to need indicating.
-That as a whole, it underwent a gradual concentration while assuming its
-present distribution of parts; and that there subsequently took place a
-like concentration of the matter forming each planet and satellite, is
-the leading feature of the hypothesis. The process of integration is
-here seen in its simplest and most decided form.
-
-Geologic evolution, if we trace it up from that molten state of the
-Earth’s substance which we are obliged to postulate, supplies us with
-more varied facts of like meaning. The advance from a thin crust, at
-first everywhere fissured and moveable, to a crust so solid and thick as
-to be but now and then very partially dislocated by disturbing forces,
-exemplifies the unifying process; as does likewise the advance from a
-surface covered with small patches of land and water, to one divided
-into continents and oceans—an advance also resulting from the Earth’s
-gradual solidification. Moreover, the collection of detritus into strata
-of great extent, and the union of such strata into extensive “systems,”
-becomes possible only as surfaces of land and water become wide, and
-subsidences great, in both area and depth; whence it follows that
-integrations of this order must have grown more pronounced as the
-Earth’s crust thickened. Different and simpler instances of the
-process through which mixed materials are separated, and the kindred
-units aggregated into masses, are exhibited in the detailed structure of
-the Earth. The phenomena of crystallization may be cited _en masse_, as
-showing how the unifications of similar elements take place wherever the
-conditions permit. Not only do we see this where there is little or no
-hindrance to the approach of the particles, as in the cases of crystals
-formed from solutions, or by sublimation; but it is also seen where
-there are great obstacles to their approach. The flints and the nodules
-of iron pyrites that are found in chalk, as well as the silicious
-concretions which occasionally occur in limestone, can be interpreted
-only as aggregations of atoms of silex or sulphuret of iron, originally
-diffused almost uniformly through the deposit, but gradually collected
-round certain centres, notwithstanding the solid or semi-solid state of
-the surrounding matter. Iron-stone as it ordinarily occurs, presents a
-similar phenomenon to be similarly explained; and what is called bog
-iron-ore supplies the conditions and the result in still more obvious
-correlation.
-
-During the evolution of an organism, there occurs, as every physiologist
-knows, not only separation of parts, but coalescence of parts. In the
-mammalian embryo, the heart, at first a long pulsating blood-vessel, by
-and by twists upon itself and becomes integrated. The layer of
-bile-cells constituting the rudimentary liver, do not simply become
-different from the wall of the intestine in which they at first lie; but
-they simultaneously diverge from it and consolidate into an organ. The
-anterior segments of the cerebro-spinal axis, which are at first
-continuous with the rest, and distinguished only by their larger size,
-undergo a gradual union; and at the same time the resulting head
-consolidates into a mass clearly marked off from the rest of the
-vertebral column. The like process, variously exemplified in other
-organs, is meanwhile exhibited by the body as a whole; which becomes
-integrated, somewhat in the same way that the contents of an outspread
-handkerchief become integrated when its edges are drawn in and fastened
-to make a bundle. Analogous changes go on long after birth, and continue
-even up to old age. In the human being that gradual solidification of
-the bony framework, which, during childhood, is seen in the coalescence
-of portions of the same bone ossified from different centres, is
-afterwards seen in the coalescence of bones that were originally
-distinct. The appendages of the vertebræ unite with the vertebral
-centres to which they belong—a change not completed until towards
-thirty. At the same time the epiphyses, formed separately from the main
-bodies of their respective bones, have their cartilaginous connexions
-turned into osseous ones—are fused to the masses beneath them. The
-component vertebræ of the sacrum, which remain separate till about the
-sixteenth year, then begin to unite; and in ten or a dozen years more
-their union is complete. Still later occurs the coalescence of the
-coccygeal vertebræ; and there are some other bony unions which are not
-completed until advanced age. To which add that the increase of density
-and toughness, going on throughout the tissues in general during life,
-may be regarded as the formation of a more highly integrated substance.
- The species of change thus illustrated under its several aspects
-in the unfolding of the human body, may be traced in all animals. That
-mode of it which consists in the union of homogeneous parts originally
-separate, has been described by Milne-Edwards and others, as exhibited
-in various of the invertebrata; though it does not seem to have been
-included by them as an essential peculiarity in the process of organic
-development. We shall, however, be led strongly to suspect that
-progressive integration should form part of the definition of this
-process, when we find it displayed not only in tracing up the stages
-passed through by every embryo, but also in ascending from the lower
-living creatures to the higher. And here, as in the evolution of
-individual organisms, it goes on both longitudinally and transversely:
-under which different forms we may indeed most conveniently consider it.
- Of _longitudinal integration_, the sub-kingdom _Annulosa_ supplies
-abundant examples. Its lower members, such as worms and myriapods, are
-mostly characterized by the great number of segments composing them:
-reaching in some cases to several hundreds. But in the higher
-divisions—crustaceans, insects, and spiders—we find this number reduced
-down to twenty-two, thirteen, or even fewer; while, accompanying the
-reduction, there is a shortening or integration of the whole body,
-reaching its extreme in the crab and the spider. The significance of
-these contrasts, as bearing upon the general doctrine of Evolution, will
-be seen when it is pointed out that they are parallel to those which
-arise during the development of individual _Annulosa_. In the lobster,
-the head and thorax form one compact box, made by the union of a number
-of segments which in the embryo were separable. Similarly, the butterfly
-shows us segments so much more closely united than they were in the
-caterpillar, as to be, some of them, no longer distinguishable from each
-other. The _Vertebrata_ again, throughout their successively higher
-classes, furnish like instances of longitudinal union. In most fishes,
-and in reptiles that have no limbs, the only segments of the spinal
-column that coalesce, are those forming the skull. In most mammals and
-in birds, a variable number of vertebræ become fused together to form
-the sacrum; and in the higher quadrumana and man, the caudal vertebræ
-also lose their separate individualities in a single _os coccygis_.
- That which we may distinguish as _transverse integration_, is well
-illustrated among the _Annulosa_ in the development of the nervous
-system. Leaving out those most degraded forms which do not present
-distinct ganglia, it is to be observed that the lower annulose animals,
-in common with the larvæ of the higher, are severally characterized by a
-double chain of ganglia running from end to end of the body; while in
-the more perfectly formed annulose animals, this double chain becomes
-more or less completely united into a single chain. Mr. Newport has
-described the course of this concentration as exhibited in insects; and
-by Rathke it has been traced in crustaceans. During the early stages of
-the _Astacus fluviatilis_, or common cray-fish, there is a pair of
-separate ganglia to each ring. Of the fourteen pairs belonging to the
-head and thorax, the three pairs in advance of the mouth consolidate
-into one mass to form the brain, or cephalic ganglion. Meanwhile, out of
-the remainder, the first six pairs severally unite in the median line,
-while the rest remain more or less separate. Of these six double ganglia
-thus formed, the anterior four coalesce into one mass; the remaining two
-coalesce into another mass; and then these two masses coalesce into one.
-Here we see longitudinal and transverse integration going on
-simultaneously; and in the highest crustaceans they are both carried
-still further. The _Vertebrata_ clearly exhibit transverse integration
-in the development of the generative system. The lowest of the
-mammalia—the _Monotremata_—in common with birds, to which they are in
-many respects allied, have oviducts which towards their lower
-extremities are dilated into cavities, severally performing in an
-imperfect way the function of a uterus. “In the _Marsupialia_ there is a
-closer approximation of the two lateral sets of organs on the median
-line; for the oviducts converge towards one another and meet (without
-coalescing) on the median line; so that their uterine dilatations are in
-contact with each other, forming a true ‘double uterus....’ As we ascend
-the series of ‘placental’ mammals, we find the lateral coalescence
-becoming more and more complete.... In many of the _Rodentia_ the uterus
-still remains completely divided into two lateral halves; whilst in
-others these coalesce at their lower portions, forming a rudiment of the
-true ‘body’ of the uterus in the human subject. This part increases at
-the expense of the lateral ‘cornua’ in the higher herbivora and
-carnivora; but even in the lower quadrumana the uterus is somewhat cleft
-at its summit.”[10]
-
-In the social organism integrative changes are not less clearly and
-abundantly exemplified. Uncivilized societies display them when
-wandering families, such as the bushmen show us, unite into tribes of
-considerable numbers. Among these we see a further progress of like
-nature everywhere manifested in the subjugation of weaker tribes by
-stronger ones; and in the subordination of their respective chiefs to
-the conquering chief. The partial combinations thus resulting, which
-among aboriginal races are being continually formed and continually
-broken up, become, among the superior races, both more complete and more
-permanent. If we trace the metamorphoses through which our own society,
-or any adjacent one, has passed, we see this unification from time to
-time repeated on a larger scale and with increasing stability. The
-aggregation of juniors and the children of juniors under elders and the
-children of elders; the consequent establishment of groups of vassals
-bound to their respective nobles; the subordination afterwards
-established of groups of inferior nobles to dukes or earls; and the
-still later establishment of the kingly power over dukes or earls; are
-so many instances of increasing consolidation. This process through
-which petty tenures are combined into feuds, feuds into provinces,
-provinces into kingdoms, and finally contiguous kingdoms into a single
-one, slowly completes itself by destroying the original lines of
-demarcation. And it may be further remarked of the European nations as a
-whole, that in the tendency to form alliances more or less lasting, in
-the restraining influences exercised by the several governments over
-each other, in the system that is gradually establishing itself of
-settling international disputes by congresses, as well as in the
-breaking down of commercial barriers and the increasing facilities of
-communication, we may trace the incipient stage of a European
-confederation—a still larger integration than any now established.
- But it is not only in these external unions of groups with groups,
-and of the compound groups with each other, that the general law is
-exemplified. It is exemplified also in unions that take place
-internally, as the groups become more highly organized. These, of which
-the most conspicuous are commercial in their origin and function, are
-well illustrated in our own society. We have integrations consequent on
-the simple growth of adjacent parts performing like functions: as, for
-instance, the junction of Manchester with its calico-weaving suburbs. We
-have other integrations that arise when, out of several places producing
-a particular commodity, one monopolizes more and more of the business,
-and leaves the rest to dwindle: as witness the growth of the Yorkshire
-cloth-districts at the expense of those in the west of England; or the
-absorption by Staffordshire of the pottery-manufacture, and the
-consequent decay of the establishments that once flourished at
-Worcester, Derby, and elsewhere. And we have those yet other
-integrations produced by the actual approximation of the
-similarly-occupied parts: whence result such facts as the concentration
-of publishers in Paternoster Row; of lawyers in the Temple and
-neighbourhood; of corn-merchants about Mark Lane; of civil engineers in
-Great George Street; of bankers in the centre of the city. Industrial
-combinations that consist, not in the approximation or fusion of parts,
-but in the establishment of common centres of connexion, are exhibited
-in the Bank clearing-house and the Railway clearing-house. While of yet
-another genus are those unions which bring into relation the more or
-less dispersed citizens who are occupied in like ways: as traders are
-brought by the Exchange and the Stock-Exchange; and as are professional
-men by institutes, like those of Civil Engineers, Architects, &c.
-
-Here, as before, it is manifest that a law of Evolution which holds of
-organisms, must hold too of all objective results of their activity; and
-that hence Language, and Science, and Art, must not only in the course
-of their development display increasing heterogeneity and definiteness,
-but also increasing integration. We shall find this conclusion to be in
-harmony with the facts.
-
-Among uncivilized races, the many-syllabled terms used for not uncommon
-objects, as well as the descriptive character of proper names, show us
-that the words used for the less familiar things are formed by
-compounding the words used for the more familiar things. This process of
-composition is sometimes found in its incipient stage—a stage in which
-the component words are temporarily united to signify some unnamed
-object, and do not (from lack of frequent use) permanently cohere. But
-in the majority of inferior languages, the process of “agglutination,”
-as it is called, has gone far enough to produce considerable stability
-in the compound words: there is a manifest integration. How small is the
-degree of this integration, however, when compared with that reached in
-well-developed languages is shown both by the great length of the
-compound words used for things and acts of constant occurrence, and by
-the separableness of their elements. Certain North-American tongues very
-well illustrate this. In a Ricaree vocabulary extending to fifty names
-of common objects, which in English are nearly all expressed by single
-syllables, there is not one monosyllabic word; and in the nearly-allied
-vocabulary of the Pawnees, the names for these same common objects are
-monosyllabic in but two instances. Things so familiar to these hunting
-tribes as _dog_ and _bow_, are, in the Pawnee language, _ashakish_ and
-_teeragish_; the _hand_ and the _eyes_ are respectively _iksheeree_ and
-_keereekoo_; for _day_ the term is _shakoorooeeshairet_, and for _devil_
-it is _tsaheekshkakooraiwah_; while the numerals are composed of from
-two syllables up to five, and in Ricaree up to seven. That the great
-length of these familiar words implies a low degree of development, and
-that in the formation of higher languages out of lower there is a
-progressive integration, which reduces the polysyllables to dissyllables
-and monosyllables, is an inference fully confirmed by the history of our
-own language. Anglo-Saxon _steorra_ has been in course of time
-consolidated into English _star_, _mona_ into _moon_, and _nama_ into
-_name_. The transition through the intermediate semi-Saxon is clearly
-traceable. _Sunu_ became in semi-Saxon _sune_, and in English _son_: the
-final _e_ of _sune_ being an evanescent form of the original _u_. The
-change from the Anglo-Saxon plural, formed by the distinct syllable
-_as_, to our plural formed by the appended consonant _s_, shows us the
-same thing: _smithas_ in becoming _smiths_, and _endas_ in becoming
-_ends_, illustrate progressive coalescence. So too does the
-disappearance of the terminal _an_ in the infinitive mood of verbs; as
-shown in the transition from the Anglo-Saxon _cuman_ to the semi-Saxon
-_cumme_, and to the English _come_. Moreover the process has been slowly
-going on, even since what we distinguish as English was formed. In
-Elizabeth’s time, verbs were still very frequently pluralized by the
-addition of _en_—we _tell_ was we _tellen_; and in some rural districts
-this form of speech may even now be heard. In like manner the terminal
-_ed_ of the past tense, has united with the word it modifies. _Burn-ed_
-has in pronunciation become _burnt_; and even in writing the terminal
-_t_ has in some cases taken the place of the _ed_. Only where antique
-forms in general are adhered to, as in the church-service, is the
-distinctness of this inflection still maintained. Further, we see that
-the compound vowels have been in many cases fused into single vowels.
-That in _bread_ the _e_ and _a_ were originally both sounded, is proved
-by the fact that they are still so sounded in parts where old habits
-linger. We, however, have contracted the pronunciation into _bred_; and
-we have made like changes in many other common words. Lastly, let it be
-noted that where the frequency of repetition is greatest, the process is
-carried furthest; as instance the contraction of _lord_ (originally
-_laford_) into _lud_ in the mouths of Barristers; and still better the
-coalescence of _God be with you_ into _Good bye_. Besides
-exhibiting in this way the integrative process, Language equally
-exhibits it throughout all grammatical development. The lowest kinds of
-human speech, having merely nouns and verbs without inflections to them,
-manifestly permit no such close union of the elements of a proposition
-as results when the relations are either marked by inflections or by
-words specially used for purposes of connexion. Such speech is
-necessarily what we significantly call “incoherent.” To a considerable
-extent, incoherence is seen in the Chinese language. “If, instead of
-saying _I go_ to _London_, _figs come_ from _Turkey_, _the sun shines_
-through _the air_, we said, _I go_ end _London_, _figs come_ origin
-_Turkey_, _the sun shines_ passage _air_, we should discourse of the
-manner of the Chinese.” From this “aptotic” form, there is clear
-evidence of a transition by coalescence to a form in which the
-connexions of words are expressed by the addition to them of certain
-inflectional words. “In Languages like the Chinese,” remarks Dr Latham,
-“the separate words most in use to express relation may become adjuncts
-or annexes.” To this he adds the fact that “the numerous inflexional
-languages fall into two classes. In one, the inflexions have no
-appearance of having been separate words. In the other, their origin as
-separate words is demonstrable.” From which the inference drawn is, that
-the “aptotic” languages, by the more and more constant use of adjuncts,
-gave rise to the “agglutinate” languages, or those in which the original
-separateness of the inflexional parts can be traced; and that out of
-these, by further use, arose the “amalgamate” languages, or these in
-which the original separateness of the inflexional parts can no longer
-be traced. Strongly corroborative of this inference is the
-unquestionable fact, that by such a process there have grown out of the
-amalgamate languages, the “anaptotic” languages; of which our own is the
-most perfect example—languages in which, by further consolidation,
-inflexions have almost disappeared, while, to express the verbal
-relations, certain new kinds of words have been developed. When we see
-the Anglo-Saxon inflexions gradually lost by contraction during the
-development of English, and, though to a less degree, the Latin
-inflexions dwindling away during the development of French, we cannot
-deny that grammatical structure is modified by integration; and seeing
-how clearly the earlier stages of grammatical structure are explained by
-it, we can scarcely doubt that it has been going on from the first.
- And now mark that in proportion to the degree of the integration
-above described, is the extent to which integration of another order is
-shown. Aptotic languages are, as already pointed out, necessarily
-incoherent—the elements of a proposition cannot be tied into a definite
-and complete whole. But as fast as coalescence produces inflected words,
-it becomes possible to unite them into sentences of which the parts are
-so mutually dependent that no considerable change can be made without
-destroying the meaning. Yet a further stage in this process may be
-noted. After the development of those grammatical forms which make
-definite statements possible, we do not at first find them used to
-express anything beyond statements of a simple kind. A single subject
-with a single predicate, accompanied by but few qualifying terms, are
-usually all. If we compare, for instance, the Hebrew scriptures with
-writings of modern times, a marked difference of aggregation among the
-groups of words, is visible. In the number of subordinate propositions
-which accompany the principal one; in the various complements to
-subjects and predicates; and in the numerous qualifying clauses—all of
-them united into one complex whole—many sentences in modern composition
-exhibit a degree of integration not to be found in ancient ones.
-
-The history of Science presents facts of the same meaning at every step.
-Indeed the integration of groups of like entities and like relations,
-may be said to constitute the most conspicuous part of scientific
-progress. A glance at the classificatory sciences, shows us not only
-that the confused aggregations which the vulgar make of natural objects,
-are differentiated into groups that are respectively more homogeneous,
-but also that these groups are gradually rendered complete and compact.
-While, instead of considering all marine creatures as fish, shell-fish,
-and jelly-fish, Zoology establishes divisions and sub-divisions under
-the heads _Vertebrata_, _Annulosa_, _Mollusca_, &c.—while in place of
-the wide and vague assemblage popularly described as “creeping things,”
-it makes the specific classes _Annelida_, _Myriopoda_, _Insecta_,
-_Arachnida_; it at the same time gives to these an increasing
-consolidation. The several orders and genera of which each consists, are
-arranged according to their affinities and bound together under common
-definitions; at the same time that, by extended observation and rigorous
-criticism, the previously unknown and undetermined forms are integrated
-with their respective congeners. Nor is the same process less
-clearly manifested in those sciences which have for their
-subject-matter, not classified objects, but classified relations. Under
-one of its chief aspects, the advance of Science is the advance of
-generalization; and generalization is the uniting into groups all like
-co-existencies and sequences among phenomena. Not only, however, does
-the colligation of a number of concrete relations into a generalization
-of the lowest order, exemplify the principle enunciated; but it is again
-and again exemplified in the colligation of these lowest generalizations
-into higher ones, and these into still higher ones. Year by year are
-established certain connexions among orders of phenomena that seem
-wholly unallied; and these connexions, multiplying and strengthening,
-gradually bring the seemingly unallied orders under a common bond. When,
-for example, Humboldt quotes the saying of the Swiss—“it is going to
-rain because we hear the murmur of the torrents nearer,”—when he remarks
-the relation between this and an observation of his own, that the
-cataracts of the Orinoco are heard at a greater distance by night than
-by day—when he notes the essential parallelism existing between these
-facts and the fact that the unusual visibility of remote objects is also
-an indication of coming rain—and when he points out that the common
-cause of these variations is the smaller hindrance offered to the
-passage of both light and sound, by media which are comparatively
-homogeneous, either in temperature or hygrometric state; he helps in
-bringing under one generalization the phenomena of light and those of
-sound. Experiment having shown that these conform to like laws of
-reflection and refraction, the conclusion that they are both produced by
-undulations gains probability: there is an incipient integration of two
-great orders of phenomena, between which no connexion was suspected in
-times past. A still more decided integration has been of late taking
-place between the once independent sub-sciences of Electricity,
-Magnetism, and Light. And indeed it must be obvious to those who are
-familiar with the present state of Science, that there will eventually
-take place a far wider integration, by which all orders of phenomena
-will be combined as differently conditioned forms of one ultimate fact.
-
-Nor do the industrial and æsthetic Arts fail to supply us with equally
-conclusive evidence. The progress from rude, small, and simple tools, to
-perfect, complex, and large machines, illustrates not only a progress in
-heterogeneity and in definiteness, but also in integration. Among what
-are classed as the mechanical powers, the advance from the lever to the
-wheel-and-axle is an advance from a simple agent to an agent made up of
-several simple ones combined together. On comparing the wheel-and-axle,
-or any of the machines used in early times with those used now, we find
-an essential difference to be, that in each of our machines several of
-the primitive machines are united into one. A modern apparatus for
-spinning or weaving, for making stockings or lace, contains not simply a
-lever, an inclined plane, a screw, a wheel-and-axle, united together;
-but several of each integrated into one complex whole. Again, in early
-ages, when horse-power and man-power were alone employed, the motive
-agent was not bound up with the tool moved; but the two have now become
-in many cases fused together: the fire-box and boiler of a locomotive
-are combined with the machinery which the steam works. Nor is this the
-most extreme case. A still more extensive integration is exhibited in
-every large factory. Here we find a large number of complicated
-machines, all connected by driving shafts with the same steam-engine—all
-united with it into one vast apparatus. Contrast the mural
-decorations of the Egyptians and Assyrians with modern historical
-paintings, and there becomes manifest a great advance in unity of
-composition—in the subordination of the parts to the whole. One of these
-ancient frescoes is in truth made up of a number of pictures that have
-little mutual dependence. The several figures of which each group
-consists, show very imperfectly by their attitudes, and not at all by
-their expressions, the relations in which they stand to each other; the
-respective groups might be separated with but little loss of meaning;
-and the centre of chief interest, which should link all parts together,
-is often inconspicuous. The same trait may be noted in the tapestries of
-medieval days. Representing perhaps a hunting scene, one of these
-exhibits men, horses, dogs, beasts, birds, trees, and flowers,
-miscellaneously dispersed: the living objects being variously occupied,
-and mostly with no apparent consciousness of each other’s proximity. But
-in the paintings since produced, faulty as many of them are in this
-respect, there is always a more or less manifest co-ordination of
-parts—an arrangement of attitudes, expressions, lights, and colours,
-such as to combine the picture into an organic whole; and the success
-with which unity of effect is educed from variety of components, is a
-chief test of merit. In music, progressive integration is
-displayed in still more numerous ways. The simple cadence embracing but
-a few notes, which in the chants of savages is monotonously repeated,
-becomes among civilized races, a long series of different musical
-phrases combined into one whole; and so complete is the integration,
-that the melody cannot be broken off in the middle, nor shorn of its
-final note, without giving us a painful sense of incompleteness. When to
-the air, a bass, a tenor, and an alto are added; and when to the harmony
-of different voice-parts there is added an accompaniment; we see
-exemplified integrations of another order, which grow gradually more
-elaborate. And the process is carried a stage higher when these complex
-solos, concerted pieces, choruses, and orchestral effects, are combined
-into the vast ensemble of a musical drama; of which, be it remembered,
-the artistic perfection largely consists in the subordination of the
-particular effects to the total effect. Once more the Arts of
-literary delineation, narrative and dramatic, furnish us with parallel
-illustrations. The tales of primitive times, like those with which the
-story-tellers of the East still daily amuse their listeners, are made up
-of successive occurrences that are not only in themselves unnatural, but
-have no natural connexion: they are but so many separate adventures put
-together without necessary sequence. But in a good modern work of
-imagination, the events are the proper products of the characters
-working under given conditions; and cannot at will be changed in their
-order or kind, without injuring or destroying the general effect. And
-further, the characters themselves, which in early fictions play their
-respective parts without showing us how their minds are modified by each
-other or by the events, are now presented to us as held together by
-complex moral relations, and as acting and re-acting upon each other’s
-natures.
-
-Evolution, then, is in all cases a change from a more diffused or
-incoherent form, to a more consolidated or coherent form. This proves to
-be a characteristic displayed equally in those earliest changes which
-the Universe as a whole is supposed to have undergone, and in those
-latest changes which we trace in society and the products of social
-life. Nor is it only that in the development of a planet, of an
-organism, of a society, of a science, of an art, the process of
-integration is seen in a more complete aggregation of each whole and of
-its constituent parts; but it is also shown in an increasing mutual
-dependence of the parts. Dimly foreshadowed as this mutual dependence is
-among inorganic phenomena, both celestial and terrestrial, it becomes
-distinct among organic phenomena. From the lowest living forms upwards,
-the degree of development is marked by the degree in which the several
-parts constitute a mutually-dependent whole. The advance from those
-creatures which live on in each part when cut in pieces, up to those
-creatures which cannot lose any considerable part without death, nor any
-inconsiderable part without great constitutional disturbance, is clearly
-an advance to creatures which are not only more integrated in respect of
-their solidification, but are also more integrated as consisting of
-organs that live for and by each other. The like contrast between
-undeveloped and developed societies, need not be shown in detail: the
-ever-increasing co-ordination of parts, is conspicuous to all. And it
-must suffice just to indicate that the same thing holds true of social
-products: as, for instance, of Science; which has become highly
-integrated not only in the sense that each division is made up of
-mutually-dependent propositions, but also in the sense that the several
-divisions are mutually-dependent—cannot carry on their respective
-investigations without aid from each other.
-
-It seems proper to remark that the generalization here variously
-illustrated, is akin to one enunciated by Schelling, that Life is the
-tendency to individuation. Struck by the fact that an aggregative
-process is traceable throughout nature, from the growth of a crystal up
-to the development of a man; and by the fact that the wholes resulting
-from this process, completer in organic than in inorganic bodies, are
-completest where the vital manifestations are the highest; Schelling
-concluded that this characteristic was the essential one. According to
-him, the formation of individual bodies is not incident to Life, but is
-that in which Life fundamentally consists. This position is, for
-several reasons, untenable. In the first place, it requires the
-conception of Life to be extended so as to embrace inorganic phenomena;
-since in crystallization, and even in the formation of amorphous masses
-of matter, this tendency to individuation is displayed. Schelling, fully
-perceiving this, did indeed accept the implication; and held that
-inorganic bodies had life lower only in degree than that of organic
-bodies—their degree of life being measured by their degree of
-individuation. This bold assumption, which Schelling evidently made to
-save his definition, is inadmissible. Rational philosophy cannot ignore
-those broad distinctions which the general sense of mankind has
-established. If it transcends them, it must at the same time show what
-is their origin; how far only they are valid; and why they disappear
-from a higher point of view. Note next that the more complete
-individuality which Schelling pointed out as characterizing bodies
-having the greatest amount of life, is only _one_ of their structural
-traits. The greater degree of heterogeneity which they exhibit, is, as
-we have seen, a much more conspicuous peculiarity; and though it might
-possibly be contended that greater heterogeneity is remotely implied by
-greater individuality, it must be admitted that in defining Life as the
-tendency to individuation, no hint is given that the bodies which live
-most are the most heterogeneous bodies. Moreover it is to be
-remarked that this definition of Schelling, refers much more to the
-structures of living bodies than to the processes which constitute Life.
-Not Life, but the invariable accompaniment of Life, is that which his
-formula alone expresses. The formation of a completer organic whole, a
-more fully individuated body, is truly a necessary concomitant of a
-higher life; and the development of a higher life must therefore be
-accompanied by a tendency to greater individuation. But to represent
-this tendency as Life itself, is to mistake an incidental result for an
-original cause. Life, properly so called, consists of multiform changes
-united together in various ways; and is not expressed either by an
-anatomical description of the organism which manifests it, or by a
-history of the modifications through which such organism has reached its
-present structure. Yet it is only in such description and such history
-that the tendency to individuation is seen. Lastly, this
-definition which Schelling gave of Life is untenable, not only because
-it refers rather to the organism than to the actions going on in it; but
-also because it wholly ignores that connexion between the organism and
-the external world, on which Life depends. All organic processes,
-physical and psychial, having for their object the maintenance of
-certain relations with environing agencies and objects; it is impossible
-that there should be a true definition of Life, in which the environment
-is not named. Nevertheless, Schelling’s conception was not a
-baseless one. Though not a truth, it was yet the adumbration of a truth.
-In defining Life as the tendency to individuation, he had in view that
-formation of a more compact, complete, and mutually-dependent whole,
-which, as we have seen, is one characteristic of Evolution in general.
-His error was, firstly, in regarding it as a characteristic of Life,
-instead of a characteristic of living bodies, displayed, though in a
-less degree, by other bodies; and, secondly, in regarding it as the sole
-characteristic of such bodies. It remains only to add, that for
-expressing this aspect of the process of Evolution, the word integration
-is for several reasons preferable to the word individuation. Integration
-is the true antithesis of differentiation; it has not that tacit
-reference to living bodies which the word individuation cannot be wholly
-freed from; it expresses the aggregative tendency not only as displayed
-in the formation of more complete wholes, but also as displayed in the
-consolidation of the several parts of which such wholes are made up; and
-it has not the remotest teleological implication. In short, it simply
-formulates in the most abstract manner, a wide induction untainted by
-any hypothesis.
-
- * * * * *
-
-§ 57. Thus we find that to complete the definition arrived at in the
-last chapter, much has to be added. What was there alleged is true; but
-it is not the whole truth. Evolution is unquestionably a change from a
-homogeneous state to a heterogeneous state; but, as we have seen, there
-are some advances in heterogeneity which cannot be included in the idea
-of Evolution. This undue width of the definition, implies the omission
-of some further peculiarity by which Evolution is distinguished; and
-this peculiarity we find to be that the more highly developed things
-become, the more definite they become. Advance from the indefinite to
-the definite, is as constantly and variously displayed as advance from
-the homogeneous to the heterogeneous. And we are thus obliged to regard
-it as an essential characteristic of Evolution. Further analysis,
-however, shows us that this increase of definiteness is not an
-independent process; but is rather the necessary concomitant of another
-process. A very little consideration of the facts proves that a change
-from the indefinite to the definite, can arise only through a completer
-consolidation of the respective parts, and of the whole which they
-constitute. And so we find that while Evolution is a transformation of
-the homogeneous into the heterogeneous, and of the indefinite into the
-definite, it is also a transformation of the incoherent into the
-coherent. Along with the differentiation shown in increasing contrasts
-of parts with each other, there goes on an integration, by which the
-parts are rendered distinct units, as well as closely united components
-of one whole. These clauses here added to the definition, are
-essential ones; not only as being needful to distinguish Evolution from
-that which is not Evolution, but likewise as being needful to express
-all which the idea of Evolution includes. Progressive integration with
-the growing definiteness necessarily resulting from it, is of
-co-ordinate importance with the progressive differentiation before dwelt
-upon—nay, from one point of view, may be held of greater importance. For
-organization, in which what we call Evolution is most clearly and
-variously displayed, consists even more in the union of many parts into
-one whole, than in the formation of many parts. The Evolution which we
-see throughout inorganic nature, is lower than that which organic nature
-exhibits to us, for the especial reason that the mutual dependence of
-parts is extremely indefinite, even when traceable at all. In an
-amorphous mass of matter, you may act mechanically or chemically upon
-one part without appreciably affecting the other parts. Though their
-electrical or thermal states may be for the moment altered, their
-original states are soon resumed. Even in the highest inorganic
-aggregation—a crystal—the apex may be broken off and leave the rest
-intact: the only clear evidence of mutual dependence of parts, being,
-the ability of the crystal to regenerate its apex if replaced in the
-solution from which it was formed. But the constituent parts of organic
-bodies can severally maintain their existing states, only while
-remaining in connexion. Even in the lowest living forms, mutilation
-cannot be carried beyond a certain point without decomposition ensuing.
-As we advance through the higher up to the highest forms, we see a
-gradual narrowing of the limits within which the mutilation does not
-cause destruction: a progressive increase of mutual dependence or
-integration which is, at the same time, the condition to greater
-functional perfection. In societies this truth is equally manifest. That
-the component units slowly segregate into groups of different ranks and
-occupations, is a fact scarcely more conspicuous than is the fact that
-these groups are necessary to each other’s existence. And we cannot
-contemplate the still-progressing division of labour, without seeing
-that the interdependence becomes ever greater as the evolution becomes
-higher. It remains only to point out definitely, what has been
-already implied, that these several forms of change which have been
-successively described as making up the process of Evolution, are not in
-reality separate forms of change, but different aspects of the same
-change. Intrinsically the transformation is one and indivisible. The
-establishment of differences that become gradually more decided, is
-evidently but the beginning of an action which cannot be pushed to its
-extreme without producing definite divisions between the parts, and
-reducing each part to a separate mass. But with our limited faculties,
-it is not possible to take in the entire process at one view; nor have
-we any single terms by which the process can be described. Hence we are
-obliged to contemplate each of its aspects separately, and to find a
-separate expression for its characteristic.
-
-Having done this, we are now in a position to frame a true idea of
-Evolution. Combining these partial definitions we get a complete
-definition, which may be most conveniently expressed thus—_Evolution is
-a change from an indefinite, incoherent homogeneity, to a definite,
-coherent heterogeneity; through continuous differentiations and
-integrations._
-
-It may perhaps be remarked that the last of these clauses is
-superfluous; since the differentiation and integration are implied in
-the first clause. This is true: the transition which the first clause
-specifies, is impossible save through the process specified in the
-second. Nevertheless, a mere statement of the two extreme stages with
-which Evolution begins and ends, omitting all reference to changes
-connecting them, leaves the mind with but an incomplete idea. The idea
-becomes much more concrete when these changes are described. Hence,
-though not logically necessary, the second clause of the definition is
-practically desirable.
-
-Before closing the chapter, a few words must be added respecting certain
-other modes of describing Evolution. Organic bodies, from the changes of
-which the idea of Evolution has arisen, and to the changes of which
-alone it is usually applied, are often said to progress from simplicity
-to complexity. The transformation of the simple into the complex, and of
-the homogeneous into the heterogeneous, are used as equivalent phrases;
-or, if any difference is recognized between them, it is to the advantage
-of the first, which is held to be the more specific. After what has been
-said, however, it must be obvious that Evolution cannot be thus
-adequately formulated. No hint is given of that increased definiteness
-which we have found to be a concomitant of development. Nor is there
-anything implying the greater mutual dependence of parts. Nevertheless,
-the brevity of the expression gives it a value for ordinary purposes;
-and I shall probably hereafter frequently use it, both in those cases
-where more precise language is not demanded, and in those cases where it
-indicates the particular aspect of Evolution referred to. Another
-description frequently given of Evolution, is, that it is a change from
-the general to the special. The more or less spherical germ from which
-every organism, animal and vegetal, proceeds, is comparatively general:
-alike in the sense that in appearance and chemical nature it is very
-similar to all other germs; and also in the sense that its form is less
-markedly distinguished from the average forms of objects at large, than
-is that of the mature organism—a contrast which equally holds of
-internal structure. But this progress from the more general to the more
-special, is rather a derivative than an original characteristic. An
-increase of speciality being really an increase in the number of
-attributes—an addition of traits not possessed by bodies that are in
-other respects similar—is a necessary result of multiplying
-differentiations. In other words, general and special are subjective or
-ideal distinctions involved in our conceptions of classes, rather than
-objective or real distinctions presented in the bodies classified.
-Nevertheless, this abstract formula is not without its use. It expresses
-a fact of much significance; and one which we shall have constantly to
-refer to when dealing with the relations between organic bodies and
-their surrounding conditions.
-
-The law of Evolution however, be it expressed in full as above, or in
-these shorter but less specific phrases, is essentially that which has
-been exhibited in detail throughout the foregoing pages. So far as we
-can ascertain, this law is universal. It is illustrated with endless
-repetition, and in countless ways, wherever the facts are abundant; and
-where the facts do not suffice for induction, deduction goes far to
-supply its place. Among all orders of phenomena that lie within the
-sphere of observation, we see ever going on the process of change above
-defined; and many significant indications warrant us in believing, that
-the same process of change went on throughout that remote past which
-lies beyond the sphere of observation. If we must form any conclusion
-respecting the general course of things, past, present, and future, the
-one which the evidence as far as it goes justifies, and the only one for
-which there is any justification, is, that the change from an
-indeterminate uniformity to a determinate multiformity which we
-everywhere see going on, has been going on from the first, and will
-continue to go on.
-
------
-
-Footnote 10:
-
- Carpenter’s Prin. of Comp. Phys., p. 617.
-
-
-
-
- CHAPTER IV.
- THE CAUSES OF EVOLUTION.
-
-
-§ 58. Is this law ultimate or derivative? Must we rest satisfied with
-the conclusion that throughout all classes of concrete phenomena such is
-the mode of evolution? Or is it possible for us to ascertain _why_ such
-is the mode of evolution? May we seek for some all-pervading principle
-which underlies this all-pervading process? Can we by a further step
-reduce our empirical generalization to a rational generalization?
-
-Manifestly this community of result implies community of causation. It
-may be that of such causation no account can be given, further than that
-the Unknowable is manifested to us after this manner. Or, it may be,
-that the mode of manifestation is reducible to simpler ones, from which
-these many complex consequences follow. Analogy suggests the latter
-inference. At present, the conclusion that every kind of Evolution is
-from a state of indefinite incoherent homogeneity to a state of definite
-coherent heterogeneity, stands in the same position as did the once
-ultimate conclusion that every kind of organized body undergoes, when
-dead, a more or less rapid decay. And as, for the various kinds of
-decomposition through which animal and vegetal products pass, we have
-now discovered a rationale in the chemical affinities of their
-constituent elements; so, possibly, this universal transformation of the
-simple into the complex may be affiliated upon certain simple primordial
-principles.
-
-Such cause or causes of Evolution, may be sought for without in the
-least assuming that the ultimate mystery can be fathomed. Fully
-conscious that an absolute solution is for ever beyond us, we may still
-look for a relative solution—may try to reduce the problem to its lowest
-terms. Just as it was possible to interpret Kepler’s laws as necessary
-consequences of the law of gravitation, and then to admit that
-gravitation transcends analysis; so it may be possible to interpret the
-law of Evolution as the necessary consequence of some deeper law, beyond
-which we may nevertheless be unable to go.
-
- * * * * *
-
-§ 59. The probability of common causation, and the possibility of
-formulating it, being granted, it will be well before going further, to
-consider what must be the general characteristics of such causation, and
-in what direction we ought to look for it. We can with certainty predict
-that be it simple or compound, the cause has a high degree of
-generality; seeing that it is common to such infinitely varied
-phenomena: in proportion to the universality of its application must be
-the abstractness of its character. Whatever be the agency and the
-conditions under which it acts, we need not expect to see in them an
-obvious explanation of this or that species of Evolution, because they
-equally underlie species of Evolution of quite a different order.
-Determining Evolution of every kind—astronomic, geologic, organic,
-ethnologic, social, economic, artistic, &c.—they must be concerned with
-something common to all these; and to see what these possess in common,
-will therefore be the best method of guiding ourselves towards the
-desired solution.
-
-The only obvious respect in which all kinds of Evolution are alike, is,
-that they are modes of _change_. Every phenomenon to which we apply the
-term, presents us with a succession of states; and when such succession
-ceases, we no longer predicate Evolution. Equally in those past forms of
-it which are more or less hypothetical, and in those forms of it which
-we see going on around, this is the common characteristic. Note
-next, that the kind of change which constitutes Evolution, is broadly
-distinguished from change of an equally general kind, in this, that it
-is change of internal relations instead of change of external relations.
-All things in motion through space are the subjects of change; but while
-in this which we call mechanical motion, the relative position as
-measured from surrounding objects is continually altered, there is not
-implied any alteration in the positions of the parts of the moving body
-in respect to each other. Conversely, a body exhibiting what we call
-Evolution, while it either may or may not display new relations of
-position to the things around it, _must_ display new relations of
-position among the parts of which it is made up. Thus we narrow the
-field of inquiry by recognizing the change in which Evolution consists,
-as _a change in the arrangement of parts_: of course using the word
-parts in its most extended sense, as signifying both ultimate units and
-masses of such units. Further, we have to remember that this
-change in the arrangement of parts which constitutes Evolution, is a
-certain order of such change. As we saw in the last chapter, there is a
-change in the arrangement of parts which is not Evolution but
-Dissolution—a destructive change as opposed to a constructive change—a
-change by which the definite is gradually rendered indefinite, the
-coherent slowly becomes incoherent, and the heterogeneous eventually
-lapses into comparative homogeneity. Thus then we reduce that
-which we have to investigate to its most abstract shape. Our task is to
-find the cause or causes of a certain order of change that takes place
-in the arrangement of parts.
-
- * * * * *
-
-§ 60. Evidently the problem, as thus expressed, brings us face to face
-with the ultimate elements of phenomena in general. It is impossible to
-account for a certain change in the arrangement of the parts of any
-mass, without involving—first, the _matter_ which makes up the parts
-thus re-arranged; next, the _motion_ exhibited during the
-re-arrangement; and then, the _force_ producing this motion. The problem
-is a dynamical one; and there can be no truly scientific solution of it,
-save one given in terms of Matter, Motion, and Force—terms in which all
-other dynamical problems are expressed and solved.
-
-The proposal thus to study the question from a purely physical point of
-view, will most likely, notwithstanding what has been said in the first
-part of this work, raise in some minds either alarm or prejudice.
-Having, throughout life, constantly heard the charge of materialism made
-against those who ascribed the more involved phenomena to agencies like
-those seen in the simplest phenomena, most persons have acquired a
-repugnance to such methods of interpretation; and when it is proposed to
-apply them universally, even though it is premised that the solution
-they give can be but relative, more or less of the habitual feeling will
-probably arise. Such an attitude of mind, however, is significant, not
-so much of a reverence for the Unknown Cause, as of an irreverence for
-those omnipresent forms in which the Unknown Cause is manifested to us.
-Men who have not risen above that vulgar conception which unites with
-Matter the contemptuous epithets “gross” and “brute,” may naturally
-enough feel dismay at the proposal to reduce the phenomena of Life, of
-Mind, and of Society, to a level with those which they think so
-degraded. But whoever remembers that the forms of existence which the
-uncultivated speak of with so much scorn, are not only shown by the man
-of science to be the more marvellous in their attributes the more they
-are investigated, but are also proved to be in their ultimate nature
-absolutely incomprehensible—as absolutely incomprehensible as sensation,
-or the conscious something which perceives it—whoever fully realizes
-this truth, I say, will see that the course proposed does not imply a
-degradation of the so-called higher, but an elevation of the so-called
-lower. Perceiving, as he will, that the Materialist and Spiritualist
-controversy is a mere war of words, in which the disputants are equally
-absurd—each thinking he understands that which it is impossible for any
-man to understand—he will perceive how utterly groundless is the fear
-referred to. Being fully convinced that whatever nomenclature is used,
-the ultimate mystery must remain the same, he will be as ready to
-formulate all phenomena in terms of Matter, Motion, and Force, as in any
-other terms; and will rather indeed anticipate, that only in a doctrine
-which recognizes the Unknown Cause as co-extensive with all orders of
-phenomena, can there be a consistent Religion, or a consistent Science.
-
-On the other hand, the conclusion that Evolution, considered under its
-most abstract form, is a certain change in the arrangement of parts; and
-that the causes of this change can be expressed only in terms of Matter,
-Motion, and Force; may in critical minds raise the question—What are
-Matter, Motion, and Force? Referring back in thought to the reasonings
-contained in the chapter on “Ultimate Scientific Ideas;” and remembering
-how it was there shown that absolute knowledge of Matter, Motion, and
-Force, is impossible; some readers will perhaps conclude that any such
-interpretation as the one above proposed, must be visionary. It may be
-asked—How can a comprehensible account of Evolution be given in terms
-that are themselves incomprehensible?
-
-Before proceeding, this question must be met. There can be no sound
-philosophy without clearly defined terms; and as, on the meanings of the
-terms to be here used, doubts have probably been cast by the reasonings
-contained in the chapter referred to, such doubts must be removed. If,
-as was shown, our ideas of things do not correspond with things in
-themselves, it becomes necessary to inquire in what way they are to be
-accepted. If they are not absolutely true, then what is the exact
-meaning of the assertion that they are relatively true? To this question
-let us now address ourselves.
-
-
-
-
- CHAPTER V.
- SPACE, TIME, MATTER, MOTION, AND FORCE.
-
-
-§ 61. That sceptical state of mind which the criticisms of Philosophy
-usually produce, is, in great measure, caused by the misinterpretation
-of words. A sense of universal illusion ordinarily follows the reading
-of metaphysics; and is strong in proportion as the argument has appeared
-conclusive. This sense of universal illusion would probably never have
-arisen, had the terms used been always rightly construed. Unfortunately,
-these terms have by association acquired meanings that are quite
-different from those given to them in philosophical discussions; and the
-ordinary meanings being unavoidably suggested, there results more or
-less of that dreamlike idealism which is so incongruous with our
-instinctive convictions. The word _phenomenon_ and its equivalent word
-_appearance_, are in great part to blame for this. In ordinary speech,
-these are uniformly employed in reference to visual perceptions. Habit,
-almost, if not quite, disables us from thinking of _appearance_ except
-as something seen; and though _phenomenon_ has a more generalized
-meaning, yet we cannot rid it of associations with _appearance_, which
-is its verbal equivalent. When, therefore, Philosophy proves that our
-knowledge of the external world can be but phenomenal—when it concludes
-that the things of which we are conscious are appearances; it inevitably
-arouses in us the notion of an illusiveness like that to which our
-visual perceptions are so liable in comparison with our tactual
-perceptions. Good pictures show us that the aspects of things may be
-very nearly simulated by colours on canvass. The looking-glass still
-more distinctly proves how deceptive is sight when unverified by touch.
-And the frequent cases in which we misinterpret the impressions made on
-our eyes, and think we see something which we do not see, further shake
-our faith in vision. So that the implication of uncertainty has infected
-the very word _appearance_. Hence, Philosophy, by giving it an extended
-meaning, leads us to think of all our senses as deceiving us in the same
-way that the eyes do; and so makes us feel ourselves floating in a world
-of phantasms. Had _phenomenon_ and _appearance_ no such misleading
-associations, little, if any, of this mental confusion would result. Or
-did we in place of them use the term _effect_, which is equally
-applicable to all impressions produced on consciousness through any of
-the senses, and which carries with it in thought the necessary
-correlative _cause_, with which it is equally real, we should be in
-little danger of falling into the insanities of idealism.
-
-Such danger as there might still remain, would disappear on making a
-further verbal correction. At present, the confusion resulting from the
-above misinterpretation, is made greater by an antithetical
-misinterpretation. We increase the seeming unreality of that phenomenal
-existence which we can alone know, by contrasting it with a noumenal
-existence which we imagine would, if we could know it, be more truly
-real to us. But we delude ourselves with a verbal fiction. What is
-the meaning of the word _real_? This is the question which underlies
-every metaphysical inquiry; and the neglect of it is the remaining cause
-of the chronic antagonisms of metaphysicians. In the interpretation put
-on the word _real_, the discussions of philosophy retain one element of
-the vulgar conception of things, while they reject all its other
-elements; and create confusion by the inconsistency. The peasant, on
-contemplating an object, does not regard that which he contemplates as
-something in himself, but believes the thing of which he is conscious to
-be the external object—imagines that his consciousness extends to the
-very place where the object lies: to him the appearance and the reality
-are one and the same thing. The metaphysician, however, is convinced
-that consciousness cannot embrace the reality, but only the appearance
-of it; and so he transfers the appearance into consciousness and leaves
-the reality outside. This reality left outside of consciousness, he
-continues to think of much in the same way as the ignorant man thinks of
-the appearance. Though the reality is asserted to be out of
-consciousness, yet the _realness_ ascribed to it is constantly spoken of
-as though it were a knowledge possessed apart from consciousness. It
-seems to be forgotten that the conception of reality can be nothing more
-than some mode of consciousness; and that the question to be considered
-is—What is the relation between this mode and other modes?
-
-By reality we mean _persistence_ in consciousness: a persistence that is
-either unconditional, as our consciousness of space, or that is
-conditional, as our consciousness of a body while grasping it. The real,
-as we conceive it, is distinguished solely by the test of persistence;
-for by this test we separate it from what we call the unreal. Between a
-person standing before us, and the idea of such a person, we
-discriminate by our ability to expel the idea from consciousness, and
-our inability, while looking at him, to expel the person from
-consciousness. And when in doubt as to the validity or illusiveness of
-some impression made upon us in the dusk, we settle the matter by
-observing whether the impression persists on closer observation; and we
-predicate reality if the persistence is complete. How truly
-persistence is what we mean by reality, is shown in the fact that when,
-after criticism has proved that the real as we are conscious of it is
-not the objectively real, the indefinite notion which we form of the
-objectively real, is of something which persists absolutely, under all
-changes of mode, form, or appearance. And the fact that we cannot form
-even an indefinite notion of the absolutely real, except as the
-absolutely persistent, clearly implies that persistence is our ultimate
-test of the real as present to consciousness.
-
-Reality then, as we think it, being nothing more than persistence in
-consciousness, the result must be the same to us whether that which we
-perceive be the Unconditioned itself, or an effect invariably wrought on
-us by the Unconditioned. If some mode of the Unconditioned uniformly
-produces some mode of consciousness—if the mode of consciousness so
-produced, is as persistent as would be such mode of the Unconditioned
-were it immediately known; it follows that the reality will be to our
-consciousness as complete in the one case as in the other. Were the
-Unconditioned itself present in thought, it could but be persistent; and
-if instead of it, there is present its persistent effect, the resulting
-consciousness of reality must be exactly the same.
-
-Hence there may be drawn these conclusions:—First, that we have an
-indefinite consciousness of an absolute reality transcending relations,
-which is produced by the absolute persistence in us of something which
-survives all changes of relation. Second, that we have a definite
-consciousness of relative reality, which unceasingly persists in us
-under one or other of its forms, and under each form so long as the
-conditions of presentation are fulfilled; and that the relative reality,
-being thus continuously persistent in us, is as real to us as would be
-the absolute reality could it be immediately known. Third, that thought
-being possible only under relation, the relative reality can be
-conceived as such only in connexion with an absolute reality; and the
-connexion between the two being absolutely persistent in our
-consciousness, is real in the same sense as the terms it unites are
-real.
-
-Thus then we may resume, with entire confidence, those realistic
-conceptions which philosophy at first sight seems to dissipate. Though
-reality under the forms of our consciousness, is but a conditioned
-effect of the absolute reality, yet this conditioned effect standing in
-indissoluble relation with its unconditioned cause, and being equally
-persistent with it so long as the conditions persist, is, to the
-consciousness supplying those conditions, equally real. The persistent
-impressions being the persistent results of a persistent cause, are for
-practical purposes the same to us as the cause itself; and may be
-habitually dealt with as its equivalents. Somewhat in the same way that
-our visual perceptions, though merely symbols found to be the
-equivalents of tactual perceptions, are yet so identified with those
-tactual perceptions that we actually appear to see the solidity and
-hardness which we do but infer, and thus conceive as objects what are
-only the signs of objects; so, on a higher stage, do we deal with these
-relative realities as though they were absolutes instead of effects of
-the absolute. And we may legitimately continue so to deal with them as
-long as the conclusions to which they help us are understood as relative
-realities and not absolute ones.
-
-This general conclusion it now remains to interpret specifically, in its
-application to each of our ultimate scientific ideas.
-
- * * * * *
-
-§ 62.[11] We think in relations. This is truly the form of all thought;
-and if there are any other forms, they must be derived from this. We
-have seen (Chap. iii. Part I.) that the several ultimate modes of being
-cannot be known or conceived as they exist in themselves; that is, out
-of _relation_ to our consciousness. We have seen, by analyzing the
-product of thought, (§ 23,) that it always consists of _relations_; and
-cannot include anything beyond the most general of these. On analyzing
-the process of thought, we found that cognition of the Absolute was
-impossible, because it presented neither _relation_, nor its
-elements—difference and likeness. Further, we found that not only
-Intelligence but Life itself, consists in the establishment of internal
-_relations_ in correspondence with external relations. And lastly, it
-was shown that though by the relativity of our thought we are eternally
-debarred from knowing or conceiving Absolute Being; yet that this very
-_relativity_ of our thought, necessitates that vague consciousness of
-Absolute Being which no mental effort can suppress. That _relation_ is
-the universal form of thought, is thus a truth which all kinds of
-demonstration unite in proving.
-
-By the transcendentalists, certain other phenomena of consciousness are
-regarded as forms of thought. Presuming that relation would be admitted
-by them to be a universal mental form, they would class with it two
-others as also universal. Were their hypothesis otherwise tenable
-however, it must still be rejected if such alleged further forms are
-interpretable as generated by the primary form. If we think in
-relations, and if relations have certain universal forms, it is manifest
-that such universal forms of relations will become universal forms of
-our consciousness. And if these further universal forms are thus
-explicable, it is superfluous, and therefore unphilosophical, to assign
-them an independent origin. Now relations are of two
-orders—relations of sequence, and relations of co-existence; of which
-the one is original and the other derivative. The relation of sequence
-is given in every change of consciousness. The relation of co-existence,
-which cannot be originally given in a consciousness of which the states
-are serial, becomes distinguished only when it is found that certain
-relations of sequence have their terms presented in consciousness in
-either order with equal facility; while the others are presented only in
-one order. Relations of which the terms are not reversible, become
-recognized as sequences proper; while relations of which the terms occur
-indifferently in both directions, become recognized as co-existences.
-Endless experiences, which from moment to moment present both orders of
-these relations, render the distinction between them perfectly definite;
-and at the same time generate an abstract conception of each. The
-abstract of all sequences is Time. The abstract of all co-existences is
-Space. From the fact that in thought, Time is inseparable from sequence,
-and Space from co-existence, we do not here infer that Time and Space
-are original conditions of consciousness under which sequences and
-co-existences are known; but we infer that our conceptions of Time and
-Space are generated, as other abstracts are generated from other
-concretes: the only difference being, that the organization of
-experiences has, in these cases, been going on throughout the entire
-evolution of intelligence.
-
-This synthesis is confirmed by analysis. Our consciousness of Space is a
-consciousness of co-existent positions. Any limited portion of space can
-be conceived only by representing its limits as co-existing in certain
-relative positions; and each of its imagined boundaries, be it line or
-plane, can be thought of in no other way than as made up of co-existent
-positions in close proximity. And since a position is not an
-entity—since the congeries of positions which constitute any conceived
-portion of space, and mark its bounds, are not sensible existences; it
-follows that the co-existent positions which make up our consciousness
-of Space, are not co-existences in the full sense of the word (which
-implies realities as their terms), but are the blank forms of
-co-existences, left behind when the realities are absent; that is, are
-the abstracts of co-existences. The experiences out of which,
-during the evolution of intelligence, this abstract of all co-existences
-has been generated, are experiences of individual positions as
-ascertained by touch; and each of such experiences involves the
-resistance of an object touched, and the muscular tension which measures
-this resistance. By countless unlike muscular adjustments, involving
-unlike muscular tensions, different resisting positions are disclosed;
-and these, as they can be experienced in one order as readily as
-another, we regard as co-existing. But since, under other circumstances,
-the same muscular adjustments do not produce contact with resisting
-positions, there result the same states of consciousness, minus the
-resistances—blank forms of co-existence from which the co-existent
-objects before experienced are absent. And from a building up of these,
-too elaborate to be here detailed, results that abstract of all
-relations of co-existence which we call Space. It remains only to
-point out, as a thing which we must not forget, that the experiences
-from which the consciousness of Space arises, are experiences of
-_force_. A certain correlation of the muscular forces we ourselves
-exercise, is the index of each position as originally disclosed to us;
-and the resistance which makes us aware of something existing in that
-position, is an equivalent of the pressure we consciously exert. Thus,
-experiences of forces variously correlated, are those from which our
-consciousness of Space is abstracted.
-
-That which we know as Space being thus shown, alike by its genesis and
-definition, to be purely relative, what are we to say of that which
-causes it? Is there an absolute Space which relative Space in some sort
-represents? Is Space in itself a form or condition of absolute
-existence, producing in our minds a corresponding form or condition of
-relative existence? These are unanswerable questions. Our conception of
-Space is produced by some mode of the Unknowable; and the complete
-unchangeableness of our conception of it simply implies a complete
-uniformity in the effects wrought by this mode of the Unknowable upon
-us. But therefore to call it a necessary mode of the Unknowable, is
-illegitimate. All we can assert is, that Space is a relative reality;
-that our consciousness of this unchanging relative reality implies an
-absolute reality equally unchanging in so far as we are concerned; and
-that the relative reality may be unhesitatingly accepted in thought as a
-valid basis for our reasonings; which, when rightly carried on, will
-bring us to truths that have a like relative reality—the only truths
-which concern us or can possibly be known to us.
-
-Concerning Time, relative and absolute, a parallel argument leads to
-parallel conclusions. These are too obvious to need specifying in
-detail.
-
- * * * * *
-
-§ 63. Our conception of Matter, reduced to its simplest shape, is that
-of co-existent positions that offer resistance; as contrasted with our
-conception of Space, in which the co-existent positions offer no
-resistance. We think of Body as bounded by surfaces that resist; and as
-made up throughout of parts that resist. Mentally abstract the
-co-existent resistances, and the consciousness of Body disappears;
-leaving behind it the consciousness of Space. And since the group of
-co-existing resistent positions constituting a portion of matter, is
-uniformly capable of giving us impressions of resistance in combination
-with various muscular adjustments, according as we touch its near, its
-remote, its right, or its left side; it results that as different
-muscular adjustments habitually indicate different co-existences, we are
-obliged to conceive every portion of matter as containing more than one
-resistent position—that is, as occupying Space. Hence the necessity we
-are under of representing to ourselves the ultimate elements of Matter
-as being at once extended and resistent: this being the universal form
-of our sensible experiences of Matter, becomes the form which our
-conception of it cannot transcend, however minute the fragments which
-imaginary subdivisions produce. Of these two inseparable elements,
-the resistance is primary, and the extension secondary. Occupied
-extension, or Body, being distinguished in consciousness from unoccupied
-extension, or Space, by its resistance, this attribute must clearly have
-precedence in the genesis of the idea. Such a conclusion is, indeed, an
-obvious corollary from that at which we arrived in the foregoing
-section. If, as was there contended, our consciousness of Space is a
-product of accumulated experiences, partly our own but chiefly
-ancestral—if, as was pointed out, the experiences from which our
-consciousness of Space is abstracted, can be received only through
-impressions of resistance made upon the organism; the necessary
-inference is, that experiences of resistance being those from which the
-conception of Space is generated, the resistance-attribute of Matter
-must be regarded as primordial and the space-attribute as derivative.
- Whence it becomes manifest that our experience of _force_, is that
-out of which the idea of Matter is built. Matter as opposing our
-muscular energies, being immediately present to consciousness in terms
-of force; and its occupancy of Space being known by an abstract of
-experiences originally given in terms of force; it follows that forces,
-standing in certain correlations, form the whole content of our idea of
-Matter.
-
-Such being our cognition of the relative reality, what are we to say of
-the absolute reality? We can only say that it is some mode of the
-Unknowable, related to the Matter we know, as cause to effect. The
-relativity of our cognition of Matter is shown alike by the above
-analysis, and by the contradictions which are evolved when we deal with
-the cognition as an absolute one (§ 16). But, as we have lately seen,
-though known to us only under relation, Matter is as real in the true
-sense of that word, as it would be could we know it out of relation; and
-further, the relative reality which we know as Matter, is necessarily
-represented to the mind as standing in a persistent or real relation to
-the absolute reality. We may therefore deliver ourselves over
-without hesitation, to those terms of thought which experience has
-organized in us. We need not in our physical, chemical, or other
-researches, refrain from dealing with Matter as made up of extended and
-resistent atoms; for this conception, necessarily resulting from our
-experiences of Matter, is not less legitimate, than the conception of
-aggregate masses as extended and resistent. The atomic hypothesis, as
-well as the kindred hypothesis of an all-pervading ether consisting of
-molecules, is simply a necessary development of those universal forms
-which the actions of the Unknowable have wrought in us. The conclusions
-logically worked out by the aid of these hypotheses, are sure to be in
-harmony with all others which these same forms involve, and will have a
-relative truth that is equally complete.
-
- * * * * *
-
-§ 64. The conception of Motion as presented or represented in the
-developed consciousness, involves the conceptions of Space, of Time, and
-of Matter. A something that moves; a series of positions occupied in
-succession; and a group of co-existent positions united in thought with
-the successive ones—these are the constituents of the idea. And since,
-as we have seen, these are severally elaborated from experiences of
-_force_ as given in certain correlations, it follows that from a further
-synthesis of such experiences, the idea of Motion is also elaborated. A
-certain other element in the idea, which is in truth its fundamental
-element, (namely, the necessity which the moving body is under to go on
-changing its position), results immediately from the earliest
-experiences of force. Movements of different parts of the organism in
-relation to each other, are the first presented in consciousness. These,
-produced by the action of the muscles, necessitate reactions upon
-consciousness in the shape of sensations of muscular tension.
-Consequently, each stretching-out or drawing-in of a limb, is originally
-known as a series of muscular tensions, varying in intensity as the
-position of the limb changes. And this rudimentary consciousness of
-Motion, consisting of serial impressions of force, becomes inseparably
-united with the consciousness of Space and Time as fast as these are
-abstracted from further impressions of force. Or rather, out of this
-primitive conception of Motion, the adult conception of it is developed
-simultaneously with the development of the conceptions of Space and
-Time: all three being evolved from the more multiplied and varied
-impressions of muscular tension and objective resistance. Motion, as we
-know it, is thus traceable, in common with the other ultimate scientific
-ideas, to experiences of force.
-
-That this relative reality answers to some absolute reality, it is
-needful only for form’s sake to assert. What has been said above,
-respecting the Unknown Cause which produces in us the effects called
-Matter, Space, and Time, will apply, on simply changing the terms, to
-Motion.
-
- * * * * *
-
-§ 65. We come down then finally to Force, as the ultimate of ultimates.
-Though Space, Time, Matter, and Motion, are apparently all necessary
-data of intelligence, yet a psychological analysis (here indicated only
-in rude outline) shows us that these are either built up of, or
-abstracted from, experiences of Force. Matter and Motion, as we know
-them, are differently conditioned manifestations of Force. Space and
-Time, as we know them, are disclosed along with these different
-manifestations of Force as the conditions under which they are
-presented. Matter and Motion are concretes built up from the _contents_
-of various mental relations; while Space and Time are abstracts of the
-_forms_ of these various relations. Deeper down than these, however, are
-the primordial experiences of Force, which, as occurring in
-consciousness in different combinations, supply at once the materials
-whence the forms of relations are generalized, and the related objects
-built up. A single impression of force is manifestly receivable by a
-sentient being devoid of mental forms: grant but sensibility, with no
-established power of thought, and a force producing some nervous change,
-will still be presentable at the supposed seat of sensation. Though no
-single impression of force so received, could itself produce
-consciousness (which implies relations between different states), yet a
-multiplication of such impressions, differing in kind and degree, would
-give the materials for the establishment of relations, that is, of
-thought. And if such relations differed in their forms as well as in
-their contents, the impressions of such forms would be organized
-simultaneously with the impressions they contained. Thus all other modes
-of consciousness are derivable from experiences of Force; but
-experiences of Force are not derivable from anything else. Indeed, it
-needs but to remember that consciousness consists of changes, to see
-that the ultimate datum of consciousness must be that of which change is
-the manifestation; and that thus the force by which we ourselves produce
-changes, and which serves to symbolize the cause of changes in general,
-is the final disclosure of analysis.
-
-It is a truism to say that the nature of this undecomposable element of
-our knowledge is inscrutable. If, to use an algebraic illustration, we
-represent Matter, Motion, and Force, by the symbols _x_, _y_, and _z_;
-then, we may ascertain the values of _x_ and _y_ in terms of _z_; but
-the value of _z_ can never be found: _z_ is the unknown quantity which
-must for ever remain unknown; for the obvious reason that there is
-nothing in which its value can be expressed. It is within the possible
-reach of our intelligence to go on simplifying the equations of all
-phenomena, until the complex symbols which formulate them are reduced to
-certain functions of this ultimate symbol; but when we have done this,
-we have reached that limit which eternally divides science from
-nescience.
-
-That this undecomposable mode of consciousness into which all other
-modes may be decomposed, cannot be itself the Power manifested to us
-through phenomena, has been already proved (§ 18). We saw that to assume
-an identity of nature between the cause of changes as it absolutely
-exists, and that cause of change of which we are conscious in our own
-muscular efforts, betrays us into alternative impossibilities of
-thought. Force, as we know it, can be regarded only as a certain
-conditioned effect of the Unconditioned Cause—as the relative reality
-indicating to us an Absolute Reality by which it is immediately
-produced. And here, indeed, we see even more clearly than before, how
-inevitable is that transfigured realism to which sceptical criticism
-finally brings us round. Getting rid of all complications, and
-contemplating pure Force, we are irresistibly compelled by the
-relativity of our thought, to vaguely conceive some unknown force as the
-correlative of the known force. Conditioned effect and unconditioned
-cause, are here presented in their primordial relation as two sides of
-the same change; of which we are obliged to regard the conditioned and
-the unconditioned sides as equally real: the only difference being that
-the reality of the one is made relative by the imposition of the forms
-and limits of our consciousness, while the reality of the other, in the
-absence of those forms and limits, remains absolute.
-
-Thus much respecting the nature of our ultimate scientific ideas. Before
-proceeding to our general inquiry concerning the causes of Evolution, we
-have still to consider certain ultimate scientific truths.
-
------
-
-Footnote 11:
-
- For the psychological conclusions briefly set forth in this and the
- three sections following it, the justification will be found in the
- writer’s _Principles of Psychology_.
-
-
-
-
- CHAPTER VI.
- THE INDESTRUCTIBILITY OF MATTER.
-
-
-§ 66. Not because the truth is unfamiliar, is it needful here to say
-something concerning the indestructibility of Matter; but partly because
-the symmetry of our argument demands the enunciation of this truth, and
-partly because the evidence on which it is accepted requires
-examination. Could it be shown, or could it with any rationality be even
-supposed, that Matter, either in its aggregates or in its units, ever
-became non-existent, there would be an end to the inquiry on which we
-are now setting out. Evolution, considered as a re-arrangement of parts,
-could not be scientifically explained, if, during its course, any of the
-parts might arise out of nothing or might lapse into nothing. The
-question would no longer be one comprehending only the forces and
-motions by which the re-arrangement is effected; but would involve an
-incalculable element, and would hence be insoluble. Clearly, therefore,
-the indestructibility of Matter is an indispensable axiom.
-
-So far from being admitted as a self-evident truth, this would, in
-primitive times, have been rejected as a self-evident error. There was
-once universally current, a notion that things could vanish into
-absolute nothing, or arise out of absolute nothing. If we analyze early
-superstitions, or that faith in magic which was general in later times
-and even still survives among the uncultured, we find one of its
-postulates to be, that by some potent spell Matter can be called out of
-nonentity, and can be made non-existent. If men did not believe this in
-the strict sense of the word (which would imply that the process of
-creation or annihilation was clearly represented in consciousness), they
-still believed that they believed it; and how nearly, in their confused
-thoughts, the one was equivalent to the other, is shown by their
-conduct. Nor, indeed, have dark ages and inferior minds alone betrayed
-this belief. The current theology, in its teachings respecting the
-beginning and end of the world, is clearly pervaded by it; and it may be
-even questioned whether Shakespeare, in his poetical anticipation of a
-time when all things should disappear and “leave not a wrack behind,”
-was not under its influence. The gradual accumulation of
-experiences however, and still more the organization of experiences, has
-tended slowly to reverse this conviction; until now, the doctrine that
-Matter is indestructible has become a common-place. Whatever may be true
-of it absolutely, we have learnt that relatively to our consciousness,
-Matter never either comes into existence or ceases to exist. Cases which
-once gave an apparent support to the illusion that something could come
-out of nothing, a wider knowledge has one by one cancelled. The comet
-that is all at once discovered in the heavens and nightly waxes larger,
-is proved not to be a newly-created body, but a body that was until
-lately beyond the range of vision. The cloud which in the course of a
-few minutes forms in the sky, consists not of substance that has just
-begun to be, but of substance that previously existed in a more diffused
-and transparent form. And similarly with a crystal or precipitate in
-relation to the fluid depositing it. Conversely, the seeming
-annihilations of Matter turn out, on closer observation, to be only
-changes of state. It is found that the evaporated water, though it has
-become invisible, may be brought by condensation to its original shape.
-The discharged fowling-piece gives evidence that though the gunpowder
-has disappeared, there have appeared in place of it certain gases,
-which, in assuming a larger volume, have caused the explosion.
- Not, however, until the rise of quantitative chemistry, could the
-conclusion suggested by such experiences be reduced to a certainty.
-When, having ascertained not only the combinations into which various
-substances enter, but also the proportions in which they combine,
-chemists were enabled to account for the matter that had made its
-appearance or become invisible, the proof was rendered complete. When,
-in place of the candle that had slowly burnt away, it was shown that
-certain calculable quantities of carbonic acid and water had
-resulted—when it was demonstrated that the joint weight of the carbonic
-acid and water thus produced, was equal to the weight of the candle plus
-that of the oxygen uniting with its constituents during combustion; it
-was put beyond doubt that the carbon and hydrogen forming the candle,
-were still in existence, and had simply changed their state. And of the
-general conclusion thus exemplified, the exact analyses daily made, in
-which the same portion of matter is pursued through numerous
-transformations and finally separated, furnish never-ceasing
-confirmations.
-
-Such has become the effect of this specific evidence, joined to that
-general evidence which the continued existence of familiar objects
-unceasingly gives us; that the indestructibility of Matter is now
-recognized by many as a truth of which the negation is inconceivable.
-Habitual experiences being no longer met by any counter-experiences, as
-they once seemed to be; but these apparent counter-experiences
-furnishing new proof that Matter exists permanently, even where the
-senses fail to detect it; it has grown into an axiom of science, that
-whatever metamorphoses Matter undergoes, its quantity is fixed. The
-chemist, the physicist, and the physiologist, not only one and all take
-this for granted, but would severally profess themselves unable to
-realize any supposition to the contrary.
-
- * * * * *
-
-§ 67. This last fact naturally raises the question, whether we have any
-higher warrant for this fundamental belief, than the warrant of
-conscious induction. The indestructibility of Matter is proved
-experimentally to be an absolute uniformity within the range of our
-experience. But absolute uniformities of experience, generate absolute
-uniformities of thought. Does it not follow, then, that this ultimate
-truth must be a cognition involved in our mental organization? An
-affirmative answer we shall find unavoidable.
-
-What is termed the ultimate incompressibility of Matter, is an admitted
-law of thought. Though it is possible to imagine a piece of matter to be
-compressed without limit, yet however small the bulk to which we
-conceive it reduced, it is impossible to conceive it reduced into
-nothing. While we can represent to ourselves the parts of the matter as
-indefinitely approximated, and the space occupied as indefinitely
-decreased, we cannot represent to ourselves the quantity of matter as
-made less. To do this would imply an imagined disappearance of some of
-the constituent parts—would imply that some of the constituent parts
-were in thought compressed into nothing; which is no more possible than
-the compression of the whole into nothing. Whence it is an obvious
-corollary, that the total quantity of matter in the Universe, cannot
-really be conceived as diminished, any more than it can be conceived as
-increased. Our inability to conceive Matter becoming non-existent,
-is immediately consequent on the very nature of thought. Thought
-consists in the establishment of relations. There can be no relation
-established, and therefore no thought framed, when one of the related
-terms is absent from consciousness. Hence it is impossible to think of
-something becoming nothing, for the same reason that it is impossible to
-think of nothing becoming something—the reason, namely, that nothing
-cannot become an object of consciousness. The annihilation of Matter is
-unthinkable for the same reason that the creation of Matter is
-unthinkable; and its indestructibility thus becomes an _à priori_
-cognition of the highest order—not one that results from a long
-continued registry of experiences gradually organized into an
-irreversible mode of thought; but one that is given in the form of all
-experiences whatever.
-
-Doubtless it will be considered strange that a truth only in modern
-times accepted as unquestionable, and then only by men of science,
-should be classed as an _à priori_ truth; not only of equal certainty
-with those commonly so classed, but of even higher certainty. To set
-down as a proposition which cannot be thought, one which mankind once
-universally professed to think, and which the great majority profess to
-think even now, seems absurd. The explanation is, that in this, as in
-countless other cases, men have supposed themselves to think what they
-did not think. As was shown at the outset, the greater part of our
-conceptions are symbolic. Many of these symbolic conceptions, though
-rarely developed into real ones, admit of being so developed; and, being
-directly or indirectly proved to correspond with actualities, are valid.
-But along with these there pass current others which cannot be
-developed—cannot by any direct or indirect process be realized in
-thought; much less proved to correspond with actualities. Not being
-habitually tested, however, the legitimate and illegitimate symbolic
-conceptions are confounded together; and supposing themselves to have
-literally thought, that which they have thought only symbolically, men
-say they believe propositions of which the terms cannot even be put
-together in consciousness. Hence the ready acceptance given to sundry
-hypotheses respecting the origin of the Universe, which yet are
-absolutely unthinkable. And as before we found the commonly asserted
-doctrine that Matter was created out of nothing, to have been never
-really conceived at all, but to have been conceived only symbolically;
-so here we find the annihilation of Matter to have been conceived only
-symbolically, and the symbolic conception mistaken for a real one.
- Possibly it will be objected that the words _thought_, and
-_belief_, and _conception_, are here employed in new senses; and that it
-is a misuse of language to say that men did not really think that which
-has nevertheless so profoundly influenced their conduct. It must be
-confessed that there is an inconvenience in so restricting the meanings
-of these words. There is no remedy however. Definite conclusions can be
-reached, only by the use of well-defined terms. Questions touching the
-validity of any portion of our knowledge, cannot be profitably discussed
-unless the words _knowing_, and _thinking_, have specific
-interpretations. We must not include under them whatever confused
-processes of consciousness the popular speech applies them to; but only
-the distinct processes of consciousness. And if this obliges us to
-reject a large part of human thinking as not thinking at all, but merely
-pseudo-thinking, there is no help for it.
-
-Returning to the general question, we find the results to be:—that we
-have positive experience of the continued existence of Matter; that the
-form of our thought renders it impossible for us to have experience of
-Matter passing into non-existence, since such experience would involve
-cognition of a relation having one of its terms not representable in
-consciousness; that hence the indestructibility of Matter is in
-strictness an _à priori_ truth; that nevertheless, certain illusive
-experiences, suggesting the notion of its annihilation, have produced in
-undisciplined minds not only the supposition that Matter could be
-conceived to become non-existent, but the notion that it did so; but
-that careful observation, showing the supposed annihilations to have
-never taken place, has confirmed, _à posteriori_, the _à priori_
-cognition which Psychology shows to result from a uniformity of
-experience that can never be met by counter-experience.
-
- * * * * *
-
-§ 68. The fact, however, which it most concerns us here to observe, is,
-the nature of the perceptions by which the permanence of Matter is
-perpetually illustrated to us, and from which Science draws the
-inference that Matter is indestructible. These perceptions, under all
-their forms, amount simply to this—that the _force_ which a given
-quantity of matter exercises, remains always the same. This is the proof
-on which common sense and exact science alike rely. When, for
-example, somebody known to have existed a few years since is said to
-exist still, by one who yesterday saw him, his assertion amounts to
-this—that an object which in past time wrought on his consciousness a
-certain group of changes, still exists because a like group of changes
-has been again wrought on his consciousness: the continuance of the
-power thus to impress him, he holds to prove the continuance of the
-object. Should some auditor allege a mistake in identity, the witness is
-admitted to give conclusive proof when he says that he not only saw, but
-shook hands with this person, and remarked while grasping his hand, that
-absence of the index finger which was his known peculiarity: the
-implication being, that an object which through a special combination of
-forces, produces special tactual impressions, is concluded still to
-exist while it continues still to do this. Even more clearly do we see
-that force is our ultimate measure of Matter, in those cases where the
-shape of the matter has been changed. A piece of gold given to an
-artizan to be worked into an ornament, and which when brought back
-appears to be less, is placed in the scales; and if it balances a much
-smaller weight than it did in its rough state, we infer that much has
-been lost either in manipulation or by direct abstraction. Here the
-obvious postulate is, that the quantity of Matter is finally
-determinable by the quantity of gravitative force it manifests.
- And this is the kind of evidence on which Science bases its
-experimentally-established induction that Matter is indestructible.
-Whenever a piece of substance lately visible and tangible, has been
-reduced to an invisible, intangible shape, but is proved by the weight
-of the gas into which it has been transformed to be still existing; the
-assumption is, that though otherwise insensible to us, the amount of
-matter is the same, if it still tends towards the Earth with the same
-force. Similarly, every case in which the weight of an element present
-in combination, is inferred from the known weight of another element
-which it neutralizes, is a case in which the quantity of matter is
-expressed in terms of the quantity of chemical force it exerts; and in
-which this specific chemical force is assumed to be the necessary
-correlative of a specific gravitative force.
-
-Thus then by the indestructibility of Matter, we really mean the
-indestructibility of the _force_ with which Matter affects us. As we
-become conscious of Matter only through that resistance which it opposes
-to our muscular energy, so do we become conscious of the permanence of
-Matter only through the permanence of this resistance; as either
-immediately or mediately proved to us. And this truth is made manifest
-not only by analysis of the _à posteriori_ cognition, but equally so by
-analysis of the _à priori_ one. For that which we cannot conceive to be
-diminished by the continued compression of Matter, is not its occupancy
-of space, but its ability to resist.
-
-
-
-
- CHAPTER VII.
- THE CONTINUITY OF MOTION.
-
-
-§ 69. Another general truth of the same order with the foregoing, must
-here be specified—one which, though not so generally recognized, has yet
-long been familiar among men of science. The continuity of Motion, like
-the indestructibility of Matter, is clearly an axiom underlying the very
-possibility of a rational theory of Evolution. That kind of change in
-the arrangement of parts, which we have found to constitute Evolution,
-could not be deductively explained were it possible for Motion either to
-appear or disappear. If those motions through which the parts pass into
-a new arrangement, might either proceed from nothing or lapse into
-nothing, there would be an end to scientific interpretation of them.
-Each constituent change might as well as not be supposed to begin and
-end of itself.
-
-The axiomatic character of the truth that Motion is continuous, is
-recognized only after the discipline of exact science has given
-precision to the conceptions. Aboriginal men, our uneducated population,
-and even most of the so-called educated, think in an extremely
-indefinite manner. From careless observations, they pass by careless
-reasoning, to conclusions of which they do not contemplate the
-implications—conclusions which they never develope for the purpose of
-seeing whether they are consistent. Accepting without criticism the
-dicta of unaided perception, to the effect that surrounding bodies when
-put in motion soon return to rest, the great majority tacitly assume
-that the motion is actually lost. They do not consider whether the
-phenomenon can be otherwise interpreted; or whether the interpretation
-they put on it can be mentally realized. They are content with a
-colligation of mere appearances. But the establishment of certain
-facts having quite an opposite implication, led to inquiries which have
-gradually proved such appearances to be illusive. The discovery that the
-planets revolve round the Sun with undiminishing speed, raised the
-suspicion that a moving body, when not interfered with, will go on for
-ever without change of velocity; and suggested the question whether
-bodies which lose their motion, do not at the same time communicate as
-much motion to other bodies. It was a familiar fact that a stone would
-glide further over a smooth surface, such as ice, presenting no small
-objects to which it could part with its motion by collision, than over a
-surface strewn with such small objects; and that a projectile would
-travel a far greater distance through a rare medium like air, than
-through a dense medium like water. Thus the primitive notion that moving
-bodies had an inherent tendency gradually to lose their motion and
-finally stop—a notion of which the Greeks did not get rid, but which
-lasted till the time of Galileo—began to give way. It was further shaken
-by such experiments as those of Hooke, which proved that the spinning of
-a top continued long in proportion as it was prevented from
-communicating movement to surrounding matter—experiments which, when
-repeated with the aid of modern appliances, have shown that _in vacuo_
-such rotation, retarded only by the friction of the axis, will continue
-for nearly an hour. Thus have been gradually dispersed, the obstacles to
-the reception of the first law of motion;—the law, namely, that when not
-influenced by external forces, a moving body will go on in a straight
-line with a uniform velocity. And this law is in our day being merged in
-the more general one, that Motion, like Matter, is indestructible; and
-that whatever is lost by any one portion of matter is transferred to
-other portions—a conclusion which, however much at variance it seems
-with cases of sudden arrest from collision with an immovable object, is
-yet reconciled with such cases by the discovery that the motion
-apparently lost continues under new forms, though forms not directly
-perceptible.
-
- * * * * *
-
-§ 70. And here it may be remarked of Motion, as it was before of Matter,
-that its indestructibility is not only to be inductively inferred, but
-that it is a necessity of thought: its destructibility never having been
-truly conceived at all, but having always been, as it is now, a mere
-verbal proposition that cannot be realized in consciousness—a
-pseud-idea. Whether that absolute reality which produces in us the
-consciousness we call Motion, be or be not an eternal mode of the
-Unknowable, it is impossible for us to say; but that the relative
-reality which we call Motion never can come into existence, or cease to
-exist, is a truth involved in the very nature of our consciousness. To
-think of Motion as either being created or annihilated—to think of
-nothing becoming something, or something becoming nothing—is to
-establish in consciousness a relation between two terms of which one is
-absent from consciousness, which is impossible. The very nature of
-intelligence, negatives the supposition that Motion can be conceived
-(much less known) to either commence or cease.
-
- * * * * *
-
-§ 71. It remains to be pointed out that the continuity of Motion, as
-well as the indestructibility of Matter, is really known to us in terms
-of _force_. That a certain manifestation of force remains for ever
-undiminished, is the ultimate content of the thought; whether reached _à
-posteriori_ or _à priori_.
-
-From terrestrial physics let us take the case of sound propagated to a
-great distance. Whenever we are directly conscious of the causation of
-sound (namely, when we produce it ourselves), its invariable antecedent
-is force. The immediate sequence of this force we know to be
-motion—first, of our own organs, and then of the body which we set
-vibrating. The vibrations so generated we can discern both through the
-fingers and through the ears; and that the sensations received by the
-ears are the equivalents of mechanical force communicated to the air,
-and by it impressed on surrounding objects, we have clear proof when
-objects are fractured: as windows by the report of a cannon; or a glass
-vessel by a powerful voice. On what, then, rests the reasoning when, as
-occasionally happens under favourable circumstances, men on board a
-vessel a hundred miles from shore, hear the ringing of church-bells on
-placing their ears in the focus of the main sail; and when it is
-inferred that atmospheric undulations have traversed this immense
-distance? Manifestly, the assertion that the motion of the clapper,
-transformed into the vibrations of the bell, and communicated to the
-surrounding air, has propagated itself thus far on all sides,
-diminishing in intensity as the mass of air moved became greater, is
-based solely upon a certain change produced in consciousness through the
-ears. The listeners are not conscious of motion; they are conscious of
-an impression produced on them—an impression which implies a force as
-its necessary correlative. With force they begin, and with force they
-end: the intermediate motion being simply inferred. Again, where,
-as in celestial physics, the continuity of motion is quantitatively
-proved, the proof is not direct but inferential; and forces furnish the
-data for the inference. A particular planet can be identified only by
-its constant power to affect our visual organs in a special way—to
-impress upon the retina a group of forces standing in a particular
-correlation. Further, such planet has not been _seen_ to move by the
-astronomical observer; but its motion is _inferred_ from a comparison of
-its present position with the position it before occupied. If rigorously
-examined, this comparison proves to be a comparison between the
-different impressions produced on him by the different adjustments of
-the observing instruments. Going a step further back, it turns out that
-this difference is meaningless until shown to correspond with a certain
-calculated position which the planet must occupy, supposing that no
-motion has been lost. And if, finally, we examine the implied
-calculation, we find that it makes allowances for those accelerations
-and retardations which ellipticity of the orbit involves, as well as
-those variations of velocity caused by adjacent planets—we find, that
-is, that the motion is concluded to be indestructible not from the
-uniform velocity of the planet, but from the constant quantity of motion
-exhibited when allowance is made for the motion communicated to, or
-received from, other celestial bodies. And when we ask how this
-communicated motion is estimated, we discover that the estimate is based
-upon certain laws of force; which laws, one and all, embody the
-postulate that force cannot be destroyed. Without the axiom that action
-and re-action are equal and opposite, astronomy could not make its exact
-predictions; and we should lack the rigorous inductive proof they
-furnish that motion can never be lost, but can only be transferred.
-
-Similarly with the _à priori_ conclusion that Motion is continuous. That
-which defies suppression in thought, is really the force which the
-motion indicates. The unceasing change of position, considered by
-itself, may be mentally abolished without difficulty. We can readily
-imagine retardation and stoppage to result from the action of external
-bodies. But to imagine this, is not possible without an abstraction of
-the force implied by the motion. We are obliged to conceive this force
-as impressed in the shape of re-action on the bodies that cause the
-arrest. And the motion that is communicated to them, we are compelled to
-regard, not as directly communicated, but as a product of the
-communicated force. We can mentally diminish the velocity or
-space-element of motion, by diffusing the momentum or force-element over
-a larger mass of matter; but the quantity of this force-element, which
-we regard as the cause of the motion, is unchangeable in thought.
-
-
-
-
- CHAPTER VIII.
- THE PERSISTENCE OF FORCE.[12]
-
-
-§ 72. Before taking a first step in the rational interpretation of
-Evolution, it is needful to recognize, not only the facts that Matter is
-indestructible and Motion continuous, but also the fact that Force
-persists. An attempt to assign the _causes_ of Evolution, would
-manifestly be absurd, if that agency to which the metamorphosis in
-general and in detail is due, could either come into existence or cease
-to exist. The succession of phenomena would in such case be altogether
-arbitrary; and deductive science impossible.
-
-Here, indeed, the necessity is even more imperative than in the two
-preceding cases. For the validity of the proofs given that Matter is
-indestructible and Motion continuous, really depends upon the validity
-of the proof that Force is persistent. An analysis of the reasoning
-demonstrated that in both cases, the _à posteriori_ conclusion involves
-the assumption that unchanged quantities of Matter and Motion are proved
-by unchanged manifestations of Force; and in the _à priori_ cognition we
-found this to be the essential constituent. Hence, that the quantity of
-Force remains always the same, is the fundamental cognition in the
-absence of which these derivative cognitions must disappear.
-
- * * * * *
-
-§ 73. But now on what grounds do we assert the persistence of Force?
-Inductively we can allege no evidence except such as is presented to us
-throughout the world of sensible phenomena. No force however, save that
-of which we are conscious during our own muscular efforts, is
-immediately known to us. All other force is mediately known through the
-changes we attribute to it. Since, then, we cannot infer the persistence
-of Force from our own sensation of it, which does not persist; we must
-infer it, if it is inferred at all, from the continuity of Motion, and
-the undiminished ability of Matter to produce certain effects. But to
-reason thus is manifestly to reason in a circle. It is absurd to allege
-the indestructibility of Matter, because we find experimentally that
-under whatever changes of form a given mass of matter exhibits the same
-gravitation, and then afterwards to argue that gravitation is constant
-because a given mass of matter exhibits always the same quantity of it.
-We cannot prove the continuity of Motion by assuming that Force is
-persistent, and then prove the persistence of Force by assuming that
-Motion is continuous.
-
-The data of both objective and subjective science being involved in this
-question touching the nature of our cognition that Force is persistent,
-it will be desirable here to examine it more closely. At the risk of
-trying the reader’s patience, we must reconsider the reasoning through
-which the indestructibility of Matter and the continuity of Motion are
-established; that we may see how impossible it is to arrive by parallel
-reasoning at the persistence of Force. In all three cases the
-question is one of quantity:—does the Matter, or Motion, or Force, ever
-diminish in quantity? Quantitative science implies measurement; and
-measurement implies a unit of measure. The units of measure from which
-all others of any exactness are derived, are units of linear extension.
-From these, through the medium of the equal-armed lever or scales, we
-derive our equal units of weight, or gravitative force. And it is by
-means of these equal units of extension and equal units of weight, that
-we make those quantitative comparisons by which the truths of exact
-science are reached. Throughout the investigations leading the chemist
-to the conclusion that of the carbon which has disappeared during
-combustion, no portion has been lost, and that in any compound
-afterwards formed by the resulting carbonic acid the whole of the
-original carbon is present, what is his repeatedly assigned proof? That
-afforded by the scales. In what terms is the verdict of the scales
-given? In grains—in units of weight—in units of gravitative force. And
-what is the total content of the verdict? That as many units of
-gravitative force as the carbon exhibited at first, it exhibits still.
-The quantity of matter is asserted to be the same, if the number of
-units of force it counter-balances is the same. The validity of the
-inference, then, depends entirely upon _the constancy of the units of
-force_. If the force with which the portion of metal called a
-grain-weight, tends towards the Earth, has varied, the inference that
-Matter is indestructible is vicious. Everything turns on the truth of
-the assumption that the gravitation of the weights is persistent; and of
-this no proof is assigned, or can be assigned. In the reasonings
-of the astronomer there is a like implication; from which we may draw
-the like conclusion. No problem in celestial physics can be solved
-without the assumption of some unit of force. This unit need not be,
-like a pound or a ton, one of which we can take direct cognizance. It is
-requisite only that the mutual attraction which some two of the bodies
-concerned exercise at a given distance, should be taken as one; so that
-the other attractions with which the problem deals, may be expressed in
-terms of this one. Such unit being assumed, the momenta which the
-respective masses will generate in each other in a given time, are
-calculated; and compounding these with the momenta they already have,
-their places at the end of that time are predicted. The prediction is
-verified by observation. From this, either of two inferences may be
-drawn. Assuming the masses to be fixed, the motion may be proved to be
-undiminished; or assuming the motion to be undiminished, the masses may
-be proved to be fixed. But the validity of one or other inference,
-depends wholly on the truth of the assumption that the unit of force is
-unchanged. Let it be supposed that the gravitation of the two bodies
-towards each other at the given distance, has varied, and the
-conclusions drawn are no longer true. Nor is it only in their
-concrete data that the reasonings of terrestrial and celestial physics
-assume the persistence of Force. They equally assume it in the abstract
-principle with which they set out; and which they repeat in
-justification of every step. The equality of action and reaction is
-taken for granted from beginning to end of either argument; and to
-assert that action and reaction are equal and opposite, is to assert
-that Force is persistent. The allegation really amounts to this, that
-there cannot be an isolated force beginning and ending in nothing; but
-that any force manifested, implies an equal antecedent force from which
-it is derived, and against which it is a reaction. Further, that the
-force so originating cannot disappear without result; but must expend
-itself in some other manifestation of force, which, in being produced,
-becomes its reaction; and so on continually. Clearly then the
-persistence of Force is an ultimate truth of which no inductive proof is
-possible.
-
-We might indeed be certain, even in the absence of any such analysis as
-the foregoing, that there must exist some principle which, as being the
-basis of science, cannot be established by science. All reasoned-out
-conclusions whatever, must rest on some postulate. As before shown (§
-23), we cannot go on merging derivative truths in those wider and wider
-truths from which they are derived, without reaching at last a widest
-truth which can be merged in no other, or derived from no other. And
-whoever contemplates the relation in which it stands to the truths of
-science in general, will see that this truth transcending demonstration
-is the persistence of Force.
-
- * * * * *
-
-§ 74. But now what is the force of which we predicate persistence? It is
-not the force we are immediately conscious of in our own muscular
-efforts; for this does not persist. As soon as an outstretched limb is
-relaxed, the sense of tension disappears. True, we assert that in the
-stone thrown or in the weight lifted, is exhibited the effect of this
-muscular tension; and that the force which has ceased to be present in
-our consciousness, exists elsewhere. But it does not exist elsewhere
-under any form cognizable by us. It was proved (§ 18), that though, on
-raising an object from the ground, we are obliged to think of its
-downward pull as equal and opposite to our upward pull; and though it is
-impossible to represent these pulls as equal without representing them
-as like in kind; yet, since their likeness in kind would imply in the
-object a sensation of muscular tension, which cannot be ascribed to it,
-we are compelled to admit that force as it exists out of our
-consciousness, is not force as we know it. Hence the force of which we
-assert persistence is that Absolute Force of which we are indefinitely
-conscious as the necessary correlate of the force we know. Thus,
-by the persistence of Force, we really mean the persistence of some
-Power which transcends our knowledge and conception. The manifestations,
-as occurring either in ourselves or outside of us, do not persist; but
-that which persists is the Unknown Cause of these manifestations. In
-other words, asserting the persistence of Force, is but another mode of
-asserting an Unconditioned Reality, without beginning or end.
-
-Thus, quite unexpectedly, we come down once more to that ultimate truth
-in which, as we saw, Religion and Science coalesce. On examining the
-data underlying a rational theory of Evolution, we find them all at last
-resolvable into that datum without which consciousness was shown to be
-impossible—the continued existence of an Unknowable as the necessary
-correlative of the Knowable. Once commenced, the analysis of the truths
-taken for granted in scientific inquiries, inevitably brings us down to
-this deepest truth, in which Common Sense and Philosophy are reconciled.
-
-The arguments and conclusion contained in this and the foregoing three
-chapters, supply, indeed, the complement to the arguments and conclusion
-set forth in the preceding part of this work. It was there first shown,
-by an examination of our ultimate religious ideas, that knowledge of
-Absolute Being is impossible; and the impossibility of knowing Absolute
-Being, was also shown by an examination of our ultimate scientific
-ideas. In a succeeding chapter a subjective analysis proved, that while,
-by the very conditions of thought, we are prevented from knowing
-anything beyond relative being; yet that by these very same conditions
-of thought, an indefinite consciousness of Absolute Being is
-necessitated. And here, by objective analysis, we similarly find that
-the axiomatic truths of physical science, unavoidably postulate Absolute
-Being as their common basis.
-
-Thus there is even a more profound agreement between Religion and
-Science than was before shown. Not only are they wholly at one on the
-negative proposition that the Non-relative cannot be known; but they are
-wholly at one on the positive proposition that the Non-relative is an
-actual existence. Both are obliged by the demonstrated untenability of
-their supposed cognitions, to confess that the Ultimate Reality is
-incognizable; and yet both are obliged to assert the existence of an
-Ultimate Reality. Without this, Religion has no subject-matter; and
-without this, Science, subjective and objective, lacks its indispensable
-datum. We cannot construct a theory of internal phenomena without
-postulating Absolute Being; and unless we postulate Absolute Being, or
-being which persists, we cannot construct a theory of external
-phenomena.
-
- * * * * *
-
-§ 75. A few words must be added respecting the nature of this
-fundamental consciousness. Already it has been looked at from several
-points of view; and here it seems needful finally to sum up the results.
-
-In Chapter IV. we saw that the Unknown Power of which neither beginning
-nor end can be conceived, is present to us as that unshaped material of
-consciousness which is shaped afresh in every thought. Our inability to
-conceive its limitation, is thus simply the obverse of our inability to
-put an end to the thinking subject while still continuing to think.
- In the two foregoing chapters, we contemplated this fundamental
-truth under another aspect. The indestructibility of Matter and the
-continuity of Motion, we saw to be really corollaries from the
-impossibility of establishing in thought a relation between something
-and nothing. What we call the establishment of a relation in thought, is
-the passage of the substance of consciousness, from one form into
-another. To think of something becoming nothing, would involve that this
-substance of consciousness having just existed under a given form,
-should next assume no form; or should cease to be consciousness. And
-thus our inability to conceive Matter and Motion destroyed, is our
-inability to suppress consciousness itself. What, in these two
-foregoing chapters, was proved true of Matter and Motion, is, _à
-fortiori_, true of the Force out of which our conceptions of Matter and
-Motion are built. Indeed, as we saw, that which is indestructible in
-matter and motion, is the force they present. And, as we here see, the
-truth that Force is indestructible, is the obverse of the truth that the
-Unknown Cause of the changes going on in consciousness is
-indestructible. So that the persistence of consciousness, constitutes at
-once our immediate experience of the persistence of Force, and imposes
-on us the necessity we are under of asserting its persistence.
-
- * * * * *
-
-§ 76. Thus, in all ways there is forced on us the fact, that here is an
-ultimate truth given in our mental constitution. It is not only a datum
-of science, but it is a datum which even the assertion of our nescience
-involves. Whoever alleges that the inability to conceive a beginning or
-end of the Universe, is a _negative_ result of our mental structure,
-cannot deny that our consciousness of the Universe as persistent, is a
-_positive_ result of our mental structure. And this persistence of the
-Universe, is the persistence of that Unknown Cause, Power, or Force,
-which is manifested to us through all phenomena.
-
-Such then is the foundation of any possible system of positive
-knowledge. Deeper than demonstration—deeper even than definite
-cognition—deep as the very nature of mind, is the postulate at which we
-have arrived. Its authority transcends all other whatever; for not only
-is it given in the constitution of our own consciousness, but it is
-impossible to imagine a consciousness so constituted as not to give it.
-Thought, involving simply the establishment of relations, may be readily
-conceived to go on while yet these relations have not been organized
-into the abstracts we call Space and Time; and so there is a conceivable
-kind of consciousness which does not contain the truths, commonly called
-_à priori_, involved in the organization of these forms of relations.
-But thought cannot be conceived to go on without some element between
-which its relations may be established; and so there is no conceivable
-kind of consciousness which does not imply continued existence as its
-datum. Consciousness without this or that particular _form_ is possible;
-but consciousness without _contents_ is impossible.
-
-The sole truth which transcends experience by underlying it, is thus the
-persistence of Force. This being the basis of experience, must be the
-basis of any scientific organization of experiences. To this an ultimate
-analysis brings us down; and on this a rational synthesis must build up.
-
------
-
-Footnote 12:
-
- Some two years ago, I expressed to my friend Professor Huxley, my
- dissatisfaction with the current expression—“Conservation of Force;”
- assigning as reasons, first, that the word “conservation” implies a
- conserver and an act of conserving; and, second, that it does not
- imply the existence of the force before that particular manifestation
- of it with which we commence. In place of “conservation,” Professor
- Huxley suggested _persistence_. This entirely meets the first of the
- two objections; and though the second may be urged against it, no
- other word less faulty in this respect can be found. In the absence of
- a word specially coined for the purpose, it seems the best; and as
- such I adopt it.
-
-
-
-
- CHAPTER IX.
- THE CORRELATION AND EQUIVALENCE OF FORCES.
-
-
-§ 77. When, to the unaided senses, Science began to add supplementary
-senses in the shape of measuring instruments, men began to perceive
-various phenomena which eyes and fingers could not distinguish. Of known
-forms of force, minuter manifestations became appreciable; and forms of
-force before unknown were rendered cognizable and measurable. Where
-forces had apparently ended in nothing, and had been carelessly supposed
-to have actually done so, instrumental observation proved that effects
-had in every instance been produced: the forces reappearing in new
-shapes. Hence there has at length arisen the inquiry whether the force
-displayed in each surrounding change, does not in the act of expenditure
-undergo metamorphosis into an equivalent amount of some other force or
-forces. And to this inquiry experiment is giving an affirmative answer,
-which becomes day by day more decisive. Grove, Helmholtz, and Meyer, are
-more than any others to be credited with the clear enunciation of this
-doctrine. Let us glance at the evidence on which it rests.
-
-Motion, wherever we can directly trace its genesis, we find to pre-exist
-as some other mode of force. Our own voluntary acts have always certain
-sensations of muscular tension as their antecedents. When, as in letting
-fall a relaxed limb, we are conscious of a bodily movement requiring no
-effort, the explanation is that the effort was exerted in raising the
-limb to the position whence it fell. In this case, as in the case of an
-inanimate body descending to the Earth, the force accumulated by the
-downward motion is just equal to the force previously expended in the
-act of elevation. Conversely, Motion that is arrested produces,
-under different circumstances, heat, electricity, magnetism, light. From
-the warming of the hands by rubbing them together, up to the ignition of
-a railway-brake by intense friction—from the lighting of detonating
-powder by percussion, up to the setting on fire a block of wood by a few
-blows from a steam-hammer; we have abundant instances in which heat
-arises as Motion ceases. It is uniformly found, that the heat generated
-is great in proportion as the Motion lost is great; and that to diminish
-the arrest of motion, by diminishing the friction, is to diminish the
-quantity of heat evolved. The production of electricity by Motion is
-illustrated equally in the boy’s experiment with rubbed sealing-wax, in
-the common electrical machine, and in the apparatus for exciting
-electricity by the escape of steam. Wherever there is friction between
-heterogeneous bodies, electrical disturbance is one of the consequences.
-Magnetism may result from Motion either immediately, as through
-percussion on iron, or mediately as through electric currents previously
-generated by Motion. And similarly, Motion may create light; either
-directly, as in the minute incandescent fragments struck off by violent
-collisions, or indirectly, as through the electric spark. “Lastly,
-Motion may be again reproduced by the forces which have emanated from
-Motion; thus, the divergence of the electrometer, the revolution of the
-electrical wheel, the deflection of the magnetic needle, are, when
-resulting from frictional electricity, palpable movements reproduced by
-the intermediate modes of force, which have themselves been originated
-by motion.”
-
-That mode of force which we distinguish as Heat, is now generally
-regarded by physicists as molecular motion—not motion as displayed in
-the changed relations of sensible masses to each other, but as occurring
-among the units of which such sensible masses consist. If we cease to
-think of Heat as that particular sensation given to us by bodies in
-certain conditions, and consider the phenomena otherwise presented by
-these bodies, we find that motion, either in them or in surrounding
-bodies, or in both, is all that we have evidence of. With one or two
-exceptions which are obstacles to every theory of Heat, heated bodies
-expand; and expansion can be interpreted only as a movement of the units
-of a mass in relation to each other. That so-called radiation through
-which anything of higher temperature than things around it, communicates
-Heat to them, is clearly a species of motion. Moreover, the evidence
-afforded by the thermometer that Heat thus diffuses itself, is simply a
-movement caused in the mercurial column. And that the molecular motion
-which we call Heat, may be transformed into visible motion, familiar
-proof is given by the steam-engine; in which “the piston and all its
-concomitant masses of matter are moved by the molecular dilatation of
-the vapour of water.” Where Heat is absorbed without apparent
-result, modern inquiries show that decided though unobtrusive changes
-are produced: as on glass, the molecular state of which is so far
-changed by heat, that a polarized ray of light passing through it
-becomes visible, which it does not do when the glass is cold; or as on
-polished metallic surfaces, which are so far changed in structure by
-thermal radiations from objects very close to them, as to retain
-permanent impressions of such objects. The transformation of Heat into
-electricity, occurs when dissimilar metals touching each other are
-heated at the point of contact: electric currents being so induced.
-Solid, incombustible matter introduced into heated gas, as lime into the
-oxyhydrogen flame, becomes incandescent; and so exhibits the conversion
-of Heat into light. The production of magnetism by Heat, if it cannot be
-proved to take place directly, may be proved to take place indirectly
-through the medium of electricity. And through the same medium may be
-established the correlation of Heat and chemical affinity—a correlation
-which is indeed implied by the marked influence that Heat exercises on
-chemical composition and decomposition.
-
-The transformations of Electricity into other modes of force, are still
-more clearly demonstrable. Produced by the motion of heterogeneous
-bodies in contact, Electricity, through attractions and repulsions, will
-immediately reproduce motion in neighbouring bodies. Now a current of
-Electricity generates magnetism in a bar of soft iron; and now the
-rotation of a permanent magnet generates currents of Electricity. Here
-we have a battery in which from the play of chemical affinities an
-electric current results; and there, in the adjacent cell, we have an
-electric current effecting chemical decomposition. In the conducting
-wire we witness the transformation of Electricity into heat; while in
-electric sparks and in the voltaic arc we see light produced. Atomic
-arrangement, too, is changed by Electricity: as instance the transfer of
-matter from pole to pole of a battery; the fractures caused by the
-disruptive discharge; the formation of crystals under the influence of
-electric currents. And whether, conversely, Electricity be or be not
-directly generated by re-arrangement of the atoms of matter, it is at
-any rate indirectly so generated through the intermediation of
-magnetism.
-
-How from Magnetism the other physical forces result, must be next
-briefly noted—briefly, because in each successive case the illustrations
-become in great part the obverse forms of those before given. That
-Magnetism produces motion is the ordinary evidence we have of its
-existence. In the magneto-electric machine we see a rotating magnet
-evolving electricity. And the electricity so evolved may immediately
-after exhibit itself as heat, light, or chemical affinity. Faraday’s
-discovery of the effect of Magnetism on polarized light, as well as the
-discovery that change of magnetic state is accompanied by heat, point to
-further like connexions. Lastly, various experiments show that the
-magnetization of a body alters its internal structure; and that
-conversely, the alteration of its internal structure, as by mechanical
-strain, alters its magnetic condition.
-
-Improbable as it seemed, it is now proved that from Light also may
-proceed the like variety of agencies. The solar rays change the atomic
-arrangements of particular crystals. Certain mixed gases, which do not
-otherwise combine, combine in the sunshine. In some compounds Light
-produces decomposition. Since the inquiries of photographers have drawn
-attention to the subject, it has been shown that “a vast number of
-substances, both elementary and compound, are notably affected by this
-agent, even those apparently the most unalterable in character, such as
-metals.” And when a daguerreotype plate is connected with a proper
-apparatus “we get chemical action on the plate, electricity circulating
-through the wires, magnetism in the coil, heat in the helix, and motion
-in the needles.”
-
-The genesis of all other modes of force from Chemical Action, scarcely
-needs pointing out. The ordinary accompaniment of chemical combination
-is heat; and when the affinities are intense, light also is, under fit
-conditions, produced. Chemical changes involving alteration of bulk,
-cause motion, both in the combining elements and in adjacent masses of
-matter: witness the propulsion of a bullet by the explosion of
-gunpowder. In the galvanic battery we see electricity resulting from
-chemical composition and decomposition. While through the medium of this
-electricity, Chemical Action produces magnetism.
-
-These facts, the larger part of which are culled from Mr. Grove’s work
-on “The Correlation of Physical Forces,” show us that each force is
-transformable, directly or indirectly, into the others. In every change
-Force undergoes metamorphosis; and from the new form or forms it
-assumes, may subsequently result either the previous one or any of the
-rest, in endless variety of order and combination. It is further
-becoming manifest that the physical forces stand not simply in
-qualitative correlations with each other, but also in quantitative
-correlations. Besides proving that one mode of force may be transformed
-into another mode, experiments illustrate the truth that from a definite
-amount of one, definite amounts of others always arise. Ordinarily it is
-indeed difficult to show this; since it mostly happens that the
-transformation of any force is not into some one of the rest but into
-several of them: the proportions being determined by the ever-varying
-conditions. But in certain cases, positive results have been reached.
-Mr. Joule has ascertained that the fall of 772 lbs. through one foot,
-will raise the temperature of a pound of water one degree of Fahrenheit.
-The investigations of Dulong, Petit and Neumann, have proved a relation
-in amount between the affinities of combining bodies and the heat
-evolved during their combination. Between chemical action and voltaic
-electricity, a quantitative connexion has also been established:
-Faraday’s experiments implying that a specific measure of electricity is
-disengaged by a given measure of chemical action. The well-determined
-relations between the quantities of heat generated and water turned into
-steam, or still better the known expansion produced in steam by each
-additional degree of heat, may be cited in further evidence. Whence it
-is no longer doubted that among the several forms which force assumes,
-the quantitative relations are fixed. The conclusion tacitly agreed on
-by physicists, is, not only that the physical forces undergo
-metamorphoses, but that a certain amount of each is the constant
-equivalent of certain amounts of the others.
-
- * * * * *
-
-§ 78. Throughout Evolution under all its phases, this truth of course
-invariably holds. Every successive change or group of changes forming
-part of it, is of necessity limited by the conditions thus implied. The
-forces which any step in Evolution exhibits, must be affiliable on the
-like or unlike forces previously existing; while from the forces so
-generated must thereafter be derived others more or less transformed.
-And besides recognizing the forces at any time existing, as necessarily
-linked with those preceding and succeeding them, we must also recognize
-the amounts of these forces successively manifested as determinate,—as
-necessarily producing such and such quantities of results, and as
-necessarily limited to those quantities.
-
-Involved as are the phenomena of Evolution, it is not to be expected
-that a _definite_ quantitative relation can in each case, or indeed in
-any case, be shown between the forces expended in successive phases. We
-have not adequate data for this; and probably shall never have them. The
-antecedents of the simpler forms of Evolution, belong to a remote past
-respecting which we can have nothing but inferential knowledge; while
-the antecedents of the only kind of Evolution which is traceable from
-beginning to end (namely, that of individual organisms) are too complex
-to be dealt with by exact methods. Hence we cannot hope to establish
-_equivalence_ among the successive manifestations of force which each
-order of Evolution affords. The most we can hope is to establish a
-qualitative correlation that is indefinitely quantitative—quantitative
-in so far as involving something like a due proportion between causes
-and effects. If this can be done, however, some progress will be made
-towards the solution of our problem. Though it may be beyond our power
-to show a measurable relation between the force or group of forces which
-any phase of Evolution displays, and the force or group of forces
-immediately succeeding it; yet if we can show that there always are
-antecedent forces, and that the effects they produce always become the
-antecedents of further ones—if while unable to calculate how much of
-each change will be produced, we can prove that a change of that kind
-was necessitated—if we can discern even the vaguest correspondence
-between the amount of such change and the amount of the pre-existing
-force; we shall advance a step towards interpreting the transformation
-of the simple into the complex.
-
-With the view of attempting this, let us now reconsider the different
-types of Evolution awhile since delineated: taking them in the same
-order as before.
-
- * * * * *
-
-§ 79. On contemplating our Solar System the first fact which strikes us,
-is, that all its members are in motion; and that their motion is of a
-two-fold, or rather of a three-fold, kind. Each planet and satellite has
-a movement of rotation and a movement of translation; besides the
-movement through space which all have in common with their rotating
-primary. Whence this unceasing change of place?
-
-The hypothesis of Evolution supplies us with an answer. Impossible as it
-is to assign a reason for the pre-existence of matter in the diffused
-form supposed; yet assuming its pre-existence in that form, we have in
-the gravitation of its parts a cause of motion adequate to the results.
-So far too as the evidence carries us, we can perceive some quantitative
-relation between the motions produced, and the gravitative forces
-expended in producing them. The planets formed from that matter which
-has travelled the shortest distance towards the common centre of
-gravity, have the smallest velocities: the uniform law being that in
-advancing from the outermost to the innermost planets, the rate of
-orbital motion progressively increases. It may indeed be remarked that
-this is explicable on the teleological hypothesis; since it is a
-condition to equilibrium. But without dwelling on the fact that this is
-beside the question, it will suffice to point out that the like cannot
-be said of the planetary rotations. No such final cause can be assigned
-for the rapid axial movement of Jupiter and Saturn, or the slow axial
-movement of Mercury. But if in pursuance of the doctrine of correlation
-we look for the antecedents of these gyrations which all planets
-exhibit, the theory of Evolution furnishes us with equivalent ones; and
-ones which bear manifest quantitative relations to the motions
-displayed. For the planets that turn on their axes with extreme
-rapidity, are those having great masses and large orbits—those, that is,
-of which the once diffused elements moved to their centres of gravity
-through immense spaces, and so acquired high velocities. While,
-conversely, there has resulted the smallest axial movement where the
-orbit and the mass are both the smallest.
-
-“But what,” it may be asked, “has in such case become of all that motion
-which brought about the aggregation of this diffused matter into solid
-bodies?” The rotation of each body can be but a residuary result of
-concentration—a result due to the imperfect balancing of gravitative
-movements from opposite points towards the common centre. Such
-gravitative movements from opposite points must in great measure destroy
-each other. What then has become of these mutually-destroyed motions?
-The answer which the doctrine of correlation suggests is—they must have
-been radiated in the form of heat and light. And this answer the
-evidence, so far as it goes, confirms. Apart from any speculation
-respecting the genesis of the solar system, the inquiries of geologists
-lead to the conclusion that the heat of the Earth’s still molten nucleus
-is but a remnant of the heat which once made molten the entire Earth.
-The mountainous surfaces of the Moon and of Venus (which alone are near
-enough to be scrutinized), indicating, as they do, crusts that have,
-like our own, been corrugated by contraction, imply that these bodies
-too have undergone refrigeration—imply in each of them a primitive heat,
-such as the hypothesis necessitates. Lastly, we have in the Sun a
-still-continued production of this heat and light, which must result
-from the arrest of diffused matter moving towards a common centre of
-gravity. Here also, as before, a quantitative relation is
-traceable. Among the bodies which make up the Solar System, those
-containing comparatively small amounts of matter whose centripetal
-motion has been destroyed, have already lost nearly all the produced
-heat: a result which their relatively larger surfaces have facilitated.
-But the Sun, a thousand times as great in mass as the largest planet,
-and having therefore to give off an enormously greater quantity of heat
-and light due to arrest of moving matter, is still radiating with great
-intensity.
-
-Thus we see that when, in pursuance of the doctrine of correlation, we
-ask whence come the forces which our Solar System displays, the
-hypothesis of Evolution gives us a proximate explanation. If the Solar
-System once existed in a state of indefinite, incoherent homogeneity,
-and has progressed to its present state of definite, coherent
-heterogeneity; then the Motion, Heat, and Light now exhibited by its
-members, are interpretable as the correlatives of pre-existing forces;
-and between them and their antecedents we may discern relations that are
-not only qualitative, but also rudely quantitative. How matter came to
-exist under the form assumed, is a mystery which we must regard as
-ultimate. But grant such a previous form of existence, and the
-hypothesis of Evolution interpreted by the laws of correlation, explains
-for us the forces as we now see them.
-
- * * * * *
-
-§ 80. If we inquire the origin of those forces which have wrought the
-surface of our planet into its present shape, we find them traceable to
-the same primordial source as that just assigned. Assuming the solar
-system to have been evolved, then geologic changes are either direct or
-indirect results of the unexpended heat caused by nebular condensation.
-These changes are commonly divided into igneous and aqueous:—heads under
-which we may most conveniently consider them.
-
-All those periodic disturbances which we call earthquakes, all those
-elevations and subsidences which they severally produce, all those
-accumulated effects of many such elevations and subsidences exhibited in
-ocean-basins, islands, continents, table-lands, mountain-chains, and all
-those formations which are distinguished as volcanic, geologists now
-regard as modifications of the Earth’s crust produced by the
-still-molten matter occupying its interior. However untenable may be the
-details of M. Elie de Beaumont’s theory, there is good reason to accept
-the general proposition that the disruptions and variations of level
-which take place at intervals on the terrestrial surface, are due to the
-progressive collapse of the Earth’s solid envelope upon its cooling and
-contracting nucleus. Even supposing that volcanic eruptions, extrusions
-of igneous rock, and upheaved mountain-chains, could be otherwise
-satisfactorily accounted for, which they cannot; it would be impossible
-otherwise to account for those wide-spread elevations and depressions
-whence continents and oceans result. The conclusion to be drawn is,
-then, that the forces displayed in these so-called igneous changes, are
-derived positively or negatively from the unexpended heat of the Earth’s
-interior. Such phenomena as the fusion or agglutination of sedimentary
-deposits, the warming of springs, the sublimation of metals into the
-fissures where we find them as ores, may be regarded as positive results
-of this residuary heat; while fractures of strata and alterations of
-level are its negative results, since they ensue on its escape. The
-original cause of all these effects is still, however, as it has been
-from the first, the gravitating movement of the Earth’s matter towards
-the Earth’s centre; seeing that to this is due both the internal heat
-itself and the collapse which takes place as it is radiated into space.
-
-When we inquire under what forms previously existed the force which
-works out the geological changes classed as aqueous, the answer is less
-obvious. The effects of rain, of rivers, of winds, of waves, of marine
-currents, do not manifestly proceed from one general source. Analysis,
-nevertheless, proves to us that they have a common genesis. If we
-ask,—Whence comes the power of the river-current, bearing sediment down
-to the sea? the reply is,—The gravitation of water throughout the tract
-which this river drains. If we ask,—How came the water to be dispersed
-over this tract? the reply is,—It fell in the shape of rain. If we
-ask,—How came the rain to be in that position whence it fell? the reply
-is,—The vapour from which it was condensed was drifted there by the
-winds. If we ask,—How came this vapour to be at that elevation? the
-reply is,—It was raised by evaporation. And if we ask,—What force thus
-raised it? the reply is,—The sun’s heat. Just that amount of gravitative
-force which the sun’s heat overcame in raising the atoms of water, is
-given out again in the fall of those atoms to the same level. Hence the
-denudations effected by rain and rivers, during the descent of this
-condensed vapour to the level of the sea, are indirectly due to the
-sun’s heat. Similarly with the winds that transport the vapours hither
-and thither. Consequent as atmospheric currents are on differences of
-temperature (either general, as between the equatorial and polar
-regions, or special as between tracts of the Earth’s surface of unlike
-physical characters) all such currents are due to that source from which
-the varying quantities of heat proceed. And if the winds thus originate,
-so too do the waves raised by them on the sea’s surface. Whence it
-follows that whatever changes waves produce—the wearing away of shores,
-the breaking down of rocks into shingle, sand, and mud—are also
-traceable to the solar rays as their primary cause. The same may be said
-of ocean-currents. Generated as the larger ones are by the excess of
-heat which the ocean in tropical climates continually acquires from the
-Sun; and generated as the smaller ones are by minor local differences in
-the quantities of solar heat absorbed; it follows that the distribution
-of sediment and other geological processes which these marine currents
-effect, are affiliable upon the force which the sun radiates. The only
-aqueous agency otherwise originating is that of the tides—an agency
-which, equally with the others, is traceable to unexpended astronomical
-motion. But making allowance for the changes which this works, we reach
-the conclusion that the slow wearing down of continents and gradual
-filling up of seas, by rain, rivers, winds, waves, and ocean-streams,
-are the indirect effects of solar heat.
-
-Thus the implication forced on us by the doctrine of correlation, that
-the forces which have moulded and re-moulded the Earth’s crust must have
-pre-existed under some other shape, is quite in conformity with the
-theory of Evolution; since this pre-supposes certain forces that are
-both adequate to the results, and cannot be expended without producing
-the results. We see that while the geological changes classed as
-igneous, result from the still-progressing motion of the Earth’s
-substance to its centre of gravity; the antagonistic changes classed as
-aqueous, result from the still-progressing motion of the Sun’s substance
-towards its centre of gravity—a motion which, transformed into heat and
-radiated to us, is here re-transformed, directly into motions of the
-gaseous and liquid matters on the Earth’s surface, and indirectly into
-motions of the solid matters.
-
- * * * * *
-
-§ 81. That the forces exhibited in vital actions, vegetal and animal,
-are similarly derived, is so obvious a deduction from the facts of
-organic chemistry, that it will meet with ready acceptance from readers
-acquainted with these facts. Let us note first the physiological
-generalizations; and then the generalizations which they necessitate.
-
-Plant-life is all directly or indirectly dependant on the heat and light
-of the sun—directly dependant in the immense majority of plants, and
-indirectly dependant in plants which, as the fungi, flourish in the
-dark: since these, growing as they do at the expense of decaying organic
-matter, mediately draw their forces from the same original source. Each
-plant owes the carbon and hydrogen of which it mainly consists, to the
-carbonic acid and water contained in the surrounding air and earth. The
-carbonic acid and water must, however, be decomposed before their carbon
-and hydrogen can be assimilated. To overcome the powerful affinities
-which hold their elements together, requires the expenditure of force;
-and this force is supplied by the Sun. In what manner the decomposition
-is effected we do not know. But we know that when, under fit conditions,
-plants are exposed to the Sun’s rays, they give off oxygen and
-accumulate carbon and hydrogen. In darkness this process ceases. It
-ceases too when the quantities of light and heat received are greatly
-reduced, as in winter. Conversely, it is active when the light and heat
-are great, as in summer. And the like relation is seen in the fact that
-while plant-life is luxuriant in the tropics, it diminishes in temperate
-regions, and disappears as we approach the poles. Thus the irresistible
-inference is, that the forces by which plants abstract the materials of
-their tissues from surrounding inorganic compounds—the forces by which
-they grow and carry on their functions, are forces that previously
-existed as solar radiations.
-
-That animal life is immediately or mediately dependant on vegetal life
-is a familiar truth; and that, in the main, the processes of animal life
-are opposite to those of vegetal life is a truth long current among men
-of science. Chemically considered, vegetal life is chiefly a process of
-de-oxidation, and animal life chiefly a process of oxidation: chiefly,
-we must say, because in so far as plants are expenders of force for the
-purposes of organization, they are oxidizers (as is shown by the
-exhalation of carbonic acid during the night); and animals, in some of
-their minor processes, are probably de-oxidizers. But with this
-qualification, the general truth is that while the plant, decomposing
-carbonic acid and water and liberating oxygen, builds up the detained
-carbon and hydrogen (along with a little nitrogen and small quantities
-of other elements elsewhere obtained) into branches, leaves, and seeds;
-the animal, consuming these branches, leaves, and seeds, and absorbing
-oxygen, recomposes carbonic acid and water, together with certain
-nitrogenous compounds in minor amounts. And while the decomposition
-effected by the plant, is at the expense of certain forces emanating
-from the sun, which are employed in overcoming the affinities of carbon
-and hydrogen for the oxygen united with them; the recomposition effected
-by the animal, is at the profit of these forces, which are liberated
-during the combination of such elements. Thus the movements, internal
-and external, of the animal, are re-appearances in new forms of a power
-absorbed by the plant under the shape of light and heat. Just as, in the
-manner above explained, the solar forces expended in raising vapour from
-the sea’s surface, are given out again in the fall of rain and rivers to
-the same level, and in the accompanying transfer of solid matters; so,
-the solar forces that in the plant raised certain chemical elements to a
-condition of unstable equilibrium, are given out again in the actions of
-the animal during the fall of these elements to a condition of stable
-equilibrium.
-
-Besides thus tracing a qualitative correlation between these two great
-orders of organic activity, as well as between both of them and
-inorganic agencies, we may rudely trace a quantitative correlation.
-Where vegetal life is abundant, we usually find abundant animal life;
-and as we advance from torrid to temperate and frigid climates, the two
-decrease together. Speaking generally, the animals of each class reach a
-larger size in regions where vegetation is abundant, than in those where
-it is sparse. And further, there is a tolerably apparent connexion
-between the quantity of energy which each species of animal expends, and
-the quantity of force which the nutriment it absorbs gives out during
-oxidation.
-
-Certain phenomena of development in both plants and animals, illustrate
-still more directly the ultimate truth enunciated. Pursuing the
-suggestion made by Mr. Grove, in the first edition of his work on the
-“Correlation of the Physical Forces,” that a connexion probably exists
-between the forces classed as vital and those classed as physical, Dr.
-Carpenter has pointed out that such a connexion is clearly exhibited
-during incubation. The transformation of the unorganized contents of an
-egg into the organized chick, is altogether a question of heat: withhold
-heat and the process does not commence; supply heat and it goes on while
-the temperature is maintained, but ceases when the egg is allowed to
-cool. The developmental changes can be completed only by keeping the
-temperature with tolerable constancy at a definite height for a definite
-time; that is—only by supplying a definite quantity of heat. In the
-metamorphoses of insects we may discern parallel facts. Experiments show
-not only that the hatching of their eggs is determined by temperature,
-but also that the evolution of the pupa into the imago is similarly
-determined; and may be immensely accelerated or retarded according as
-heat is artificially supplied or withheld. It will suffice just to add
-that the germination of plants presents like relations of cause and
-effect—relations so similar that detail is superfluous.
-
-Thus then the various changes exhibited to us by the organic creation,
-whether considered as a whole, or in its two great divisions, or in its
-individual members, conform, so far as we can ascertain, to the law of
-correlation. Where, as in the transformation of an egg into a chick, we
-can investigate the phenomena apart from all complications, we find that
-the re-arrangement of parts which constitutes evolution, involves
-expenditure of a pre-existing force. Where it is not, as in the egg or
-the chrysalis, merely the change of a fixed quantity of matter into a
-new shape, but where, as in the growing plant or animal, we have an
-incorporation of matter existing outside, there is still a pre-existing
-external force at the cost of which this incorporation is effected. And
-where, as in the higher division of organisms, there remain over and
-above the forces expended in organization, certain surplus forces
-expended in movement, these too are indirectly derived from this same
-pre-existing external force.
-
- * * * * *
-
-§ 82. Even after all that has been said in the foregoing part of this
-work, many will be alarmed by the assertion, that the forces which we
-distinguish as mental, come within the same generalization. Yet there is
-no alternative but to make this assertion: the facts which justify, or
-rather which necessitate it, being abundant and conspicuous. They fall
-into the following groups.
-
-All impressions from moment to moment made on our organs of sense, stand
-in direct correlation with physical forces existing externally. The
-modes of consciousness called pressure, motion, sound, light, heat, are
-effects produced in us by agencies which, as otherwise expended, crush
-or fracture pieces of matter, generate vibrations in surrounding
-objects, cause chemical combinations, and reduce substances from a solid
-to a liquid form. Hence if we regard the changes of relative position,
-of aggregation, or of chemical state, thus arising, as being transformed
-manifestations of the agencies from which they arise; so must we regard
-the sensations which such agencies produce in us, as new forms of the
-forces producing them. Any hesitation to admit that, between the
-physical forces and the sensations there exists a correlation like that
-between the physical forces themselves, must disappear on remembering
-how the one correlation, like the other, is not qualitative only but
-quantitative. Masses of matter which, by scales or dynamometer, are
-shown to differ greatly in weight, differ as greatly in the feelings of
-pressure they produce on our bodies. In arresting moving objects, the
-strains we are conscious of are proportionate to the momenta of such
-objects as otherwise measured. Under like conditions the impressions of
-sounds given to us by vibrating strings, bells, or columns of air, are
-found to vary in strength with the amount of force applied. Fluids or
-solids proved to be markedly contrasted in temperature by the different
-degrees of expansion they produce in the mercurial column, produce in us
-correspondingly different degrees of the sensation of heat. And
-similarly unlike intensities in our impressions of light, answer to
-unlike effects as measured by photometers.
-
-Besides the correlation and equivalence between external physical
-forces, and the mental forces generated by them in us under the form of
-sensations, there is a correlation and equivalence between sensations
-and those physical forces which, in the shape of bodily actions, result
-from them. The feelings we distinguish as light, heat, sound, odour,
-taste, pressure, &.c, do not die away without immediate results; but are
-invariably followed by other manifestations of force. In addition to the
-excitements of secreting organs, that are in some cases traceable, there
-arises a contraction of the involuntary muscles, or of the voluntary
-muscles, or of both. Sensations increase the action of the
-heart—slightly when they are slight; markedly when they are marked; and
-recent physiological inquiries imply not only that contraction of the
-heart is excited by every sensation, but also that the muscular fibres
-throughout the whole, vascular system, are at the same time more or less
-contracted. The respiratory muscles, too, are stimulated into greater
-activity by sensations. The rate of breathing is visibly and audibly
-augmented both by pleasurable and painful impressions on the nerves,
-when these reach any intensity. It has even of late been shown that
-inspiration becomes more frequent on transition from darkness into
-sunshine,—a result probably due to the increased amount of direct and
-indirect nervous stimulation involved. When the quantity of sensation is
-great, it generates contractions of the voluntary muscles, as well as of
-the involuntary ones. Unusual excitement of the nerves of touch, as by
-tickling, is followed by almost incontrollable movements of the limbs.
-Violent pains cause violent struggles. The start that succeeds a loud
-sound, the wry face produced by the taste of anything extremely
-disagreeable, the jerk with which the hand or foot is snatched out of
-water that is very hot, are instances of the transformation of feeling:
-into motion; and in these cases, as in all others, it is manifest that
-the quantity of bodily action is proportionate to the quantity of
-sensation. Even where from pride there is a suppression of the screams
-and groans expressive of great pain (also indirect results of muscular
-contraction), we may still see in the clenching of the hands, the
-knitting of the brows, and the setting of the teeth, that the bodily
-actions developed are as great, though less obtrusive in their results.
- If we take emotions instead of sensations, we find the correlation
-and equivalence equally manifest. Not only are the modes of
-consciousness directly produced in us by physical forces,
-re-transformable into physical forces under the form of muscular motions
-and the changes they initiate; but the like is true of those modes of
-consciousness which are not directly produced in us by the physical
-forces. Emotions of moderate intensity, like sensations of moderate
-intensity, generate little beyond excitement of the heart and vascular
-system, joined sometimes with increased action of glandular organs. But
-as the emotions rise in strength, the muscles of the face, body, and
-limbs, begin to move. Of examples may be mentioned the frowns, dilated
-nostrils, and stampings of anger; the contracted brows, and wrung hands,
-of grief; the smiles and leaps of joy; and the frantic struggles of
-terror or despair. Passing over certain apparent, but only apparent,
-exceptions, we see that whatever be the kind of emotion, there is a
-manifest relation between its amount, and the amount of muscular action
-induced: alike from the erect carriage and elastic step of exhilaration,
-up to the dancings of immense delight, and from the fidgetiness of
-impatience up to the almost convulsive movements accompanying great
-mental agony. To these several orders of evidence must be joined
-the further one, that between our feelings and those voluntary motions
-into which they are transformed, there comes the sensation of muscular
-tension, standing in manifest correlation with both—a correlation that
-is distinctly quantitative: the sense of strain varying, other things
-equal, directly as the quantity of momentum generated.
-
-“But how,” it may be asked, “can we interpret by the law of correlation
-the genesis of those thoughts and feelings which, instead of following
-external stimuli, arise spontaneously? Between the indignation caused by
-an insult, and the loud sounds or violent acts that follow, the alleged
-connexion may hold; but whence come the crowd of ideas and the mass of
-feelings that expend themselves in these demonstrations? They are
-clearly not equivalents of the sensations produced by the words on the
-ears; for the same words otherwise arranged, would not have caused them.
-The thing said bears to the mental action it excites, much the same
-relation that the pulling of a trigger bears to the subsequent
-explosion—does not produce the power, but merely liberates it. Whence
-then arises this immense amount of nervous energy which a whisper or a
-glance may call forth?” The reply is, that the immediate
-correlates of these and other such modes of consciousness, are not to be
-found in the agencies acting on us externally, but in certain internal
-agencies. The forces called vital, which we have seen to be correlates
-of the forces called physical, are the immediate sources of these
-thoughts and feelings; and are expended in producing them. The proofs of
-this are various. Here are some of them. It is a conspicuous fact
-that mental action is contingent on the presence of a certain nervous
-apparatus; and that, greatly obscured as it is by numerous and involved
-conditions, a general relation may be traced between the size of this
-apparatus and the quantity of mental action as measured by its results.
-Further, this apparatus has a particular chemical constitution on which
-its activity depends; and there is one element in it between the amount
-of which and the amount of function performed, there is an ascertained
-connexion: the proportion of phosphorus present in the brain being the
-smallest in infancy, old age and idiotcy, and the greatest during the
-prime of life. Note next, that the evolution of thought and
-emotion varies, other things equal, with the supply of blood to the
-brain. On the one hand, a cessation of the cerebral circulation, from
-arrest of the heart’s action, immediately entails unconsciousness. On
-the other hand, excess of cerebral circulation (unless it is such as to
-cause undue pressure) results in an excitement rising finally to
-delirium. Not the quantity only, but also the condition of the
-blood passing through the nervous system, influences the mental
-manifestations. The arterial currents must be duly aerated, to produce
-the normal amount of cerebration. At the one extreme, we find that if
-the blood is not allowed to exchange its carbonic acid for oxygen, there
-results asphyxia, with its accompanying stoppage of ideas and feelings.
-While at the other extreme, we find that by the inspiration of nitrous
-oxide, there is produced an excessive, and indeed irrepressible, nervous
-activity. Besides the connexion between the development of the
-mental forces and the presence of sufficient oxygen in the cerebral
-arteries, there is a kindred connexion between the development of the
-mental forces and the presence in the cerebral arteries of certain other
-elements. There must be supplied special materials for the nutrition of
-the nervous centres, as well as for their oxidation. And how what we may
-call the quantity of consciousness, is, other things equal, determined
-by the constituents of the blood, is unmistakably seen in the exaltation
-that follows when certain chemical compounds, as alcohol and the
-vegeto-alkalies, are added to it. The gentle exhilaration which tea and
-coffee create, is familiar to all; and though the gorgeous imaginations
-and intense feelings of happiness produced by opium and hashish, have
-been experienced by few, (in this country at least,) the testimony of
-those who have experienced them is sufficiently conclusive. Yet
-another proof that the genesis of the mental energies is immediately
-dependent on chemical change, is afforded by the fact, that the effete
-products separated from the blood by the kidneys, vary in character with
-the amount of cerebral action. Excessive activity of mind is habitually
-accompanied by the excretion of an unusual quantity of the alkaline
-phosphates. Conditions of abnormal nervous excitement bring on analogous
-effects. And the “peculiar odour of the insane,” implying as it does
-morbid products in the perspiration, shows a connexion between insanity
-and a special composition of the circulating fluids—a composition which,
-whether regarded as cause or consequence, equally implies correlation of
-the mental and the physical forces. Lastly we have to note that
-this correlation too, is, so far as we can trace it, quantitative.
-Provided the conditions to nervous action are not infringed on, and the
-concomitants are the same, there is a tolerably constant ratio between
-the amounts of the antecedents and consequents. Within the implied
-limits, nervous stimulants and anæsthetics produce effects on the
-thoughts and feelings, proportionate to the quantities administered. And
-conversely, where the thoughts and feelings form the initial term of the
-relation, the degree of reaction on the bodily energies is great, in
-proportion as they are great: reaching in extreme cases a total
-prostration of physique.
-
-Various classes of facts thus unite to prove that the law of
-metamorphosis, which holds among the physical forces, holds equally
-between them and the mental forces. Those modes of the Unknowable which
-we call motion, heat, light, chemical affinity, &c., are alike
-transformable into each other, and into those modes of the Unknowable
-which we distinguish as sensation, emotion, thought: these, in their
-turns, being directly or indirectly re-transformable into the original
-shapes. That no idea or feeling arises, save as a result of some
-physical force expended in producing it, is fast becoming a common place
-of science; and whoever duly weighs the evidence will see, that nothing
-but an overwhelming bias in favour of a pre-conceived theory, can
-explain its non-acceptance. How this metamorphosis takes place—how
-a force existing as motion, heat, or light, can become a mode of
-consciousness—how it is possible for aerial vibrations to generate the
-sensation we call sound, or for the forces liberated by chemical changes
-in the brain to give rise to emotion—these are mysteries which it is
-impossible to fathom. But they are not profounder mysteries than the
-transformations of the physical forces into each other. They are not
-more completely beyond our comprehension than the natures of Mind and
-Matter. They have simply the same insolubility as all other ultimate
-questions. We can learn nothing more than that here is one of the
-uniformities in the order of phenomena.
-
- * * * * *
-
-§ 83. Of course if the law of correlation and equivalence holds of the
-forces we class as vital and mental, it must hold also of those which we
-class as social. Whatever takes place in a society is due to organic or
-inorganic agencies, or to a combination of the two—results either from
-the undirected physical forces around, from these physical forces as
-directed by men, or from the forces of the men themselves. No change can
-occur in its organization, its modes of activity, or the effects it
-produces on the face of the Earth, but what proceeds, mediately or
-immediately, from these. Let us consider first the correlation between
-the phenomena which societies display, and the vital phenomena.
-
-Social power and life varies, other things equal, with the population.
-Though different races, differing widely in their fitness for
-combination, show us that the forces manifested in a society are not
-necessarily proportionate to the number of people; yet we see that under
-given conditions, the forces manifested are confined within the limits
-which the number of people imposes. A small society, no matter how
-superior the character of its members, cannot exhibit the same quantity
-of social action as a large one. The production and distribution of
-commodities must be on a comparatively small scale. A multitudinous
-press, a prolific literature, or a massive political agitation, is not
-possible. And there can be but a small total of results in the shape of
-art-products and scientific discoveries. The correlation of the
-social with the physical forces through the intermediation of the vital
-ones, is, however, most clearly shown in the different amounts of
-activity displayed by the same society according as its members are
-supplied with different amounts of force from the external world. In the
-effects of good and bad harvests, we yearly see this relation
-illustrated. A greatly deficient yield of wheat is soon followed by a
-diminution of business. Factories are worked half-time, or close
-entirely; railway traffic falls; retailers find their sales much
-lessened; house-building is almost suspended; and if the scarcity rises
-to famine, a thinning of the population still more diminishes the
-industrial vivacity. Conversely, an unusually abundant harvest,
-occurring under conditions not otherwise unfavourable, both excites the
-old producing and distributing agencies and sets up new ones. The
-surplus social energy finds vent in speculative enterprises. Capital
-seeking investment carries out inventions that have been lying
-unutilized. Labour is expended in opening new channels of communication.
-There is increased encouragement to those who furnish the luxuries of
-life and minister to the æsthetic faculties. There are more marriages,
-and a greater rate of increase in population. Thus the social organism
-grows larger, more complex, and more active. When, as happens with
-most civilized nations, the whole of the materials for subsistence are
-not drawn from the area inhabited, but are partly imported, the people
-are still supported by certain harvests elsewhere grown at the expense
-of certain physical forces. Our own cotton-spinners and weavers supply
-the most conspicuous instance of a section in one nation living, in
-great part, on imported commodities, purchased by the labour they expend
-on other imported commodities. But though the social activities of
-Lancashire are due chiefly to materials not drawn from our own soil,
-they are none the less evolved from physical forces elsewhere stored up
-in fit forms and then brought here.
-
-If we ask whence come these physical forces from which, through the
-intermediation of the vital forces, the social forces arise, the reply
-is of course as heretofore—the solar radiations. Based as the life of a
-society is on animal and vegetal products; and dependent as these animal
-and vegetal products are on the light and heat of the sun; it follows
-that the changes going on in societies are effects of forces having a
-common origin with those which produce all the other orders of changes
-that have been analyzed. Not only is the force expended by the horse
-harnessed to the plough, and by the labourer guiding it, derived from
-the same reservoir as is the force of the falling cataract and the
-roaring hurricane; but to this same reservoir are eventually traceable
-those subtler and more complex manifestations of force which humanity,
-as socially embodied, evolves. The assertion is a startling one, and by
-many will be thought ludicrous; but it is an unavoidable deduction which
-cannot here be passed over.
-
-Of the physical forces that are directly transformed into social ones,
-the like is to be said. Currents of air and water, which before the use
-of steam were the only agencies brought in aid of muscular effort for
-the performance of industrial processes, are, as we have seen, generated
-by the heat of the sun. And the inanimate power that now, to so vast an
-extent, supplements human labour, is similarly derived. The late George
-Stephenson was one of the first to recognize the fact that the force
-impelling his locomotive, originally emanated from the sun. Step by step
-we go back—from the motion of the piston to the evaporation of the
-water; thence to the heat evolved during the oxidation of coal; thence
-to the assimilation of carbon by the plants of whose imbedded remains
-coal consists; thence to the carbonic acid from which their carbon was
-obtained; and thence to the rays of light that de-oxidized this carbonic
-acid. Solar forces millions of years ago expended on the Earth’s
-vegetation, and since locked up beneath its surface, now smelt the
-metals required for our machines, turn the lathes by which the machines
-are shaped, work them when put together, and distribute the fabrics they
-produce. And in so far as economy of labour makes possible the support
-of a larger population; gives a surplus of human power that would else
-be absorbed in manual occupations; and so facilitates the development of
-higher kinds of activity; it is clear that these social forces which are
-directly correlated with physical forces anciently derived from the sun,
-are only less important than those whose correlates are the vital forces
-recently derived from it.
-
- * * * * *
-
-§ 84. Regarded as an induction, the doctrine set forth in this chapter
-will most likely be met by a demurrer. Many who admit that among
-physical phenomena at least, the correlation of forces is now
-established, will probably say that inquiry has not yet gone far enough
-to enable us to predicate equivalence. And in respect of the forces
-classed as vital, mental, and social, the evidence assigned, however
-little to be explained away, they will consider by no means conclusive
-even of correlation, much less of equivalence.
-
-To those who think thus, it must now however be pointed out, that the
-universal truth above illustrated under its various aspects, is a
-necessary corollary from the persistence of force. Setting out with the
-proposition that force can neither come into existence, nor cease to
-exist, the several foregoing general conclusions inevitably follow. Each
-manifestation of force can be interpreted only as the effect of some
-antecedent force: no matter whether it be an inorganic action, an animal
-movement, a thought, or a feeling. Either this must be conceded, or else
-it must be asserted that our successive states of consciousness are
-self-created. Either mental energies, as well as bodily ones, are
-quantitatively correlated to certain energies expended in their
-production, and to certain other energies which they initiate; or else
-nothing must become something and something must become nothing. The
-alternatives are, to deny the persistence of force, or to admit that
-every physical and psychial change is generated by certain antecedent
-forces, and that from given amounts of such forces neither more nor less
-of such physical and psychial changes can result. And since the
-persistence of force, being a datum of consciousness, cannot be denied,
-its unavoidable corollary must be accepted. This corollary cannot
-indeed be made more certain by accumulating illustrations. The truth as
-arrived at deductively, cannot be inductively confirmed. For every one
-of such facts as those above detailed, is established only through the
-indirect assumption of that persistence of force, from which it really
-follows as a direct consequence. The most exact proof of correlation and
-equivalence which it is possible to reach by experimental inquiry, is
-that based on measurement of the forces expended and the forces
-produced. But, as was shown in the last chapter, any such process of
-measurement implies the use of some unit of force which is assumed to
-remain constant; and for this assumption there can be no warrant but
-that it is a corollary from the persistence of force. How then can any
-reasoning based on this corollary, prove the equally direct corollary
-that when a given quantity of force ceases to exist under one form, an
-equal quantity must come into existence under some other form or forms?
-Clearly the _à priori_ truth expressed in this last corollary, cannot be
-more firmly established by any _à posteriori_ proofs which the first
-corollary helps us to.
-
-“What then,” it may be asked, “is the use of these investigations by
-which the correlation and equivalence of forces is sought to be
-established as an inductive truth? Surely it will not be alleged that
-they are useless. Yet if this correlation cannot be made more certain by
-them than it is already, does not their uselessness necessarily follow?”
-No. They are of value as disclosing the many particular implications
-which the general truth does not specify. They are of value as teaching
-us how much of one mode of force is the equivalent of so much of another
-mode. They are of value as determining under what conditions each
-metamorphosis occurs. And they are of value as leading us to inquire in
-what shape the remnant of force has escaped, when the apparent results
-are not equivalent to the cause.
-
-
-
-
- CHAPTER X.
- THE DIRECTION OF MOTION.
-
-
-§ 85. The Absolute Cause of changes, inclusive of those constituting
-Evolution, is not less incomprehensible in respect of the unity or
-duality of its action, than in all other respects. We cannot decide
-between the alternative suppositions, that phenomena are due to the
-variously-conditioned workings of a single force, and that they are due
-to the conflict of two forces. Whether, as some contend, everything is
-explicable on the hypothesis of universal pressure, whence what we call
-tension results differentially from inequalities of pressure in opposite
-directions; or whether, as might be with equal propriety contended,
-things are to be explained on the hypothesis of universal tension, from
-which pressure is a differential result; or whether, as most physicists
-hold, pressure and tension everywhere co-exist; are questions which it
-is impossible to settle. Each of these three suppositions makes the
-facts comprehensible, only by postulating an inconceivability. To assume
-a universal pressure, confessedly requires us to assume an infinite
-plenum—an unlimited space full of something which is everywhere pressed
-by something beyond; and this assumption cannot be mentally realized.
-That universal tension is the immediate agency to which phenomena are
-due, is an idea open to a parallel and equally fatal objection. And
-however verbally intelligible may be the proposition that pressure and
-tension everywhere co-exist, yet we cannot truly represent to ourselves
-one ultimate unit of matter as drawing another while resisting it.
-
-Nevertheless, this last belief is one which we are compelled to
-entertain. Matter cannot be conceived except as manifesting forces of
-attraction and repulsion. Body is distinguished in our consciousness
-from Space, by its opposition to our muscular energies; and this
-opposition we feel under the two-fold form of a cohesion that hinders
-our efforts to rend, and a resistance that hinders our efforts to
-compress. Without resistance there can be merely empty extension.
-Without cohesion there can be no resistance. Probably this conception of
-antagonistic forces, is originally derived from the antagonism of our
-flexor and extensor muscles. But be this as it may, we are obliged to
-think of all objects as made up of parts that attract and repel each
-other; since this is the form of our experience of all objects.
-
-By a higher abstraction results the conception of attractive and
-repulsive forces pervading space. We cannot dissociate force from
-occupied extension, or occupied extension from force; because we have
-never an immediate consciousness of either in the absence of the other.
-Nevertheless, we have abundant proof that force is exercised through
-what appears to our senses a vacuity. Mentally to represent this
-exercise, we are hence obliged to fill the apparent vacuity with a
-species of matter—an etherial medium. The constitution we assign to this
-etherial medium, however, like the constitution we assign to solid
-substance, is necessarily an abstract of the impressions received from
-tangible bodies. The opposition to pressure which a tangible body offers
-to us, is not shown in one direction only, but in all directions; and so
-likewise is its tenacity. Suppose countless lines radiating from its
-centre on every side, and it resists along each of these lines and
-coheres along each of these lines. Hence the constitution of those
-ultimate units through the instrumentality of which phenomena are
-interpreted. Be they atoms of ponderable matter or molecules of ether,
-the properties we conceive them to possess are nothing else than these
-perceptible properties idealized. Centres of force attracting and
-repelling each other in all directions, are simply insensible portions
-of matter having the endowments common to sensible portions of
-matter—endowments of which we cannot by any mental effort divest them.
-In brief, they are the invariable elements of the conception of matter,
-abstracted from its variable elements—size, form, quality, &c. And so to
-interpret manifestations of force which cannot be tactually experienced,
-we use the terms of thought supplied by our tactual experiences; and
-this for the sufficient reason that we must use these or none.
-
-After all that has been before shown, and after the hint given above, it
-needs scarcely be said that these universally co-existent forces of
-attraction and repulsion, must not be taken as realities, but as our
-symbols of the reality. They are the forms under which the workings of
-the Unknowable are cognizable by us—modes of the Unconditioned as
-presented under the conditions of our consciousness. But while knowing
-that the ideas thus generated in us are not absolutely true, we may
-unreservedly surrender ourselves to them as relatively true; and may
-proceed to evolve a series of deductions having a like relative truth.
-
- * * * * *
-
-§ 86. From universally co-existent forces of attraction and repulsion,
-there result certain laws of direction of all movement. Where attractive
-forces alone are concerned, or rather are alone appreciable, movement
-takes place in the direction of their resultant; which may, in a sense,
-be called the line of greatest traction. Where repulsive forces alone
-are concerned, or rather are alone appreciable, movement takes place
-along their resultant; which is usually known as the line of least
-resistance. And where both attractive and repulsive forces are
-concerned, or are appreciable, movement takes place along the resultant
-of all the tractions and resistances. Strictly speaking, this last is
-the sole law; since, by the hypothesis, both forces are everywhere in
-action. But very frequently the one kind of force is so immensely in
-excess that the effect of the other kind may be left out of
-consideration. Practically we may say that a body falling to the Earth,
-follows the line of greatest traction; since, though the resistance of
-the air must, if the body be irregular, cause some divergence from this
-line, (quite perceptible with feathers and leaves,) yet ordinarily the
-divergence is so slight that we may omit it. In the same manner, though
-the course taken by the steam from an exploding boiler, differs somewhat
-from that which it would take were gravitation out of the question; yet,
-as gravitation affects its course infinitesimally, we are justified in
-asserting that the escaping steam follows the line of least resistance.
-Motion then, we may say, always follows the line of greatest traction,
-or the line of least resistance, or the resultant of the two: bearing in
-mind that though the last is alone strictly true, the others are in many
-cases sufficiently near the truth for practical purposes.
-
-Movement set up in any direction is itself a cause of further movement
-in that direction, since it is the embodiment of a surplus force in that
-direction. This holds equally with the transit of matter through space,
-the transit of matter through matter, and the transit through matter of
-any kind of vibration. In the case of matter moving through space, this
-principle is expressed in the law of inertia—a law on which the
-calculations of physical astronomy are wholly based. In the case of
-matter moving through matter, we trace the same truth under the familiar
-experience that any breach made by one solid through another, or any
-channel formed by a fluid through a solid, becomes a route along which,
-other things equal, subsequent movements of like nature take place. And
-in the case of motion passing through matter under the form of an
-impulse communicated from part to part, the facts of magnetization go to
-show that the establishment of undulations along certain lines,
-determines their continuance along those lines.
-
-It further follows from the conditions, that the direction of movement
-can rarely if ever be perfectly straight. For matter in motion to pursue
-continuously the exact line in which it sets out, the forces of
-attraction and repulsion must be symmetrically disposed around its path;
-and the chances against this are infinitely great. The impossibility of
-making an absolutely true edge to a bar of metal—the fact that all which
-can be done by the best mechanical appliances, is to reduce the
-irregularities of such an edge to amounts that cannot be perceived
-without magnifiers—sufficiently exemplifies how, in consequence of the
-unsymmetrical distribution of forces around the line of movement, the
-movement is rendered more or less indirect. It may be well to add
-that in proportion as the forces at work are numerous and varied, the
-curve a moving body describes is necessarily complex: witness the
-contrast between the flight of an arrow and the gyrations of a stick
-tossed about by breakers.
-
-We have now to trace these laws of direction of movement throughout the
-process of Evolution, under its various forms. We have to note how every
-change in the arrangement of parts, takes place along the line of
-greatest traction, of least resistance, or of their resultant; how the
-setting up of motion along a certain line, becomes a cause of its
-continuance along that line; how, nevertheless, change of relations to
-external forces, always renders this line indirect; and how the degree
-of its indirectness increases with every addition to the number of
-influences at work.
-
- * * * * *
-
-§ 87. If we assume the first stage in nebular condensation to be the
-precipitation into flocculi of denser matter previously diffused through
-a rarer medium, (a supposition both physically justified, and in harmony
-with certain astronomical observations,) we shall find that nebular
-motion is interpretable in pursuance of the above general laws. Each
-portion of such vapour-like matter must begin to move towards the common
-centre of gravity. The tractive forces which would of themselves carry
-it in a straight line to the centre of gravity, are opposed by the
-resistant forces of the medium through which it is drawn. The direction
-of movement must be the resultant of these—a resultant which, in
-consequence of the unsymmetrical form of the flocculus, must be a curve
-directed, not to the centre of gravity, but towards one side of it. And
-it may be readily shown that in an aggregation of such flocculi,
-severally thus moving, there must, by composition of forces, eventually
-result a rotation of the whole nebula in one direction.
-
-Merely noting this hypothetical illustration for the purpose of showing
-how the law applies to the case of nebular evolution, supposing it to
-have taken place, let us pass to the phenomena of the Solar System as
-now exhibited. Here the general principles above set forth are every
-instant exemplified. Each planet and satellite has a momentum which
-would, if acting alone, carry it forward in the direction it is at any
-instant pursuing. This momentum hence acts as a resistance to motion in
-any other direction. Each planet and satellite, however, is drawn by a
-force which, if unopposed, would take it in a straight line towards its
-primary. And the resultant of these two forces is that curve which it
-describes—a curve manifestly consequent on the unsymmetrical
-distribution of the forces around its path. This path, when more closely
-examined, supplies us with further illustrations. For it is not an exact
-circle or ellipse; which it would be were the tangential and centripetal
-forces the only ones concerned. Adjacent members of the Solar System,
-ever varying in their relative positions, cause what we call
-perturbations; that is, slight divergences in various directions from
-that circle or ellipse which the two chief forces would produce. These
-perturbations severally show us in minor degrees, how the line of
-movement is the resultant of all the forces engaged; and how this line
-becomes more complicated in proportion as the forces are multiplied.
- If instead of the motions of the planets and satellites as wholes,
-we consider the motions of their parts, we meet with comparatively
-complex illustrations. Every portion of the Earth’s substance in its
-daily rotation, describes a curve which is in the main a resultant of
-that resistance which checks its nearer approach to the centre of
-gravity, that momentum which would carry it off at a tangent, and those
-forces of gravitation and cohesion which keep it from being so carried
-off. If this axial motion be compounded with the orbital motion, the
-course of each part is seen to be a much more involved one. And we find
-it to have a still greater complication on taking into account that
-lunar attraction which mainly produces the tides and the precession of
-the equinoxes.
-
- * * * * *
-
-§ 88. We come next to terrestrial changes: present ones as observed, and
-past ones as inferred by geologists. Let us set out with the
-hourly-occurring alterations in the Earth’s atmosphere; descend to the
-slower alterations in progress on its surface; and then to the still
-slower ones going on beneath.
-
-Masses of air, absorbing heat from surfaces warmed by the sun, expand,
-and so lessen the weight of the atmospheric columns of which they are
-parts. Hence they offer to adjacent atmospheric columns, diminished
-lateral resistance; and these, moving in the directions of the
-diminished resistance, displace the expanded air; while this, pursuing
-an upward course, displays a motion along that line in which there is
-least pressure. When again, by the ascent of such heated masses from
-extended areas like the torrid zone, there is produced at the upper
-surface of the atmosphere, a protuberance beyond the limits of
-equilibrium—when the air forming this protuberance begins to overflow
-laterally towards the poles; it does so because, while the tractive
-force of the Earth is nearly the same, the lateral resistance is greatly
-diminished. And throughout the course of each current thus generated, as
-well as throughout the course of each counter-current flowing: into the
-vacuum that is left, the direction is always the resultant of the
-Earth’s tractive force and the resistance offered by the surrounding
-masses of air: modified only by conflict with other currents similarly
-determined, and by collision with prominences on the Earth’s crust.
- The movements of water, in both its gaseous and liquid states,
-furnish further examples. In conformity with the mechanical theory of
-heat, it may be shown that evaporation is the escape of particles of
-water in the direction of least resistance; and that as the resistance
-(which is due to the pressure of the water diffused in a gaseous state)
-diminishes, the evaporation increases. Conversely, that rushing together
-of particles called condensation, which takes place when any portion of
-atmospheric vapour has its temperature much lowered, may be interpreted
-as a diminution of the mutual pressure among the condensing particles,
-while the pressure of surrounding particles remains the same; and so is
-a motion taking place in the direction of lessened resistance. In the
-course followed by the resulting rain-drops, we have one of the simplest
-instances of the joint effect of the two antagonist forces. The Earth’s
-attraction, and the resistance of atmospheric currents ever varying in
-direction and intensity, give as their resultants, lines which incline
-to the horizon in countless different degrees and undergo perpetual
-variations. More clearly still is the law exemplified by these same
-rain-drops when they reach the ground. In the course they take while
-trickling over its surface, in every rill, in every larger stream, and
-in every river, we see them descending as straight as the antagonism of
-surrounding objects permits. From moment to moment, the motion of water
-towards the Earth’s centre is opposed by the solid matter around and
-under it; and from moment to moment its route is the resultant of the
-lines of greatest traction and least resistance. So far from a cascade
-furnishing, as it seems to do, an exception, it furnishes but another
-illustration. For though all solid obstacles to a vertical fall of the
-water are removed, yet the water’s horizontal momentum is an obstacle;
-and the parabola in which the stream leaps from the projecting ledge, is
-generated by the combined gravitation and momentum. It may be well
-just to draw attention to the degree of complexity here produced in the
-line of movement by the variety of forces at work. In atmospheric
-currents, and still more clearly in water-courses (to which might be
-added ocean-streams), the route followed is too complex to be defined,
-save as a curve of three dimensions with an ever varying equation.
-
-The Earth’s solid crust undergoes changes that supply another group of
-illustrations. The denudation of lands and the depositing of the removed
-sediment in new strata at the bottoms of seas and lakes, is a process
-throughout which motion is obviously determined in the same way as is
-that of the water effecting the transport. Again, though we have no
-direct inductive proof that the forces classed as igneous, expend
-themselves along lines of least resistance; yet what little we know of
-them is in harmony with the belief that they do so. Earthquakes
-continually revisit the same localities, and special tracts undergo for
-long periods together successive elevations or subsidences,—facts which
-imply that already-fractured portions of the Earth’s crust are those
-most prone to yield under the pressure caused by further contractions.
-The distribution of volcanoes along certain lines, as well as the
-frequent recurrence of eruptions from the same vents, are facts of like
-meaning.
-
- * * * * *
-
-§ 89. That organic growth takes place in the direction of least
-resistance, is a proposition that has been set forth and illustrated by
-Mr. James Hinton, in the _Medico-Chirurgical Review_ for October, 1858.
-After detailing a few of the early observations which led him to this
-generalization, he formulates it thus:—
-
-“Organic form is the result of motion.”
-
-“Motion takes the direction of least resistance.”
-
-“Therefore organic form is the result of motion in the direction of
-least resistance.”
-
-After an elucidation and defence of this position, Mr. Hinton proceeds
-to interpret, in conformity with it, sundry phenomena of development.
-Speaking of plants he says:—
-
-“The formation of the root furnishes a beautiful illustration of the law
-of least resistance, for it grows by insinuating itself, cell by cell,
-through the interstices of the soil; it is by such minute additions that
-it increases, winding and twisting whithersoever the obstacles it meets
-in its path determine, and growing there most, where the nutritive
-materials are added to it most abundantly. As we look on the roots of a
-mighty tree, it appears to us as if they had forced themselves with
-giant violence into the solid earth. But it is not so; they were led on
-gently, cell added to cell, softly as the dews descended, and the
-loosened earth made way. Once formed, indeed, they expand with an
-enormous power, but the spongy condition of the growing radicles utterly
-forbids the supposition that they are forced into the earth. Is it not
-probable, indeed, that the enlargement of the roots already formed may
-crack the surrounding soil, and help to make the interstices into which
-the new rootlets grow?” * * *
-
-“Throughout almost the whole of organic nature the spiral form is more
-or less distinctly marked. Now, motion under resistance takes a spiral
-direction, as may be seen by the motion of a body rising or falling
-through water. A bubble rising rapidly in water describes a spiral
-closely resembling a corkscrew, and a body of moderate specific gravity
-dropped into water may be seen to fall in a curved direction, the spiral
-tendency of which may be distinctly observed. * * * In this prevailing
-spiral form of organic bodies, therefore, it appears to me, that there
-is presented a strong _prima facie_ case for the view I have maintained.
-* * * The spiral form of the branches of many trees is very apparent,
-and the universally spiral arrangement of the leaves around the stem of
-plants needs only to be referred to. * * * The heart commences as a
-spiral turn, and in its perfect form a manifest spiral may be traced
-through the left ventricle, right ventricle, right auricle, left auricle
-and appendix. And what is the spiral turn in which the heart commences
-but a necessary result of the lengthening, under a limit, of the
-cellular mass of which it then consists?” * * *
-
-“Every one must have noticed the peculiar curling up of the young leaves
-of the common fern. The appearance is as if the leaf were rolled up, but
-in truth this form is merely a phenomenon of growth. The curvature
-results from the increase of the leaf, it is only another form of the
-wrinkling up, or turning at right angles by extension under limit.”
-
-“The rolling up or imbrication of the petals in many flower-buds is a
-similar thing; at an early period the small petals may be seen lying
-side by side, afterwards growing within the capsule, they become folded
-round one another.” * * *
-
-“If a flower-bud be opened at a sufficiently early period, the stamens
-will be found as if moulded in the cavity between the pistil and the
-corolla, which cavity the antlers exactly fill; the stalks lengthen at
-an after period. I have noticed also in a few instances, that in those
-flowers in which the petals are imbricated, or twisted together, the
-pistil is tapering as growing up between the petals; in some flowers
-which have the petals so arranged in the bud as to form a dome (as the
-hawthorn; e. g.), the pistil is flattened at the apex, and in the bud
-occupies a space precisely limited by the stamens below, and the
-enclosing petals above and at the sides. I have not, however, satisfied
-myself that this holds good in all cases.”
-
-Without endorsing all Mr. Hinton’s illustrations, to some of which
-exception might be taken, his conclusion may be accepted as a large
-instalment of the truth. It is, however, to be remarked, that in the
-case of organic growth, as in all other cases, the line of movement is
-in strictness the resultant of tractive and resistant forces; and that
-the tractive forces here form so considerable an element that the
-formula is scarcely complete without them. The shapes of plants are
-manifestly modified by gravitation: the direction of each branch is not
-what it would have been were the tractive force of the Earth absent; and
-every flower and leaf is somewhat altered in the course of development
-by the weight of its parts. Though in animals such effects are less
-conspicuous, yet the instances in which flexible organs have their
-directions in great measure determined by gravity, justify the assertion
-that throughout the whole organism the forms of parts must be affected
-by this force.
-
-The organic movements which constitute growth, are not, however, the
-only organic movements to be interpreted. There are also those which
-constitute function. And throughout these the same general principles
-are discernible. That the vessels along which blood, lymph, bile, and
-all the secretions, find their ways, are channels of least resistance,
-is a fact almost too conspicuous to be named as an illustration. Less
-conspicuous, however, is the truth, that the currents setting along
-these vessels are affected by the tractive force of the Earth: witness
-varicose veins; witness the relief to an inflamed part obtained by
-raising it; witness the congestion of head and face produced by
-stooping. And in the fact that dropsy in the legs gets greater by day
-and decreases at night, while, conversely, that œdematous fullness under
-the eyes common in debility, grows worse during the hours of reclining
-and decreases after getting up, shows us how the transudation of fluid
-through the walls of the capillaries, varies according as change of
-position changes the effect of gravity in different parts of the body.
-
-It may be well in passing just to note the bearing of the principle on
-the development of species. From a dynamic point of view, “natural
-selection” is the evolution of Life along lines of least resistance. The
-multiplication of any kind of plant or animal in localities that are
-favourable to it, is a growth where the antagonistic forces are less
-than elsewhere. And the preservation of varieties that succeed better
-than their allies in coping with surrounding conditions, is the
-continuance of vital movement in those directions where the obstacles to
-it are most eluded.
-
- * * * * *
-
-§ 90. Throughout the phenomena of mind the law enunciated is not so
-readily established. In a large part of them, as those of thought and
-emotion, there is no perceptible movement. Even in sensation and
-volition, which show us in one part of the body an effect produced by a
-force applied to another part, the intermediate movement is inferential
-rather than visible. Such indeed are the difficulties that it is not
-possible here to do more than briefly indicate the proofs which might be
-given did space permit.
-
-Supposing the various forces throughout an organism to be previously in
-equilibrium, then any part which becomes the seat of a further force,
-added or liberated, must be one from which the force, being resisted by
-smaller forces around, will initiate motion towards some other part of
-the organism. If elsewhere in the organism there is a point at which
-force is being expended, and which so is becoming minus a force which it
-before had, instead of plus a force which it before had not, and thus is
-made a point at which the re-action against surrounding forces is
-diminished; then, manifestly, a motion taking place between the first
-and the last of these points is a motion along the line of least
-resistance. Now a sensation implies a force added to, or evolved in,
-that part of the organism which is its seat; while a mechanical movement
-implies an expenditure or loss of force in that part of the organism
-which is its seat. Hence if, as we find to be the fact, motion is
-habitually propagated from those parts of an organism to which the
-external world adds forces in the shape of nervous impressions, to those
-parts of an organism which react on the external world through muscular
-contractions, it is simply a fulfilment of the law above enunciated.
- From this general conclusion we may pass to a more special one.
-When there is anything in the circumstances of an animal’s life,
-involving that a sensation in one particular place is habitually
-followed by a contraction in another particular place—when there is thus
-a frequently-repeated motion through the organism between these places;
-what must be the result as respects the line along which the motions
-take place? Restoration of equilibrium between the points at which the
-forces have been increased and decreased, must take place through some
-channel. If this channel is affected by the discharge—if the obstructive
-action of the tissues traversed, involves any reaction upon them,
-deducting from their obstructive power; then a subsequent motion between
-these two points will meet with less resistance along this channel than
-the previous motion met with; and will consequently take this channel
-still more decidedly. If so, every repetition will still further
-diminish the resistance offered by this route; and hence will gradually
-be formed between the two a permanent line of communication, differing
-greatly from the surrounding tissue in respect of the ease with which
-force traverses it. We see, therefore, that if between a particular
-impression and a particular motion associated with it, there is
-established a connexion producing what is called reflex action, the law
-that motion follows the line of least resistance, and that, if the
-conditions remain constant, resistance in any direction is diminished by
-motion occurring in that direction, supplies an explanation.
- Without further details it will be manifest that a like
-interpretation may be given to the succession of all other nervous
-changes. If in the surrounding world there are objects, attributes, or
-actions, that usually occur together, the effects severally produced by
-them in the organism will become so connected by those repetitions which
-we call experience, that they also will occur together. In proportion to
-the frequency with which any external connexion of phenomena is
-experienced, will be the strength of the answering internal connexion of
-nervous states. Thus there will arise all degrees of cohesion among
-nervous states, as there are all degrees of commonness among the
-surrounding co-existences and sequences that generate them: whence must
-result a general correspondence between associated ideas and associated
-actions in the environment.[13]
-
-The relation between emotions and actions may be similarly construed. As
-a first illustration let us observe what happens with emotions that are
-undirected by volitions. These, like feelings in general, expend
-themselves in generating organic changes, and chiefly in muscular
-contractions. As was pointed out in the last chapter, there result
-movements of the involuntary and voluntary muscles, that are great in
-proportion as the emotions are strong. It remains here to be pointed
-out, however, that the order in which these muscles are affected is
-explicable only on the principle above set forth. Thus, a pleasurable or
-painful state of mind of but slight intensity, does little more than
-increase the pulsations of the heart. Why? For the reason that the
-relation between nervous excitement and vascular contraction, being
-common to every genus and species of feeling, is the one of most
-frequent repetition; that hence the nervous connexion is, in the way
-above shown, the one which offers the least resistance to a discharge;
-and is therefore the one along which a feeble force produces motion. A
-sentiment or passion that is somewhat stronger, affects not only the
-heart but the muscles of the face, and especially those around the
-mouth. Here the like explanation applies; since these muscles, being
-both comparatively small, and, for purposes of speech, perpetually used,
-offer less resistance than other voluntary muscles to the nerve-motor
-force. By a further increase of emotion the respiratory and vocal
-muscles become perceptibly excited. Finally, under strong passion, the
-muscles in general of the trunk and limbs are violently contracted.
-Without saying that the facts can be thus interpreted in all their
-details (a task requiring data impossible to obtain) it may be safely
-said that the order of excitation is from muscles that are small and
-frequently acted on, to those which are larger and less frequently acted
-on. The single instance of laughter, which is an undirected discharge of
-feeling that affects first the muscles round the mouth, then those of
-the vocal and respiratory apparatus, then those of the limbs, and then
-those of the spine;[14] suffices to show that when no special route is
-opened for it, a force evolved in the nervous centres produces motion
-along channels which offer the least resistance, and if it is too great
-to escape by these, produces motion along channels offering successively
-greater resistance.
-
-Probably it will be thought impossible to extend this reasoning so as to
-include volitions. Yet we are not without evidence that the transition
-from special desires to special muscular acts, conforms to the same
-principle. It may be shown that the mental antecedents of a voluntary
-movement, are antecedents which temporarily make the line along which
-this movement takes place, the line of least resistance. For a volition,
-suggested as it necessarily is by some previous thought connected with
-it by associations that determine the transition, is itself a
-representation of the movements that are willed, and of their sequences.
-But to represent in consciousness certain of our own movements, is
-partially to arouse the sensations accompanying such movements,
-inclusive of those of muscular tension—is partially to excite the
-appropriate motor-nerves and all the other nerves implicated. That is to
-say, the volition is itself an incipient discharge along a line which
-previous experiences have rendered a line of least resistance. And the
-passing of volition into action is simply a completion of the discharge.
-
-One corollary from this must be noted before proceeding; namely, that
-the particular set of muscular movements by which any object of desire
-is reached, are movements implying the smallest total of forces to be
-overcome. As each feeling generates motion along the line of least
-resistance, it is tolerably clear that a group of feelings, constituting
-a more or less complex desire, will generate motion along a series of
-lines of least resistance. That is to say, the desired end will be
-achieved with the smallest expenditure of effort. Should it be objected
-that through want of knowledge or want of skill, a man often pursues the
-more laborious of two courses, and so overcomes a larger total of
-opposing forces than was necessary; the reply is, that relatively to his
-mental state the course he takes is that which presents the fewest
-difficulties. Though there is another which in the abstract is easier,
-yet his ignorance of it, or inability to adopt it, is, physically
-considered, the existence of an insuperable obstacle to the discharge of
-his energies in that direction. Experience obtained by himself, or
-communicated by others, has not established in him such channels of
-nervous communication as are required to make this better course the
-course of least resistance to him.
-
- * * * * *
-
-§ 91. As in individual animals, inclusive of man, motion follows lines
-of least resistance, it is to be inferred that among aggregations of
-men, the like will hold good. The changes in a society, being due to the
-joint actions of its members, the courses of such changes will be
-determined as are those of all other changes wrought by composition of
-forces.
-
-Thus when we contemplate a society as an organism, and observe the
-direction of its growth, we find this direction to be that in which the
-average of opposing forces is the least. Its units have energies to be
-expended in self-maintenance and reproduction. These energies are met by
-various environing energies that are antagonistic to them—those of
-geological origin, those of climate, of wild animals, of other human
-races with whom they are at enmity or in competition. And the tracts the
-society spreads over, are those in which there is the smallest total
-antagonism. Or, reducing the matter to its ultimate terms, we may say
-that these social units have jointly and severally to preserve
-themselves and their offspring from those inorganic and organic forces
-which are ever tending to destroy them (either indirectly by oxidation
-and by undue abstraction of heat, or directly by bodily mutilation);
-that these forces are either counteracted by others which are available
-in the shape of food, clothing, habitations, and appliances of defence,
-or are, as far as may be, eluded; and that population spreads in
-whichever directions there is the readiest escape from these forces, or
-the least exertion in obtaining the materials for resisting them, or
-both. For these reasons it happens that fertile valleys where
-water and vegetal produce abound, are early peopled. Sea-shores, too,
-supplying a large amount of easily-gathered food, are lines along which
-mankind have commonly spread. The general fact that, so far as we can
-judge from the traces left by them, large societies first appeared in
-those tropical regions where the fruits of the earth are obtainable with
-comparatively little exertion, and where the cost of maintaining bodily
-heat is but slight, is a fact of like meaning. And to these instances
-may be added the allied one daily furnished by emigration; which we see
-going on towards countries presenting the fewest obstacles to the
-self-preservation of individuals, and therefore to national growth.
- Similarly with that resistance to the movements of a society which
-neighbouring societies offer. Each of the tribes or nations inhabiting
-any region, increases in numbers until it outgrows its means of
-subsistence. In each there is thus a force ever pressing outwards on to
-adjacent areas—a force antagonized by like forces in the tribes or
-nations occupying those areas. And the ever-recurring wars that
-result—the conquests of weaker tribes or nations, and the over-running
-of their territories by the victors, are instances of social movements
-taking place in the directions of least resistance. Nor do the conquered
-peoples, when they escape extermination or enslavement, fail to show us
-movements that are similarly determined. For migrating as they do to
-less fertile regions—taking refuge in deserts or among mountains—moving
-in a direction where the resistance to social growth is comparatively
-great; they still do this only under an excess of pressure in all other
-directions: the physical obstacles to self-preservation they encounter,
-being really less than the obstacles offered by the enemies from whom
-they fly.
-
-Internal social movements may also be thus interpreted. Localities
-naturally fitted for producing particular commodities—that is,
-localities in which such commodities are got at the least cost of
-force—that is, localities in which the desires for these commodities
-meet with the least resistance; become localities especially devoted to
-the obtainment of these commodities. Where soil and climate render wheat
-a profitable crop, or a crop from which the greatest amount of
-life-sustaining power is gained by a given quantity of effort, the
-growth of wheat becomes the dominant industry. Where wheat cannot be
-economically produced, oats, or rye, or maize, or rice, or potatoes, is
-the agricultural staple. Along sea-shores men support themselves with
-least effort by catching fish; and hence choose fishing as an
-occupation. And in places that are rich in coal or metallic ores, the
-population, finding that labour devoted to the raising of these
-materials brings a larger return of food and clothing than when
-otherwise directed, becomes a population of miners. This last
-instance introduces us to the phenomena of exchange; which equally
-illustrate the general law. For the practice of barter begins as soon as
-it facilitates the fulfilment of men’s desires, by diminishing the
-exertion needed to reach the objects of those desires. When instead of
-growing his own corn, weaving his own cloth, sewing his own shoes, each
-man began to confine himself to farming, or weaving, or shoemaking; it
-was because each found it more laborious to make everything he wanted,
-than to make a great quantity of one thing and barter the surplus for
-the rest: by exchange, each procured the necessaries of life without
-encountering so much resistance. Moreover, in deciding what commodity to
-produce, each citizen was, as he is at the present day, guided in the
-same manner. For besides those local conditions which determine whole
-sections of a society towards the industries easiest for them, there are
-also individual conditions and individual aptitudes which to each
-citizen render certain occupations preferable; and in choosing those
-forms of activity which their special circumstances and faculties
-dictate, these social units are severally moving towards the objects of
-their desires in the directions which present to them the fewest
-obstacles. The process of transfer which commerce pre-supposes,
-supplies another series of examples. So long as the forces to be
-overcome in procuring any necessary of life in the district where it is
-consumed, are less than the forces to be overcome in procuring it from
-an adjacent district, exchange does not take place. But when the
-adjacent district produces it with an economy that is not out-balanced
-by cost of transit—when the distance is so small and the route so easy
-that the labour of conveyance plus the labour of production is less than
-the labour of production in the consuming district, transfer commences.
-Movement in the direction of least resistance is also seen in the
-establishment of the channels along which intercourse takes place. At
-the outset, when goods are carried on the backs of men and horses, the
-paths chosen are those which combine shortness with levelness and
-freedom from obstacles—those which are achieved with the smallest
-exertion. And in the subsequent formation of each highway, the course
-taken is that which deviates horizontally from a straight line so far
-only as is needful to avoid vertical deviations entailing greater labour
-in draught. The smallest total of obstructive forces determines the
-route, even in seemingly exceptional cases; as where a detour is made to
-avoid the opposition of a landowner. All subsequent improvements, ending
-in macadamized roads, canals, and railways, which reduce the antagonism
-of friction and gravity to a minimum, exemplify the same truth. After
-there comes to be a choice of roads between one point and another, we
-still see that the road chosen is that along which the cost of transit
-is the least: cost being the measure of resistance. Even where, time
-being a consideration, the more expensive route is followed, it is so
-because the loss of time involves loss of force. When, division of
-labour having been carried to a considerable extent and means of
-communication made easy, there arises a marked localization of
-industries, the relative growths of the populations devoted to them may
-be interpreted on the same principle. The influx of people to each
-industrial centre, as well as the rate of multiplication of those
-already inhabiting it, is determined by the payment for labour; that
-is—by the quantity of commodities which a given amount of effort will
-obtain. To say that artisans flock to places where, in consequence of
-facilities for production, an extra proportion of produce can be given
-in the shape of wages; is to say that they flock to places where there
-are the smallest obstacles to the support of themselves and families.
-Hence, the rapid increase of number which occurs in such places, is
-really a social growth at points where the opposing forces are the
-least.
-
-Nor is the law less clearly to be traced in those functional changes
-daily going on. The flow of capital into businesses yielding the largest
-returns; the buying in the cheapest market and selling in the dearest;
-the introduction of more economical modes of manufacture; the
-development of better agencies for distribution; and all those
-variations in the currents of trade that are noted in our newspapers and
-telegrams from hour to hour; exhibit movement taking place in directions
-where it is met by the smallest total of opposing forces. For if we
-analyze each of these changes—if instead of interest on capital we read
-surplus of products which remains after maintenance of labourers; if we
-so interpret large interest or large surplus to imply labour expended
-with the greatest results; and if labour expended with the greatest
-results means muscular action so directed as to evade obstacles as far
-as possible; we see that all these commercial phenomena are complicated
-motions set up along lines of least resistance.
-
-Objections of two opposite kinds will perhaps be made to these
-sociological applications of the law. By some it may be said that the
-term force as here used, is used metaphorically—that to speak of men as
-_impelled_ in certain directions by certain desires, is a figure of
-speech and not the statement of a physical fact. The reply is, that the
-foregoing illustrations are to be interpreted literally, and that the
-processes described _are_ physical ones. The pressure of hunger is an
-actual force—a sensation implying some state of nervous tension; and the
-muscular action which the sensation prompts is really a discharge of it
-in the shape of bodily motion—a discharge which, on analyzing the mental
-acts involved, will be found to follow lines of least resistance. Hence
-the motions of a society whose members are impelled by this or any other
-desire, are actually, and not metaphorically, to be understood in the
-manner shown. An opposite objection may possibly be, that the
-several illustrations given are elaborated truisms; and that the law of
-direction of motion being once recognized, the fact that social
-movements, in common with all others, must conform to it, follows
-inevitably. To this it may be rejoined, that a mere abstract assertion
-that social movements must do this, would carry no conviction to the
-majority; and that it is needful to show _how_ they do it. For social
-evolution to be interpreted after the method proposed, it is requisite
-that such generalisations as those of political economy shall be reduced
-to equivalent propositions expressed in terms of force and motion.
-
-Social movements of these various orders severally conform to the two
-derivative principles named at the outset. In the first place we may
-observe how, once set up in given directions, such movements, like all
-others, tend to continue in these directions. A commercial mania or
-panic, a current of commodities, a social custom, a political agitation,
-or a popular delusion, maintains its course for a long time after its
-original source has ceased; and requires antagonistic forces to arrest
-it. In the second place it is to be noted that in proportion to the
-complexity of social forces is the tortuousness of social movements. The
-involved series of muscular contractions gone through by the artizan,
-that he may get the wherewithal to buy a loaf lying at the baker’s next
-door, show us how extreme becomes the indirectness of motion when the
-agencies at work become very numerous—a truth still better illustrated
-by the more public social actions; as those which end in bringing a
-successful man of business, towards the close of his life, into
-parliament.
-
- * * * * *
-
-§ 92. And now of the general truth set forth in this chapter, as of that
-dealt with in the last, let us ask—what is our ultimate evidence? Must
-we accept it simply as an empirical generalization? or is it to be
-established as a corollary from a still deeper truth? The reader will
-anticipate the answer. We shall find it deducible from that datum of
-consciousness which underlies all science.
-
-Suppose several tractive forces, variously directed, to be acting on a
-given body. By what is known among mathematicians as the composition of
-forces, there may be found for any two of these, a single force of such
-amount and direction as to produce on the body an exactly equal effect.
-If in the direction of each of them there be drawn a straight line, and
-if the lengths of these two straight lines be made proportionate to the
-amounts of the forces; and if from the end of each line there be drawn a
-line parallel to the other, so as to complete a parallelogram; then the
-diagonal of this parallelogram represents the amount and direction of a
-force that is equivalent to the two. Such a resultant force, as it is
-called, may be found for any pair of forces throughout the group.
-Similarly, for any pair of such resultants a single resultant may be
-found. And by repeating this course, all of them may be reduced to two.
-If these two are equal and opposite—that is, if there is no line of
-greatest traction, motion does not take place. If they are opposite but
-not equal, motion takes place in the direction of the greater. And if
-they are neither equal nor opposite, motion takes place in the direction
-of their resultant. For in either of these cases there is an
-unantagonized force in one direction. And this residuary force that is
-not neutralized by an opposing one, must move the body in the direction
-in which it is acting. To assert the contrary is to assert that a force
-can be expended without effect—without generating an equivalent force;
-and by so implying that force can cease to exist, this involves a denial
-of the persistence of force. It needs scarcely be added that if in
-place of tractions we take resistances, the argument equally holds; and
-that it holds also where both tractions and resistances are concerned.
-Thus the law that motion follows the line of greatest traction, or the
-line of least resistance, or the resultant of the two, is a necessary
-deduction from that primordial truth which transcends proof.
-
-Reduce the proposition to its simplest form, and it becomes still more
-obviously consequent on the persistence of force. Suppose two weights
-suspended over a pulley or from the ends of an equal-armed lever; or
-better still—suppose two men pulling against each other. In such cases
-we say that the heavier weight will descend, and that the stronger man
-will draw the weaker towards him. But now, if we are asked how we know
-which is the heavier weight or the stronger man; we can only reply that
-it is the one producing motion in the direction of its pull. Our only
-evidence of excess of force is the movement it produces. But if of two
-opposing tractions we can know one as greater than the other only by the
-motion it generates in its own direction, then the assertion that motion
-occurs in the direction of greatest traction is a truism. When, going a
-step further back, we seek a warrant for the assumption that of the two
-conflicting forces, that is the greater which produces motion in its own
-direction, we find no other than the consciousness that such part of the
-greater force as is unneutralized by the lesser, must produce its
-effect—the consciousness that this residuary force cannot disappear, but
-must manifest itself in some equivalent change—the consciousness that
-force is persistent. Here too, as before, it may be remarked that
-no amount of varied illustrations, like those of which this chapter
-mainly consists, can give greater certainty to the conclusion thus
-immediately drawn from the ultimate datum of consciousness. For in all
-cases, as in the simple ones just given, we can identify the greatest
-force only by the resulting motion. It is impossible for us ever to get
-evidence of the occurrence of motion in any other direction than that of
-the greatest force; since our measure of relative greatness among forces
-is their relative power of generating motion. And clearly, while the
-comparative greatness of forces is thus determined, no multiplication of
-instances can add certainty to a law of direction of movement which
-follows immediately from the persistence of force.
-
-From this same primordial truth, too, may be deduced the principle that
-motion once set up along any line, becomes itself a cause of subsequent
-motion along that line. The mechanical axiom that, if left to itself,
-matter moving in any direction will continue in that direction with
-undiminished velocity, is but an indirect assertion of the persistence
-of force; since it is an assertion that the force manifested in the
-transfer of a body along a certain length of a certain line in a certain
-time, cannot disappear without producing some equal manifestation—a
-manifestation which, in the absence of conflicting forces, must be a
-further transfer in the same direction at the same velocity. In
-the case of matter traversing matter the like inference is necessitated.
-Here indeed the actions are much more complicated. A liquid that follows
-a certain channel through or over a solid, as water along the Earth’s
-surface, loses part of its motion in the shape of heat, through friction
-and collision with the matters forming its bed. A further amount of its
-motion may be absorbed in overcoming forces which it liberates; as when
-it loosens a mass which falls into, and blocks up, its channel. But
-after these deductions by transformation into other modes of force, any
-further deduction from the motion of the water is at the expense of a
-reaction on the channel, which by so much diminishes its obstructive
-power: such reaction being shown in the motion acquired by the detached
-portions which are carried away. The cutting out of river-courses is a
-perpetual illustration of this truth. Still more involved is the
-case of motion passing through matter by impulse from part to part; as a
-nervous discharge through animal tissue. Some chemical change may be
-wrought along the route traversed, which may render it less fit than
-before for conveying a current. Or the motion may itself be in part
-metamorphosed into some obstructive form of force; as in metals, the
-conducting power of which is, for the time, decreased by the heat which
-the passage of electricity itself generates. The real question is,
-however, what structural modification, if any, is produced throughout
-the matter traversed, apart from _incidental_ disturbing forces—apart
-from everything but the _necessary_ resistance of the matter: that,
-namely, which results from the inertia of its units. If we confine our
-attention to that part of the motion which, escaping transformation,
-continues its course, then it is a corollary from the persistence of
-force that as much of this remaining motion as is taken up in changing
-the positions of the units, must leave these by so much less able to
-obstruct subsequent motion in the same direction.
-
-Thus in all the changes heretofore and at present displayed by the Solar
-System; in all those that have gone on and are still going on in the
-Earth’s crust; in all processes of organic development and function; in
-all mental actions and the effects they work on the body; and in all
-modifications of structure and activity in societies; the implied
-movements are of necessity determined in the manner above set forth.
-Every alteration in the arrangement of parts, constituting Evolution
-under each of its phases, must conform to this universal principle.
-Wherever we see motion, its direction must be that of the greatest
-force. And wherever we see the greatest force to be acting in a given
-direction, in that direction motion must ensue.
-
------
-
-Footnote 13:
-
- This paragraph is a re-statement, somewhat amplified, of an idea set
- forth in the _Medico-Chirurgical Review_ for January, 1859 (pp. 189
- and 190); and contains the germ of the intended fifth part of the
- _Principles of Psychology_, which was withheld for the reasons given
- in the preface to that work.
-
-Footnote 14:
-
- For details see a paper on “The Physiology of Laughter,” published in
- _Macmillan’s Magazine_ for March 1860.
-
-
-
-
- CHAPTER XI.
- THE RHYTHM OF MOTION.
-
-
-§ 93. When the pennant of a vessel lying becalmed first shows the coming
-breeze, it does so by gentle undulations that travel from its fixed to
-its free end. Presently the sails begin to flap; and their blows against
-the mast increase in rapidity as the breeze rises. Even when, being
-fully bellied out, they are in great part steadied by the strain of the
-yards and cordage, their free edges tremble with each stronger gust. And
-should there come a gale, the jar that is felt on laying hold of the
-shrouds shows that the rigging vibrates; while the rush and whistle of
-the wind prove that in it, also, rapid undulations are generated. Ashore
-the conflict between the current of air and the things it meets results
-in a like rhythmical action. The leaves all shiver in the blast; each
-branch oscillates; and every exposed tree sways to and fro. The blades
-of grass and dried bents in the meadows, and still better the stalks in
-the neighbouring corn-fields, exhibit the same rising and falling
-movement. Nor do the more stable objects fail to do the like, though in
-a less manifest fashion; as witness the shudder that may be felt
-throughout a house during the paroxysms of a violent storm.
- Streams of water produce in opposing objects the same general
-effects as do streams of air. Submerged weeds growing in the middle of a
-brook, undulate from end to end. Branches brought down by the last
-flood, and left entangled at the bottom where the current is rapid, are
-thrown into a state of up and down movement that is slow or quick in
-proportion as they are large or small; and where, as in great rivers
-like the Mississippi, whole trees are thus held, the name “sawyers,” by
-which they are locally known, sufficiently describes the rhythm produced
-in them. Note again the effect of the antagonism between the current and
-its channel. In shallow places, where the action of the bottom on the
-water flowing over it is visible, we see a ripple produced—a series of
-undulations. And if we study the action and re-action going on between
-the moving fluid and its banks, we still find the principle illustrated,
-though in a different way. For in every rivulet, as in the mapped-out
-course of every great river, the bends of the stream from side to side
-throughout its tortuous course constitute a lateral undulation—an
-undulation so inevitable that even an artificially straightened channel
-is eventually changed into a serpentine one. Analogous phenomena may be
-observed where the water is stationary and the solid matter moving. A
-stick drawn laterally through the water with much force, proves by the
-throb which it communicates to the hand that it is in a state of
-vibration. Even where the moving body is massive, it only requires that
-great force should be applied to get a sensible effect of like kind:
-instance the screw of a screw-steamer, which instead of a smooth
-rotation falls into a rapid rhythm that sends a tremor through the whole
-vessel. The sound which results when a bow is drawn over a
-violin-string, shows us vibrations produced by the movement of a solid
-over a solid. In lathes and planing machines, the attempt to take off a
-thick shaving causes a violent jar of the whole apparatus, and the
-production of a series of waves on the iron or wood that is cut. Every
-boy in scraping his slate-pencil finds it scarcely possible to help
-making a ridged surface. If you roll a ball along the ground or over the
-ice, there is always more or less up and down movement—a movement that
-is visible while the velocity is considerable, but becomes too small and
-rapid to be seen by the unaided eye as the velocity diminishes. However
-smooth the rails, and however perfectly built the carriages, a
-railway-train inevitably gets into oscillations, both lateral and
-vertical. Even where moving matter is suddenly arrested by collision,
-the law is still illustrated; for both the body striking and the body
-struck are made to tremble; and trembling is rhythmical movement. Little
-as we habitually observe it, it is yet certain that the impulses our
-actions impress from moment to moment on surrounding objects, are
-propagated through them in vibrations. It needs but to look through a
-telescope of high power, to be convinced that each pulsation of the
-heart gives a jar to the whole room. If we pass to motions of
-another order—those namely which take place in the etherial medium—we
-still find the same thing. Every fresh discovery confirms the hypothesis
-that light consists of undulations. The rays of heat, too, are now found
-to have a like fundamental nature; their undulations differing from
-those of light only in their comparative length. Nor do the movements of
-electricity fail to furnish us with an illustration; though one of a
-different order. The northern aurora may often be observed to pulsate
-with waves of greater brightness; and the electric discharge through a
-vacuum shows us by its stratified appearance that the current is not
-uniform, but comes in gushes of greater and lesser intensity.
- Should it be said that at any rate there are some motions, as
-those of projectiles, which are not rhythmical, the reply is, that the
-exception is apparent only; and that these motions would be rhythmical
-if they were not interrupted. It is common to assert that the trajectory
-of a cannon ball is a parabola; and it is true that (omitting
-atmospheric resistance) the curve described differs so slightly from a
-parabola that it may practically be regarded as one. But, strictly
-speaking, it is a portion of an extremely eccentric ellipse, having the
-Earth’s centre of gravity for its remoter focus; and but for its arrest
-by the substance of the Earth, the cannon ball would travel round that
-focus and return to the point whence it started; again to repeat this
-slow rhythm. Indeed, while seeming at first sight to do the reverse, the
-discharge of a cannon furnishes one of the best illustrations of the
-principle enunciated. The explosion produces violent undulations in the
-surrounding air. The whizz of the shot, as it flies towards its mark, is
-due to another series of atmospheric undulations. And the movement to
-and from the Earth’s centre, which the cannon ball is beginning to
-perform, being checked by solid matter, is transformed into a rhythm of
-another order; namely, the vibration which the blow sends through
-neighbouring bodies.[15]
-
-Rhythm is very generally not simple but compound. There are usually at
-work various forces, causing undulations differing in rapidity; and
-hence it continually happens that besides the primary rhythms there are
-secondary rhythms, produced by the periodic coincidence and antagonism
-of the primary ones. Double, triple, and even quadruple rhythms, are
-thus generated. One of the simplest instances is afforded by what in
-acoustics are known as “beats:” recurring intervals of sound and silence
-which are perceived when two notes of nearly the same pitch are struck
-together; and which are due to the alternate correspondence and
-antagonism of the atmospheric waves. In like manner the various
-phenomena due to what is called interference of light, severally result
-from the periodic agreement and disagreement of etherial
-undulations—undulations which, by alternately intensifying and
-neutralizing each other, produce intervals of increased and diminished
-light. On the sea-shore may be noted sundry instances of compound
-rhythm. We have that of the tides, in which the daily rise and fall
-undergoes a fortnightly increase and decrease, due to the alternate
-coincidence and antagonism of the solar and lunar attractions. We have
-again that which is perpetually furnished by the surface of the sea:
-every large wave bearing smaller ones on its sides, and these still
-smaller ones; with the result that each flake of foam, along with the
-portion of water bearing it, undergoes minor ascents and descents of
-several orders while it is being raised and lowered by the greater
-billows. A quite different and very interesting example of compound
-rhythm, occurs in the little rills which, at low tide, run over the sand
-out of the shingle banks above. Where the channel of one of these is
-narrow, and the stream runs strongly, the sand at the bottom is raised
-into a series of ridges corresponding to the ripple of the water. On
-watching for a short time, it will be seen that these ridges are being
-raised higher and the ripple growing stronger; until at length, the
-action becoming violent, the whole series of ridges is suddenly swept
-away, the stream runs smoothly, and the process commences afresh.
-Instances of still more complex rhythms might be added; but they will
-come more appropriately in connexion with the several forms of
-Evolution, hereafter to be dealt with.
-
-From the ensemble of the facts as above set forth, it will be seen that
-rhythm results wherever there is a conflict of forces not in
-equilibrium. If the antagonist forces at any point are balanced, there
-is rest; and in the absence of motion there can of course be no rhythm.
-But if instead of a balance there is an excess of force in one
-direction—if, as necessarily follows, motion is set up in that
-direction; then for that motion to continue uniformly in that direction,
-it is requisite that the moving matter should, notwithstanding its
-unceasing change of place, present unchanging relations to the sources
-of force by which its motion is produced and opposed. This however is
-impossible. Every further transfer through space must alter the ratio
-between the forces concerned—must increase or decrease the predominance
-of one force over the other—must prevent uniformity of movement. And if
-the movement cannot be uniform, then, in the absence of acceleration or
-retardation continued through infinite time and space, (results which
-cannot be conceived) the only alternative is rhythm.
-
-A secondary conclusion must not be omitted. In the last chapter we saw
-that motion is never absolutely rectilinear; and here it remains to be
-added that, as a consequence, rhythm is necessarily incomplete. A truly
-rectilinear rhythm can arise only when the opposing forces are in
-exactly the same line; and the probabilities against this are infinitely
-great. To generate a perfectly circular rhythm, the two forces concerned
-must be exactly at right angles to each other, and must have exactly a
-certain ratio; and against this the probabilities are likewise
-infinitely great. All other proportions and directions of the two forces
-will produce an ellipse of greater or less eccentricity. And when, as
-indeed always happens, above two forces are engaged, the curve described
-must be more complex; and cannot exactly repeat itself. So that in fact
-throughout nature, this action and re-action of forces never brings
-about a complete return to a previous state. Where the movement is very
-involved, and especially where it is that of some aggregate whose units
-are partially independent, anything like a regular curve is no longer
-traceable; we see nothing more than a general oscillation. And on the
-completion of any periodic movement, the degree in which the state
-arrived at differs from the state departed from, is usually marked in
-proportion as the influences at work are numerous.
-
- * * * * *
-
-§ 94. That spiral arrangement so general among the more diffused
-nebulæ—an arrangement which must be assumed by matter moving towards a
-centre of gravity through a resisting medium—shows us the progressive
-establishment of revolution, and therefore of rhythm; in those remote
-spaces which the nebulæ occupy. Double stars, moving round common
-centres of gravity in periods some of which are now ascertained, exhibit
-settled rhythmical actions in distant parts of our sidereal system. And
-another fact which, though of a different order, has a like general
-significance, is furnished by variable stars—stars which alternately
-brighten and fade.
-
-The periodicities of the planets, satellites, and comets, are so
-familiar that it would be inexcusable to name them, were it not needful
-here to point out that they are so many grand illustrations of this
-general law of movement. But besides the revolutions of these bodies in
-their orbits (all more or less excentric) and their rotations on their
-axes, the Solar System presents us with various rhythms of a less
-manifest and more complex kind. In each planet and satellite there is
-the revolution of the nodes—a slow change in the position of the
-orbit-plane, which after completing itself commences afresh. There is
-the gradual alteration in the length of the axis major of the orbit; and
-also of its excentricity: both of which are rhythmical alike in the
-sense that they alternate between maxima and minima, and in the sense
-that the progress from one extreme to the other is not uniform, but is
-made with fluctuating velocity. Then, too, there is the revolution of
-the line of apsides, which in course of time moves round the heavens—not
-regularly, but through complex oscillations. And further we have
-variations in the directions of the planetary axes—that known as
-nutation, and that larger gyration which, in the case of the Earth,
-causes the precession of the equinoxes. These rhythms, already
-more or less compound, are compounded with each other. Such an instance
-as the secular acceleration and retardation of the moon, consequent on
-the varying excentricity of the Earth’s orbit, is one of the simplest.
-Another, having more important consequences, results from the changing
-direction of the axes of rotation in planets whose orbits are decidedly
-excentric. Every planet, during a certain long period, presents more of
-its northern than of its southern hemisphere to the sun at the time of
-its nearest approach to him; and then again, during a like period,
-presents more of its southern hemisphere than of its northern—a
-recurring coincidence which, though causing in some planets no sensible
-alterations of climate, involves in the case of the Earth an epoch of
-21,000 years, during which each hemisphere goes through a cycle of
-temperate seasons, and seasons that are extreme in their heat and cold.
-Nor is this all. There is even a variation of this variation. For the
-summers and winters of the whole Earth become more or less strongly
-contrasted, as the excentricity of its orbit increases and decreases.
-Hence during increase of the excentricity, the epochs of moderately
-contrasted seasons and epochs of strongly contrasted seasons, through
-which alternately each hemisphere passes, must grow more and more
-different in the degrees of their contrasts; and contrariwise during
-decrease of the excentricity. So that in the quantity of light and heat
-which any portion of the Earth receives from the sun, there goes on a
-quadruple rhythm: that of day and night; that of summer and winter; that
-due to the changing position of the axis at perihelion and aphelion,
-taking 21,000 years to complete; and that involved by the variation of
-the orbit’s excentricity, gone through in millions of years.
-
- * * * * *
-
-§ 95. Those terrestrial processes whose dependence on the solar heat is
-direct, of course exhibit a rhythm that corresponds to the periodically
-changing amount of heat which each part of the Earth receives. The
-simplest, though the least obtrusive, instance is supplied by the
-magnetic variations. In these there is a diurnal increase and decrease,
-an annual increase and decrease, and a decennial increase and decrease;
-the latter answering to a period during which the solar spots become
-alternately abundant and scarce: besides which known variations there
-are probably others corresponding with the astronomical cycles just
-described. More obvious examples are furnished by the movements of the
-ocean and the atmosphere. Marine currents from the equator to the poles
-above, and from the poles to the equator beneath, show us an unceasing
-backward and forward motion throughout this vast mass of water—a motion
-varying in amount according to the seasons, and compounded with smaller
-like motions of local origin. The similarly-caused general currents in
-the air, have similar annual variations similarly modified. Irregular as
-they are in detail, we still see in the monsoons and other tropical
-atmospheric disturbances, or even in our own equinoctial gales and
-spring east winds, a periodicity sufficiently decided. Again, we
-have an alternation of times during which evaporation predominates with
-times during which condensation predominates: shown in the tropics by
-strongly marked rainy seasons and seasons of drought, and in the
-temperate zones by corresponding changes of which the periodicity,
-though less definite, is still traceable. The diffusion and
-precipitation of water, besides the slow alternations answering to
-different parts of the year, furnish us with examples of rhythm of a
-more rapid kind. During wet weather, lasting, let us say, over some
-weeks, the tendency to condense, though greater than the tendency to
-evaporate, does not show itself in continuous rain; but the period is
-made up of rainy days and days that are wholly or partially fair. Nor is
-it in this rude alternation only that the law is manifested. During any
-day throughout this wet weather a minor rhythm is traceable; and
-especially so when the tendencies to evaporate and to condense are
-nearly balanced. Among mountains this minor rhythm and its causes may be
-studied to great advantage. Moist winds, which do not precipitate their
-contained water in passing over the comparatively warm lowlands, lose so
-much heat when they reach the cold mountain peaks, that condensation
-rapidly takes place. Water, however, in passing from the gaseous to the
-fluid state, gives out a considerable amount of heat; and hence the
-resulting clouds are warmer than the air that precipitates them, and
-much warmer than the high rocky surfaces round which they fold
-themselves. Hence in the course of the storm, these high rocky surfaces
-are raised in temperature, partly by radiation from the enwrapping
-cloud, partly by contact of the falling rain-drops. Giving off more heat
-than before, they no longer lower so greatly the temperature of the air
-passing over them; and so cease to precipitate its contained water. The
-clouds break; the sky begins to clear; and a gleam of sunshine promises
-that the day is going to be fine. But the small supply of heat which the
-cold mountain’s sides have received, is soon lost: especially when the
-dispersion of the clouds permits free radiation into space. Very soon,
-therefore, these elevated surfaces, becoming as cold as at first, (or
-perhaps even colder in virtue of the evaporation set up,) begin again to
-condense the vapour in the air above; and there comes another storm,
-followed by the same effects as before. In lowland regions this action
-and reaction is usually less conspicuous, because the contrast of
-temperatures is less marked. Even here, however, it may be traced; and
-that not only on showery days, but on days of continuous rain; for in
-these we do not see uniformity: always there are fits of harder and
-gentler rain that are probably caused as above explained.
-
-Of course these meteorologic rhythms involve something corresponding to
-them in the changes wrought by wind and water on the Earth’s surface.
-Variations in the quantities of sediment brought down by rivers that
-rise and fall with the seasons, must cause variations in the resulting
-strata—alternations of colour or quality in the successive laminæ. Beds
-formed from the detritus of shores worn down and carried away by the
-waves, must similarly show periodic differences answering to the
-periodic winds of the locality. In so far as frost influences the rate
-of denudation, its recurrence is a factor in the rhythm of sedimentary
-deposits. And the geological changes produced by glaciers and icebergs
-must similarly have their alternating periods of greater and less
-intensity.
-
-There is evidence also that modifications in the Earth’s crust due to
-igneous action have a certain periodicity. Volcanic eruptions are not
-continuous but intermittent, and as far as the data enable us to judge,
-have a certain average rate of recurrence; which rate of recurrence is
-complicated by rising into epochs of greater activity and falling into
-epochs of comparative quiescence. So too is it with earthquakes and the
-elevations or depressions caused by them. At the mouth of the
-Mississippi, the alternation of strata gives decisive proof of
-successive sinkings of the surface, that have taken place at tolerably
-equal intervals. Everywhere, in the extensive groups of conformable
-strata that imply small subsidences recurring with a certain average
-frequency, we see a rhythm in the action and reaction between the
-Earth’s crust and its molten contents—a rhythm compounded with those
-slower ones shown in the termination of groups of strata, and the
-commencement of other groups not conformable to them. There is
-even reason for suspecting a geological periodicity that is immensely
-slower and far wider in its effects; namely, an alternation of those
-vast upheavals and submergencies by which continents are produced where
-there were oceans, and oceans where there were continents. For
-supposing, as we may fairly do, that the Earth’s crust is throughout of
-tolerably equal thickness, it is manifest that such portions of it as
-become most depressed below the average level, must have their inner
-surfaces most exposed to the currents of molten matter circulating
-within, and will therefore undergo a larger amount of what may be called
-igneous denudation; while, conversely, the withdrawal of the inner
-surfaces from these currents where the Earth’s crust is most elevated,
-will cause a thickening more or less compensating the aqueous denudation
-going on externally. Hence those depressed areas over which the deepest
-oceans lie, being gradually thinned beneath and not covered by much
-sedimentary deposit above, will become areas of least resistance, and
-will then begin to yield to the upward pressure of the Earth’s contents;
-whence will result, throughout such areas, long-continued elevations,
-ceasing only when the reverse state of things has been brought about.
-Whether this speculation be well or ill founded, does not however affect
-the general conclusion. Apart from it we have sufficient evidence that
-geologic processes are rhythmical.
-
- * * * * *
-
-§ 96. Perhaps nowhere are the illustrations of rhythm so numerous and so
-manifest as among the phenomena of life. Plants do not, indeed, usually
-show us any decided periodicities, save those determined by day and
-night and by the seasons. But in animals we have a great variety of
-movements in which the alternation of opposite extremes goes on with all
-degrees of rapidity. The swallowing of food is effected by a wave of
-constriction passing along the œsophagus; its digestion is accompanied
-by a muscular action of the stomach that is also undulatory; and the
-peristaltic motion of the intestines is of like nature. The blood
-obtained from this food is propelled not in a uniform current but in
-pulses; and it is aerated by lungs that alternately contract and expand.
-All locomotion results from oscillating movements: even where it is
-apparently continuous, as in many minute forms, the microscope proves
-the vibration of cilia to be the agency by which the creature is moved
-smoothly forwards.
-
-Primary rhythms of the organic actions are compounded with secondary
-ones of longer duration. These various modes of activity have their
-recurring periods of increase and decrease. We see this in the periodic
-need for food, and in the periodic need for repose. Each meal induces a
-more rapid rhythmic action of the digestive organs; the pulsation of the
-heart is accelerated; and the inspirations become more frequent. During
-sleep, on the contrary, these several movements slacken. So that in the
-course of the twenty-four hours, those small undulations of which the
-different kinds of organic action are constituted, undergo one long wave
-of increase and decrease, complicated with several minor waves.
- Experiments have shown that there are still slower rises and falls
-of functional activity. Waste and assimilation are not balanced by every
-meal, but one or other maintains for some time a slight excess; so that
-a person in ordinary health is found to undergo an increase and decrease
-of weight during recurring intervals of tolerable equality. Besides
-these regular periods there are still longer and comparatively irregular
-ones; namely, those alternations of greater and less vigour, which even
-healthy people experience. So inevitable are these oscillations that
-even men in training cannot be kept stationary at their highest power,
-but when they have reached it begin to retrograde. Further
-evidence of rhythm in the vital movements is furnished by invalids.
-Sundry disorders are named from the intermittent character of their
-symptoms. Even where the periodicity is not very marked, it is mostly
-traceable. Patients rarely if ever get uniformly worse; and
-convalescents have usually their days of partial relapse or of less
-decided advance.
-
-Aggregates of living creatures illustrate the general truth in other
-ways. If each species of organism be regarded as a whole, it displays
-two kinds of rhythm. Life as it exists in all the members of such
-species, is an extremely complex kind of movement, more or less distinct
-from the kinds of movement which constitutes life in other species. In
-each individual of the species, this extremely complex kind of movement
-begins, rises to its climax, declines, and ceases in death. And every
-successive generation thus exhibits a wave of that peculiar activity
-characterizing the species as a whole. The other form of rhythm is
-to be traced in that variation of number which each tribe of animals and
-plants is ever undergoing. Throughout the unceasing conflict between the
-tendency of a species to increase and the antagonistic tendencies, there
-is never an equilibrium: one always predominates. In the case even of a
-cultivated plant or domesticated animal, where artificial means are used
-to maintain the supply at a uniform level, we still see that
-oscillations of abundance and scarcity cannot be avoided. And among the
-creatures uncared for by man, such oscillations are usually more marked.
-After a race of organisms has been greatly thinned by enemies or lack of
-food, its surviving members become more favourably circumstanced than
-usual. During the decline in their numbers their food has grown
-relatively more abundant; while their enemies have diminished from want
-of prey. The conditions thus remain for some time favourable to their
-increase; and they multiply rapidly. By and by their food is rendered
-relatively scarce, at the same time that their enemies have become more
-numerous; and the destroying influences being thus in excess, their
-number begins to diminish again. Yet one more rhythm, extremely
-slow in its action, may be traced in the phenomena of Life, contemplated
-under their most general aspect. The researches of palæontologists show,
-that there have been going on, during the vast period of which our
-sedimentary rocks bear record, successive changes of organic forms.
-Species have appeared, become abundant, and then disappeared. Genera, at
-first constituted of but few species, have for a time gone on growing
-more multiform; and then have begun to decline in the number of their
-subdivisions; leaving at last but one or two representatives, or none at
-all. During longer epochs whole orders have thus arisen, culminated, and
-dwindled away. And even those wider divisions containing many orders
-have similarly undergone a gradual rise, a high tide, and a
-long-continued ebb. The stalked _Crinoidea_, for example, which, during
-the carboniferous epoch, became abundant, have almost disappeared: only
-a single species being extant. Once a large family of molluscs, the
-_Brachiopoda_ have now become rare. The shelled Cephalopods, at one time
-dominant among the inhabitants of the ocean, both in number of forms and
-of individuals, are in our day nearly extinct. And after an “age of
-reptiles,” there has come an age in which reptiles have been in great
-measure supplanted by mammals. Whether these vast rises and falls of
-different kinds of life ever undergo anything approaching to
-repetitions, (which they may possibly do in correspondence with those
-vast cycles of elevation and subsidence that produce continents and
-oceans,) it is sufficiently clear that Life on the Earth has not
-progressed uniformly, but in immense undulations.
-
- * * * * *
-
-§ 97. It is not manifest that the changes of consciousness are in any
-sense rhythmical. Yet here, too, analysis proves both that the mental
-state existing at any moment is not uniform, but is decomposable into
-rapid oscillations; and also that mental states pass through longer
-intervals of increasing and decreasing intensity.
-
-Though while attending to any single sensation, or any group of related
-sensations constituting the consciousness of an object, we seem to
-remain for the time in a persistent and homogeneous condition of mind, a
-careful self-examination shows that this apparently unbroken mental
-state is in truth traversed by a number of minor states, in which
-various other sensations and perceptions are rapidly presented and
-disappear. From the admitted fact that thinking consists in the
-establishment of relations, it is a necessary corollary that the
-maintenance of consciousness in any one state to the entire exclusion of
-other states, would be a cessation of thought, that is, of
-consciousness. So that any seemingly continuous feeling, say of
-pressure, really consists of portions of that feeling perpetually
-recurring after the momentary intrusion of other feelings and
-ideas—quick thoughts concerning the place where it is felt, the external
-object producing it, its consequences, and other things suggested by
-association. Thus there is going on an extremely rapid departure from,
-and return to, that particular mental state which we regard as
-persistent. Besides the evidence of rhythm in consciousness which direct
-analysis thus affords, we may gather further evidence from the
-correlation between feeling and movement. Sensations and emotions expend
-themselves in producing muscular contractions. If a sensation or emotion
-were strictly continuous, there would be a continuous discharge along
-those motor nerves acted upon. But so far as experiments with artificial
-stimuli enable us to judge, a continuous discharge along the nerve
-leading to a muscle, does not contract it: a broken discharge is
-required—a rapid succession of shocks. Hence muscular contraction
-pre-supposes that rhythmic state of consciousness which direct
-observation discloses. A much more conspicuous rhythm, having
-longer waves, is seen during the outflow of emotion into dancing,
-poetry, and music. The current of mental energy that shows itself in
-these modes of bodily action, is not continuous, but falls into a
-succession of pulses. The measure of a dance is produced by the
-alternation of strong muscular contractions with weaker ones; and, save
-in measures of the simplest order such as are found among barbarians and
-children, this alternation is compounded with longer rises and falls in
-the degree of muscular excitement. Poetry is a form of speech which
-results when the emphasis is regularly recurrent; that is, when the
-muscular effort of pronunciation has definite periods of greater and
-less intensity—periods that are complicated with others of like nature
-answering to the successive verses. Music, in still more various ways,
-exemplifies the law. There are the recurring bars, in each of which
-there is a primary and a secondary beat. There is the alternate increase
-and decrease of muscular strain, implied by the ascents and descents to
-the higher and lower notes—ascents and descents composed of smaller
-waves, breaking the rises and falls of the larger ones, in a mode
-peculiar to each melody. And then we have, further, the alternation of
-_piano_ and _forte_ passages. That these several kinds of rhythm,
-characterizing æsthetic expression, are not, in the common sense of the
-word, artificial, but are intenser forms of an undulatory movement
-habitually generated by feeling in its bodily discharge, is shown by the
-fact that they are all traceable in ordinary speech; which in every
-sentence has its primary and secondary emphases, and its cadence
-containing a chief rise and fall complicated with subordinate rises and
-falls; and which is accompanied by a more or less oscillatory action of
-the limbs when the emotion is great. Still longer undulations may
-be observed by every one, in himself and in others, on occasions of
-extreme pleasure or extreme pain. Note, in the first place, that pain
-having its origin in bodily disorder, is nearly always perceptibly
-rhythmical. During hours in which it never actually ceases, it has its
-variations of intensity—fits or paroxysms; and then after these hours of
-suffering there usually come hours of comparative ease. Moral pain has
-the like smaller and larger waves. One possessed by intense grief does
-not utter continuous moans, or shed tears with an equable rapidity; but
-these signs of passion come in recurring bursts. Then after a time
-during which such stronger and weaker waves of emotion alternate, there
-comes a calm—a time of comparative deadness; to which again succeeds
-another interval, when dull sorrow rises afresh into acute anguish, with
-its series of paroxysms. Similarly in great delight, especially as
-manifested by children who have its display less under control, there
-are visible variations in the intensity of feeling shown—fits of
-laughter and dancing about, separated by pauses in which smiles, and
-other slight manifestations of pleasure, suffice to discharge the
-lessened excitement. Nor are there wanting evidences of mental
-undulations greater in length than any of these—undulations which take
-weeks, or months, or years, to complete themselves. We continually hear
-of moods which recur at intervals. Very many persons have their epochs
-of vivacity and depression. There are periods of industry following
-periods of idleness; and times at which particular subjects or tastes
-are cultivated with zeal, alternating with times at which they are
-neglected. Respecting which slow oscillations, the only qualification to
-be made is, that being affected by numerous influences, they are
-comparatively irregular.
-
- * * * * *
-
-§ 98. In nomadic societies the changes of place, determined as they
-usually are by exhaustion or failure of the supply of food, are
-periodic; and in many cases show a recurrence answering to the seasons.
-Each tribe that has become in some degree fixed in its locality, goes on
-increasing, till under the pressures of unsatisfied desires, there
-results migration of some part of it to a new region—a process repeated
-at intervals. From such excesses of population, and such successive
-waves of migration, come conflicts with other tribes; which are also
-increasing and tending to diffuse themselves. This antagonism, like all
-others, results not in an uniform motion, but in an intermittent one.
-War, exhaustion, recoil—peace, prosperity, and renewed aggression:—see
-here the alternation more or less discernible in the military activities
-of both savage and civilized nations. And irregular as is this rhythm,
-it is not more so than the different sizes of the societies, and the
-extremely involved causes of variation in their strengths, would lead us
-to anticipate.
-
-Passing from external to internal changes, we meet with this backward
-and forward movement under many forms. In the currents of commerce it is
-especially conspicuous. Exchange during early times is almost wholly
-carried on at fairs, held at long intervals in the chief centres of
-population. The flux and reflux of people and commodities which each of
-these exhibits, becomes more frequent as national development leads to
-greater social activity. The more rapid rhythm of weekly markets begins
-to supersede the slow rhythm of fairs. And eventually the process of
-exchange becomes at certain places so active, as to bring about daily
-meetings of buyers and sellers—a daily wave of accumulation and
-distribution of cotton, or corn, or capital. If from exchange we
-turn to production and consumption, we see undulations, much longer
-indeed in their periods, but almost equally obvious. Supply and demand
-are never completely adapted to each other; but each of them from time
-to time in excess, leads presently to an excess of the other. Farmers
-who have one season produced wheat very abundantly, are disgusted with
-the consequent low price; and next season, sowing a much smaller
-quantity, bring to market a deficient crop; whence follows a converse
-effect. Consumption undergoes parallel undulations that need not be
-specified. The balancing of supplies between different districts, too,
-entails analogous oscillations. A place at which some necessary of life
-is scarce, becomes a place to which currents of it are set up from other
-places where it is relatively abundant; and these currents from all
-sides lead to a wave of accumulation where they meet—a glut: whence
-follows a recoil—a partial return of the currents. But the
-undulatory character of these actions is perhaps best seen in the rises
-and falls of prices. These, given in numerical measures which may be
-tabulated and reduced to diagrams, show us in the clearest manner how
-commercial movements are compounded of oscillations of various
-magnitudes. The price of consols or the price of wheat, as thus
-represented, is seen to undergo vast ascents and descents whose highest
-and lowest points are reached only in the course of years. These largest
-waves of variation are broken by others extending over periods of
-perhaps many months. On these again come others having a week or two’s
-duration. And were the changes marked in greater detail, we should have
-the smaller undulations that take place each day, and the still smaller
-ones which brokers telegraph from hour to hour. The whole outline would
-show a complication like that of a vast ocean-swell, on whose surface
-there rise large billows, which themselves bear waves of moderate size,
-covered by wavelets, that are roughened by a minute ripple. Similar
-diagrammatic representations of births, marriages, and deaths, of
-disease, of crime, of pauperism, exhibit involved conflicts of
-rhythmical motions throughout society under these several aspects.
-
-There are like characteristics in social changes of a more complex kind.
-Both in England and among continental nations, the action and reaction
-of political progress have come to be generally recognized. Religion,
-besides its occasional revivals of smaller magnitude, has its long
-periods of exaltation and depression—generations of belief and
-self-mortification, following generations of indifference and laxity.
-There are poetical epochs, and epochs in which the sense of the
-beautiful seems almost dormant. Philosophy, after having been awhile
-predominant, lapses for a long season into neglect; and then again
-slowly revives. Each science has its eras of deductive reasoning, and
-its eras when attention is chiefly directed to collecting and
-colligating facts. And how in such minor but more obtrusive phenomena as
-those of fashion, there are ever going on oscillations from one extreme
-to the other, is a trite observation.
-
-As may be foreseen, social rhythms well illustrate the irregularity that
-results from combination of many causes. Where the variations are those
-of one simple element in national life, as the supply of a particular
-commodity, we do indeed witness a return, after many involved movements,
-to a previous condition—the price may become what it was before:
-implying a like relative abundance. But where the action is one into
-which many factors enter, there is never a recurrence of exactly the
-same state. A political reaction never brings round just the old form of
-things. The rationalism of the present day differs widely from the
-rationalism of the last century. And though fashion from time to time
-revives extinct types of dress, these always re-appear with decided
-modifications.
-
- * * * * *
-
-§ 99. The universality of this principle suggests a question like that
-raised in foregoing cases. Rhythm being manifested in all forms of
-movement, we have reason to suspect that it is determined by some
-primordial condition to action in general. The tacit implication is that
-it is deducible from the persistence of force. This we shall find to be
-the fact.
-
-When the prong of a tuning-fork is pulled on one side by the finger, a
-certain extra tension is produced among its cohering particles; which
-resist any force that draws them out of their state of equilibrium. As
-much force as the finger exerts in pulling the prong aside, so much
-opposing force is brought into play among the cohering particles. Hence,
-when the prong is liberated, it is urged back by a force equal to that
-used in deflecting it. When, therefore, the prong reaches its original
-position, the force impressed on it during its recoil, has generated in
-it a corresponding amount of momentum—an amount of momentum nearly
-equivalent, that is, to the force originally impressed (nearly, we must
-say, because a certain portion has gone in communicating motion to the
-air, and a certain other portion has been transformed into heat). This
-momentum carries the prong beyond the position of rest, nearly as far as
-it was originally drawn in the reverse direction; until at length, being
-gradually used up in producing an opposing tension among the particles,
-it is all lost. The opposing tension into which the expended momentum
-has been transformed, then generates a second recoil; and so on
-continually—the vibration eventually ceasing only because at each
-movement a certain amount of force goes in creating atmospheric and
-etherial undulations. Now it needs but to contemplate this repeated
-action and reaction, to see that it is, like every action and reaction,
-a consequence of the persistence of force. The force exerted by the
-finger in bending the prong cannot disappear. Under what form then does
-it exist? It exists under the form of that cohesive tension which it has
-generated among the particles. This cohesive tension cannot cease
-without an equivalent result. What is its equivalent result? The
-momentum generated in the prong while being carried back to its position
-of rest. This momentum too—what becomes of it? It must either continue
-as momentum, or produce some correlative force of equal amount. It
-cannot continue as momentum, since change of place is resisted by the
-cohesion of the parts; and thus it gradually disappears by being
-transformed into tension among these parts. This is re-transformed into
-the equivalent momentum; and so on continuously. If instead of
-motion that is directly antagonized by the cohesion of matter, we
-consider motion through space, the same truth presents itself under
-another form. Though here no opposing force seems at work, and therefore
-no cause of rhythm is apparent, yet its own accumulated momentum must
-eventually carry the moving body beyond the body attracting it; and so
-must become a force at variance with that which generated it. From this
-conflict, rhythm necessarily results as in the foregoing case. The force
-embodied as momentum in a given direction, cannot be destroyed; and if
-it eventually disappears, it re-appears in the reaction on the retarding
-body; which begins afresh to draw the now arrested mass back from its
-aphelion. The only conditions under which there could be absence of
-rhythm—the only conditions, that is, under which there could be a
-continuous motion through space in the same straight line for ever,
-would be the existence of an infinity void of everything but the moving
-body. And neither of these conditions can be represented in thought.
-Infinity is inconceivable; and so also is a motion which never had a
-commencement in some pre-existing source of power. Thus, then,
-rhythm is a necessary characteristic of all motion. Given the
-coexistence everywhere of antagonist forces—a postulate which, as we
-have seen, is necessitated by the form of our experience—and rhythm is
-an inevitable corollary from the persistence of force.
-
-Hence, throughout that re-arrangement of parts which constitutes
-Evolution, we must nowhere expect to see the change from one position of
-things to another, effected by continuous movement in the same
-direction. Be it in that kind of Evolution which the inorganic creation
-presents, or in that presented by the organic creation, we shall
-everywhere find a periodicity of action and reaction—a backward and
-forward motion, of which progress is a differential result.
-
------
-
-Footnote 15:
-
- After having for some years supposed myself alone in the belief that
- all motion is rhythmical, I discovered that my friend Professor
- Tyndall also held this doctrine.
-
-
-
-
- CHAPTER XII.
- THE CONDITIONS ESSENTIAL TO EVOLUTION.
-
-
-§ 100. One more preliminary is needful before proceeding. We have still
-to study the conditions under which alone, Evolution can take place.
-
-The process to be interpreted is, as already said, a certain change in
-the arrangement of parts. That increase of heterogeneity commonly
-displayed throughout Evolution, is not an increase in the number of
-kinds of ultimate or undecomposable units which an aggregate contains;
-but it is a change in the distribution of such units. If it be assumed
-that what we call chemical elements, are absolutely simple (which is,
-however, an hypothesis having no better warrant than the opposite one);
-then it must be admitted that in respect to the number of kinds of
-matter contained in it, the Earth is not more heterogeneous at present
-than it was at first—that in this respect, it would be as heterogeneous
-were all its undecomposable parts uniformly mixed, as it is now, when
-they are arranged and combined in countless different ways. But the
-increase of heterogeneity with which we have to deal, and of which alone
-our senses can take cognizance, is that produced by the passage from
-unity of distribution to variety of distribution. Given an aggregate
-consisting of several orders of primitive units that are unchangeable;
-then, these units may be so uniformly dispersed among each other, that
-any portion of the mass shall be like any other portion in its sensible
-properties; or they may be so segregated, simply and in endless
-combinations, that the various portions of the mass shall not be like
-each other in their sensible properties. A transformation of one of
-these arrangements into the other, is that which constitutes Evolution.
-We have to analyze the process through which structural uniformity
-becomes structural multiformity—to ascertain how the originally equal
-relations of position among the mixed units, pass into relations of
-position that are more and more unequal, and more and more numerous in
-their kinds of inequality; and how this takes place throughout all the
-ascending grades of compound units, until we come even to those of which
-societies are made up.
-
-Change in the relations of position among the component units, simple or
-complex, being the phenomenon we have to interpret; we must first
-inquire what are the circumstances which prevent its occurrence, and
-what are the circumstances which facilitate it.
-
- * * * * *
-
-§ 101. The constituents of an aggregate cannot be re-arranged, unless
-they are moveable: manifestly, they must not be so firmly bound together
-that the incident force fails to alter their positions. No bodies are,
-indeed, possessed of this absolute rigidity; since an incident force in
-being propagated through a body, always produces temporary alterations
-in the relative positions of its units, if not permanent alterations. It
-is true also, that even permanent re-arrangements of the units may be
-thus wrought throughout the interiors of comparatively dense masses,
-without any outward sign: as happens with certain crystals, which, on
-exposure to sunlight, undergo molecular changes so great as to alter
-their planes of cleavage. Nevertheless, since total immobility of the
-parts must totally negative their re-arrangement; and since that
-comparative immobility which we see in very coherent matter, is a great
-obstacle to re-arrangement; it is self-evident that Evolution can be
-exhibited in any considerable degree, only where there is comparative
-mobility of parts. On the other hand, those definite distributive
-changes which constitute Evolution, cannot be extensively or variously
-displayed, where the mobility of the parts is extreme. In liquids, the
-cohesion of the units is so slight that there is no permanency in their
-relations of position to each other. Such re-arrangement as any incident
-force generates, is immediately destroyed again by the momentum of the
-constituents moved; and so, nothing but that temporary heterogeneity
-seen in circulating currents, can be produced. The like still more
-obviously holds of gases. Thus, while the theoretical limits
-between which Evolution is possible, are absolute immobility of parts
-and absolute mobility of parts; we may say that practically, Evolution
-cannot go on to any considerable extent where the mobility is very great
-or very little. A few examples will facilitate the realization of this
-truth.
-
-The highest degrees of Evolution are found in semi-solid bodies, or
-bodies that come midway between the two extremes specified. Even
-semi-solid bodies of the inorganic class, exhibit the segregation of
-mixed units with comparative readiness: witness the fact to which
-attention was first drawn by Mr. Babbage, that when the pasty mixture of
-ground flints and kaolin, prepared for the manufacture of porcelain, is
-kept some time, it becomes gritty and unfit for use, in consequence of
-the particles of silica separating themselves from the rest, and uniting
-together in grains; or witness the fact known to every housewife, that
-in long-kept currant-jelly the sugar takes the shape of imbedded
-crystals. While throughout the immense majority of the semi-solid
-bodies, namely, the organic bodies, the proclivity to a re-arrangement
-of parts is so comparatively great, as to be usually taken for a
-distinctive characteristic of them. Among organic bodies
-themselves, we may trace contrasts having a like significance. It is an
-accepted generalization that, other things equal, the rate of Evolution
-is greatest where the plasticity is most marked. In that portion of an
-egg which displays the formative processes during the early stages of
-incubation, the changes of arrangement are more rapid than those which
-an equal portion of the body of a hatched chick undergoes. As may be
-inferred from their respective powers to acquire habits and aptitudes,
-the structural modifiability of a child is greater than that of an adult
-man; and the structural modifiability of an adult man is greater than
-that of an old man: contrasts which are accompanied by corresponding
-contrasts in the densities of the tissues; since the ratio of water to
-solid matter diminishes with advancing age. The most decisive
-proof, however, is furnished by those marked retardations or arrests of
-organic change, that take place when the tissues suffer a great loss of
-water. Certain of the lower animals, as the _Rotifera_, may be rendered
-apparently lifeless by desiccation, and will yet revive when wetted: as
-their substance passes from the fluid-solid to the solid state, it
-ceases to be the seat of those changes which constitute functional
-activity and cause structural advance; and such changes recommence as
-their substance passes from the solid to the fluid-solid state.
-Analogous instances occur among much higher animals. When the African
-rivers which it inhabits are dried up, the _Lepidosiren_ remains torpid
-in the hardened mud, until the return of the rainy season brings water.
-Humboldt states that during the summer drought, the alligators of the
-Pampas lie buried in a state of suspended animation beneath the parched
-surface, and struggle up out of the earth as soon as it becomes humid.
-Now though we have no proof that these partial arrests of vital
-activity, are consequent on the reduction of the fluid-solid tissues to
-a more solid form; yet their occurrence along with a cessation in the
-supply of water, is reason for suspecting that this is the case. And
-similarly, though in the more numerous instances where loss of water
-leads to complete arrest of vital activity, we are unable to say that
-the immediate cause is a stoppage of molecular changes that results from
-a diminution of molecular mobility; yet it seems not improbable that
-this is the rationale of death by thirst.
-
-Probably few will expect to find this same condition to Evolution,
-illustrated in aggregates so widely different in kind as societies. Yet
-even here it may be shown that no considerable degree of Evolution is
-exhibited, where there is either great mobility of the parts, or great
-immobility of them. In such tribes as those inhabiting Australia, we see
-extremely little cohesion among the units: there is neither that partial
-fixity of relative positions which results from the commencement of
-agriculture, nor that partial fixity of relative positions implied by
-the establishment of social grades. And along with this want of
-cohesion, we find an absence of permanent differentiations. Conversely,
-in societies of the oriental type, where accumulated traditions, laws,
-and usages, and long-fixed class-arrangements, exercise great
-restraining power over individual actions, we find Evolution almost
-stopped. Through the medium of institutions and opinions, the forces
-brought to bear on each unit by the rest, are so great as to prevent the
-units from sensibly yielding to forces tending to re-arrange them. The
-condition most favourable to increase of social heterogeneity, is a
-medium coherence among the parts—a moderate facility of change in the
-relations of citizens, joined with a moderate resistance to such
-change—a considerable freedom of individual actions, qualified by a
-considerable restraint over individual actions—a certain attachment to
-pre-established arrangements, and a certain readiness to be impelled by
-new influences into new arrangements—a compromise between fixity and
-unfixity such as that which we, perhaps as much as any nation, exhibit.
-
- * * * * *
-
-§ 102. Another condition to Evolution, of the same order as the last
-though of a different genus, must be noted. We have found that permanent
-re-arrangement among the units of an aggregate, can take place only when
-they have neither extreme immobility nor extreme mobility. The mobility
-and immobility thus far considered (at least in all aggregates except
-social ones) are those due to mechanical cohesion. There is, however,
-what we must call chemical cohesion, which also influences the mobility
-of the units, and consequently the re-arrangement of them. Manifestly,
-if two or more kinds of units contained in any aggregate, are united by
-powerful affinities, an incident force, failing to destroy their
-cohesions, will not cause such various re-arrangements as it would,
-could it produce new chemical combinations as well as new mechanical
-adjustments. On the other hand, chemical affinities that are easily
-overcome, must be favourable to multiplied re-arrangements of the units.
-
-This condition, as well as the preceding one, is fulfilled in the
-highest degree, by those aggregates which most variously display the
-transformation of the uniform into the multiform. Organic bodies are on
-the average distinguished from inorganic bodies, by the readiness with
-which the compounds they consist of undergo decomposition, and
-recomposition: the chemical cohesions of their components are so
-comparatively small, that small incident forces suffice to overcome them
-and cause transpositions of the components. Further, between the two
-great divisions of organisms, we find a contrast in the degree of
-Evolution co-existing with a contrast in the degree of chemical
-modifiability. As a class, the nitrogenous compounds are peculiarly
-unstable; and, speaking generally, these are present in much larger
-quantities in animal tissues than they are in vegetal tissues; while,
-speaking generally, animals are much more heterogeneous than plants.
-
-Under this head it may be well also to point out that, other things
-equal, the structural variety which is possible in any aggregate, must
-bear a relation to the number of kinds of units contained in the
-aggregate. A body made up of units of one order, cannot admit of so many
-different re-arrangements, as one made up of units of two orders. And
-each additional order of units must increase, in a geometrical
-proportion, the number of re-arrangements that may be made.
-
- * * * * *
-
-§ 103. Yet one more condition to be specified, is the state of agitation
-in which the constituents of an aggregate are kept. A familiar
-expedience will introduce us to this condition. When a vessel has been
-filled to the brim with loose fragments, shaking the vessel causes them
-to settle down into less space, so that more may be put in. And when
-among these fragments, there are some of much greater specific gravity
-than the rest, these will, in the course of a prolonged shaking, find
-their way to the bottom. What now is the meaning of these two results,
-when expressed in general terms? We have a group of units acted on by an
-incident force—the attraction of the Earth. So long as these units are
-not agitated, this incident force produces no changes in their relative
-positions; agitate them, and immediately their loose arrangement passes
-into a more compact arrangement. Again, so long as they are not
-agitated, the incident force cannot separate the heavier units from the
-lighter; agitate them, and immediately the heavier units begin to
-segregate. By these illustrations, a rude idea will be conveyed of the
-effect which vibration has in facilitating those re-arrangements which
-constitute Evolution. What here happens with visible units subject to
-visible oscillations, happens also with invisible units subject to
-invisible oscillations.
-
-One or two cases in which these oscillations are of mechanical origin,
-may first be noted. When a bar of steel is suspended in the magnetic
-meridian, and repeatedly so struck as to send vibrations through it, it
-becomes magnetized: the magnetic force of the Earth, which does not
-permanently affect it while undisturbed, alters its internal state when
-a mechanical agitation is propagated among its particles; and the
-alteration is believed by physicists, to be a molecular re-arrangement.
-It may be fairly objected that this re-arrangement is hypothetical; and
-did the fact stand alone, it would be of little worth. It gains
-significance, however, when joined with the fact that in the same
-substance, long-continued mechanical vibrations are followed by
-molecular re-arrangements that are abundantly visible. A piece of iron
-which, when it leaves the workshop, is fibrous in structure, will become
-crystalline if exposed to a perpetual jar. Though the polar forces
-mutually exercised by the atoms, fail to change their disorderly
-arrangement into an orderly arrangement while the atoms are relatively
-quiescent, these forces produce this change when the atoms are kept in a
-state of intestine disturbance.
-
-But the effects which visible oscillations and oscillations sensible to
-touch, have in facilitating the re-arrangement of parts by an incident
-force, are insignificant compared with the effects which insensible
-oscillations have in aiding such change of structure. It is a doctrine
-now generally accepted among men of science, that the particles of
-tangible matter, as well as the particles of ether, undulate. As
-interpreted in conformity with this doctrine, the heat of a body is
-simply its state of molecular motion. A mass which feels cold, is one
-having but slight molecular motion, and conveying but slight molecular
-motion to the surrounding medium or to the hand touching it. A mass hot
-enough to radiate a sensible warmth, is one of which the more violently
-agitated molecules, communicate increased undulations to the surrounding
-ethereal medium; while the burn inflicted by it on the skin, is the
-expression of increased undulations of the organic molecules. Such
-further heat as produces softening and a consequent distortion of the
-mass, is an agitation so much augmented that the units can no longer
-completely maintain their relative positions. Fusion is an agitation so
-extreme, that the relative positions of the units are changeable with
-ease. When, finally, at a still higher temperature, the liquid is
-transformed into a gas, the explanation is, that the oscillations are so
-violent as to overbalance that force which held the units in close
-contiguity—so violent as to keep the units at those relatively great
-distances apart to which they are now thrown. Since the
-establishment of the correlation between heat and motion first gave
-probability to this hypothesis, it has been receiving various
-confirmations—especially by recent remarkable discoveries respecting the
-absorption of heat by gases. Prof. Tyndall has proved that the quantity
-of heat which any gas takes up from rays of heat passing through it, has
-a distinct relation to the complexity of the atoms composing the gas.
-The simple gases abstract but little; the gases composed of binary atoms
-abstract, say in round numbers, a hundred times as much; while the gases
-composed of atoms severally containing three, four, or more simple ones,
-abstract something like a thousand times as much. These differences
-Prof. Tyndall regards as due to the different abilities of the different
-atoms to take up, in the increase of their own undulations, those
-undulations of the ethereal medium which constitute heat—an
-interpretation in perfect accordance with the late results of
-spectrum-analysis; which go to show that the various elementary atoms,
-when in an aeriform state, intercept those luminiferous vibrations of
-the ether which are in unison or harmony with their own. And since it
-holds of solid as of gaseous matters, that those consisting of simple
-units transmit heat far more readily than those consisting of complex
-units; we get confirmation of the inference otherwise reached, that the
-units of matter in whatever state of aggregation they exist, oscillate,
-and that variations of temperature are variations in the amounts of
-their oscillations.
-
-Proceeding on this hypothesis, which it would be out of place here to
-defend at greater length, we have now to note how the re-arrangement of
-parts is facilitated by these insensible vibrations, as we have seen it
-to be by sensible vibrations. One or two cases of physical
-re-arrangement may first be noted. When some molten glass is
-dropped into water, and when its outside is thus, by sudden
-solidification, prevented from partaking in that contraction which the
-subsequent cooling of the inside tends to produce; the units are left in
-such a state of tension, that the mass flies into fragments if a small
-portion of it be broken off. But now, if this mass be kept for a day or
-two at a considerable heat, though a heat not sufficient to alter its
-form or produce any sensible diminution of hardness, this extreme
-brittleness disappears: the component particles being thrown into
-greater agitation, the tensile forces are enabled to re-arrange them
-into a state of equilibrium. An illustration of another order is
-furnished by the subsidence of fine precipitates. These sink down very
-slowly from solutions that are cold; while warm solutions deposit them
-with comparative rapidity. That is to say, an increase of molecular
-vibration throughout the mass, allows the suspended particles to
-separate more readily from the particles of fluid. The effect of
-heat on chemical re-arrangement is so familiar, that examples are
-scarcely needed. Be the substances concerned gaseous, liquid, or solid,
-it equally holds that their chemical unions and disunions are aided by a
-rise of temperature. Affinities which do not suffice to effect the
-re-arrangement of mixed units that are in a state of feeble agitation,
-suffice to effect it when the agitation is raised to a certain point.
-And so long as this molecular motion is not great enough to prevent
-those chemical cohesions which the affinities tend to produce, increase
-of it gives increased facility of chemical re-arrangement.
-
-This condition, in common with the preceding ones, is fulfilled most
-completely in those aggregates which exhibit the phenomena of Evolution
-in the highest degree; namely, the organic aggregates. And throughout
-the various orders and states of these, we find minor contrasts showing
-the relation between amount of molecular vibration and activity of the
-metamorphic changes. Such contrasts may be arranged in the several
-following groups. Speaking generally, the phenomena of Evolution
-are manifested in a much lower degree throughout the vegetal kingdom
-than throughout the animal kingdom; and speaking generally, the heat of
-plants is less than that of animals. Among plants themselves, the
-organic changes vary in rate as the temperature varies. Though light is
-the agent which effects those molecular changes causing vegetal growth,
-yet we see that in the absence of heat, such changes are not effected:
-in winter there is enough light, but the heat being insufficient,
-plant-life is suspended. That this is the sole cause of the suspension,
-is proved by the fact that at the same season, plants contained in
-hot-houses, where they receive even a smaller amount of light, go on
-producing leaves and flowers. A comparison of the several
-divisions of the animal kingdom with each other, shows among them
-parallel relations. Regarded as a whole, vertebrate animals are higher
-in temperature than invertebrate ones; and they are as a whole higher in
-organic activity and development. Between subdivisions of the vertebrata
-themselves, like differences in the state of molecular vibration,
-accompany like differences in the degree of evolution. The least
-heterogeneous of the vertebrata are the fishes; and in most cases, the
-heat of fishes is nearly the same as that of the water in which they
-swim: only some of them being decidedly warmer. Though we habitually
-speak of reptiles as cold-blooded; and though they have not much more
-power than fishes of maintaining a temperature above that of their
-medium; yet since their medium (which is, in the majority of cases, the
-air of warm climates) is on the average warmer than the medium inhabited
-by fishes, the temperature of the class of reptiles is higher than that
-of the class of fishes; and we see in them a correspondingly higher
-complexity. The much more active molecular agitation in mammals and
-birds, is associated with a considerably greater multiformity of
-structure and a very much greater vivacity. And though birds, which are
-hotter blooded than mammals, do not show us a greater multiformity; yet,
-judging from their apparently greater locomotive powers, we may infer
-more rapid functional changes, which, equally with structural changes,
-imply molecular re-arrangement. The most instructive contrasts,
-however, are those presented by the same organic aggregates at different
-temperatures. Thus we see that ova undergoing development, must be kept
-more or less warm—that in the absence of a certain molecular vibration,
-the re-arrangement of parts does not go on. We see, again, that in
-hybernating animals, loss of heat carried to a particular point, results
-in extreme retardation of the organic changes. Yet further, we see that
-in animals which do not hybernate, as in man, prolonged exposure to
-extreme cold, produces an irresistible tendency to sleep (which implies
-a lowering of the functional activity); and then, if the abstraction of
-heat continues, this sleep ends in death, or arrest of functional
-activity. Lastly, we see that when the temperature is lowered till the
-contained water solidifies, there is a stoppage not only of those
-molecular re-arrangements which constitute life and development, but
-also of those molecular re-arrangements which constitute decomposition.
-
-Evidently then, both sensible and insensible agitations among the
-components of an aggregate, facilitate any re-distributions to which
-there may be a tendency. When that rhythmic change in the relative
-positions of the units which constitutes vibration, is considerable, the
-relative positions of the units more readily undergo permanent changes
-through the action of incident forces.
-
- * * * * *
-
-§ 104. These special conditions to Evolution, are clearly but different
-forms of one general condition. The abstract proposition, that a
-permanent re-arrangement of units is possible only when they have
-neither absolute immobility nor absolute mobility with respect to each
-other, we saw to be practically equivalent to the proposition, that
-extreme cohesion and extreme want of cohesion among the units are
-unfavourable to Evolution. Be this cohesion or want of cohesion that
-which physically characterizes the matter as we ordinarily know it; be
-it that cohesion or want of cohesion distinguished as chemical; or be it
-that cohesion or want of cohesion consequent on the degree of molecular
-vibration; matters not, in so far as the general conclusion is
-concerned. Inductively as well as deductively, we find that the genesis
-of such permanent changes in the relative positions of parts, as can be
-effected without destroying the continuity of the aggregate, implies a
-medium stability in the relative positions of the parts: be this
-stability physical, chemical, or that which varies with the state of
-agitation. And as might be anticipated _à priori_, it is proved _à
-posteriori_, that this re-arrangement of parts goes on most actively in
-those aggregates whose units are moderately influenced by all these
-forces which affect their mobility.
-
-Here also may properly be added the remark, that to effect these changes
-in the relative positions of parts, the incident forces must range
-within certain limits. It is wholly a question of the ratio between
-those agencies which hold the units in their positions, and those
-agencies which tend to change their positions. Having given intensities
-in the powers that oppose re-arrangement, there need proportionate
-intensities in the powers that work re-arrangement. As there must be
-neither too great nor too little cohesion; so there must be neither too
-little nor too great amounts of the influences antagonistic to cohesion.
-While a slight mechanical strain produces no lasting alterations in the
-relative positions of parts, an excessive mechanical strain causes
-disruption—causes so great an alteration in the relative positions of
-parts as to destroy their union in one aggregate. While a very feeble
-chemical affinity brought to bear on the associated units, fails to work
-any re-arrangement of them; a chemical affinity that is extremely
-intense, destroys their structural continuity, and reduces such complex
-re-arrangements as have been made, to comparatively simple ones. And
-while in the absence of adequate thermal undulations, the units have not
-freedom enough to obey the re-arranging influences impressed on them,
-the incidence of violent thermal undulations gives them such extreme
-freedom that they break their connexions, and the aggregate lapses into
-a liquid or gaseous form.
-
-On the one hand, therefore, the statical forces which uphold the state
-of aggregation must not be so great as wholly to prevent those changes
-of relative position among the units which the dynamical forces tend to
-produce; and, on the other hand, the dynamical forces must not be so
-great as wholly to overcome the statical forces, and destroy the state
-of aggregation. The excess of the dynamical forces must be sufficient to
-produce Evolution, but not sufficient to produce Dissolution.
-
- * * * * *
-
-§ 105. And now we are naturally introduced to a consideration which,
-though it does not come quite within the limits of this chapter as
-expressed in its title, may yet be more conveniently dealt with here
-than elsewhere. Hitherto we have studied the metamorphosis of things,
-only as exhibited in the changed distribution of matter. It remains to
-look at it as exhibited in the changed distribution of motion. The
-definition of Evolution in its material aspect, has to be supplemented
-by a definition of Evolution in its dynamical aspect.
-
-On inquiring the source of the sensible motions seen in every kind of
-Evolution, we find them all traceable to insensible motions; either of
-that tangible matter which we perceive as constituting the objects
-around us, or of that intangible matter which we infer as occupying
-space. A brief reconsideration of the facts will make this obvious.
- The formation of celestial bodies, supposing it caused by the
-union of dispersed units, must, from the beginning, have involved a
-diminished motion of these units with respect to each other; and such
-motion as each resulting body acquired, must previously have existed in
-the motions of its units. If concrete matter has arisen by the
-aggregation of diffused matter, then concrete motion has arisen by the
-aggregation of diffused motion. That which now exists as the movement of
-masses, implies the cessation of an equivalent molecular movement.
- Those transpositions of matter which constitute geological
-changes, are clearly referable to the same source. As before shown, the
-denudation of lands and deposit of new strata, are effected by water in
-the course of its descent from the clouds to the sea, or during the
-arrest of those undulations produced on it by winds; and, as before
-shown, the elevation of water to the height whence it fell, is due to
-solar heat, as is also the genesis of those aerial currents which drift
-it about when evaporated and agitate its surface when condensed. That is
-to say, the molecular motion of the etherial medium, is transformed into
-the motion of gases, thence into the motion of liquids, and thence into
-the motion of solids—stages in each of which, successively, a certain
-amount of molecular motion is lost and an equivalent motion of masses
-produced. If we seek the origin of vital movements, we soon reach
-a like conclusion. The actinic rays issuing from the Sun, enable the
-plant to reduce special elements existing in gaseous combination around
-it, to a solid form,—enable the plant, that is, to grow and carry on its
-functional changes. And since growth, equally with circulation of sap,
-is a mode of sensible motion, while those rays which have been expended
-in generating it consist of insensible motions, we have here, too, a
-transformation of the kind alleged. Animals, derived as their forces
-are, directly or indirectly, from plants, carry this transformation a
-step further. The automatic movements of the viscera, together with the
-voluntary movements of the limbs and body at large, arise at the expense
-of certain molecular movements throughout the nervous and muscular
-tissues; and these originally arose at the expense of certain other
-molecular movements propagated by the Sun to the Earth; so that both the
-structural and functional motions which organic Evolution displays, are
-motions of aggregates generated by the arrested motions of units.
- Even with the aggregates of these aggregates the same rule holds.
-For among associated men, the progress is ever towards a merging of
-individual actions in the actions of corporate bodies. An undeveloped
-society is composed of members between whom there is little concert:
-they fulfil their several wants without mutual aid; and only on
-occasions of aggression or defence, act together—occasions on which
-their combination, small as it is in extent, frequently fails because it
-is so imperfect. In the course of civilization, however, co-operation
-becomes step by step more decided. As tribes grow into nations, there
-result larger aggregates, each of which has a joint political life—a
-common policy and movement with respect to other aggregates. Legislative
-and administrative progress, involves an increase in the number of
-restraining agents brought into united and simultaneous action. In
-military organization, we see an advance from small undisciplined hordes
-of armed men, to vast bodies of regular troops, so drilled that the
-movements of the units are entirely subordinated to the movements of the
-masses. Nor does industrial development fail to show parallel changes.
-Beginning with independent workers, and passing step by step to the
-employment of several assistants by one master, there has ever been, and
-still is, a progress towards the co-operation of greater masses of
-labourers in the same establishment, and towards the union of
-capitalists into more numerous and larger companies: in both which kinds
-of combined action, equivalent amounts of individual action disappear.
- Under all its forms, then, Evolution, considered dynamically, is a
-decrease in the relative movements of parts, and an increase in the
-relative movements of wholes—using the words parts and wholes in their
-widest senses. From the infinitesimal motions of those infinitesimal
-units composing the etherial medium, to the larger though still
-insensible motions of the larger though still insensible units composing
-gaseous, fluid, and solid matter, and thence to the visible motions of
-visible aggregates, the advance is from molecular motion to the motion
-of masses.
-
-But now what of the converse process? If the foregoing proposition is
-true, then a change from the motion of masses to molecular motion, is
-the opposite to Evolution—is Dissolution. Is this so? Of inorganic
-dissolution we have but little experience; or at least, our experience
-of it is on too small a scale to exhibit it as the antithesis of
-Evolution. We know, indeed, that when solids are dissolved in liquids,
-their dissolution implies increased movements of their units, at the
-expense of diminished movements among the units of their solvents; and
-we know that when a liquid evaporates, its dissipation or dissolution
-similarly implies greater relative movements of the units, and decrease
-of such combined movement as they before had. But since these small
-aggregates of inorganic matter, do not exhibit the phenomena of
-Evolution, save in the form of simple integration; so they do not
-exhibit the phenomena of dissolution, save in the form of simple
-disintegration. Of organic dissolution, however, our experience
-suffices to show that it is a decrease of combined motion, and an
-increase in the motion of uncombined parts. The gradual cessation of
-functions, vegetal or animal, is a cessation of the sensible movements
-of fluids and solids. In animals, the impulsions of the body from place
-to place, first cease; presently the limbs cannot be stirred; later
-still the respiratory actions stop; finally the heart becomes
-stationary, and, with it, the circulating fluids. That is, the
-transformation of molecular motion into the motion of masses, comes to
-an end. What next takes place? We cannot say that sensible movements are
-transformed into insensible movements; for sensible movements no longer
-exist. Nevertheless, the process of decay involves an increase of
-insensible movements; since this is far greater in the gases generated
-by decomposition, than it is in the fluid-solid matters generating them.
-Indeed, it might be contended that as, during Dissolution, there is a
-change from the vibration of large compound atoms to the vibration of
-small and comparatively simple ones, the process is strictly
-antithetical to that of Evolution. In conformity with the now current
-conception lately explained, each of the highly complex chemical units
-composing an organic body, possesses a rhythmic movement—a movement in
-which its many component units jointly partake. When decomposition
-breaks up these highly complex atoms, and their constituents assume a
-gaseous form, there is both an increase of molecular motion implied by
-the diffusion, and a further increase implied by the resolving of such
-motions as the aggregate atoms possessed, into motions of their
-constituent atoms. So that in organic dissolution we have, first, an end
-put to that transformation of the motion of units into the motion of
-aggregates, which constitutes Evolution, dynamically considered; and we
-have also, though in a subtler sense, a transformation of the motion of
-aggregates into the motion of units. The formula equally applies
-to the dissolution of a society. When social ties, be they governmental
-or industrial, are destroyed, the combined actions of citizens lapse
-into uncombined actions. Those general forces which restrained
-individual doings, having disappeared, the only remaining restraints are
-those separately exercised by individuals on each other. There are no
-longer any of the joint operations by which men satisfy their wants;
-and, in so far as they can, they satisfy their wants by separate
-operations. That is to say, the movement of parts replaces the movement
-of wholes.
-
-Under its dynamical aspect then, Evolution, so far as we can trace it,
-is a change from molecular motion to the motion of masses; while
-Dissolution, so far as we can trace it, is a change from the motion of
-masses to molecular motion.
-
- * * * * *
-
-§ 106. To these abstract definitions may be added concrete ones. Besides
-an integration of motions corresponding to the integration of masses,
-Evolution involves an increase in the multiformity of the motions,
-corresponding to the increase in the multiformity of the masses. If,
-contemplating it as materially displayed, we find Evolution to consist
-in the change from an indefinite, homogeneous distribution of parts to a
-definite, heterogeneous distribution of parts; then, contemplating
-Evolution as dynamically displayed, it consists in a change from
-indefinite, homogeneous motions to definite, heterogeneous motions.
-
-This change takes place under the form of an increased variety of
-rhythms. We have already seen that all motion is rhythmical, from the
-infinitesimal vibrations of infinitesimal molecules, up to those vast
-oscillations between perihelion and aphelion performed by vast celestial
-bodies. And as the contrast between these extreme cases suggests, a
-multiplication of rhythms must accompany a multiplication in the degrees
-and modes of aggregation, and in the relations of the aggregated masses
-to incident forces. The degree or mode of aggregation will not, indeed,
-affect the rate or extent of rhythm where the incident force increases
-as the aggregate increases, which is the case with gravitation: here the
-only cause of variation in rhythm, is difference of relation to the
-incident forces; as we see in a pendulum, which, though unaffected in
-its movements by a change in the weight of the bob, alters its rate of
-oscillation when taken to the equator. But in all cases where the
-incident forces do not vary as the masses, every new order of
-aggregation initiates a new order of rhythm: witness the conclusion
-drawn from the recent researches into radiant heat and light, that the
-atoms of different gases have different rates of undulation. So that
-increased multiformity in the arrangement of matter, has necessarily
-generated increased multiformity of rhythm; both through increased
-variety in the sizes and forms of aggregates, and through increased
-variety in their relations to the forces which move them. The
-advancing heterogeneity of motion, thus entailed by advancing
-heterogeneity in the distribution of matter, does not, however, end
-here. Besides multiplication in the kinds of rhythm, there is a
-progressing complexity in their combinations. As there arise wholes
-composed of heterogeneous parts, each of which has its own rhythm, there
-must arise compound rhythms proportionately heterogeneous. We before saw
-that this is visible even in the cyclical perturbations of the Solar
-System—simple as are its structure and movements. And when we
-contemplate highly-developed organic bodies, we find the complication of
-rhythms so great, that it defies definite analysis, and from moment to
-moment works out in resultants that are incalculable.
-
-This conception of Evolution forms a needful complement to that on which
-we have hitherto chiefly dwelt. To comprehend the phenomena in their
-entirety, we have to contemplate both the increasing multiformity of
-parts, and the increasing multiformity of the actions simultaneously
-assumed by these parts. At the same time that there are differentiations
-and integrations of the matter, there are differentiations and
-integrations of its motion. And this increasingly heterogeneous
-distribution of motion, constitutes Evolution _functionally_ considered;
-as distinguished from that increasingly heterogeneous distribution of
-matter, which constitutes Evolution _structurally_ considered. While of
-course, Dissolution exhibits the transition to a reverse distribution,
-both structurally and functionally.
-
- * * * * *
-
-§ 107. One other preliminary must be set down. When specifically
-interpreting Evolution, we shall have to consider under their concrete
-forms, the various resolutions of force that follow its conflict with
-matter. Here it will be well to contemplate such resolutions under their
-most general or abstract forms.
-
-Any incident force is primarily resolvable or divisible into its
-_effective_ and _non-effective_ portions. In mechanical impact, the
-entire momentum of a striking body is never communicated to the body
-struck: even under those most favourable conditions in which the
-striking body loses all its sensible motion, there still remains with it
-a portion of the original momentum, under the shape of that insensible
-motion produced among its particles by the collision. Of the light or
-heat falling on any mass, a part, more or less considerable, is
-reflected; and only the remaining part works molecular changes in the
-mass. Next it is to be noted that the effective force, is itself
-divisible into the _temporarily effective_ and the _permanently
-effective_. The units of an aggregate acted on, may undergo those
-rhythmical changes of relative position which constitute increased
-vibration, as well as other changes of relative position which are not
-from instant to instant neutralized by opposite ones. Of these, the
-first, disappearing in the shape of radiating undulations, leave the
-molecular arrangement as it originally was; while the second conduce to
-that re-arrangement constituting Evolution. Yet a further
-distinction has to be made. The permanently effective force works out
-changes of relative position of two kinds—the _insensible_ and the
-_sensible_. The insensible transpositions among the units are those
-constituting what we call chemical composition and decomposition; and it
-is these which we recognize as the qualitative differences that arise in
-an aggregate. The sensible transpositions are such as result when
-certain of the units, instead of being put into different relations with
-their immediate neighbours, are carried away from them and united
-together elsewhere.
-
-Concerning these divisions and sub-divisions of any force affecting an
-aggregate, the fact which it chiefly concerns us to observe, is, that
-they are complementary to each other. Of the whole incident force, the
-effective must be that which remains after deducting the non-effective.
-The two parts of the effective force must vary inversely as each other:
-where much of it is temporarily effective, little of it can be
-permanently effective; and _vice versâ_. Lastly, the permanently
-effective force, being expended in working both the insensible
-re-arrangements which constitute chemical modification, and the sensible
-re-arrangements which result in structure, must generate of either kind
-an amount that is great or small in proportion as it has generated a
-small or great amount of the other.
-
- * * * * *
-
-§ 108. And now of the propositions grouped together in this chapter, it
-may be well to remark that, in common with foregoing propositions, they
-have for their warrant the fundamental truth with which our synthesis
-set out.
-
-That when a given force falls on any aggregate, the permanently
-effective part of it will produce an amount of re-arrangement that is
-inversely proportional to the cohesion existing among the parts of the
-aggregate, is demonstrable _à priori_. Whether the cohesion be
-mechanical or chemical, or whether it be temporarily modified by a
-changed degree of molecular vibration, matters not to the general
-conclusion. In all these cases it follows from the persistence of force,
-that in proportion as the units offer great resistance to alteration in
-their relative positions, must the amount of motion which a given force
-impresses on them be small. The proposition is in fact an identical one;
-since the cohesion of units is known to be great or small, only by the
-smallness or greatness of the re-arrangement which a given incident
-force produces.
-
-The continuity of motion we found to be a corollary from the persistence
-of force; and from the continuity of motion, it follows that molecular
-motion and the motion of masses can be respectively increased only at
-each other’s expense. Hence, if in the course of Evolution there arises
-a motion of masses that did not before exist, there must have ceased an
-equivalent molecular motion; and if in the course of Dissolution there
-arises a molecular motion that did not before exist, an equivalent
-motion of masses must have disappeared.
-
-Equally necessary is the conclusion that the several results of the
-force expended on any aggregate, must be complementary to each other. It
-is not less obviously a corollary from the persistence of force, that of
-the whole incident force the effective is the part which remains after
-deducting the non-effective; than it is, that of the effective force,
-whatever does not work permanent results, works temporary results, and
-that such amount of the permanently effective force as is not absorbed
-in producing insensible re-arrangements, will produce sensible
-re-arrangements.
-
-
-
-
- CHAPTER XIII.
- THE INSTABILITY OF THE HOMOGENEOUS.[16]
-
-
-§ 109. Thus far our steps towards the interpretation of Evolution have
-been preparatory. We have dealt with the factors of the process, rather
-than the process itself. After the ultimate truth that, Matter, Motion,
-and Force, as cognizable by human intelligence, can neither come into
-existence nor cease to exist, we have considered certain other ultimate
-truths concerning the modes in which Force and Motion are manifested
-during the changes they produce in Matter. Now we have to study the
-changes themselves. We have here to analyze that re-arrangement in the
-parts of Matter, which occurs under the influence of Force, that is
-unchangeable in quantity though changeable in form, through the medium
-of Motion taking place rhythmically along lines of least resistance. The
-proposition which comes first in logical order, is, that some
-re-arrangement must result; and this proposition may be best dealt with
-under the more specific shape, that the condition of homogeneity is a
-condition of unstable equilibrium.
-
-First, as to the meaning of the terms; respecting which some readers may
-need explanation. The phrase _unstable equilibrium_ is one used in
-mechanics to express a balance of forces of such kind, that the
-interference of any further force, however minute, will destroy the
-arrangement previously subsisting; and bring about a totally different
-arrangement. Thus, a stick poised on its lower end is in unstable
-equilibrium: however exactly it may be placed in a perpendicular
-position, as soon as it is left to itself it begins, at first
-imperceptibly, to lean on one side, and with increasing rapidity falls
-into another attitude. Conversely, a stick suspended from its upper end
-is in stable equilibrium: however much disturbed, it will return to the
-same position. The proposition is, then, that the state of homogeneity,
-like the state of the stick poised on its lower end, is one that cannot
-be maintained. Let us take a few illustrations.
-
-Of mechanical ones the most familiar is that of the scales. If they be
-accurately made, and not clogged by dirt or rust, it is impossible to
-keep a pair of scales perfectly balanced: eventually one scale will
-descend and the other ascend—they will assume a heterogeneous relation.
-Again, if we sprinkle over the surface of a fluid a number of
-equal-sized particles, having an attraction for each other, they will,
-no matter how uniformly distributed, by and by concentrate irregularly
-into one or more groups. Were it possible to bring a mass of water into
-a state of perfect homogeneity—a state of complete quiescence, and
-exactly equal density throughout—yet the radiation of heat from
-neighbouring bodies, by affecting differently its different parts, would
-inevitably produce inequalities of density and consequent currents; and
-would so render it to that extent heterogeneous. Take a piece of red-hot
-matter, and however evenly heated it may at first be, it will quickly
-cease to be so: the exterior, cooling faster than the interior, will
-become different in temperature from it. And the lapse into
-heterogeneity of temperature, so obvious in this extreme case, takes
-place more or less in all cases. The action of chemical forces
-supplies other illustrations. Expose a fragment of metal to air or
-water, and in course of time it will be coated with a film of oxide,
-carbonate, or other compound: that is—its outer parts will become unlike
-its inner parts. Usually the heterogeneity produced by the action of
-chemical forces on the surfaces of masses, is not striking; because the
-changed portions are soon washed away, or otherwise removed. But if this
-is prevented, comparatively complex structures result. Quarries of
-trap-rock contain some striking examples. Not unfrequently a piece of
-trap may be found reduced, by the action of the weather, to a number of
-loosely-adherent coats, like those of an onion. Where the block has been
-quite undisturbed, we may trace the whole series of these, from the
-angular, irregular outer one, through successively included ones in
-which the shape becomes gradually rounded, ending finally in a spherical
-nucleus. On comparing the original mass of stone with this group of
-concentric coats, each of which differs from the rest in form, and
-probably in the state of decomposition at which it has arrived, we get a
-marked illustration of the multiformity to which, in lapse of time, a
-uniform body may be brought by external chemical action. The
-instability of the homogeneous is equally seen in the changes set up
-throughout the interior of a mass, when it consists of units that are
-not rigidly bound together. The atoms of a precipitate never remain
-separate, and equably distributed through the fluid in which they make
-their appearance. They aggregate either into crystalline grains, each
-containing an immense number of atoms, or they aggregate into flocculi,
-each containing a yet larger number; and where the mass of fluid is
-great, and the process prolonged, these flocculi do not continue
-equidistant, but break up into groups. That is to say, there is a
-destruction of the balance at first subsisting among the diffused
-particles, and also of the balance at first subsisting among the groups
-into which these particles unite. Certain solutions of
-non-crystalline substances in highly volatile liquids, exhibit in the
-course of half an hour a whole series of changes that are set up in the
-alleged way. If for example a little shell-lac-varnish (made by
-dissolving shell-lac in coal-naphtha until it is of the consistence of
-cream) be poured on a piece of paper, the surface of the varnish will
-shortly become marked by polygonal divisions, which, first appearing
-round the edge of the mass, spread towards its centre. Under a lense
-these irregular polygons of five or more sides, are seen to be severally
-bounded by dark lines, on each side of which there are light-coloured
-borders. By the addition of matter to their inner edges, the borders
-slowly broaden, and thus encroach on the areas of the polygons; until at
-length there remains nothing but a dark spot in the centre of each. At
-the same time the boundaries of the polygons become curved; and they end
-by appearing like spherical sacs pressed together; strangely simulating
-(but only simulating) a group of nucleated cells. Here a rapid loss of
-homogeneity is exhibited in three ways:—First, in the formation of the
-film, which is the seat of these changes; second, in the formation of
-the polygonal sections into which this film divides; and third, in the
-contrast that arises between the polygonal sections round the edge,
-where they are small and early formed, and those in the centre which are
-larger and formed later.
-
-The instability thus variously illustrated is obviously consequent on
-the fact, that the several parts of any homogeneous aggregation are
-necessarily exposed to different forces—forces that differ either in
-kind or amount; and being exposed to different forces they are of
-necessity differently modified. The relations of outside and inside, and
-of comparative nearness to neighbouring sources of influence, imply the
-reception of influences that are unlike in quantity or quality, or both;
-and it follows that unlike changes will be produced in the parts thus
-dissimilarly acted upon.
-
-For like reasons it is manifest that the process must repeat itself in
-each of the subordinate groups of units that are differentiated by the
-modifying forces. Each of these subordinate groups, like the original
-group, must gradually, in obedience to the influences acting upon it,
-lose its balance of parts—must pass from a uniform into a multiform
-state. And so on continuously. Whence indeed it is clear that not
-only must the homogeneous lapse into the non-homogeneous, but that the
-more homogeneous must tend ever to become less homogeneous. If any given
-whole, instead of being absolutely uniform throughout, consist of parts
-distinguishable from each other—if each of these parts, while somewhat
-unlike other parts, is uniform within itself; then, each of them being
-in unstable equilibrium, it follows that while the changes set up within
-it must render it multiform, they must at the same time render the whole
-more multiform than before. The general principle, now to be followed
-out in its applications, is thus somewhat more comprehensive than the
-title of the chapter implies. No demurrer to the conclusions drawn, can
-be based on the ground that perfect homogeneity nowhere exists; since,
-whether that state with which we commence be or be not one of perfect
-homogeneity, the process must equally be towards a relative
-heterogeneity.
-
- * * * * *
-
-§ 110. The stars are distributed with a three-fold irregularity. There
-is first the marked contrast between the plane of the milky way and
-other parts of the heavens, in respect of the quantities of stars within
-given visual areas. There are secondary contrasts of like kind in the
-milky way itself, which has its thick and thin places; as well as
-throughout the celestial spaces in general, which are much more closely
-strewn in some regions than in others. And there is a third order of
-contrasts produced by the aggregation of stars into small clusters.
-Besides this heterogeneity of distribution of the stars in general,
-considered without distinction of kinds, a further such heterogeneity is
-disclosed when they are classified by their differences of colour, which
-doubtless answer to differences of physical constitution. While the
-yellow stars are found in all parts of the heavens, the red and blue
-stars are not so: there are wide regions in which both red and blue
-stars are rare; there are regions in which the blue occur in
-considerable numbers, and there are other regions in which the red are
-comparatively abundant. Yet one more irregularity of like significance
-is presented by the nebulæ,—aggregations of matter which, whatever be
-their nature, most certainly belong to our sidereal system. For the
-nebulæ are not dispersed with anything like uniformity; but are abundant
-around the poles of the galactic circle and rare in the neighbourhood of
-its plane. No one will expect that anything like a definite
-interpretation of this structure can be given on the hypothesis of
-Evolution, or any other hypothesis. The most that can be looked for is
-some reason for thinking that irregularities, not improbably of these
-kinds, would occur in the course of Evolution, supposing it to have
-taken place. Any one called on to assign such reason might argue, that
-if the matter of which stars and all other celestial bodies consist, be
-assumed to have originally existed in a diffused form throughout a space
-far more vast even than that which our sidereal system now occupies, the
-instability of the homogeneous would negative its continuance in that
-state. In default of an absolute balance among the forces with which the
-dispersed particles acted on each other (which could not exist in any
-aggregation having limits) he might show that motion and consequent
-changes of distribution would necessarily result. The next step in the
-argument would be that in matter of such extreme tenuity and feeble
-cohesion there would be motion towards local centres of gravity, as well
-as towards the general centre of gravity; just as, to use a humble
-illustration, the particles of a precipitate aggregate into flocculi at
-the same time that they sink towards the earth. He might urge that in
-the one case as in the other, these smallest and earliest local
-aggregations must gradually divide into groups, each concentrating to
-its own centre of gravity,—a process which must repeat itself on a
-larger and larger scale. In conformity with the law that motion once set
-up in any direction becomes itself a cause of subsequent motion in that
-direction, he might further infer that the heterogeneities thus set up
-would tend ever to become more pronounced. Established mechanical
-principles would justify him in the conclusion that the motions of these
-irregular masses of slightly aggregated nebular matter towards their
-common centre of gravity must be severally rendered curvelinear, by the
-resistance of the medium from which they were precipitated; and that in
-consequence of the irregularities of distribution already set up, such
-conflicting curvelinear motions must, by composition of forces, end in a
-rotation of the incipient sidereal system. He might without difficulty
-show that the resulting centrifugal force must so far modify the process
-of general aggregation, as to prevent anything like uniform distribution
-of the stars eventually formed—that there must arise a contrast such as
-we see between the galactic circle and the rest of the heavens. He might
-draw the further not unwarrantable inference, that differences in the
-process of local concentration would probably result from the unlikeness
-between the physical conditions existing around the general axis of
-rotation and those existing elsewhere. To which he might add, that after
-the formation of distinct stars, the ever-increasing irregularities of
-distribution due to continuance of the same causes would produce that
-patchiness which distinguishes the heavens in both its larger and
-smaller areas. We need not here however commit ourselves to such
-far-reaching speculations. For the purposes of the general argument it
-is needful only to show, that any finite mass of diffused matter, even
-though vast enough to form our whole sidereal system, could not be in
-stable equilibrium; that in default of absolute sphericity, absolute
-uniformity of composition, and absolute symmetry of relation to all
-forces external to it; its concentration must go on with an
-ever-increasing irregularity; and that thus the present aspect of the
-heavens is not, so far as we can judge, incongruous with the hypothesis
-of a general evolution consequent on the instability of the homogeneous.
-
-Descending to that more limited form of the nebular hypothesis which
-regards the solar system as having resulted by gradual concentration;
-and assuming this concentration to have advanced so far as to produce a
-rotating spheroid of nebulous matter; let us consider what further
-consequence the instability of the homogeneous necessitates. Having
-become oblate in figure, unlike in the densities of its centre and
-surface, unlike in their temperatures, and unlike in the velocities with
-which its parts move round their common axis, such a mass can no longer
-be called homogeneous; and therefore any further changes exhibited by it
-as a whole, can illustrate the general law, only as being changes from a
-more homogeneous to a less homogeneous state. Changes of this kind are
-to be found in the transformations of such of its parts as are still
-homogeneous within themselves. If we accept the conclusion of Laplace,
-that the equatorial portion of this rotating and contracting spheroid
-will at successive stages acquire a centrifugal force great enough to
-prevent any nearer approach to the centre round which it rotates, and
-will so be left behind by the inner parts of the spheroid in its
-still-continued contraction; we shall find, in the fate of the detached
-ring, a fresh exemplification of the principle we are following out.
-Consisting of gaseous matter, such a ring, even if absolutely uniform at
-the time of its detachment, cannot continue so. To maintain its
-equilibrium there must be an almost perfect uniformity in the action of
-all external forces upon it (almost, we must say, because the cohesion,
-even of extremely attenuated matter, might suffice to neutralize very
-minute disturbances); and against this the probabilities are immense. In
-the absence of equality among the forces, internal and external, acting
-on such a ring, there must be a point or points at which the cohesion of
-its parts is less than elsewhere—a point or points at which rupture will
-therefore take place. Laplace assumed that the ring would rupture at one
-place only; and would then collapse on itself. But this is a more than
-questionable assumption—such at least I know to be the opinion of an
-authority second to none among those now living. So vast a ring,
-consisting of matter having such feeble cohesion, must break up into
-many parts. Nevertheless, it is still inferrable from the instability of
-the homogeneous, that the ultimate result which Laplace predicted would
-take place. For even supposing the masses of nebulous matter into which
-such a ring separated, were so equal in their sizes and distances as to
-attract each other with exactly equal forces (which is infinitely
-improbable); yet the unequal action of external disturbing forces would
-inevitably destroy their equilibrium—there would be one or more points
-at which adjacent masses would begin to part company. Separation once
-commenced, would with ever-accelerating speed lead to a grouping of the
-masses. And obviously a like result would eventually take place with the
-groups thus formed; until they at length aggregated into a single mass.
-
-Leaving the region of speculative astronomy, let us consider the Solar
-System as it at present exists. And here it will be well, in the first
-place, to note a fact which may be thought at variance with the
-foregoing argument—namely, the still-continued existence of Saturn’s
-rings; and especially of the internal nebulous ring lately discovered.
-To the objection that the outer rings maintain their equilibrium, the
-reply is that the comparatively great cohesion of liquid or solid
-substance would suffice to prevent any slight tendency to rupture from
-taking effect. And that a nebulous ring here still preserves its
-continuity, does not really negative the foregoing conclusion; since it
-happens under the quite exceptional influence of those symmetrically
-disposed forces which the external rings exercise on it. Here
-indeed it deserves to be noted, that though at first sight the Saturnian
-system appears at variance with the doctrine that a state of homogeneity
-is one of unstable equilibrium, it does in reality furnish a curious
-confirmation of this doctrine. For Saturn is not quite concentric with
-his rings; and it has been proved mathematically that were he and his
-rings concentrically situated, they could not remain so: the homogeneous
-relation being unstable, would gravitate into a heterogeneous one. And
-this fact serves to remind us of the allied one presented throughout the
-whole Solar System. All orbits, whether of planets or satellites, are
-more or less excentric—none of them are perfect circles; and were they
-perfect circles they would soon become ellipses. Mutual perturbations
-would inevitably generate excentricities. That is to say, the
-homogeneous relations would lapse into heterogeneous ones.
-
- * * * * *
-
-§ 111. Already so many references have been made to the gradual
-formation of a crust over the originally incandescent Earth, that it may
-be thought superfluous again to name it. It has not, however, been
-before considered in connexion with the general principle under
-discussion. Here then it must be noted as a necessary consequence of the
-instability of the homogeneous. In this cooling down and solidification
-of the Earth’s surface, we have one of the simplest, as well as one of
-the most important, instances, of that change from a uniform to a
-multiform state which occurs in any mass through exposure of its
-different parts to different conditions. To the differentiation of
-the Earth’s exterior from its interior thus brought about, we must add
-one of the most conspicuous differentiations which the exterior itself
-afterwards undergoes, as being similarly brought about. Were the
-conditions to which the surface of the Earth is exposed, alike in all
-directions, there would be no obvious reason why certain of its parts
-should become permanently unlike the rest. But being unequally exposed
-to the chief external centre of force—the Sun—its main divisions become
-unequally modified: as the crust thickens and cools, there arises that
-contrast, now so decided, between the polar and equatorial regions.
-
-Along with these most marked physical differentiations of the Earth,
-which are manifestly consequent on the instability of the homogeneous,
-there have been going on numerous chemical differentiations, admitting
-of similar interpretation. Without raising the question whether, as some
-think, the so-called simple substances are themselves compounded of
-unknown elements (elements which we cannot separate by artificial heat,
-but which existed separately when the heat of the Earth was greater than
-any which we can produce),—without raising this question, it will
-suffice the present purpose to show how, in place of that comparative
-homogeneity of the Earth’s crust, chemically considered, which must have
-existed when its temperature was high, there has arisen, during its
-cooling, an increasing chemical heterogeneity: each element or compound,
-being unable to maintain its homogeneity in presence of various
-surrounding affinities, having fallen into heterogeneous combinations.
-Let us contemplate this change somewhat in detail. There is every
-reason to believe that at an extreme heat, the bodies we call elements
-cannot combine. Even under such heat as can be generated artificially,
-some very strong affinities yield; and the great majority of chemical
-compounds are decomposed at much lower temperatures. Whence it seems not
-improbable that, when the Earth was in its first state of incandescence,
-there were no chemical combinations at all. But without drawing this
-inference, let us set out with the unquestionable fact that the
-compounds which can exist at the highest temperatures, and which must
-therefore have been the first formed as the Earth cooled, are those of
-the simplest constitutions. The protoxides—including under that head the
-alkalies, earths, &c.—are, as a class, the most fixed compounds known:
-the majority of them resisting decomposition by any heat we can
-generate. These, consisting severally of one atom of each component
-element, are combinations of the simplest order—are but one degree less
-homogeneous than the elements themselves. More heterogeneous than these,
-more decomposable by heat, and therefore later in the Earth’s history,
-are the deutoxides, tritoxides, peroxides, &c.; in which two, three,
-four, or more atoms of oxygen are united with one atom of metal or other
-base. Still less able to resist heat, are the salts; which present us
-with compound atoms each made up of five, six, seven, eight, ten,
-twelve, or more atoms, of three, if not more, kinds. Then there are the
-hydrated salts, of a yet greater heterogeneity, which undergo partial
-decomposition at much lower temperatures. After them come the
-further-complicated supersalts and double salts, having a stability
-again decreased; and so throughout. After making a few unimportant
-qualifications demanded by peculiar affinities, I believe no chemist
-will deny it to be a general law of these inorganic combinations that,
-other things equal, the stability decreases as the complexity increases.
-And then when we pass to the compounds that make up organic bodies, we
-find this general law still further exemplified: we find much greater
-complexity and much less stability. An atom of albumen, for instance,
-consists of 482 ultimate atoms of five different kinds. Fibrine, still
-more intricate in constitution, contains in each atom, 298 atoms of
-carbon, 49 of nitrogen, 2 of sulphur, 228 of hydrogen, and 92 of
-oxygen—in all, 660 atoms; or, more strictly speaking—equivalents. And
-these two substances are so unstable as to decompose at quite moderate
-temperatures; as that to which the outside of a joint of roast meat is
-exposed. Possibly it will be objected that some inorganic compounds, as
-phosphuretted hydrogen and chloride of nitrogen, are more decomposable
-than most organic compounds. This is true. But the admission may be made
-without damage to the argument. The proposition is not that _all_ simple
-combinations are more fixed than _all_ complex ones. To establish our
-inference it is necessary only to show that, as an _average fact_, the
-simple combinations can exist at a higher temperature than the complex
-ones. And this is wholly beyond question. Thus it is manifest that
-the present chemical heterogeneity of the Earth’s surface has arisen by
-degrees as the decrease of heat has permitted; and that it has shown
-itself in three forms—first, in the multiplication of chemical
-compounds; second, in the greater number of different elements contained
-in the more modern of these compounds; and third, in the higher and more
-varied multiples in which these more numerous elements combine.
-
-Without specifying them, it will suffice just to name the meteorologic
-processes eventually set up in the Earth’s atmosphere, as further
-illustrating the alleged law. They equally display that destruction of a
-homogeneous state which results from unequal exposure to incident
-forces.
-
- * * * * *
-
-§ 112. Take a mass of unorganized but organizable matter—either the body
-of one of the lowest living forms, or the germ of one of the higher.
-Consider its circumstances. Either it is immersed in water or air, or it
-is contained within a parent organism. Wherever placed, however, its
-outer and inner parts stand differently related to surrounding
-agencies—nutriment, oxygen, and the various stimuli. But this is not
-all. Whether it lies quiescent at the bottom of the water or on the leaf
-of a plant; whether it moves through the water preserving some definite
-attitude; or whether it is in the inside of an adult; it equally results
-that certain parts of its surface are more exposed to surrounding
-agencies than other parts—in some cases more exposed to light, heat, or
-oxygen, and in others to the maternal tissues and their contents. Hence
-must follow the destruction of its original equilibrium. This may take
-place in one of two ways. Either the disturbing forces may be such as to
-overbalance the affinities of the organic elements, in which case there
-result those changes which are known as decomposition; or, as is
-ordinarily the case, such changes are induced as do not destroy the
-organic compounds, but only modify them: the parts most exposed to the
-modifying forces being most modified. To elucidate this, suppose we take
-a few cases.
-
-Note first what appear to be exceptions. Certain minute animal forms
-present us either with no appreciable differentiations or with
-differentiations so obscure as to be made out with great difficulty. In
-the Rhizopods, the substance of the jelly-like body remains throughout
-life unorganized, even to the extent of having no limiting membrane; as
-is proved by the fact that the thread-like processes protruded by the
-mass, coalesce on touching each other. Whether or not the nearly allied
-_Amœba_, of which the less numerous and more bulky processes do not
-coalesce, has, as lately alleged, something like a cell-wall and a
-nucleus, it is clear that the distinction of parts is very slight; since
-particles of food pass bodily into the inside through any part of the
-periphery, and since when the creature is crushed to pieces, each piece
-behaves as the whole did. Now these cases, in which there is either no
-contrast of structure between exterior and interior or very little,
-though seemingly opposed to the above inference, are really very
-significant evidences of its truth. For what is the peculiarity of this
-division of the _Protozoa_? Its members undergo perpetual and irregular
-changes of form—they show no persistent relation of parts. What lately
-formed a portion of the interior is now protruded, and, as a temporary
-limb, is attached to some object it happens to touch. What is now a part
-of the surface will presently be drawn, along with the atom of nutriment
-sticking to it, into the centre of the mass. Either the relations of
-inner and outer have no permanent existence, or they are very slightly
-marked. But by the hypothesis, it is only because of their unlike
-positions with respect to modifying forces, that the originally like
-units of a living mass become unlike. We must therefore expect no
-established differentiation of parts in creatures which exhibit no
-established differences of position in their parts; and we must expect
-extremely little differentiation of parts where the differences of
-position are but little determined—which is just what we find.
- This negative evidence is borne out by positive evidence. When we
-turn from these proteiform specks of living jelly to organisms having an
-unchanging distribution of substance, we find differences of tissue
-corresponding to differences of relative position. In all the higher
-_Protozoa_, as also in the _Protophyta_, we meet with a fundamental
-differentiation into cell-membrane and cell-contents; answering to that
-fundamental contrast of conditions implied by the terms outside and
-inside. On passing from what are roughly classed as unicellular
-organisms, to the lowest of those which consist of aggregated cells, we
-equally observe the connection between structural differences and
-differences of circumstance. Negatively, we see that in the sponge,
-permeated throughout by currents of sea-water, the indefiniteness of
-organization corresponds with the absence of definite unlikeness of
-conditions: the peripheral and central portions are as little contrasted
-in structure as in exposure to surrounding agencies. While positively,
-we see that in a form like the _Thalassicolla_, which, though equally
-humble, maintains its outer and inner parts in permanently unlike
-circumstances, there is displayed a rude structure obviously
-subordinated to the primary relations of centre and surface: in all its
-many and important varieties, the parts exhibit a more or less
-concentric arrangement.
-
-After this primary modification, by which the outer tissues are
-differentiated from the inner, the next in order of constancy and
-importance is that by which some part of the outer tissues is
-differentiated from the rest; and this corresponds with the almost
-universal fact that some part of the outer tissues is more exposed to
-certain environing influences than the rest. Here, as before, the
-apparent exceptions are extremely significant. Some of the lowest
-vegetal organisms, as the _Hematococci_ and _Protococci_, evenly
-imbedded in a mass of mucus, or dispersed through the Arctic snow,
-display no differentiations of surface; the several parts of their
-surfaces being subjected to no definite contrasts of conditions.
-Ciliated spheres such as the _Volvox_ have no parts of their periphery
-unlike other parts; and it is not to be expected that they should have;
-since, as they revolve in all directions, they do not, in traversing the
-water, permanently expose any part to special conditions. But when we
-come to organisms that are either fixed, or while moving preserve
-definite attitudes, we no longer find uniformity of surface. The most
-general fact which can be asserted with respect to the structures of
-plants and animals, is, that however much alike in shape and texture the
-various parts of the exterior may at first be, they acquire unlikenesses
-corresponding to the unlikenesses of their relations to surrounding
-agencies. The ciliated germ of a Zoophyte, which, during its locomotive
-stage, is distinguishable only into outer and inner tissues, no sooner
-becomes fixed, than its upper end begins to assume a different structure
-from its lower. The disc-shaped _gemmæ_ of the _Marchantia_, originally
-alike on both surfaces, and falling at random with either side
-uppermost, immediately begin to develop rootlets on the under side, and
-_stomata_ on the upper side: a fact proving beyond question, that this
-primary differentiation is determined by this fundamental contrast of
-conditions.
-
-Of course in the germs of higher organisms, the metamorphoses
-immediately due to the instability of the homogeneous, are soon masked
-by those due to the assumption of the hereditary type. Such early
-changes, however, as are common to all classes of organisms, and so
-cannot be ascribed to heredity, entirely conform to the hypothesis. A
-germ which has undergone no developmental modifications, consists of a
-spheroidal group of homogeneous cells. Universally, the first step in
-its evolution is the establishment of a difference between some of the
-peripheral cells and the cells which form the interior—some of the
-peripheral cells, after repeated spontaneous fissions, coalesce into a
-membrane; and by continuance of the process this membrane spreads until
-it speedily invests the entire mass, as in mammals, or, as in birds,
-stops short of that for some time. Here we have two significant facts.
-The first is, that the primary unlikeness arises between the exterior
-and the interior. The second is, that the change which thus initiates
-development, does not take place simultaneously over the whole exterior;
-but commences at one place, and gradually involves the rest. Now these
-facts are just those which might be inferred from the instability of the
-homogeneous. The surface must, more than any other part, become unlike
-the centre, because it is most dissimilarly conditioned; and all parts
-of the surface cannot simultaneously exhibit this differentiation,
-because they cannot be exposed to the incident forces with absolute
-uniformity. One other general fact of like implication remains.
-Whatever be the extent of this peripheral layer of cells, or blastoderm
-as it is called, it presently divides into two layers—the serous and
-mucous; or, as they have been otherwise called, the ectoderm and the
-endoderm. The first of these is formed from that portion of the layer
-which lies in contact with surrounding agents; and the second of them is
-formed from that portion of the layer which lies in contact with the
-contained mass of yelk. That is to say, after the primary
-differentiation, more or less extensive, of surface from centre, the
-resulting superficial portion undergoes a secondary differentiation into
-inner and outer parts—a differentiation which is clearly of the same
-order with the preceding, and answers to the next most marked contrast
-of conditions.
-
-But, as already hinted, this principle, understood in the simple form
-here presented, supplies no key to the detailed phenomena of organic
-development. It fails entirely to explain generic and specific
-peculiarities; and indeed leaves us equally in the dark respecting those
-more important distinctions by which families and orders are marked out.
-Why two ova, similarly exposed in the same pool, should become the one a
-fish, and the other a reptile, it cannot tell us. That from two
-different eggs placed under the same hen, should respectively come forth
-a duckling and a chicken, is a fact not to be accounted for on the
-hypothesis above developed. We have here no alternative but to fall back
-upon the unexplained principle of hereditary transmission. The capacity
-possessed by an unorganized germ of unfolding into a complex adult,
-which repeats ancestral traits in the minutest details, and that even
-when it has been placed in conditions unlike those of its ancestors, is
-a capacity we cannot at present understand. That a microscopic portion
-of seemingly structureless matter should embody an influence of such
-kind, that the resulting man will in fifty years after become gouty or
-insane, is a truth which would be incredible were it not daily
-illustrated. Should it however turn out, as we shall hereafter
-find reason for suspecting, that these complex differentiations which
-adults exhibit, are themselves the slowly accumulated and transmitted
-results of a process like that seen in the first changes of the germ; it
-will follow that even those embryonic changes due to hereditary
-influence, are remote consequences of the alleged law. Should it be
-shown that the slight modifications wrought during life on each adult,
-and bequeathed to offspring along with all like preceding modifications,
-are themselves unlikenesses of parts that are produced by unlikenesses
-of conditions; then it will follow that the modifications displayed in
-the course of embryonic development, are partly direct consequences of
-the instability of the homogeneous, and partly indirect consequences of
-it. To give reasons for entertaining this hypothesis, however, is
-not needful for the justification of the position here taken. It is
-enough that the most conspicuous differentiations which incipient
-organisms universally display, correspond to the most marked differences
-of conditions to which their parts are subject. It is enough that the
-habitual contrast between outside and inside, which we _know_ is
-produced in inorganic masses by unlikeness of exposure to incident
-forces, is strictly paralleled by the first contrast that makes its
-appearance in all organic masses.
-
-It remains to point out that in the assemblage of organisms
-constituting a species, the principle enunciated is equally traceable.
-We have abundant materials for the induction that each species will
-not remain uniform, but is ever becoming to some extent multiform; and
-there is ground for the deduction that this lapse from homogeneity to
-heterogeneity is caused by the subjection of its members to unlike
-sets of circumstances. The fact that in every species, animal and
-vegetal, the individuals are never quite alike; joined with the fact
-that there is in every species a tendency to the production of
-differences marked enough to constitute varieties; form a sufficiently
-wide basis for the induction. While the deduction is confirmed by the
-familiar experience that varieties are most numerous and decided
-where, as among cultivated plants and domestic animals, the conditions
-of life depart from the original ones, most widely and in the most
-numerous ways. Whether we regard “natural selection” as wholly, or
-only in part, the agency through which varieties are established,
-matters not to the general conclusion. For as the survival of any
-variety proves its constitution to be in harmony with a certain
-aggregate of surrounding forces—as the multiplication of a variety and
-the usurpation by it of an area previously occupied by some other part
-of the species, implies different effects produced by such aggregate
-of forces on the two, it is clear that this aggregate of forces is the
-real cause of the differentiation—it is clear that if the variety
-supplants the original species in some localities but not in others,
-it does so because the aggregate of forces in the one locality is
-unlike that in the other—it is clear that the lapse of the species
-from a state of homogeneity to a state of heterogeneity arises from
-the exposure of its different parts to different aggregates of forces.
-
- * * * * *
-
-§ 113. Among mental phenomena it is difficult to establish the alleged
-law without an analysis too extensive for the occasion. To show
-satisfactorily how states of consciousness, originally homogeneous,
-become heterogeneous through differences in the changes wrought by
-different forces, would require us carefully to trace out the
-organization of early experiences. Were this done it would become
-manifest that the development of intelligence, is, under one of its
-chief aspects, a dividing into separate classes, the unlike things
-previously confounded together in one class—a formation of sub-classes
-and sub-sub-classes, until the once confused aggregate of objects known,
-is resolved into an aggregate which unites extreme heterogeneity among
-its multiplied groups, with complete homogeneity among the members of
-each group. If, for example, we followed, through ascending grades of
-creatures, the genesis of that vast structure of knowledge acquired by
-sight, we should find that in the first stage, where eyes suffice for
-nothing beyond the discrimination of light from darkness, the only
-possible classifications of objects seen, must be those based on the
-manner in which light is obstructed, and the degree in which it is
-obstructed. We should find that by such undeveloped visual organs, the
-shadows traversing the rudimentary retina would be merely distinguished
-into those of the stationary objects which the creature passed during
-its own movements, and those of the moving objects which came near the
-creature while it was at rest; and that so the extremely general
-classification of visible things into stationary and moving, would be
-the earliest formed. We should find that whereas the simplest eyes are
-not fitted to distinguish between an obstruction of light caused by a
-small object close to, and an obstruction caused by a large object at
-some distance, eyes a little more developed must be competent to such a
-distinction; whence must result a vague differentiation of the class of
-moving objects, into the nearer and the more remote. We should find that
-such further improvements in vision as those which make possible a
-better estimation of distances by adjustment of the optic axes, and
-those which, through enlargement and subdivision of the retina, make
-possible the discrimination of shapes, must have the effects of giving
-greater definiteness to the classes already formed, and of sub-dividing
-these into smaller classes, consisting of objects less unlike. And we
-should find that each additional refinement of the perceptive organs,
-must similarly lead to a multiplication of divisions and a sharpening of
-the limits of each division. In every infant might be traced the
-analogous transformation of a confused aggregate of impressions of
-surrounding objects, not recognized as differing in their distances,
-sizes, and shapes, into separate classes of objects unlike each other in
-these and various other respects. And in the one case as in the other,
-it might be shown that the change from this first indefinite, incoherent
-and comparatively homogeneous consciousness, to a definite, coherent,
-and heterogeneous one, is due to differences in the actions of incident
-forces on the organism. These brief indications of what might be
-shown, did space permit, must here suffice. Probably they will give
-adequate clue to an argument by which each reader may satisfy himself
-that the course of mental evolution offers no exception to the general
-law. In further aid of such an argument, I will here add an illustration
-that is comprehensible apart from the process of mental evolution as a
-whole.
-
-It has been remarked (I am told by Coleridge, though I have been unable
-to find the passage) that with the advance of language, words which were
-originally alike in their meanings acquire unlike meanings—a change
-which he expresses by the formidable word “desynonymization.” Among
-indigenous words this loss of equivalence cannot be clearly shown;
-because in them the divergencies of meaning began before the dawn of
-literature. But among words that have been coined, or adopted from other
-languages, since the writing of books commenced, it is demonstrable. In
-the old divines, _miscreant_ is used in its etymological sense of
-_unbeliever_; but in modern speech it has entirely lost this sense.
-Similarly with _evil-doer_ and _malefactor_: exactly synonymous as these
-are by derivation, they are no longer synonymous by usage: by a
-_malefactor_ we now understand a convicted criminal, which is far from
-being the acceptation of _evil-doer_. The verb _produce_, bears in
-Euclid its primary meaning—to _prolong_, or _draw out_; but the now
-largely developed meanings of _produce_ have little in common with the
-meanings of _prolong_, or _draw out_. In the Church of England liturgy,
-an odd effect results from the occurrence of _prevent_ in its original
-sense—_to come before_, instead of its modern specialized sense—_to come
-before with the effect of arresting_. But the most conclusive cases are
-those in which the contrasted words consist of the same parts
-differently combined; as in _go under_ and _undergo_. We _go under_ a
-tree, and we _undergo_ a pain. But though, if analytically considered,
-the meanings of these expressions would be the same were the words
-transposed, habit has so far modified their meanings that we could not
-without absurdity speak of _undergoing_ a tree and _going under_ a pain.
- Countless such instances might be brought to show that between two
-words which are originally of like force, an equilibrium cannot be
-maintained. Unless they are daily used in exactly equal degrees, in
-exactly similar relations (against which there are infinite
-probabilities), there necessarily arises a habit of associating one
-rather than the other with particular acts, or objects. Such a habit,
-once commenced, becomes confirmed; and gradually their homogeneity of
-meaning disappears. In each individual we may see the tendency which
-inevitably leads to this result. A certain vocabulary and a certain set
-of phrases, distinguish the speech of each person: each person
-habitually uses certain words in places where other words are habitually
-used by other persons; and there is a continual recurrence of favourite
-expressions. This inability to maintain a balance in the use of verbal
-symbols, which characterizes every man, characterizes, by consequence,
-aggregates of men; and the desynonymization of words is the ultimate
-effect.
-
-Should any difficulty be felt in understanding how these mental changes
-exemplify a law of physical transformations that are wrought by physical
-forces, it will disappear on contemplating acts of mind as nervous
-functions. It will be seen that each loss of equilibrium above
-instanced, is a loss of functional equality between some two elements of
-the nervous system. And it will be seen that, as in other cases, this
-loss of functional equality is due to differences in the incidence of
-forces.
-
- * * * * *
-
-§ 114. Masses of men, in common with all other masses, show a like
-proclivity similarly caused. Small combinations and large societies
-equally manifest it; and in the one, as in the other, both governmental
-and industrial differentiations are initiated by it. Let us glance at
-the facts under these two heads.
-
-A business partnership, balanced as the authorities of its members may
-theoretically be, practically becomes a union in which the authority of
-one partner is tacitly recognized as greater than that of the other or
-others. Though the shareholders have given equal powers to the directors
-of their company, inequalities of power soon arise among them; and
-usually the supremacy of some one director grows so marked, that his
-decisions determine the course which the board takes. Nor in
-associations for political, charitable, literary, or other purposes, do
-we fail to find a like process of division into dominant and subordinate
-parties; each having its leader, its members of less influence, and its
-mass of uninfluential members. These minor instances in which
-unorganized groups of men, standing in homogeneous relations, may be
-watched gradually passing into organized groups of men standing in
-heterogeneous relations, give us the key to social inequalities.
-Barbarous and civilized communities are alike characterized by
-separation into classes, as well as by separation of each class into
-more important and less important units; and this structure is
-manifestly the gradually-consolidated result of a process like that
-daily exemplified in trading and other combinations. So long as men are
-constituted to act on one another, either by physical force or by force
-of character, the struggles for supremacy must finally be decided in
-favour of some one; and the difference once commenced must tend to
-become ever more marked. Its unstable equilibrium being destroyed, the
-uniform must gravitate with increasing rapidity into the multiform. And
-so supremacy and subordination must establish themselves, as we see they
-do, throughout the whole structure of a society, from the great
-class-divisions pervading its entire body, down to village cliques, and
-even down to every posse of school-boys. Probably it will be
-objected that such changes result, not from the homogeneity of the
-original aggregations, but from their non-homogeneity—from certain
-slight differences existing among their units at the outset. This is
-doubtless the proximate cause. In strictness, such changes must be
-regarded as transformations of the relatively homogeneous into the
-relatively heterogeneous. But it is abundantly clear that an aggregation
-of men, absolutely alike in their endowments, would eventually undergo a
-similar transformation. For in the absence of perfect uniformity in the
-lives severally led by them—in their occupations, physical conditions,
-domestic relations, and trains of thought and feeling—there must arise
-differences among them; and these must finally initiate social
-differentiations. Even inequalities of health caused by accidents, must,
-by entailing inequalities of physical and mental power, disturb the
-exact balance of mutual influences among the units; and the balance once
-disturbed, must inevitably be lost. Whence, indeed, besides seeing that
-a body of men absolutely homogeneous in their governmental relations,
-must, like all other homogeneous bodies, become heterogeneous, we also
-see that it must do this from the same ultimate cause—unequal exposure
-of its parts to incident forces.
-
-The first industrial divisions of societies are much more obviously due
-to unlikenesses of external circumstances. Such divisions are absent
-until such unlikenesses are established. Nomadic tribes do not
-permanently expose any groups of their members to special local
-conditions; nor does a stationary tribe, when occupying only a small
-area, maintain from generation to generation marked contrasts in the
-local conditions of its members; and in such tribes there are no decided
-economical differentiations. But a community which, growing populous,
-has overspread a large tract, and has become so far settled that its
-members live and die in their respective districts, keeps its several
-sections in different physical circumstances; and then they no longer
-remain alike in their occupations. Those who live dispersed continue to
-hunt or cultivate the earth; those who spread to the sea-shore fall into
-maritime occupations; while the inhabitants of some spot chosen, perhaps
-for its centrality, as one of periodical assemblage, become traders, and
-a town springs up. Each of these classes undergoes a modification of
-character consequent on its function, and better fitting it to its
-function. Later in the process of social evolution these local
-adaptations are greatly multiplied. A result of differences in soil and
-climate, is that the rural inhabitants in different parts of the kingdom
-have their occupations partially specialized; and become respectively
-distinguished as chiefly producing cattle, or sheep, or wheat, or oats,
-or hops, or cyder. People living where coal-fields are discovered are
-transformed into colliers; Cornishmen take to mining because Cornwall is
-metalliferous; and the iron-manufacture is the dominant industry where
-ironstone is plentiful. Liverpool has assumed the office of importing
-cotton, in consequence of its proximity to the district where cotton
-goods are made; and for analogous reasons, Hull has become the chief
-port at which foreign wools are brought in. Even in the establishment of
-breweries, of dye-works, of slate-quarries, of brickyards, we may see
-the same truth. So that both in general and in detail, the
-specializations of the social organism which characterize separate
-districts, primarily depend on local circumstances. Those divisions of
-labour which under another aspect were interpreted as due to the setting
-up of motion in the directions of least resistance (§ 91), are here
-interpreted as due to differences in the incident forces; and the two
-interpretations are quite consistent with each other. For that which in
-each case _determines_ the direction of least resistance, is the
-distribution of the forces to be overcome; and hence unlikenesses of
-distribution in separate localities, entails unlikenesses in the course
-of human action in those localities—entails industrial differentiations.
-
- * * * * *
-
-§ 115. In common with the general truths set forth in preceding
-chapters, the instability of the homogeneous is demonstrable _à priori_.
-It, like each of them, is a corollary from the persistence of force.
-Already this has been tacitly implied by assigning unlikeness in the
-exposure of its part to surrounding agencies, as the reason why a
-uniform mass loses its uniformity. But here it will be proper to expand
-this tacit implication into definite proof.
-
-On striking a mass of matter with such force as either to indent it or
-make it fly to pieces, we see both that the blow affects differently its
-different parts, and that the differences are consequent on the unlike
-relations of its parts to the force impressed. The part with which the
-striking body comes in contact, receiving the whole of the communicated
-momentum, is driven in towards the centre of the mass. It thus
-compresses and tends to displace the more centrally situated portions of
-the mass. These, however, cannot be compressed or thrust out of their
-places without pressing on all surrounding portions. And when the blow
-is violent enough to fracture the mass, we see, in the radial dispersion
-of its fragments, that the original momentum, in being distributed
-throughout it, has been divided into numerous minor momenta, unlike in
-their directions. We see that these directions are determined by the
-positions of the parts with respect to each other, and with respect to
-the point of impact. We see that the parts are differently affected by
-the disruptive force, because they are differently related to it in
-their directions and attachments—that the effects being the joint
-products of the cause and the conditions, cannot be alike in parts which
-are differently conditioned. A body on which radiant heat is
-falling, exemplifies this truth still more clearly. Taking the simplest
-case (that of a sphere) we see that while the part nearest to the
-radiating centre receives the rays at right angles, the rays strike the
-other parts of the exposed side at all angles from 90° down to 0°.
-Again, the molecular vibrations propagated through the mass from the
-surface which receives the heat, must proceed inwards at angles
-differing for each point. Further, the interior parts of the sphere
-affected by the vibrations proceeding from all points of the heated
-side, must be dissimilarly affected in proportion as their positions are
-dissimilar. So that whether they be on the recipient area, in the
-middle, or at the remote side, the constituent atoms are all thrown into
-states of vibration more or less unlike each other.
-
-But now, what is the ultimate meaning of the conclusion that a uniform
-force produces different changes throughout a uniform mass, because the
-parts of the mass stand in different relations to the force? Fully to
-understand this, we must contemplate each part as simultaneously subject
-to other forces—those of gravitation, of cohesion, of molecular motion,
-&c. The effect wrought by an additional force, must be a resultant of it
-and the forces already in action. If the forces already in action on two
-parts of any aggregate, are different in their directions, the effects
-produced on these two parts by like forces must be different in their
-directions. Why must they be different? They must be different because
-such unlikeness as exists between the two sets of factors, is made by
-the presence in the one of some specially-directed force that is not
-present in the other; and that this force will produce an effect,
-rendering the total result in the one case unlike that in the other, is
-a necessary corollary from the persistence of force. Still more
-manifest does it become that the dissimilarly-placed parts of any
-aggregate must be dissimilarly modified by an incident force, when we
-remember that the _quantities_ of the incident force to which they are
-severally subject, are not equal, as above supposed; but are nearly
-always very unequal. The outer parts of masses are usually alone exposed
-to chemical actions; and not only are their inner parts shielded from
-the affinities of external elements, but such affinities are brought to
-bear unequally on their surfaces; since chemical action sets up currents
-through the medium in which it takes place, and so brings to the various
-parts of the surface unequal quantities of the active agent. Again, the
-amounts of any external radiant force which the different parts of an
-aggregate receive, are widely contrasted: we have the contrast between
-the quantity falling on the side next the radiating centre, and the
-quantity, or rather no quantity, falling on the opposite side; we have
-contrasts in the quantities received by differently-placed areas on the
-exposed side; and we have endless contrasts between the quantities
-received by the various parts of the interior. Similarly when mechanical
-force is expended on any aggregate, either by collision, continued
-pressure, or tension, the amounts of strain distributed throughout the
-mass are manifestly unlike for unlike positions. But to say the
-different parts of an aggregate receive different quantities of any
-incident force, is to say that their states are modified by it in
-different degrees—is to say that if they were before homogeneous in
-their relations they must be rendered to a proportionate extent
-heterogeneous; since, force being persistent, the different quantities
-of it falling on the different parts, must work in them different
-quantities of effect—different changes. Yet one more kindred
-deduction is required to complete the argument. We may, by parallel
-reasoning, reach the conclusion that, even apart from the action of any
-external force, the equilibrium of a homogeneous aggregate must be
-destroyed by the unequal actions of its parts on each other. That mutual
-influence which produces aggregation (not to mention other mutual
-influences) must work different effects on the different parts; since
-they are severally exposed to it in unlike amounts and directions. This
-will be clearly seen on remembering that the portions of which the whole
-is made up, may be severally regarded as minor wholes; that on each of
-these minor wholes, the action of the entire aggregate then becomes an
-external incident force; that such external incident force must, as
-above shown, work unlike changes in the parts of any such minor whole;
-and that if the minor wholes are severally thus rendered heterogeneous,
-the entire aggregate is rendered heterogeneous.
-
-The instability of the homogeneous is thus deducible from that
-primordial truth which underlies our intelligence. One stable
-homogeneity only, is hypothetically possible. If centres of force,
-absolutely uniform in their powers, were diffused with absolute
-uniformity through unlimited space, they would remain in equilibrium.
-This however, though a verbally intelligible supposition, is one that
-cannot be represented in thought; since unlimited space is
-inconceivable. But all finite forms of the homogeneous—all forms of it
-which we can know or conceive, must inevitably lapse into heterogeneity.
-In three several ways does the persistence of force necessitate this.
-Setting external agencies aside, each unit of a homogeneous whole must
-be differently affected from any of the rest by the aggregate action of
-the rest upon it. The resultant force exercised by the aggregate on each
-unit, being in no two cases alike in both amount and direction, and
-usually not in either, any incident force, even if uniform in amount and
-direction, cannot produce like effects on the units. And the various
-positions of the parts in relation to any incident force, preventing
-them from receiving it in uniform amounts and directions, a further
-difference in the effects wrought on them is inevitably produced.
-
-One further remark is needed. To the conclusion that the changes with
-which Evolution _commences_, are thus necessitated, remains to be added
-the conclusion that these changes must _continue_. The absolutely
-homogeneous must lose its equilibrium; and the relatively homogeneous
-must lapse into the relatively less homogeneous. That which is true of
-any total mass, is true of the parts into which it segregates. The
-uniformity of each such part must as inevitably be lost in multiformity,
-as was that of the original whole; and for like reasons. And thus the
-continued changes which characterize Evolution, in so far as they are
-constituted by the lapse of the homogeneous into the heterogeneous, and
-of the less heterogeneous into the more heterogeneous, are necessary
-consequences of the persistence of force.
-
------
-
-Footnote 16:
-
- The idea developed in this chapter originally formed part of an
- article on “Transcendental Physiology,” published in 1857. See
- _Essays_, pp. 279–290.
-
-
-
-
- CHAPTER XIV.
- THE MULTIPLICATION OF EFFECTS.
-
-
-§ 116. To the cause of increasing complexity set forth in the last
-chapter, we have in this chapter to add another. Though secondary in
-order of time, it is scarcely secondary in order of importance. Even in
-the absence of the cause already assigned, it would necessitate a change
-from the homogeneous to the heterogeneous; and joined with it, it makes
-this change both more rapid and more involved. To come in sight of it,
-we have but to pursue a step further, that conflict between force and
-matter already delineated. Let us do this.
-
-When a uniform aggregate is subject to a uniform force, we have seen
-that its constituents, being differently conditioned, are differently
-modified. But while we have contemplated the various parts of the
-aggregate as thus undergoing unlike changes, we have not yet
-contemplated the unlike changes simultaneously produced on the various
-parts of the incident force. These must be as numerous and important as
-the others. Action and re-action being equal and opposite, it follows
-that in differentiating the parts on which it falls in unlike ways, the
-incident force must itself be correspondingly differentiated. Instead of
-being as before, a uniform force, it must thereafter be a multiform
-force—a group of dissimilar forces. A few illustrations will make this
-truth manifest.
-
-A single force is divided by conflict with matter into forces that
-widely diverge. In the case lately cited, of a body shattered by violent
-collision, besides the change of the homogeneous mass into a
-heterogeneous group of scattered fragments, there is a change of the
-homogeneous momentum into a group of momenta, heterogeneous in both
-amounts and directions. Similarly with the forces we know as light and
-heat. After the dispersion of these by a radiating body towards all
-points, they are re-dispersed towards all points by the bodies on which
-they fall. Of the Sun’s rays, issuing from him on every side, some few
-strike the Moon. These being reflected at all angles from the Moon’s
-surface, some few of them strike the Earth. By a like process the few
-which reach the Earth are again diffused through surrounding space. And
-on each occasion, such portions of the rays as are absorbed instead of
-reflected, undergo refractions that equally destroy their parallelism.
- More than this is true. By conflict with matter, a uniform force
-is in part changed into forces differing in their directions; and in
-part it is changed into forces differing in their kinds. When one body
-is struck against another, that which we usually regard as the effect,
-is a change of position or motion in one or both bodies. But a moment’s
-thought shows that this is a very incomplete view of the matter. Besides
-the visible mechanical result, sound is produced; or, to speak
-accurately, a vibration in one or both bodies, and in the surrounding
-air: and under some circumstances we call this the effect. Moreover, the
-air has not simply been made to vibrate, but has had currents raised in
-it by the transit of the bodies. Further, if there is not that great
-structural change which we call fracture, there is a disarrangement of
-the particles of the two bodies around their point of collision;
-amounting in some cases to a visible condensation. Yet more, this
-condensation is accompanied by disengagement of heat. In some cases a
-spark—that is, light—results, from the incandescence of a portion struck
-off; and occasionally this incandescence is associated with chemical
-combination. Thus, by the original mechanical force expended in the
-collision, at least five, and often more, different kinds of forces have
-been produced. Take, again, the lighting of a candle. Primarily, this is
-a chemical change consequent on a rise of temperature. The process of
-combination having once been set going by extraneous heat, there is a
-continued formation of carbonic acid, water, &c.—in itself a result more
-complex than the extraneous heat that first caused it. But along with
-this process of combination there is a production of heat; there is a
-production of light; there is an ascending column of hot gases
-generated; there are currents established in the surrounding air. Nor
-does the decomposition of one force into many forces end here. Each of
-the several changes worked becomes the parent of further changes. The
-carbonic acid formed, will by and by combine with some base; or under
-the influence of sunshine give up its carbon to the leaf of a plant. The
-water will modify the hygrometric state of the air around; or, if the
-current of hot gases containing it come against a cold body, will be
-condensed: altering the temperature, and perhaps the chemical state, of
-the surface it covers. The heat given out melts the subjacent tallow,
-and expands whatever it warms. The light, falling on various substances,
-calls forth from them reactions by which it is modified; and so divers
-colours are produced. Similarly even with these secondary actions, which
-may be traced out into ever-multiplying ramifications, until they become
-too minute to be appreciated. Universally, then, the effect is
-more complex than the cause. Whether the aggregate on which it falls be
-homogeneous or otherwise, an incident force is transformed by the
-conflict into a number of forces that differ in their amounts, or
-directions, or kinds; or in all these respects. And of this group of
-variously-modified forces, each ultimately undergoes a like
-transformation.
-
-Let us now mark how the process of evolution is furthered by this
-multiplication of effects. An incident force decomposed by the reactions
-of a body into a group of unlike forces—a uniform force thus reduced to
-a multiform force—becomes the cause of a secondary increase of
-multiformity in the body which decomposes it. In the last chapter we saw
-that the several parts of an aggregate are differently modified by any
-incident force. It has just been shown that by the reactions of the
-differently modified parts, the incident force itself must be divided
-into differently modified parts. Here it remains to point out that each
-differentiated division of the aggregate, thus becomes a centre from
-which a differentiated division of the original force is again diffused.
-And since unlike forces must produce unlike results, each of these
-differentiated forces must produce, throughout the aggregate, a further
-series of differentiations. This secondary cause of the change
-from homogeneity to heterogeneity, obviously becomes more potent in
-proportion as the heterogeneity increases. When the parts into which any
-evolving whole has segregated itself, have diverged widely in nature,
-they will necessarily react very diversely on any incident force—they
-will divide an incident force into so many strongly contrasted groups of
-forces. And each of them becoming the centre of a quite distinct set of
-influences, must add to the number of distinct secondary changes wrought
-throughout the aggregate. Yet another corollary must be added. The
-number of unlike parts of which an aggregate consists, as well as the
-degree of their unlikeness, is an important factor in the process. Every
-additional specialized division is an additional centre of specialized
-forces. If a uniform whole, in being itself made multiform by an
-incident force, makes the incident force multiform; if a whole
-consisting of two unlike sections, divides an incident force into two
-unlike groups of multiform forces; it is clear that each new unlike
-section must be a further source of complication among the forces at
-work throughout the mass—a further source of heterogeneity. The
-multiplication of effects must proceed in geometrical progression. Each
-stage of evolution must initiate a higher stage.
-
- * * * * *
-
-§ 117. The force of aggregation acting on irregular masses of rare
-matter, diffused through a resisting medium, will not cause such masses
-to move in straight lines to their common centre of gravity; but, as
-before said, each will take a curvilinear path, directed to one or other
-side of the centre of gravity. All of them being differently
-conditioned, gravitation will impress on each a motion differing in
-direction, in velocity, and in the degree of its curvature—uniform
-aggregative force will be differentiated into multiform momenta. The
-process thus commenced, must go on till it produces a single mass of
-nebulous matter; and these independent curvilinear motions must result
-in a movement of this mass round its axis: a simultaneous condensation
-and rotation in which we see how two effects of the aggregative force,
-at first but slightly divergent, become at last widely differentiated. A
-gradual increase of oblateness in this revolving spheroid, must take
-place through the joint action of these two forces, as the bulk
-diminishes and the rotation grows more rapid; and this we may set down
-as a third effect. The genesis of heat, which must accompany
-augmentation of density, is a consequence of yet another order—a
-consequence by no means simple; since the various parts of the mass,
-being variously condensed, must be variously heated. Acting throughout a
-gaseous spheroid, of which the parts are unlike in their temperatures,
-the forces of aggregation and rotation must work a further series of
-changes: they must set up circulating currents, both general and local.
-At a later stage light as well as heat will be generated. Thus without
-dwelling on the likelihood of chemical combinations and electric
-disturbances, it is sufficiently manifest that, supposing matter to have
-originally existed in a diffused state, the once uniform force which
-caused its aggregation, must have become gradually divided into
-different forces; and that each further stage of complication in the
-resulting aggregate, must have initiated further subdivisions of this
-force—a further multiplication of effects, increasing the previous
-heterogeneity.
-
-This section of the argument may however be adequately sustained,
-without having recourse to any such hypothetical illustrations as the
-foregoing. The astronomical attributes of the Earth, will even alone
-suffice our purpose. Consider first the effects of its momentum round
-its axis. There is the oblateness of its form; there is the alternation
-of day and night; there are certain constant marine currents; and there
-are certain constant aërial currents. Consider next the secondary series
-of consequences due to the divergence of the Earth’s plane of rotation
-from the plane of its orbit. The many differences of the seasons, both
-simultaneous and successive, which pervade its surface, are thus caused.
-External attraction acting on this rotating oblate spheroid with
-inclined axis, produces the motion called nutation, and that slower and
-larger one from which follows the precession of the equinoxes, with its
-several sequences. And then by this same force are generated the tides,
-aqueous and atmospheric.
-
-Perhaps, however, the simplest way of showing the multiplication of
-effects among phenomena of this order, will be to set down the
-influences of any member of the Solar System on the rest. A planet
-directly produces in neighbouring planets certain appreciable
-perturbations, complicating those otherwise produced in them; and in the
-remoter planets it directly produces certain less visible perturbations.
-Here is a first series of effects. But each of the perturbed planets is
-itself a source of perturbations—each directly affects all the others.
-Hence, planet A having drawn planet B out of the position it would have
-occupied in A’s absence, the perturbations which B causes are different
-from what they would else have been; and similarly with C, D, E, &c.
-Here then is a secondary series of effects: far more numerous though far
-smaller in their amounts. As these indirect perturbations must to some
-extent modify the movements of each planet, there results from them a
-tertiary series; and so on continually. Thus the force exercised by any
-planet works a different effect on each of the rest; this different
-effect is from each as a centre partially broken up into minor different
-effects on the rest; and so on in ever multiplying and diminishing waves
-throughout the entire system.
-
- * * * * *
-
-§ 118. If the Earth was formed by the concentration of diffused matter,
-it must at first have been incandescent; and whether the nebular
-hypothesis be accepted or not, this original incandescence of the Earth
-must now be regarded as inductively established—or, if not established,
-at least rendered so probable that it is a generally admitted geological
-doctrine. Several results of the gradual cooling of the Earth—as the
-formation of a crust, the solidification of sublimed elements, the
-precipitation of water, &c., have been already noticed—and I here again
-refer to them merely to point out that they are simultaneous effects of
-the one cause, diminishing heat. Let us now, however, observe the
-multiplied changes afterwards arising from the continuance of this one
-cause. The Earth, falling in temperature, must contract. Hence the
-solid crust at any time existing, is presently too large for the
-shrinking nucleus; and being unable to support itself, inevitably
-follows the nucleus. But a spheroidal envelope cannot sink down into
-contact with a smaller internal spheroid, without disruption: it will
-run into wrinkles, as the rind of an apple does when the bulk of its
-interior decreases from evaporation. As the cooling progresses and the
-envelope thickens, the ridges consequent on these contractions must
-become greater; rising ultimately into hills and mountains; and the
-later systems of mountains thus produced must not only be higher, as we
-find them to be, but they must be longer, as we also find them to be.
-Thus, leaving out of view other modifying forces, we see what immense
-heterogeneity of surface arises from the one cause, loss of heat—a
-heterogeneity which the telescope shows us to be paralleled on the Moon,
-where aqueous and atmospheric agencies have been absent. But we
-have yet to notice another kind of heterogeneity of surface, similarly
-and simultaneously caused. While the Earth’s crust was still thin, the
-ridges produced by its contraction must not only have been small, but
-the tracts between them must have rested with comparative smoothness on
-the subjacent liquid spheroid; and the water in those arctic and
-antarctic regions where it first condensed, must have been evenly
-distributed. But as fast as the crust grew thicker and gained
-corresponding strength, the lines of fracture from time to time caused
-in it, necessarily occurred at greater distances apart; the intermediate
-surfaces followed the contracting nucleus with less uniformity; and
-there consequently resulted larger areas of land and water. If any one,
-after wrapping an orange in wet tissue paper, and observing both how
-small are the wrinkles and how evenly the intervening spaces lie on the
-surface of the orange, will then wrap it in thick cartridge-paper, and
-note both the greater height of the ridges and the larger spaces
-throughout which the paper does not touch the orange, he will realize
-the fact, that as the Earth’s solid envelope thickened, the areas of
-elevation and depression became greater. In place of islands more or
-less homogeneously scattered over an all-embracing sea, there must have
-gradually arisen heterogeneous arrangements of continent and ocean, such
-as we now know. This double change in the extent and in the
-elevation of the lands, involved yet another species of
-heterogeneity—that of coast-line. A tolerably even surface raised out of
-the ocean will have a simple, regular sea-margin; but a surface varied
-by table-lands and intersected by mountain-chains, will, when raised out
-of the ocean, have an outline extremely irregular, alike in its leading
-features and in its details. Thus endless is the accumulation of
-geological and geographical results slowly brought about by this one
-cause—the escape of the Earth’s primitive heat.
-
-When we pass from the agency which geologists term igneous, to aqueous
-and atmospheric agencies, we see a like ever-growing complication of
-effects. The denuding actions of air and water have, from the beginning,
-been modifying every exposed surface: everywhere working many different
-changes. As already shown (§ 80) the original source of those gaseous
-and fluid motions which effect denudation, is the solar heat. The
-transformation of this into various modes of force, according to the
-nature and condition of the matter on which it falls, is the first stage
-of complication. The sun’s rays, striking at all angles a sphere, that
-from moment to moment presents and withdraws different parts of its
-surface, and each of them for a different time daily throughout the
-year, would produce a considerable variety of changes even were the
-sphere uniform. But falling as they do on a sphere surrounded by an
-atmosphere in some parts of which wide areas of cloud are suspended, and
-which here unveils vast tracts of sea, there of level land, there of
-mountains, there of snow and ice, they initiate in its several parts
-countless different movements. Currents of air of all sizes, directions,
-velocities, and temperatures, are set up; as are also marine currents
-similarly contrasted in their characters. In this region the surface is
-giving off water in the state of vapour; in that, dew is being
-precipitated; and in the other rain is descending—differences that arise
-from the ever-changing ratio between the absorption and radiation of
-heat in each place. At one hour, a rapid fall in temperature leads to
-the formation of ice, with an accompanying expansion throughout the
-moist bodies frozen; while at another, a thaw unlocks the dislocated
-fragments of these bodies. And then, passing to a second stage of
-complication, we see that the many kinds of motion directly or
-indirectly caused by the sun’s rays, severally produce results that vary
-with the conditions. Oxidation, drought, wind, frost, rain, glaciers,
-rivers, waves, and other denuding agents effect disintegrations that are
-determined in their amounts and qualities by local circumstances. Acting
-upon a tract of granite, such agents here work scarcely an appreciable
-effect; there cause exfoliations of the surface, and a resulting heap of
-_débris_ and boulders; and elsewhere, after decomposing the feldspar
-into a white clay, carry away this with the accompanying quartz and
-mica, and deposit them in separate beds, fluviatile and marine. When the
-exposed land consists of several unlike formations, sedimentary and
-igneous, changes proportionably more heterogeneous are wrought. The
-formations being disintegrable in different degrees, there follows an
-increased irregularity of surface. The areas drained by different rivers
-being differently constituted, these rivers carry down to the sea unlike
-combinations of ingredients; and so sundry new strata of distinct
-composition arise. And here indeed we may see very simply illustrated,
-the truth, that the heterogeneity of the effects increases in a
-geometrical progression, with the heterogeneity of the object acted
-upon. A continent of complex structure, presenting many strata
-irregularly distributed, raised to various levels, tilted up at all
-angles, must, under the same denuding agencies, give origin to immensely
-multiplied results: each district must be peculiarly modified; each
-river must carry down a distinct kind of detritus; each deposit must be
-differently distributed by the entangled currents, tidal and other,
-which wash the contorted shores; and every additional complication of
-surface must be the cause of more than one additional consequence. But
-not to dwell on these, let us, for the fuller elucidation of this truth
-in relation to the inorganic world, consider what would presently follow
-from some extensive cosmical revolution—say the subsidence of Central
-America. The immediate results of the disturbance would themselves be
-sufficiently complex. Besides the numberless dislocations of strata, the
-ejections of igneous matter, the propagation of earthquake vibrations
-thousands of miles around, the loud explosions, and the escape of gases,
-there would be the rush of the Atlantic and Pacific Oceans to supply the
-vacant space, the subsequent recoil of enormous waves, which would
-traverse both these oceans and produce myriads of changes along their
-shores, the corresponding atmospheric waves complicated by the currents
-surrounding each volcanic vent, and the electrical discharges with which
-such disturbances are accompanied. But these temporary effects would be
-insignificant compared with the permanent ones. The complex currents of
-the Atlantic and Pacific would be altered in directions and amounts. The
-distribution of heat achieved by these currents would be different from
-what it is. The arrangement of the isothermal lines, not only on the
-neighbouring continents, but even throughout Europe, would be changed.
-The tides would flow differently from what they do now. There would be
-more or less modification of the winds in their periods, strengths,
-directions, qualities. Rain would fall scarcely anywhere at the same
-times and in the same quantities as at present. In short, the
-meteorological conditions thousands of miles off, on all sides, would be
-more or less revolutionized. In these many changes, each of which
-comprehends countless minor ones, the reader will see the immense
-heterogeneity of the results wrought out by one force, when that force
-expends itself on a previously complicated area; and he will readily
-draw the corollary that from the beginning the complication has advanced
-at an increasing rate.
-
- * * * * *
-
-§ 119. We have next to trace throughout organic evolution, this same
-all-pervading principle. And here, where the transformation of the
-homogeneous into the heterogeneous was first observed, the production of
-many changes by one cause is least easy to demonstrate. The development
-of a seed into a plant, or an ovum into an animal, is so gradual; while
-the forces which determine it are so involved, and at the same time so
-unobtrusive; that it is difficult to detect the multiplication of
-effects which is elsewhere so obvious. Nevertheless, by indirect
-evidence we may establish our proposition; spite of the lack of direct
-evidence.
-
-Observe, first, how numerous are the changes which any marked stimulus
-works on an adult organism—a human being, for instance. An alarming
-sound or sight, besides impressions on the organs of sense and the
-nerves, may produce a start, a scream, a distortion of the face, a
-trembling consequent on general muscular relaxation, a burst of
-perspiration, an excited action of the heart, a rush of blood to the
-brain, followed possibly by arrest of the heart’s action and by syncope;
-and if the system be feeble, an illness with its long train of
-complicated symptoms may set in. Similarly in cases of disease. A minute
-portion of the small-pox virus introduced into the system, will, in a
-severe case, cause, during the first stage, rigors, heat of skin,
-accelerated pulse, furred tongue, loss of appetite, thirst, epigastric
-uneasiness, vomiting, headache, pains in the back and limbs, muscular
-weakness, convulsions, delirium, &c.; in the second stage, cutaneous
-eruption, itching, tingling, sore throat, swelled fauces, salivation,
-cough, hoarseness, dyspnœa, &c.; and in the third stage, œdematous
-inflammations, pneumonia, pleurisy, diarrhœa, inflammation of the brain,
-ophthalmia, erysipelas, &c.: each of which enumerated symptoms is itself
-more or less complex. Medicines, special foods, better air, might in
-like manner be instanced as producing multiplied results. Now it
-needs only to consider that the many changes thus wrought by one force
-on an adult organism, must be partially paralleled in an
-embryo-organism, to understand how here also the production of many
-effects by one cause is a source of increasing heterogeneity. The
-external heat and other agencies which determine the first complications
-of the germ, will, by acting on these, superinduce further
-complications; on these still higher and more numerous ones; and so on
-continually: each organ as it is developed, serving, by its actions and
-reactions on the rest, to initiate new complexities. The first
-pulsations of the fœtal heart must simultaneously aid the unfolding of
-every part. The growth of each tissue, by taking from the blood special
-proportions of elements, must modify the constitution of the blood; and
-so must modify the nutrition of all the other tissues. The distributive
-actions, implying as they do a certain waste, necessitate an addition to
-the blood of effete matters, which must influence the rest of the
-system, and perhaps, as some think, initiate the formation of excretory
-organs. The nervous connections established among the viscera must
-further multiply their mutual influences. And so with every modification
-of structure—every additional part and every alteration in the ratios of
-parts. Still stronger becomes the proof when we call to mind the
-fact, that the same germ may be evolved into different forms according
-to circumstances. Thus, during its earlier stages, every embryo is
-sexless—becomes either male or female as the balance of forces acting on
-it determines. Again, it is well-known that the larva of a working-bee
-will develop into a queen-bee, if, before a certain period, its food be
-changed to that on which the larvæ of queen-bees are fed. Even more
-remarkable is the case of certain entozoa. The ovum of a tape-worm,
-getting into the intestine of one animal, unfolds into the form of its
-parent; but if carried into other parts of the system, or into the
-intestine of some unlike animal, it becomes one of the sac-like
-creatures, called by naturalists _Cysticerci_, or _Cœnuri_, or
-_Echinococci_—creatures so extremely different from the tape-worm in
-aspect and structure, that only after careful investigations have they
-been proved to have the same origin. All which instances imply that each
-advance in embryonic complication results from the action of incident
-forces on the complication previously existing. Indeed, the now
-accepted doctrine of epigenesis necessitates the conclusion that organic
-evolution proceeds after this manner. For since it is proved that no
-germ, animal or vegetal, contains the slightest rudiment, trace, or
-indication of the future organism—since the microscope has shown us that
-the first process set up in every fertilized germ is a process of
-repeated spontaneous fissions, ending in the production of a mass of
-cells, not one of which exhibits any special character; there seems no
-alternative but to conclude that the partial organization at any moment
-subsisting in a growing embryo, is transformed by the agencies acting on
-it into the succeeding phase of organization, and this into the next,
-until, through ever-increasing complexities, the ultimate form is
-reached. Thus, though the subtlety of the forces and the slowness
-of the metamorphosis, prevent us from _directly_ tracing the genesis of
-many changes by one cause, throughout the successive stages which every
-embryo passes through; yet, _indirectly_, we have strong evidence that
-this is a source of increasing heterogeneity. We have marked how
-multitudinous are the effects which a single agency may generate in an
-adult organism; that a like multiplication of effects must happen in the
-unfolding organism, we have inferred from sundry illustrative cases;
-further, it has been pointed out that the ability which like germs have
-to originate unlike forms, implies that the successive transformations
-result from the new changes superinduced on previous changes; and we
-have seen that structureless as every germ originally is, the
-development of an organism out of it is otherwise incomprehensible.
-Doubtless we are still in the dark respecting those mysterious
-properties which make the germ, when subject to fit influences, undergo
-the special changes beginning this series of transformations. All here
-contended is, that given a germ possessing these mysterious properties,
-the evolution of an organism from it depends, in part, on that
-multiplication of effects which we have seen to be a cause of evolution
-in general, so far as we have yet traced it.
-
-When, leaving the development of single plants and animals, we pass to
-that of the Earth’s flora and fauna, the course of the argument again
-becomes clear and simple. Though, as before admitted, the fragmentary
-facts Palæontology has accumulated, do not clearly warrant us in saying
-that, in the lapse of geologic time, there have been evolved more
-heterogeneous organisms, and more heterogeneous assemblages of
-organisms; yet we shall now see that there _must_ ever have been a
-tendency towards these results. We shall find that the production of
-many effects by one cause, which, as already shown, has been all along
-increasing the physical heterogeneity of the Earth, has further
-necessitated an increasing heterogeneity in its flora and fauna,
-individually and collectively. An illustration will make this clear.
- Suppose that by a series of upheavals, occurring, as they are now
-known to do, at long intervals, the East Indian Archipelago were to be
-raised into a continent, and a chain of mountains formed along the axis
-of elevation. By the first of these upheavals, the plants and animals
-inhabiting Borneo, Sumatra, New Guinea, and the rest, would be subjected
-to slightly-modified sets of conditions. The climate in general would be
-altered in temperature, in humidity, and in its periodical variations;
-while the local differences would be multiplied. These modifications
-would affect, perhaps inappreciably, the entire flora and fauna of the
-region. The change of level would produce additional modifications;
-varying in different species, and also in different members of the same
-species, according to their distance from the axis of elevation. Plants,
-growing only on the sea-shore in special localities, might become
-extinct. Others, living only in swamps of a certain humidity, would, if
-they survived at all, probably undergo visible changes of appearance.
-While more marked alterations would occur in some of the plants that
-spread over the lands newly raised above the sea. The animals and
-insects living on these modified plants, would themselves be in some
-degree modified by change of food, as well as by change of climate; and
-the modification would be more marked where, from the dwindling or
-disappearance of one kind of plant, an allied kind was eaten. In the
-lapse of the many generations arising before the next upheaval, the
-sensible or insensible alterations thus produced in each species, would
-become organized—in all the races that survived there would be a more or
-less complete adaptation to the new conditions. The next upheaval would
-superinduce further organic changes, implying wider divergences from the
-primary forms; and so repeatedly. Now however let it be observed that
-this revolution would not be a substitution of a thousand modified
-species for the thousand original species; but in place of the thousand
-original species there would arise several thousand species, or
-varieties, or changed forms. Each species being distributed over an area
-of some extent, and tending continually to colonize the new area
-exposed, its different members would be subject to different sets of
-changes. Plants and animals migrating towards the equator would not be
-affected in the same way with others migrating from it. Those which
-spread towards the new shores, would undergo changes unlike the changes
-undergone by those which spread into the mountains. Thus, each original
-race of organisms would become the root from which diverged several
-races, differing more or less from it and from each other; and while
-some of these might subsequently disappear, probably more than one would
-survive in the next geologic period: the very dispersion itself
-increasing the chances of survival. Not only would there be certain
-modifications thus caused by changes of physical conditions and food;
-but also in some cases other modifications caused by changes of habit.
-The fauna of each island, peopling, step by step, the newly-raised
-tracts, would eventually come in contact with the faunas of other
-islands; and some members of these other faunas would be unlike any
-creatures before seen. Herbivores meeting with new beasts of prey,
-would, in some cases, be led into modes of defence or escape differing
-from those previously used; and simultaneously the beasts of prey would
-modify their modes of pursuit and attack. We know that when
-circumstances demand it, such changes of habit _do_ take place in
-animals; and we know that if the new habits become the dominant ones,
-they must eventually in some degree alter the organization.
- Observe now, however, a further consequence. There must arise not
-simply a tendency towards the differentiation of each race of organisms
-into several races; but also a tendency to the occasional production of
-a somewhat higher organism. Taken in the mass, these divergent
-varieties, which have been caused by fresh physical conditions and
-habits of life, will exhibit alterations quite indefinite in kind and
-degree; and alterations that do not necessarily constitute an advance.
-Probably in most cases the modified type will be not appreciably more
-heterogeneous than the original one. But it _must_ now and then occur,
-that some division of a species, falling into circumstances which give
-it rather more complex experiences, and demand actions somewhat more
-involved, will have certain of its organs further differentiated in
-proportionately small degrees—will become slightly more heterogeneous.
-Hence, there will from time to time arise an increased heterogeneity
-both of the Earth’s flora and fauna, and of individual races included in
-them. Omitting detailed explanations, and allowing for the
-qualifications which cannot here be specified, it is sufficiently clear
-that geological mutations have all along tended to complicate the forms
-of life, whether regarded separately or collectively. That
-multiplication of effects which has been a part-cause of the
-transformation of the Earth’s crust from the simple into the complex,
-has simultaneously led to a parallel transformation of the Life upon its
-surface.[17]
-
-The deduction here drawn from the established truths of geology and the
-general laws of life, gains immensely in weight on finding it to be in
-harmony with an induction drawn from direct experience. Just that
-divergence of many races from one race, which we inferred must have been
-continually occurring during geologic time, we know to have occurred
-during the pre-historic and historic periods, in man and domestic
-animals. And just that multiplication of effects which we concluded must
-have been instrumental to the first, we see has in a great measure
-wrought the last. Single causes, as famine, pressure of population, war,
-have periodically led to further dispersions of mankind and of dependent
-creatures: each such dispersion initiating new modifications, new
-varieties of type. Whether all the human races be or be not derived from
-one stock, philology makes it clear that whole groups of races, now
-easily distinguishable from each other, were originally one race—that
-the diffusion of one race into different climates and conditions of
-existence has produced many altered forms of it. Similarly with domestic
-animals. Though in some cases (as that of dogs) community of origin will
-perhaps be disputed, yet in other cases (as that of the sheep or the
-cattle of our own country) it will not be questioned that local
-differences of climate, food, and treatment, have transformed one
-original breed into numerous breeds, now become so far distinct as to
-produce unstable hybrids. Moreover, through the complication of effects
-flowing from single causes, we here find, what we before inferred, not
-only an increase of general heterogeneity, but also of special
-heterogeneity. While of the divergent divisions and subdivisions of the
-human race, many have undergone changes not constituting an advance;
-others have become decidedly more heterogeneous. The civilized European
-departs more widely from the vertebrate archetype than does the savage.
-
- * * * * *
-
-§ 120. A sensation does not expend itself in arousing some single state
-of consciousness; but the state of consciousness aroused is made up of
-various represented sensations connected by co-existence, or sequence
-with the presented sensation. And that, in proportion as the grade of
-intelligence is high, the number of ideas suggested is great, may be
-readily inferred. Let us, however, look at the proof that here too, each
-change is the parent of many changes; and that the multiplication
-increases in proportion as the area affected is complex.
-
-Were some hitherto unknown bird, driven say by stress of weather from
-the remote north, to make its appearance on our shores, it would excite
-no speculation in the sheep or cattle amid which it alighted: a
-perception of it as a creature like those constantly flying about, would
-be the sole interruption of that dull current of consciousness which
-accompanies grazing and rumination. The cow-herd, by whom we may suppose
-the exhausted bird to be presently caught, would probably gaze at it
-with some slight curiosity, as being unlike any he had before seen—would
-note its most conspicuous markings, and vaguely ponder on the questions,
-where it came from, and how it came. The village bird-stuffer would have
-suggested to him by the sight of it, sundry forms to which it bore a
-little resemblance; would receive from it more numerous and more
-specific impressions respecting structure and plumage; would be reminded
-of various instances of birds brought by storms from foreign parts—would
-tell who found them, who stuffed them, who bought them. Supposing the
-unknown bird taken to a naturalist of the old school, interested only in
-externals, (one of those described by the late Edward Forbes, as
-examining animals as though they were merely skins filled with straw,)
-it would excite in him a more involved series of mental changes: there
-would be an elaborate examination of the feathers, a noting of all their
-technical distinctions, with a reduction of these perceptions to certain
-equivalent written symbols; reasons for referring the new form to a
-particular family, order, and genus would be sought out and written
-down; communications with the secretary of some society, or editor of
-some journal, would follow; and probably there would be not a few
-thoughts about the addition of the _ii_ to the describer’s name, to form
-the name of the species. Lastly, in the mind of a comparative anatomist,
-such a new species, should it happen to have any marked internal
-peculiarity, might produce additional sets of changes—might very
-possibly suggest modified views respecting the relationships of the
-division to which it belonged; or, perhaps, alter his conceptions of the
-homologies and developments of certain organs; and the conclusions drawn
-might not improbably enter as elements into still wider inquiries
-concerning the origin of organic forms.
-
-From ideas let us turn to emotions. In a young child, a father’s anger
-produces little else than vague fear—a disagreeable sense of impending
-evil, taking various shapes of physical suffering or deprivation of
-pleasures. In elder children, the same harsh words will arouse
-additional feelings: sometimes a sense of shame, of penitence, or of
-sorrow for having offended; at other times, a sense of injustice, and a
-consequent anger. In the wife, yet a further range of feelings may come
-into existence—perhaps wounded affection, perhaps self-pity for
-ill-usage, perhaps contempt for groundless irritability, perhaps
-sympathy for some suffering which the irritability indicates, perhaps
-anxiety about an unknown misfortune which she thinks has produced it.
-Nor are we without evidence that among adults, the like differences of
-development are accompanied by like differences in the number of
-emotions that are aroused, in combination or rapid succession—the lower
-natures being characterized by that impulsiveness which results from the
-uncontrolled action of a few feelings; and the higher natures being
-characterized by the simultaneous action of many secondary feelings,
-modifying those first awakened.
-
-Possibly it will be objected that the illustrations here given, are
-drawn from the functional changes of the nervous system, not from its
-structural changes; and that what is proved among the first, does not
-necessarily hold among the last. This must be admitted. Those, however,
-who recognize the truth that the structural changes are the slowly
-accumulated results of the functional changes, will readily draw the
-corollary, that a part-cause of the evolution of the nervous system, as
-of other evolution, is this multiplication of effects which becomes ever
-greater as the development becomes higher.
-
- * * * * *
-
-§ 121. If the advance of Man towards greater heterogeneity in both body
-and mind, is in part traceable to the production of many effects by one
-cause, still more clearly may the advance of Society towards greater
-heterogeneity be so explained. Consider the growth of an industrial
-organization. When, as must occasionally happen, some individual of a
-tribe displays unusual aptitude for making an article of general use (a
-weapon, for instance) which was before made by each man for himself,
-there arises a tendency towards the differentiation of that individual
-into a maker of weapons. His companions (warriors and hunters all of
-them) severally wish to have the best weapons that can be made; and are
-therefore certain to offer strong inducements to this skilled individual
-to make weapons for them. He, on the other hand, having both an unusual
-faculty, and an unusual liking, for making weapons (the capacity and the
-desire for any occupation being commonly associated), is predisposed to
-fulfil these commissions on the offer of adequate rewards: especially as
-his love of distinction is also gratified. This first specialization of
-function, once commenced, tends ever to become more decided. On the side
-of the weapon-maker, continued practice gives increased skill—increased
-superiority to his products. On the side of his clients, cessation of
-practice entails decreased skill. Thus the influences that determine
-this division of labour grow stronger in both ways: this social movement
-tends ever to become more decided in the direction in which it was first
-set up; and the incipient heterogeneity is, on the average of cases,
-likely to become permanent for that generation, if no longer. Such
-a process, besides differentiating the social mass into two parts, the
-one monopolizing, or almost monopolizing, the performance of a certain
-function, and the other having lost the habit, and in some measure the
-power, of performing that function, has a tendency to initiate other
-differentiations. The advance described implies the introduction of
-barter: the maker of weapons has, on each occasion, to be paid in such
-other articles as he agrees to take in exchange. Now he will not
-habitually take in exchange one kind of article, but many kinds. He does
-not want mats only, or skins, or fishing-gear; but he wants all these;
-and on each occasion will bargain for the particular things he most
-needs. What follows? If among the members of the tribe there exist any
-slight differences of skill in the manufacture of these various things,
-as there are almost sure to do, the weapon-maker will take from each one
-the thing which that one excels in making: he will exchange for mats
-with him whose mats are superior, and will bargain for the fishing-gear
-of whoever has the best. But he who has bartered away his mats or his
-fishing-gear, must make other mats or fishing-gear for himself; and in
-so doing must, in some degree, further develop his aptitude. Thus it
-results that the small specialities of faculty possessed by various
-members of the tribe will tend to grow more decided. If such
-transactions are from time to time repeated, these specializations may
-become appreciable. And whether or not there ensue distinct
-differentiations of other individuals into makers of particular
-articles, it is clear that incipient differentiations take place
-throughout the tribe: the one original cause produces not only the first
-dual effect, but a number of secondary dual effects, like in kind but
-minor in degree. This process, of which traces may be seen among
-groups of school-boys, cannot well produce a lasting distribution of
-functions in an unsettled tribe; but where there grows up a fixed and
-multiplying community, such differentiations become permanent, and
-increase with each generation. An addition to the number of citizens,
-involving a greater demand for every commodity, intensifies the
-functional activity of each specialized person or class; and this
-renders the specialization more definite where it already exists, and
-establishes it where it is but nascent. By increasing the pressure on
-the means of subsistence, a larger population again augments these
-results; since every individual is forced more and more to confine
-himself to that which he can do best, and by which he can gain most. And
-this industrial progress, by aiding future production, opens the way for
-further growth of population, which reacts as before. Presently,
-under the same stimuli, new occupations arise. Competing workers,
-severally aiming to produce improved articles, occasionally discover
-better processes or better materials. In weapons and cutting-tools, the
-substitution of bronze for stone entails on him who first makes it, a
-great increase of demand—so great an increase that he presently finds
-all his time occupied in making the bronze for the articles he sells,
-and is obliged to depute the fashioning of these articles to others; and
-eventually the making of bronze, thus gradually differentiated from a
-pre-existing occupation, becomes an occupation by itself. But now mark
-the ramified changes which follow this change. Bronze soon replaces
-stone, not only in the articles it was first used for, but in many
-others; and so affects the manufacture of them. Further, it affects the
-processes which such improved utensils subserve, and the resulting
-products—modifies buildings, carvings, dress, personal decorations. Yet
-again, it sets going sundry manufactures which were before impossible,
-from lack of a material fit for the requisite tools. And all these
-changes react on the people—increase their manipulative skill, their
-intelligence, their comfort—refine their habits and tastes.
-
-It is out of the question here to follow through its successive
-complications, this increasing social heterogeneity that results from
-the production of many effects by one cause. But leaving the
-intermediate phases of social development, let us take an illustration
-from its passing phase. To trace the effects of steam-power, in its
-manifold applications to mining, navigation, and manufactures, would
-carry us into unmanageable detail. Let us confine ourselves to the
-latest embodiment of steam-power—the locomotive engine. This, as the
-proximate cause of our railway-system, has changed the face of the
-country, the course of trade, and the habits of the people. Consider,
-first, the complicated sets of changes that precede the making of every
-railway—the provisional arrangements, the meetings, the registration,
-the trial-section, the parliamentary survey, the lithographed plans, the
-books of reference, the local deposits and notices, the application to
-Parliament, the passing Standing-Orders Committee, the first, second,
-and third readings: each of which brief heads indicates a multiplicity
-of transactions, and the further development of sundry occupations, (as
-those of engineers, surveyors, lithographers, parliamentary agents,
-share-brokers,) and the creation of sundry others (as those of
-traffic-takers, reference-takers). Consider, next, the yet more marked
-changes implied in railway construction—the cuttings, em-bankings,
-tunnellings, diversions of roads; the building of bridges and stations;
-the laying down of ballast, sleepers, and rails; the making of engines,
-tenders, carriages, and wagons: which processes, acting upon numerous
-trades, increase the importation of timber, the quarrying of stone, the
-manufacture of iron, the mining of coal, the burning of bricks;
-institute a variety of special manufactures weekly advertised in the
-_Railway Times_; and call into being some new classes of
-workers—drivers, stokers, cleaners, plate-layers, &c. &c. Then come the
-changes, more numerous and involved still, which railways in action
-produce on the community at large. The organization of every business is
-more or less modified: ease of communication makes it better to do
-directly what was before done by proxy; agencies are established where
-previously they would not have paid; goods are obtained from remote
-wholesale houses instead of near retail ones; and commodities are used
-which distance once rendered inaccessible. The rapidity and small cost
-of carriage, tend to specialize more than ever the industries of
-different districts—to confine each manufacture to the parts in which,
-from local advantages, it can be best carried on. Economical
-distribution equalizes prices, and also, on the average, lowers prices:
-thus bringing divers articles within the means of those before unable to
-buy them, and so increasing their comforts and improving their habits.
-At the same time the practice of travelling is immensely extended.
-Classes who before could not afford it, take annual trips to the sea;
-visit their distant relations; make tours; and so we are benefited in
-body, feelings, and intellect. The more prompt transmission of letters
-and of news produces further changes—makes the pulse of the nation
-faster. Yet more, there arises a wide dissemination of cheap literature
-through railway book-stalls, and of advertisements in railway carriages:
-both of them aiding ulterior progress. And the innumerable changes here
-briefly indicated are consequent on the invention of the locomotive
-engine. The social organism has been rendered more heterogeneous, in
-virtue of the many new occupations introduced, and the many old ones
-further specialized; prices in all places have been altered; each trader
-has, more or less, modified his way of doing business; and every person
-has been affected in his actions, thoughts, emotions.
-
-The only further fact demanding notice, is, that we here see more
-clearly than ever, that in proportion as the area over which any
-influence extends, becomes heterogeneous, the results are in a yet
-higher degree multiplied in number and kind. While among the primitive
-tribes to whom it was first known, caoutchouc caused but few changes,
-among ourselves the changes have been so many and varied that the
-history of them occupies a volume. Upon the small, homogeneous community
-inhabiting one of the Hebrides, the electric telegraph would produce,
-were it used, scarcely any results; but in England the results it
-produces are multitudinous.
-
-Space permitting, the synthesis might here be pursued in relation to all
-the subtler products of social life. It might be shown how, in Science,
-an advance of one division presently advances other divisions—how
-Astronomy has been immensely forwarded by discoveries in Optics, while
-other optical discoveries have initiated Microscopic Anatomy, and
-greatly aided the growth of Physiology—how Chemistry has indirectly
-increased our knowledge of Electricity, Magnetism, Biology, Geology—how
-Electricity has reacted on Chemistry and Magnetism, developed our views
-of Light and Heat, and disclosed sundry laws of nervous action. In
-Literature the same truth might be exhibited in the still-multiplying
-forms of periodical publications that have descended from the first
-newspaper, and which have severally acted and reacted on other forms of
-literature and on each other; or in the bias given by each book of power
-to various subsequent books. The influence which a new school of
-Painting (as that of the pre-Raphaelites) exercises on other schools;
-the hints which all kinds of pictorial art are deriving from
-Photography; the complex results of new critical doctrines; might
-severally be dwelt on as displaying the like multiplication of effects.
-But it would needlessly tax the reader’s patience to detail, in their
-many ramifications, these various changes: here become so involved and
-subtle as to be followed with some difficulty.
-
- * * * * *
-
-§ 122. After the argument which closed the last chapter, a parallel one
-seems here scarcely required. For symmetry’s sake, however, it will be
-proper briefly to point out how the multiplication of effects, like the
-instability of the homogeneous, is a corollary from the persistence of
-force.
-
-Things which we call different are things which react in different ways;
-and we can know them as different only by the differences in their
-reactions. When we distinguish bodies as hard and soft, rough and
-smooth, we simply mean that certain like muscular forces expended on
-them are followed by unlike sets of sensations—unlike re-active forces.
-Objects that are classed as red, blue, yellow, &c., are objects that
-decompose light in strongly-contrasted ways; that is, we know contrasts
-of colour as contrasts in the changes produced in a uniform incident
-force. Manifestly, any two things which do not work unequal effects on
-consciousness, either by unequally opposing our own energies, or by
-impressing our senses with unequally modified forms of certain external
-energies, cannot be distinguished by us. Hence the proposition that the
-different parts of any whole must react differently on a uniform
-incident force, and must so reduce it to a group of multiform forces, is
-in essence a truism. A further step will reduce this truism to its
-lowest terms.
-
-When, from unlikeness between the effects they produce on consciousness,
-we predicate unlikeness between two objects, what is our warrant? and
-what do we mean by the unlikeness, objectively considered? Our warrant
-is the persistence of force. Some kind or amount of change has been
-wrought in us by the one, which has not been wrought by the other. This
-change we ascribe to some force exercised by the one which the other has
-not exercised. And we have no alternative but to do this, or to assert
-that the change had no antecedent; which is to deny the persistence of
-force. Whence it is further manifest that what we regard as the
-objective unlikeness is the presence in the one of some force, or set of
-forces, not present in the other—something in the kinds or amounts or
-directions of the constituent forces of the one, which those of the
-other do not parallel. But now if things or parts of things which we
-call different, are those of which the constituent forces differ in one
-or more respects; what must happen to any like forces, or any uniform
-force, falling on them? Such like forces, or parts of a uniform force,
-must be differently modified. The force which is present in the one and
-not in the other, must be an element in the conflict—must produce its
-equivalent reaction; and must so affect the total reaction. To say
-otherwise is to say that this differential force will produce no effect;
-which is to say that force is not persistent.
-
-I need not develop this corollary further. It manifestly follows that a
-uniform force, falling on a uniform aggregate, must undergo dispersion;
-that falling on an aggregate made up of unlike parts, it must undergo
-dispersion from each part, as well as qualitative differentiations; that
-in proportion as the parts are unlike, these qualitative
-differentiations must be marked; that in proportion to the number of the
-parts, they must be numerous; that the secondary forces so produced,
-must undergo further transformations while working equivalent
-transformations in the parts that change them; and similarly with the
-forces they generate. Thus the conclusions that a part-cause of
-Evolution is the multiplication of effects; and that this increases in
-geometrical progression as the heterogeneity becomes greater; are not
-only to be established inductively, but are deducible from the deepest
-of all truths.
-
------
-
-Footnote 17:
-
- Had this paragraph, first published in the _Westminster Review_ in
- 1857, been written after the appearance of Mr. Darwin’s work on _The
- Origin of Species_, it would doubtless have been otherwise expressed.
- Reference would have been made to the process of “natural selection,”
- as greatly facilitating the differentiations described. As it is,
- however, I prefer to let the passage stand in its original shape:
- partly because it seems to me that these successive changes of
- conditions would produce divergent varieties or species, apart from
- the influence of “natural selection” (though in less numerous ways as
- well as less rapidly); and partly because I conceive that in the
- absence of these successive changes of conditions, “natural selection”
- would effect comparatively little. Let me add that though these
- positions are not enunciated in _The Origin of Species_, yet a mutual
- friend gives me reason to think that Mr. Darwin would coincide in
- them; if he did not indeed consider them as tacitly implied in his
- work.
-
-
-
-
- CHAPTER XV.
- DIFFERENTIATION AND INTEGRATION.
-
-
-§ 123. The general interpretation of Evolution is far from being
-completed in the preceding chapters. We must contemplate its changes
-under yet another aspect, before we can form a definite conception of
-the process constituted by them. Though the laws already set forth,
-furnish a key to the re-arrangement of parts which Evolution exhibits,
-in so far as it is an advance from the uniform to the multiform; they
-furnish no key to this re-arrangement in so far as it is an advance from
-the indefinite to the definite. On studying the actions and re-actions
-everywhere going on, we have found it to follow inevitably from a
-certain primordial truth, that the homogeneous must lapse into the
-heterogeneous, and that the heterogeneous must become more
-heterogeneous; but we have not discovered why the differently-affected
-parts of any simple whole, become clearly marked off from each other, at
-the same time that they become unlike. Thus far no reason has been
-assigned why there should not ordinarily arise a vague chaotic
-heterogeneity, in place of that orderly heterogeneity displayed in
-Evolution. It still remains to find out the cause of that integration of
-parts which accompanies their differentiation—that gradually-completed
-segregation of like units into a group, distinctly separated from
-neighbouring groups which are severally made up of other kinds of units.
-The rationale will be conveniently introduced by a few instances in
-which we may watch this segregative process taking place.
-
-When towards the end of September, the trees are gaining their autumn
-colours, and we are hoping shortly to see a further change increasing
-still more the beauty of the landscape, we are not uncommonly
-disappointed by the occurrence of an equinoxial gale. Out of the mixed
-mass of foliage on each branch, the strong current of air carries away
-the decaying and brightly-tinted leaves, but fails to detach those which
-are still green. And while these last, frayed and seared by
-long-continued beatings against each other, and the twigs around them,
-give a sombre colour to the woods, the red and yellow and orange leaves
-are collected together in ditches and behind walls and in corners where
-eddies allow them to settle. That is to say, by the action of that
-uniform force which the wind exerts on both kinds, the dying leaves are
-picked out from among their still living companions and gathered in
-places by themselves. Again, the separation of particles of different
-sizes, as dust and sand from pebbles, may be similarly effected; as we
-see on every road in March. And from the days of Homer downwards, the
-power of currents of air, natural and artificial, to part from one
-another units of unlike specific gravities, has been habitually utilized
-in the winnowing of chaff from wheat. In every river we see how
-the mixed materials carried down, are separately deposited—how in rapids
-the bottom gives rest to nothing but boulders and pebbles; how where the
-current is not so strong, sand is let fall; and how, in still places,
-there is a sediment of mud. This selective action of moving water, is
-commonly applied in the arts to obtain masses of particles of different
-degrees of fineness. Emery, for example, after being ground, is carried
-by a slow current through successive compartments; in the first of which
-the largest grains subside; in the second of which the grains that reach
-the bottom before the water has escaped, are somewhat smaller; in the
-third smaller still; until in the last there are deposited only those
-finest particles which fall so slowly through the water, that they have
-not previously been able to reach the bottom. And in a way that is
-different though equally significant, this segregative effect of water
-in motion, is exemplified in the carrying away of soluble from insoluble
-matters—an application of it hourly made in every laboratory. The
-effects of the uniform forces which aerial and aqueous currents
-exercise, are paralleled by those of uniform forces of other orders.
-Electric attraction will separate small bodies from large, or light
-bodies from heavy. By magnetism, grains of iron may be selected from
-among other grains; as by the Sheffield grinder, whose magnetized gauze
-mask filters out the steel-dust which his wheel gives off, from the
-stone-dust that accompanies it. And how the affinity of any agent acting
-differently on the components of a given body, enables us to take away
-some component and leave the rest behind, is shown in almost every
-chemical experiment.
-
-What now is the general truth here variously presented? How are these
-several facts and countless similar ones, to be expressed in terms that
-embrace them all? In each case we see in action a force which may be
-regarded as simple or uniform—fluid motion in a certain direction at a
-certain velocity; electric or magnetic attraction of a given amount;
-chemical affinity of a particular kind: or rather, in strictness, the
-acting force is compounded of one of these and certain other uniform
-forces, as gravitation, etc. In each case we have an aggregate made up
-of unlike units—either atoms of different substances combined or
-intimately mingled, or fragments of the same substance of different
-sizes, or other constituent parts that are unlike in their specific
-gravities, shapes, or other attributes. And in each case these unlike
-units, or groups of units, of which the aggregate consists, are, under
-the influence of some resultant force acting indiscriminately on them
-all, separated from each other—segregated into minor aggregates, each
-consisting of units that are severally like each other and unlike those
-of the other minor aggregates. Such being the common aspect of these
-changes, let us look for the common interpretation of them.
-
-In the chapter on “The Instability of the Homogeneous,” it was shown
-that a uniform force falling on any aggregate, produces unlike
-modifications in its different parts—turns the uniform into the
-multiform and the multiform into the more multiform. The transformation
-thus wrought, consists of either insensible or sensible changes of
-relative position among the units, or of both—either of those molecular
-re-arrangements which we call chemical, or of those larger
-transpositions which are distinguished as mechanical, or of the two
-united. Such portion of the permanently effective force as reaches each
-different part, or differently-conditioned part, may be expended in
-modifying the mutual relations of its constituents; or it may be
-expended in moving the part to another place; or it may be expended
-partially in the first and partially in the second. Hence, so much of
-the permanently effective force as does not work the one kind of effect,
-must work the other kind. It is manifest that if of the permanently
-effective force which falls on some compound unit of an aggregate,
-little, if any, is absorbed in re-arranging the ultimate components of
-such compound unit, much or the whole, must show itself in motion of
-such compound unit to some other place in the aggregate; and conversely,
-if little or none of this force is absorbed in generating mechanical
-transposition, much or the whole must go to produce molecular
-alterations. What now must follow from this? In cases where none
-or only part of the force generates chemical re-distributions, what
-physical re-distributions must be generated? Parts that are similar to
-each other will be similarly acted on by the force; and will similarly
-react on it. Parts that are dissimilar will be dissimilarly acted on by
-the force; and will dissimilarly react on it. Hence the permanently
-effective incident force, when wholly or partially transformed into
-mechanical motion of the units, will produce like motions in units that
-are alike, and unlike motions in units that are unlike. If then, in an
-aggregate containing two or more orders of mixed units, those of the
-same order will be moved in the same way, and in a way that differs from
-that in which units of other orders are moved, the respective orders
-must segregate. A group of like things on which are impressed motions
-that are alike in amount and direction, must be transferred as a group
-to another place, and if they are mingled with some group of other
-things, on which the motions impressed are like each other, but unlike
-those of the first group in amount or direction or both, these other
-things must be transferred as a group to some other place—the mixed
-aggregate must undergo a simultaneous differentiation and integration.
-
-In further elucidation of this process, it will be well here to set down
-a few instances in which we may see that, other things equal, the
-definiteness of the separation is in proportion to the definiteness of
-the difference between the units. Take a handful of any pounded
-substance, containing fragments of all sizes; and let it fall to the
-ground while a gentle breeze is blowing. The large fragments will be
-collected together on the ground almost immediately under the hand;
-somewhat smaller fragments will be carried a little to the leeward;
-still smaller ones a little further; and those minute particles which we
-call dust, will be drifted a long way before they reach the earth: that
-is, the integration is indefinite where the difference among the
-fragments is indefinite, though the divergence is greatest where the
-difference is greatest. If, again, the handful be made up of quite
-distinct orders of units—as pebbles, coarse sand, and dust—these will,
-under like conditions, be segregated with comparative definiteness: the
-pebbles will drop almost vertically; the sand will fall in an inclined
-direction, and deposit itself within a tolerably circumscribed space
-beyond the pebbles; while the dust will be blown almost horizontally to
-a great distance. A case in which another kind of force comes into play,
-will still better illustrate this truth. Through a mixed aggregate of
-soluble and insoluble substances, let water slowly percolate. There will
-in the first place be a distinct parting of the substances that are the
-most widely contrasted in their relations to the acting forces: the
-soluble will be carried away; the insoluble will remain behind. Further,
-some separation, though a less definite one, will be effected among the
-soluble substances; since the first part of the current will remove the
-most soluble substances in the largest amounts, and after these have
-been all dissolved, the current will still continue to bring out the
-remaining less soluble substances. Even the undissolved matters will
-have simultaneously undergone a certain segregation; for the percolating
-fluid will carry down the minute fragments from among the large ones,
-and will deposit those of small specific gravity in one place, and those
-of great specific gravity in another. To complete the elucidation
-we must glance at the obverse fact; namely, that mixed units which
-differ but slightly, are moved in but slightly-different ways by
-incident forces, and can therefore be separated only by such adjustments
-of the incident forces as allow slight differences to become appreciable
-factors in the result. This truth is made manifest by antithesis in the
-instances just given; but it may be made much more manifest by a few
-such instances as those which chemical analysis supplies in abundance.
-The parting of alcohol from water by distillation is a good one. Here we
-have atoms consisting of oxygen and hydrogen, mingled with atoms
-consisting of oxygen, hydrogen, and carbon. The two orders of atoms have
-a considerable similarity of nature: they similarly maintain a fluid
-form at ordinary temperatures; they similarly become gaseous more and
-more rapidly as the temperature is raised; and they boil at points not
-very far apart. Now this comparative likeness of the atoms is
-accompanied by difficulty in segregating them. If the mixed fluid is
-unduly heated, much water distils over with the alcohol: it is only
-within a narrow range of temperature, that the one set of atoms are
-driven off rather than the others; and even then not a few of the others
-accompany them. The most interesting and instructive example, however,
-is furnished by certain phenomena of crystallization. When several salts
-that have little analogy of constitution, are dissolved in the same body
-of water, they are separated without much trouble, by crystallization:
-their respective units moved towards each other, as physicists suppose,
-by polar forces, segregate into crystals of their respective kinds. The
-crystals of each salt do, indeed, usually contain certain small amounts
-of the other salts present in the solution—especially when the
-crystallization has been rapid; but from these other salts they are
-severally freed by repeated resolutions and crystallizations. Mark now,
-however, that the reverse is the case when the salts contained in the
-same body of water are chemically homologous. The nitrates of baryta and
-lead, or the sulphates of zinc, soda, and magnesia, unite in the same
-crystals; nor will they crystallize separately if these crystals be
-dissolved afresh, and afresh crystallized, even with great care. On
-seeking the cause of this anomaly, chemists found that such salts were
-isomorphous—that their atoms, though not chemically identical, were
-identical in the proportions of acid, base, and water, composing them,
-and in their crystalline forms: whence it was inferred that their atoms
-are nearly alike in structure. Thus is clearly illustrated the truth,
-that units of unlike kinds are differentiated and integrated with a
-readiness proportionate to the degree of their unlikeness. In the first
-case we see that being dissimilar in their forms, but similar in so far
-as they are soluble in water of a certain temperature, the atoms
-segregate, though imperfectly. In the second case we see that the atoms,
-having not only the likeness implied by solubility in the same
-menstruum, but also a great likeness of structure, do not segregate—are
-differentiated and integrated only under quite special conditions, and
-then very incompletely. That is, the incident force of mutual polarity
-impresses unlike motions on the mixed units in proportion as they are
-unlike; and therefore, in proportion as they are unlike, tends to
-deposit them in separate places.
-
-There is a converse cause of segregation, which it is needless here to
-treat of with equal fulness. If different units acted on by the same
-force, must be differently moved; so, too, must units of the same kind
-be differently moved by different forces. Supposing some group of units
-forming part of a homogeneous aggregate, are unitedly exposed to a force
-that is unlike in amount or direction to the force acting on the rest of
-the aggregate; then this group of units will separate from the rest,
-provided that, of the force so acting on it, there remains any portion
-not dissipated in molecular vibrations, nor absorbed in producing
-molecular re-arrangements. After all that has been said above, this
-proposition needs no defence.
-
-Before ending our preliminary exposition, a complementary truth must be
-specified; namely, that mixed forces are segregated by the reaction of
-uniform matters, just as mixed matters are segregated by the action of
-uniform forces. Of this truth a complete and sufficient illustration is
-furnished by the dispersion of refracted light. A beam of light, made up
-of ethereal undulations of different orders, is not uniformly deflected
-by a homogeneous refracting body; but the different orders of
-undulations it contains, are deflected at different angles: the result
-being that these different orders of undulations are separated and
-integrated, and so produce what we know as the colours of the spectrum.
-A segregation of another kind occurs when rays of light traverse an
-obstructing medium. Those rays which consist of comparatively short
-undulations, are absorbed before those which consist of comparatively
-long ones; and the red rays, which consist of the longest undulations,
-alone penetrate when the obstruction is very great. How, conversely,
-there is produced a separation of like forces by the reaction of unlike
-matters, is also made manifest by the phenomena of refraction: since
-adjacent and parallel beams of light, falling on, and passing through,
-unlike substances, are made to diverge.
-
- * * * * *
-
-§ 124. On the assumption of their nebular origin, stars and planets
-exemplify that cause of material integration last assigned—the action of
-unlike forces on like units.
-
-In a preceding chapter (§ 110) we saw that if matter ever existed in a
-diffused form, it could not continue uniformly distributed, but must
-break up into masses. It was shown that in the absence of a perfect
-balance of mutual attractions among atoms dispersed through unlimited
-space, there must arise breeches of continuity throughout the aggregate
-formed by them, and a concentration of it towards centres of dominant
-attraction. Where any such breech of continuity occurs, and the atoms
-that were before adjacent separate from each other; they do so in
-consequence of a difference in the forces to which they are respectively
-subject. The atoms on the one side of the breech are exposed to a
-certain surplus attraction in the direction in which they begin to move;
-and those on the other to a surplus attraction in the opposite
-direction. That is, the adjacent groups of like units are exposed to
-unlike resultant forces; and accordingly separate and integrate.
-
-The formation and detachment of a nebulous ring, illustrates the same
-general principle. To conclude, as Laplace did, that the equatorial
-portion of a rotating nebulous spheroid, will, during concentration,
-acquire a centrifugal force sufficient to prevent it from following the
-rest of the contracting mass, is to conclude that such portions will
-remain behind as are in common subject to a certain differential force.
-The line of division between the ring and the spheroid, must be a line
-inside of which the aggregative force is greater than the force
-resisting aggregation; and outside of which the force resisting
-aggregation is greater than the aggregative force. Hence the alleged
-process conforms to the law that among like units, separation and
-integration is produced by the action of unlike forces.
-
-Astronomical phenomena do not furnish any other than these hypothetical
-examples. In its present comparatively settled condition, the Solar
-System exhibits no direct evidence of progressing integration: unless
-indeed under the insignificant form of the union of meteoric masses with
-the Earth, and, occasionally perhaps, of cometary matter with the Sun.
-
- * * * * *
-
-§ 125. Those geologic changes usually classed as aqueous, display under
-numerous forms the segregation of unlike units by a uniform incident
-force. On sea-shores, the waves are ever sorting-out and separating the
-mixed materials against which they break. From each mass of fallen
-cliff, the rising and ebbing tide carries away all those particles which
-are so small as to remain long suspended in the water; and, at some
-distance from shore, deposits them in the shape of fine sediment. Large
-particles, sinking with comparative rapidity, are accumulated into beds
-of sand near low water-mark. The coarse grit and small pebbles collect
-together on the incline up which the breakers rush. And on the top lie
-the larger stones and boulders. Still more specific segregations may
-occasionally be observed. Flat pebbles, produced by the breaking down of
-laminated rock, are sometimes separately collected in one part of a
-shingle bank. On this shore the deposit is wholly of mud; on that it is
-wholly of sand. Here we find a sheltered cove filled with small pebbles
-almost of one size; and there, in a curved bay one end of which is more
-exposed than the other, we see a progressive increase in the massiveness
-of the stones as we walk from the less exposed to the more exposed end.
-Indeed, our sedimentary strata form one vast series of illustrations of
-the alleged law. Trace the history of each deposit, and we are quickly
-led down to the fact, that mixed fragments of matter, differing in their
-sizes or weights, are, when exposed to the momentum and friction of
-water, joined with the attraction of the Earth, selected from each
-other, and united into groups of comparatively like fragments. We see
-that, other things equal, the separation is definite in proportion as
-the differences of the units are marked; and that, under the action of
-the same aggregate of forces, the most widely unlike units are most
-widely removed from each other.
-
-Among igneous changes we do not find so many examples of the process
-described. When specifying the conditions to Evolution, it was pointed
-out (§ 104) that molecular vibration exceeding a certain intensity, does
-not permit those integrations which result from the action of minor
-differential forces. Nevertheless, geological phenomena of this order
-are not barren of illustrations. Where the mixed matters composing the
-Earth’s crust have been raised to a very high temperature, segregation
-habitually takes place as the temperature diminishes. Sundry of the
-substances that escape in a gaseous form from volcanoes, sublime into
-crystals on coming against cool surfaces; and solidifying, as these
-substances do, at different temperatures, they are deposited at
-different parts of the crevices through which they are emitted together.
-The best illustration, however, is furnished by the changes that occur
-during the slow cooling of igneous rock. When, through one of the
-fractures from time to time made in the solid shell which forms the
-Earth’s crust, a portion of the molten nucleus is extruded; and when
-this is cooled with comparative rapidity, through free radiation and
-contact with cold masses; it forms a substance known as trap or basalt—a
-substance that is uniform in texture, though made up of various
-ingredients. But when, not escaping through the superficial strata, such
-a portion of the molten nucleus is slowly cooled, it becomes what we
-know as granite: the mingled particles of quartz, feldspar, and mica,
-being kept for a long time in a fluid and semi-fluid state—a state of
-comparative mobility—undergo those changes of position which the forces
-impressed on them by their fellow units necessitate. Having time in
-which to generate the requisite motions of the atoms, the differential
-forces arising from mutual polarity, segregate the quartz, feldspar, and
-mica, into crystals. How completely this is dependent on the
-long-continued agitation of the mixed particles, and consequent
-long-continued mobility by small differential forces, is proved by the
-fact that in granite dykes, the crystals in the centre of the mass,
-where the fluidity or semi-fluidity continued for a longer time, are
-much larger than those at the sides, where contact with the neighbouring
-rock caused more rapid cooling and solidification.
-
- * * * * *
-
-§ 126. The actions going on throughout an organism are so involved and
-subtle, that we cannot expect to identify the particular forces by which
-particular integrations are effected. Among the few instances admitting
-of tolerably definite interpretation, the best are those in which
-mechanical pressures and tensions are the agencies at work. We shall
-discover several on studying the bony frame of the higher animals.
-
-The vertebral column of a man, is subject, as a whole, to certain
-general strains—the weight of the body, together with the reactions
-involved by all considerable muscular efforts; and in conformity with
-this, it has a certain general integration. At the same time, being
-exposed to different forces in the course of those lateral bendings
-which the movements necessitate, its parts retain a certain
-separateness. And if we trace up the development of the vertebral column
-from its primitive form of a cartilaginous cord in the lowest fishes, we
-see that, throughout, it maintains an integration corresponding to the
-unity of the incident forces, joined with a division into segments
-corresponding to the variety of the incident forces. Each segment,
-considered apart, exemplifies the truth more simply. A vertebra is not a
-single bone, but consists of a central mass with sundry appendages or
-processes; and in rudimentary types of vertebræ, those appendages are
-quite separate from the central mass, and, indeed, exist before it makes
-its appearance. But these several independent bones, constituting a
-primitive spinal segment, are subject to a certain aggregate of forces
-which agree more than they differ: as the fulcrum to a group of muscles
-habitually acting together, they perpetually undergo certain reactions
-in common. And accordingly, we see that in the course of development
-they gradually coalesce. Still clearer is the illustration
-furnished by spinal segments that become fused together where they are
-together exposed to some predominant strain. The sacrum consists of a
-group of vertebræ firmly united. In the ostrich and its congeners there
-are from seventeen to twenty sacral vertebræ; and besides being
-confluent with each other, these are confluent with the iliac bones,
-which run on each side of them. If now we assume these vertebræ to have
-been originally separate, as they still are in the embryo bird; and if
-we consider the mechanical conditions to which they must in such case
-have been exposed; we shall see that their union results in the alleged
-way. For through these vertebræ the entire weight of the body is
-transferred to the legs: the legs support the pelvic arch; the pelvic
-arch supports the sacrum; and to the sacrum is articulated the rest of
-the spine, with all the limbs and organs attached to it. Hence, if
-separate, the sacral vertebræ must be held firmly together by
-strongly-contracted muscles; and must, by implication, be prevented from
-partaking in those lateral movements which the other vertebræ
-undergo—they must be subject to a common strain, while they are
-preserved from strains which would affect them differently; and so they
-fulfil the conditions under which integration occurs. But the
-cases in which cause and effect are brought into the most obvious
-relation, are supplied by the limbs. The metacarpal bones (those which
-in man support the palm of the hand) are separate from each other in the
-majority of mammalia: the separate actions of the toes entailing on them
-slight amounts of separate movements. This is not so however in the
-ox-tribe and the horse-tribe. In the ox-tribe, only the middle
-metacarpals (third and fourth) are developed; and these, attaining
-massive proportions, coalesce to form the cannon bone. In the
-horse-tribe, the integration is what we may distinguish as indirect: the
-second and fourth metacarpals are present only as rudiments united to
-the sides of the third, while the third is immensely developed; thus
-forming a cannon bone which differs from that of the ox in being a
-single cylinder, instead of two cylinders fused together. The metatarsus
-in these quadrupeds exhibits parallel changes. Now each of these
-metamorphoses occurs where the different bones grouped together have no
-longer any different functions, but retain only a common function. The
-feet of oxen and horses are used solely for locomotion—are not put like
-those of unguiculate mammals to purposes which involve some relative
-movements of the metacarpals. Thus there directly or indirectly results
-a single mass of bone where the incident force is single. And for the
-inference that these facts have a causal connexion, we find confirmation
-throughout the entire class of birds; in the wings and legs of which,
-like integrations are found under like conditions. While this
-sheet is passing through the press, a fact illustrating this general
-truth in a yet more remarkable manner, has been mentioned to me by Prof.
-Huxley; who kindly allows me to make use of it while still unpublished
-by him. The _Glyptodon_, an extinct mammal found fossilized in South
-America, has long been known as a large uncouth creature allied to the
-Armadillo, but having a massive dermal armour consisting of polygonal
-plates closely fitted together so as to make a vast box, inclosing the
-body in such way as effectually to prevent it from being bent, laterally
-or vertically, in the slightest degree. This bony box, which must have
-weighed several hundred-weight, was supported on the spinous processes
-of the vertebræ, and on the adjacent bones of the pelvic and thoracic
-arches. And the significant fact now to be noted, is, that here, where
-the trunk vertebræ were together exposed to the pressure of this heavy
-dermal armour, at the same time that, by its rigidity, they were
-preserved from all relative movements, the entire series of them were
-united into one solid, continuous bone.
-
-The formation and maintenance of a species, considered as an assemblage
-of similar organisms, is interpretable in an analogous way. We have
-already seen that in so far as the members of a species are subject to
-different sets of incident forces, they are differentiated, or divided
-into varieties. And here it remains to add that in so far as they are
-subject to like sets of incident forces, they are integrated, or reduced
-to, and kept in, the state of a uniform aggregate. For by the process of
-“natural selection,” there is a continual purification of each species
-from those individuals which depart from the common type in ways that
-unfit them for the conditions of their existence. Consequently, there is
-a continual leaving behind of those individuals which are in all
-respects fit for the conditions of their existence; and are therefore
-very nearly alike. The circumstances to which any species is exposed,
-being, as we before saw, an involved combination of incident forces; and
-the members of the species having mixed with them some that differ more
-than usual from the average structure required for meeting these forces;
-it results that these forces are constantly separating such divergent
-individuals from the rest, and so preserving the uniformity of the
-rest—keeping up its integrity as a species. Just as the changing autumn
-leaves are picked out by the wind from among the green ones around them,
-or just as, to use Prof. Huxley’s simile, the smaller fragments pass
-through the sieve while the larger are kept back; so, the uniform
-incidence of external forces affects the members of a group of organisms
-similarly in proportion as they are similar, and differently in
-proportion as they are different; and thus is ever segregating the like
-by parting the unlike from them. Whether these separated members are
-killed off, as mostly happens, or whether, as otherwise happens, they
-survive and multiply into a distinct variety, in consequence of their
-fitness to certain partially unlike conditions, matters not to the
-argument. The one case conforms to the law, that the unlike units of an
-aggregate are differentiated and integrated when uniformly subject to
-the same incident forces; and the other to the converse law, that the
-like units of an aggregate are differentiated and integrated when
-subject to different incident forces. And on consulting Mr. Darwin’s
-remarks on divergence of character, it will be seen that the
-segregations thus caused tend ever to become more definite.
-
- * * * * *
-
-§ 127. Mental evolution under one of its leading aspects, we found to
-consist in the formation of groups of like objects and like
-relations—a differentiation of the various things originally
-confounded together in one assemblage, and an integration of each
-separate order of things into a separate group (§ 113). Here it
-remains to point out that while unlikeness in the incident forces is
-the cause of such differentiations, likeness in the incident forces is
-the cause of such integrations. For what is the process through which
-classifications are established? At first, in common with the
-uninitiated, the botanist recognizes only such conventional divisions
-as those which agriculture has established—distinguishes a few
-vegetables and cereals, and groups the rest together into the one
-miscellaneous aggregate of wild plants. How do these wild plants
-become grouped in his mind into orders, genera, and species? Each
-plant he examines yields him a certain complex impression. Every now
-and then he picks up a plant like one before seen; and the recognition
-of it is the production in him of a like connected group of
-sensations, by a like connected group of attributes. That is to say,
-there is produced throughout the nerves concerned, a combined set of
-changes, similar to a combined set of changes before produced.
-Considered analytically, each such combined set of changes is a
-combined set of molecular modifications wrought in the affected part
-of the organism. On every repetition of the impression, a like
-combined set of molecular modifications is superposed on the previous
-ones, and makes them greater: thus generating an internal idea
-corresponding to these similar external objects. Meanwhile, another
-kind of plant produces in the brain of the botanist another set of
-combined changes or molecular modifications—a set which does not agree
-with and deepen the one we have been considering, but disagrees with
-it; and by repetition of such there is generated a different idea
-answering to a different species. What now is the nature of this
-process expressed in general terms? On the one hand there are the like
-and unlike things from which severally emanate the groups of forces by
-which we perceive them. On the other hand, there are the organs of
-sense and percipient centres, through which, in the course of
-observation, these groups of forces pass. In passing through these
-organs of sense and percipient centres, the like groups of forces are
-segregated, or separated from the unlike groups of forces; and each
-such differentiated and integrated series of groups of forces,
-answering to an external genus or species, constitutes a state of
-consciousness which we call our idea of the genus or species. We
-before saw that as well as a separation of mixed matters by the same
-force, there is a separation of mixed forces by the same matter; and
-here we may further see that the unlike forces so separated, work
-unlike structural changes in the aggregate that separates
-them—structural changes each of which thus represents, and is
-equivalent to, the integrated series of motions that has produced it.
-
-By a parallel process, the connexions of co-existence and sequence among
-impressions, become differentiated and integrated simultaneously with
-the impressions themselves. When two phenomena that have been
-experienced in a given order, are repeated in the same order, those
-nerves which before were affected by the transition are again affected;
-and such molecular modification as they received from the first motion
-propagated through them, is increased by this second motion along the
-same route. Each such motion works a structural alteration, which, in
-conformity with the general law set forth in Chapter X., involves a
-diminution of the resistance to all such motions that afterwards occur.
-The integration of these successive motions (or more strictly, the
-permanently effective portions of them expended in overcoming
-resistance) thus becomes the cause of, and the measure of, the mental
-connexion between the impressions which the phenomena produce.
-Meanwhile, phenomena that are recognized as different from these, being
-phenomena that therefore affect different nervous elements, will have
-their connexions severally represented by motions along other routes;
-and along each of these other routes, the nervous discharges will
-severally take place with a readiness proportionate to the frequency
-with which experience repeats the connexion of phenomena. The
-classification of relations must hence go on _pari passu_ with the
-classification of the related things. In common with the mixed
-sensations received from the external world, the mixed relations it
-presents, cannot be impressed on the organism without more or less
-segregation of them resulting. And through this continuous
-differentiation and integration of changes or motions, which constitutes
-nervous function, there is gradually wrought that differentiation and
-integration of matter, which constitutes nervous structure.
-
- * * * * *
-
-§ 128. In social evolution, the collecting together of the like and the
-separation of the unlike, by incident forces, is primarily displayed in
-the same manner as we saw it to be among groups of inferior creatures.
-The human races tend to differentiate and integrate, as do races of
-other living forms. Of the forces which effect and maintain the
-segregations of mankind, may first be named those external ones which we
-class as physical conditions. The climate and food that are favourable
-to an indigenous people, are more or less detrimental to a people of
-different bodily constitution, coming from a remote part of the Earth.
-In tropical regions the northern races cannot permanently exist: if not
-killed off in the first generation, they are so in the second; and, as
-in India, can maintain their footing only by the artificial process of
-continuous immigration and emigration. That is to say, the external
-forces acting equally on the inhabitants of a given locality, tend to
-expel all who are not of a certain type; and so to keep up the
-integration of those who are of that type. Though elsewhere, as among
-European nations, we see a certain amount of permanent intermixture,
-otherwise brought about, we still see that this takes place between
-races of not very different types, that are naturalized to not very
-different conditions. The other forces conspiring to produce these
-national integrations, are those mental ones which show themselves in
-the affinities of men for others like themselves. Emigrants usually
-desire to get back among their own people; and where their desire does
-not take effect, it is only because the restraining ties are too great.
-Units of one society who are obliged to reside in another, very
-generally form colonies in the midst of that other—small societies of
-their own. Races which have been artificially severed, show strong
-tendencies to re-unite. Now though these integrations that result from
-the mutual affinities of kindred men, do not seem interpretable as
-illustrations of the general principle above enunciated, they really are
-thus interpretable. When treating of the direction of motion (§ 91), it
-was shown that the actions performed by men for the satisfaction of
-their wants, were always motions along lines of least resistance. The
-feelings characterizing a member of a given race, are feelings which get
-complete satisfaction only among other members of that race—a
-satisfaction partly derived from sympathy with those having like
-feelings, but mainly derived from the adapted social conditions which
-grow up where such feelings prevail. When, therefore, a citizen of any
-nation is, as we see, attracted towards others of his nation, the
-rationale is, that certain agencies which we call desires, move him in
-the direction of least resistance. Human motions, like all other
-motions, being determined by the distribution of forces, it follows that
-such integrations of races as are not produced by incident external
-forces, are produced by forces which the units of the races exercise on
-each other.
-
-During the development of each society, we see analogous segregations
-caused in analogous ways. A few of them result from minor natural
-affinities; but those most important ones which constitute political and
-industrial organization, result from the union of men in whom
-similarities have been produced by education—using education in its
-widest sense, as comprehending all processes by which citizens are
-moulded to special functions. Men brought up to bodily labour, are men
-who have had wrought in them a certain likeness—a likeness which, in
-respect of their powers of action, obscures and subordinates their
-natural differences. Those trained to brain-work, have acquired a
-certain other community of character which makes them, as social units,
-more like each other than like those trained to manual occupations. And
-there arise class-integrations answering to these superinduced
-likenesses. Much more definite integrations take place among the much
-more definitely assimilated members of any class who are brought up to
-the same calling. Even where the necessities of their work forbid
-concentration in one locality, as among artizans happens with masons and
-brick-layers, and among traders happens with the retail distributors,
-and among professionals happens with the medical men; there are not
-wanting Operative Builders Unions, and Grocers Societies, and Medical
-Associations, to show that these artificially-assimilated citizens
-become integrated as much as the conditions permit. And where, as among
-the manufacturing classes, the functions discharged do not require the
-dispersion of the citizens thus artificially assimilated, there is a
-progressive aggregation of them in special localities; and a consequent
-increase in the definiteness of the industrial divisions. If now
-we seek the causes of these integrations, considered as results of force
-and motion, we find ourselves brought to the same general principle as
-before. This likeness generated in any class or subclass by training, is
-an aptitude acquired by its members for satisfying their wants in like
-ways. That is, the occupation to which each man has been brought up, has
-become to him, in common with those similarly brought up, a line of
-least resistance. Hence under that pressure which determines all men to
-activity, these similarly-modified social units are similarly affected,
-and tend to take similar courses. If then there be any locality which,
-either by its physical peculiarities or by peculiarities wrought on it
-during social evolution, is rendered a place where a certain kind of
-industrial action meets with less resistance than elsewhere; it follows
-from the law of direction of motion that those social units who have
-been moulded to this kind of industrial action, will move towards this
-place, or become integrated there. If, for instance, the proximity of
-coal and iron mines to a navigable river, gives to Glasgow a certain
-advantage in the building of iron ships—if the total labour required to
-produce the same vessel, and get its equivalent in food and clothing, is
-less there than elsewhere; a concentration of iron-ship builders is
-produced at Glasgow: either by keeping there the population born to
-iron-ship building; or by immigration of those elsewhere engaged in it;
-or by both—a concentration that would be still more marked did not other
-districts offer counter-balancing facilities. The principle equally
-holds where the occupation is mercantile instead of manufacturing.
-Stock-brokers cluster together in the city, because the amount of effort
-to be severally gone through by them in discharging their functions, and
-obtaining their profits, is less there than in other localities. A place
-of exchange having once been established, becomes a place where the
-resistance to be overcome by each is less than elsewhere; and the
-pursuit of the course of least resistance by each, involves their
-aggregation around this place.
-
-Of course, with units so complicated as those which constitute a
-society, and with forces so involved as those which move them, the
-resulting differentiations and integrations must be far more entangled,
-or far less definite, than those we have hitherto considered. But though
-there may be pointed out many anomalies which at first sight seem
-inconsistent with the alleged law, a closer study shows that they are
-but subtler illustrations of it. For men’s likenesses being of various
-kinds, lead to various order of integration. There are likenesses of
-disposition, likenesses of taste, likenesses produced by intellectual
-culture, likenesses that result from class-training, likenesses of
-political feeling; and it needs but to glance round at the
-caste-divisions, the associations for philanthropic, scientific, and
-artistic purposes, the religious parties and social cliques; to see that
-some species of likeness among the component members of each body
-determines their union. Now these different integrations, by traversing
-each other, and often by their indirect antagonism, more or less obscure
-each other; and prevent any one kind of integration from becoming
-complete. Hence the anomalies referred to. But if this cause of
-incompleteness be duly borne in mind, social segregations will be seen
-to conform entirely to the same principle as all other segregations.
-Analysis will show that either by external incident forces, or by what
-we may in a sense regard as mutual polarity, there are ever being
-produced in society integrations of those units which have either a
-natural likeness or a likeness generated by training.
-
- * * * * *
-
-§ 129. Can the general truth thus variously illustrated be deduced from
-the persistence of force, in common with foregoing ones? Probably the
-exposition at the beginning of the chapter will have led most readers to
-conclude that it can be so deduced.
-
-The abstract propositions involved are these:—First, that like units,
-subject to a uniform force capable of producing motion in them, will be
-moved to like degrees in the same direction. Second, that like units if
-exposed to unlike forces capable of producing motion in them, will be
-differently moved—moved either in different directions or to different
-degrees in the same direction. Third, that unlike units if acted on by a
-uniform force capable of producing motion in them, will be differently
-moved—moved either in different directions or to different degrees in
-the same direction. Fourth, that the incident forces themselves must be
-affected in analogous ways: like forces falling on like units must be
-similarly modified by the conflict; unlike forces falling on like units
-must be dissimilarly modified; and like forces falling on unlike units
-must be dissimilarly modified. These propositions admit of reduction to
-a still more abstract form. They all of them amount to this:—that in the
-actions and reactions of force and matter, an unlikeness in either of
-the factors necessitates an unlikeness in the effects; and that in the
-absence of unlikeness in either of the factors the effects must be
-alike.
-
-When thus generalized, the immediate dependence of these propositions on
-the persistence of force, becomes obvious. Any two forces that are not
-alike, are forces which differ either in their amounts or directions or
-both; and by what mathematicians call the resolution of forces, it may
-be proved that this difference is constituted by the presence in the one
-of some force not present in the other. Similarly, any two units or
-portions of matter which are unlike in size, weight, form, or other
-attribute, can be known by us as unlike only through some unlikeness in
-the forces they impress on our consciousness; and hence this unlikeness
-also, is constituted by the presence in the one of some force or forces
-not present in the other. Such being the common nature of these
-unlikenesses, what is the inevitable corollary? Any unlikeness in the
-incident forces, where the things acted on are alike, must generate a
-difference between the effects; since otherwise, the differential force
-produces no effect, and force is not persistent. Any unlikeness in the
-things acted on, where the incident forces are alike, must generate a
-difference between the effects; since otherwise, the differential force
-whereby these things are made unlike, produces no effect, and force is
-not persistent. While, conversely, if the forces acting and the things
-acted on, are alike, the effects must be alike; since otherwise, a
-differential effect can be produced without a differential cause, and
-force is not persistent.
-
-Thus these general truths being necessary implications of the
-persistence of force, all the re-distributions above traced out as
-characterizing Evolution in its various phases, are also implications of
-the persistence of force. Such portions of the permanently effective
-forces acting on any aggregate, as produce sensible motions in its
-parts, cannot but work the segregations which we see take place. If of
-the mixed units making up such aggregate, those of the same kind have
-like motions impressed on them by a uniform force, while units of
-another kind are moved by this uniform force in ways more or less unlike
-the ways in which those of the first kind are moved, the two kinds must
-separate and integrate. If the units are alike and the forces unlike, a
-division of the differently affected units is equally necessitated. Thus
-there inevitably arises the demarcated grouping which we everywhere see.
-By virtue of this segregation that grows ever more decided while there
-remains any possibility of increasing it, the change from uniformity to
-multiformity is accompanied by a change from indistinctness in the
-relations of parts to distinctness in the relations of parts. As we
-before saw that the transformation of the homogeneous into the
-heterogeneous is inferrable from that ultimate truth which transcends
-proof; so we here see, that from this same truth is inferrable the
-transformation of an indefinite homogeneity into a definite
-heterogeneity.
-
-
-
-
- CHAPTER XVI.
- EQUILIBRATION.
-
-
-§ 130. And now towards what do these changes tend? Will they go on for
-ever? or will there be an end to them? Can things increase in
-heterogeneity through all future time? or must there be a degree which
-the differentiation and integration of Matter and Motion cannot pass? Is
-it possible for this universal metamorphosis to proceed in the same
-general course indefinitely? or does it work towards some ultimate
-state, admitting no further modification of like kind? The last of these
-alternative conclusions is that to which we are inevitably driven.
-Whether we watch concrete processes, or whether we consider the question
-in the abstract, we are alike taught that Evolution has an impassable
-limit.
-
-The re-distributions of matter that go on around us, are ever being
-brought to conclusions by the dissipation of the motions which effect
-them. The rolling stone parts with portions of its momentum to the
-things it strikes, and finally comes to rest; as do also, in like
-manner, the various things it has struck. Descending from the clouds and
-trickling over the Earth’s surface till it gathers into brooks and
-rivers, water, still running towards a lower level, is at last arrested
-by the resistance of other water that has reached the lowest level. In
-the lake or sea thus formed, every agitation raised by a wind or the
-immersion of a solid body, propagates itself around in waves that
-diminish as they widen, and gradually become lost to observation in
-motions communicated to the atmosphere and the matter on the shores. The
-impulse given by a player to the harp-string, is transformed through its
-vibrations into aerial pulses; and these, spreading on all sides, and
-weakening as they spread, soon cease to be perceptible; and finally die
-away in generating thermal undulations that radiate into space. Equally
-in the cinder that falls out of the fire, and in the vast masses of
-molten lava ejected by a volcano, we see that the molecular agitation
-known to us as heat, disperses itself by radiation; so that however
-great its amount, it inevitably sinks at last to the same degree as that
-existing in surrounding bodies. And if the actions observed be
-electrical or chemical, we still find that they work themselves out in
-producing sensible or insensible movements, that are dissipated as
-before; until quiescence is eventually reached. The proximate
-rationale of the process exhibited under these several forms, lies in
-the fact dwelt on when treating of the Multiplication of Effects, that
-motions are ever being decomposed into divergent motions, and these into
-re-divergent motions. The rolling stone sends off the stones it hits in
-directions differing more or less from its own; and they do the like
-with the things they hit. Move water or air, and the movement is quickly
-resolved into radiating movements. The heat produced by pressure in a
-given direction, diffuses itself by undulations in all directions; and
-so do the light and electricity similarly generated. That is to say,
-these motions undergo division and subdivision; and by continuance of
-this process without limit, they are, though never lost, gradually
-reduced to insensible motions.
-
-In all cases then, there is a progress toward equilibration. That
-universal co-existence of antagonist forces which, as we before saw,
-necessitates the universality of rhythm, and which, as we before saw,
-necessitates the decomposition of every force into divergent forces, at
-the same time necessitates the ultimate establishment of a balance.
-Every motion being motion under resistance, is continually suffering
-deductions; and these unceasing deductions finally result in the
-cessation of the motion.
-
-The general truth thus illustrated under its simplest aspect, we must
-now look at under those more complex aspects it usually presents
-throughout Nature. In nearly all cases, the motion of an aggregate is
-compound; and the equilibration of each of its components, being carried
-on independently, does not affect the rest. The ship’s bell that has
-ceased to vibrate, still continues those vertical and lateral
-oscillations caused by the ocean-swell. The water of the smooth stream
-on whose surface have died away the undulations caused by the rising
-fish, moves as fast as before onward to the sea. The arrested bullet
-travels with undiminished speed round the Earth’s axis. And were the
-rotation of the Earth destroyed, there would not be implied any
-diminution of the Earth’s movement with respect to the Sun and other
-external bodies. So that in every case, what we regard as equilibration
-is a disappearance of some one or more of the many movements which a
-body possesses, while its other movements continue as before. That
-this process may be duly realized and the state of things towards which
-it tends fully understood, it will be well here to cite a case in which
-we may watch this successive equilibration of combined movements more
-completely than we can do in those above instanced. Our end will best be
-served, not by the most imposing, but by the most familiar example. Let
-us take that of the spinning top. When the string which has been wrapped
-round a top’s axis is violently drawn off, and the top falls on to the
-table, it usually happens that besides the rapid rotation, two other
-movements are given to it. A slight horizontal momentum, unavoidably
-impressed on it when leaving the handle, carries it away bodily from the
-place on which it drops; and in consequence of its axis being more or
-less inclined, it falls into a certain oscillation, described by the
-expressive though inelegant word—“wabbling.” These two subordinate
-motions, variable in their proportions to each other and to the chief
-motion, are commonly soon brought to a close by separate processes of
-equilibration. The momentum which carries the top bodily along the
-table, resisted somewhat by the air, but mainly by the irregularities of
-the surface, shortly disappears; and the top thereafter continues to
-spin on one spot. Meanwhile, in consequence of that opposition which the
-axial momentum of a rotating body makes to any change in the plane of
-rotation, (so beautifully exhibited by the gyroscope,) the “wabbling”
-diminishes; and like the other is quickly ended. These minor motions
-having been dissipated, the rotatory motion, interfered with only by
-atmospheric resistance and the friction of the pivot, continues some
-time with such uniformity that the top appears stationary: there being
-thus temporarily established a condition which the French mathematicians
-have termed _equilibrium mobile_. It is true that when the axial
-velocity sinks below a certain point, new motions commence, and increase
-till the top falls; but these are merely incidental to a case in which
-the centre of gravity is above the point of support. Were the top,
-having an axis of steel, to be suspended from a surface adequately
-magnetized, all the phenomena described would be displayed, and the
-moving equilibrium having been once arrived at, would continue until the
-top became motionless, without any further change of position. Now
-the facts which it behoves us here to observe, are these. First, that
-the various motions which an aggregate possesses are separately
-equilibrated: those which are smallest, or which meet with the greatest
-resistance, or both, disappearing first; and leaving at last, that which
-is greatest, or meets with least resistance, or both. Second, that when
-the aggregate has a movement of its parts with respect to each other,
-which encounters but little external resistance, there is apt to be
-established an _equilibrium mobile_. Third, that this moving equilibrium
-eventually lapses into complete equilibrium.
-
-Fully to comprehend the process of equilibration, is not easy; since we
-have simultaneously to contemplate various phases of it. The best course
-will be to glance separately at what we may conveniently regard as its
-four different orders. The first order includes the comparatively
-simple motions, as those of projectiles, which are not prolonged enough
-to exhibit their rhythmical character; but which, being quickly divided
-and subdivided into motions communicated to other portions of matter,
-are presently dissipated in the rhythm of ethereal undulations. In
-the second order, comprehending the various kinds of vibration or
-oscillation as usually witnessed, the motion is used up in generating a
-tension which, having become equal to it or momentarily equilibrated
-with it, thereupon produces a motion in the opposite direction, that is
-subsequently equilibrated in like manner: thus causing a visible rhythm,
-that is, however, soon lost in invisible rhythms. The third order
-of equilibration, not hitherto noticed, obtains in those aggregates
-which continually receive as much motion as they expend. The steam
-engine (and especially that kind which feeds its own furnace and boiler)
-supplies an example. Here the force from moment to moment dissipated in
-overcoming the resistance of the machinery driven, is from moment to
-moment replaced from the fuel; and the balance of the two is maintained
-by a raising or lowering of the expenditure according to the variation
-of the supply: each increase or decrease in the quantity of steam,
-resulting in a rise or fall of the engine’s movement, such as brings it
-to a balance with the increased or decreased resistance. This, which we
-may fitly call the _dependent_ moving equilibrium, should be specially
-noted; since it is one that we shall commonly meet with throughout
-various phases of Evolution. The equilibration to be distinguished
-as of the fourth order, is the _independent_ or perfect moving
-equilibrium. This we see illustrated in the rhythmical motions of the
-Solar System; which, being resisted only by a medium of inappreciable
-density, undergo no sensible diminution in such periods of time as we
-can measure.
-
-All these kinds of equilibration may, however, from the highest point of
-view, be regarded as different modes of one kind. For in every case the
-balance arrived at is relative, and not absolute—is a cessation of the
-motion of some particular body in relation to a certain point or points,
-involving neither the disappearance of the relative motion lost, which
-is simply transformed into other motions, nor a diminution of the body’s
-motions with respect to other points. Thus understanding equilibration,
-it manifestly includes that _equilibrium mobile_, which at first sight
-seems of another nature. For any system of bodies exhibiting, like those
-of the Solar System, a combination of balanced rhythms, has this
-peculiarity;—that though the constituents of the system have relative
-movements, the system as a whole has no movement. The centre of gravity
-of the entire group remains fixed. Whatever quantity of motion any
-member of it has in any direction, is from moment to moment
-counter-balanced by an equivalent motion in some other part of the group
-in an opposite direction; and so the aggregate matter of the group is in
-a state of rest. Whence it follows that the arrival at a state of moving
-equilibrium, is the disappearance of some movement which the aggregate
-had in relation to external things, and a continuance of those movements
-only which the different parts of the aggregate have in relation to each
-other. Thus generalizing the process, it becomes clear that all forms of
-equilibration are intrinsically the same; since in every aggregate, it
-is the centre of gravity only that loses its motion: the constituents
-always retaining some motion with respect to each other—the motion of
-molecules if none else.
-
-Those readers who happen to bear in mind a proposition concerning the
-functional characteristics of Evolution, which was set forth in Chapter
-XII, will probably regard it as wholly at variance with that set forth
-in this Chapter. It was there alleged that throughout Evolution,
-integration of matter is accompanied by integration of such motion as
-the matter previously had; and that thus there is a transformation of
-diffused motion into aggregated motion, parallel to the transformation
-of diffused matter into aggregated matter. Here however, it is asserted
-that every aggregate motion is constantly undergoing diffusion—every
-integrated motion undergoing perpetual disintegration. And so the motion
-of masses, which before was said gradually to arise out of molecular
-motion, is here said to be gradually lost in molecular motion. Doubtless
-these statements, if severally accepted without qualification, are
-contradictory. Neither of them, however, expresses the whole truth. Each
-needs the other as its indispensable complement. It is quite true, as
-before alleged, that there goes on an integration of motion
-corresponding to the integration of matter; and that this essential
-characteristic of Evolution, functionally considered, is clearly
-displayed in proportion as the Evolution is active. But the
-disintegration of motion, which, as we before saw, constitutes
-Dissolution, functionally considered, is all along going on; and though
-at first it forms but a small deduction from the change constituting
-Evolution, it gradually becomes equal to it, and eventually exceeding
-it, entails reverse changes. The aggregation of matter never being
-complete, but leaving behind less aggregated or unaggregated matter, in
-the shape of liquid, aeriform, or ethereal media; it results that from
-the beginning, the integrated motion of integrated masses, is ever being
-obstructed by these less integrated or unintegrated media. So that
-though while the integration of matter is rapidly going on, there is an
-increase of integrated motion, spite of the deductions thus continually
-made from it, there comes a time when the integration of matter and
-consequently of motion, ceases to increase, or increases so slowly that
-the deductions counterbalance it; and thenceforth these begin to
-decrease it, and, by its perpetual diffusion, to bring about a relative
-equilibration. From the beginning, the process of Evolution is
-antagonized by a process of Dissolution; and while the first for a long
-time predominates, the last finally arrests and reverses it.
-
-Returning from this parenthetical explanation, we must now especially
-note two leading truths brought out by the foregoing exposition: the one
-concerning the ultimate, or rather the penultimate, state of motion
-which the processes described tend to bring about; the other concerning
-the concomitant distribution of matter. This penultimate state of
-motion is the moving equilibrium; which, as we have seen, tends to arise
-in an aggregate having compound motions, as a transitional state on the
-way towards complete equilibrium. Throughout Evolution of all kinds,
-there is a continual approximation to, and more or less complete
-maintenance of, this moving equilibrium. As in the Solar System there
-has been established an independent moving equilibrium—an equilibrium
-such that the relative motions of the constituent parts are continually
-so counter-balanced by opposite motions, that the mean state of the
-whole aggregate never varies; so is it, though in a less distinct
-manner, with each form of dependent moving equilibrium. The state of
-things exhibited in the cycles of terrestrial changes, in the balanced
-functions of organic bodies that have reached their adult forms, and in
-the acting and re-acting processes of fully-developed societies, is
-similarly one characterized by compensating oscillations. The involved
-combination of rhythms seen in each of these cases, has an average
-condition which remains practically constant during the deviations ever
-taking place on opposite sides of it. And the fact which we have here
-particularly to observe, is, that as a corollary from the general law of
-equilibration above set forth, the evolution of every aggregate must go
-on until this _equilibrium mobile_ is established; since, as we have
-seen, an excess of force which the aggregate possesses in any direction,
-must eventually be expended in overcoming resistances to change in that
-direction: leaving behind only those movements which compensate each
-other, and so form a moving equilibrium. Respecting the structural
-state simultaneously reached, it must obviously be one presenting an
-arrangement of forces that counterbalance all the forces to which the
-aggregate is subject. So long as there remains a residual force in any
-direction—be it excess of a force exercised by the aggregate on its
-environment, or of a force exercised by its environment on the
-aggregate, equilibrium does not exist; and therefore the re-distribution
-of matter must continue. Whence it follows that the limit of
-heterogeneity towards which every aggregate progresses, is the formation
-of as many specializations and combinations of parts, as there are
-specialized and combined forces to be met.
-
- * * * * *
-
-§ 131. Those successively changed forms which, if the nebular hypothesis
-be granted, must have arisen during the evolution of the Solar System,
-were so many transitional kinds of moving equilibrium; severally giving
-place to more permanent kinds on the way towards complete equilibration.
-Thus the assumption of an oblate spheroidal figure by condensing
-nebulous matter, was the assumption of a temporary and partial moving
-equilibrium among the component parts—a moving equilibrium that must
-have slowly grown more settled, as local conflicting movements were
-dissipated. In the formation and detachment of the nebulous rings,
-which, according to this hypothesis, from time to time took place, we
-have instances of progressive equilibration ending in the establishment
-of a complete moving equilibrium. For the genesis of each such ring,
-implies a perfect balancing of that aggregative force which the whole
-spheroid exercises on its equatorial portion, by that centrifugal force
-which the equatorial portion has acquired during previous concentration:
-so long as these two forces are not equal, the equatorial portion
-follows the contracting mass; but as soon as the second force has
-increased up to an equality with the first, the equatorial portion can
-follow no further, and remains behind. While, however, the resulting
-ring, regarded as a whole connected by forces with external wholes, has
-reached a state of moving equilibrium; its parts are not balanced with
-respect to each other. As we before saw (§ 110) the probabilities
-against the maintenance of an annular form by nebulous matter, are
-immense: from the instability of the homogeneous, it is inferrable that
-nebulous matter so distributed must break up into portions; and
-eventually concentrate into a single mass. That is to say, the ring must
-progress towards a moving equilibrium of a more complete kind, during
-the dissipation of that motion which maintained its particles in a
-diffused form: leaving at length a planetary body, attended perhaps by a
-group of minor bodies, severally having residuary relative motions that
-are no longer resisted by sensible media; and there is thus constituted
-an _equilibrium mobile_ that is all but absolutely perfect.[18]
-
-Hypothesis aside, the principle of equilibration is still perpetually
-illustrated in those minor changes of state which the Solar System is
-undergoing. Each planet, satellite, and comet, exhibits to us at its
-aphelion a momentary equilibrium between that force which urges it
-further away from its primary, and that force which retards its retreat;
-since the retreat goes on until the last of these forces exactly
-counterpoises the first. In like manner at perihelion a converse
-equilibrium is momentarily established. The variation of each orbit in
-size, in eccentricity, and in the position of its plane, has similarly a
-limit at which the forces producing change in the one direction, are
-equalled by those antagonizing it; and an opposite limit at which an
-opposite arrest takes place. Meanwhile, each of these simple
-perturbations, as well as each of the complex ones resulting from their
-combination, exhibits, besides the temporary equilibration at each of
-its extremes, a certain general equilibration of compensating deviations
-on either side of a mean state. That the moving equilibrium thus
-constituted, tends, in the course of indefinite time, to lapse into a
-complete equilibrium, by the gradual decrease of planetary motions and
-eventually integration of all the separate masses composing the Solar
-System, is a belief suggested by certain observed cometary retardations,
-and entertained by some of high authority. The received opinion that the
-appreciable diminution in the period of Encke’s comet, implies a loss of
-momentum caused by resistance of the ethereal medium, commits
-astronomers who hold it, to the conclusion that this same resistance
-must cause a loss of planetary motions—a loss which, infinitesimal
-though it may be in such periods as we can measure, will, if
-indefinitely continued, bring these motions to a close. Even should
-there be, as Sir John Herschel suggests, a rotation of the ethereal
-medium in the same direction with the planets, this arrest, though
-immensely postponed, would not be absolutely prevented. Such an
-eventuality, however, must in any case be so inconceivably remote as to
-have no other than a speculative interest for us. It is referred to
-here, simply as illustrating the still-continued tendency towards
-complete equilibrium, through the still-continued dissipation of
-sensible motion, or transformation of it into insensible motion.
-
-But there is another species of equilibration going on in the Solar
-System, with which we are more nearly concerned—the equilibration of
-that molecular motion known as heat. The tacit assumption hitherto
-current, that the Sun can continue to give off an undiminished amount of
-light and heat through all future time, is fast being abandoned.
-Involving as it does, under a disguise, the conception of power produced
-out of nothing, it is of the same order as the belief that misleads
-perpetual-motion schemers. The spreading recognition of the truth that
-force is persistent, and that consequently whatever force is manifested
-under one shape must previously have existed under another shape, is
-carrying with it a recognition of the truth that the force known to us
-in solar radiations, is the changed form of some other force of which
-the Sun is the seat; and that by the gradual dissipation of these
-radiations into space, this other force is being slowly exhausted. The
-aggregative force by which the Sun’s substance is drawn to his centre of
-gravity, is the only one which established physical laws warrant us in
-suspecting to be the correlate of the forces thus emanating from him:
-the only source of a known kind that can be assigned for the insensible
-motions constituting solar light and heat, is the sensible motion which
-disappears during the progressing concentration of the Sun’s substance.
-We before saw it to be a corollary from the nebular hypothesis, that
-there is such a progressing concentration of the Sun’s substance. And
-here remains to be added the further corollary, that just as in the case
-of the smaller members of the Solar System, the heat generated by
-concentration, long ago in great part radiated into space, has left only
-a central residue that now escapes but slowly; so in the case of that
-immensely larger mass forming the Sun, the immensely greater quantity of
-heat generated and still in process of rapid diffusion, must, as the
-concentration approaches its limit, diminish in amount, and eventually
-leave only an inappreciable internal remnant. With or without the
-accompaniment of that hypothesis of nebular condensation, whence, as we
-see, it naturally follows, the doctrine that the Sun is gradually losing
-his heat, has now gained considerable currency; and calculations have
-been made, both respecting the amount of heat and light already
-radiated, as compared with the amount that remains, and respecting the
-period during which active radiation is likely to continue. Prof.
-Helmholtz estimates, that since the time when, according to the nebular
-hypothesis, the matter composing the Solar System extended to the orbit
-of Neptune, there has been evolved by the arrest of sensible motion, an
-amount of heat 454 times as great as that which the Sun still has to
-give out. He also makes an approximate estimate of the rate at which
-this remaining 1/454th is being diffused: showing that a diminution of
-the Sun’s diameter to the extent of 1/10,000, would produce heat, at the
-present rate, for more than 2000 years; or in other words, that a
-contraction of 1/20,000,000 of his diameter, suffices to generate the
-amount of light and heat annually emitted; and that thus, at the present
-rate of expenditure, the Sun’s diameter will diminish by something like
-1/20 in the lapse of the next million years.[19] Of course these
-conclusions are not to be considered as more than rude approximations to
-the truth. Until quite recently, we have been totally ignorant of the
-Sun’s chemical composition; and even now have obtained but a superficial
-knowledge of it. We know nothing of his internal structure; and it is
-quite possible (probable, I believe,) that the assumptions respecting
-central density, made in the foregoing estimates, are wrong. But no
-uncertainty in the data on which these calculations proceed, and no
-consequent error in the inferred rate at which the Sun is expending his
-reserve of force, militates against the general proposition that this
-reserve of force _is_ being expended; and must in time be exhausted.
-Though the residue of undiffused motion in the Sun, may be much greater
-than is above concluded; though the rate of radiation cannot, as
-assumed, continue at a uniform rate, but must eventually go on with
-slowly-decreasing rapidity; and though the period at which the Sun will
-cease to afford us adequate light and heat, is very possibly far more
-distant than above implied; yet such a period must some time be reached,
-and this is all which it here concerns us to observe.
-
-Thus while the Solar System, if evolved from diffused matter, has
-illustrated the law of equilibration in the establishment of a complete
-moving equilibrium; and while, as at present constituted, it illustrates
-the law of equilibration in the balancing of all its movements; it also
-illustrates this law in the processes which astronomers and physicists
-infer are still going on. That motion of masses produced during
-Evolution, is being slowly re-diffused in molecular motion of the
-ethereal medium; both through the progressive integration of each mass,
-and the resistance to its motion through space. Infinitely remote as may
-be the state when all the motions of masses shall be transformed into
-molecular motion, and all the molecular motion equilibrated; yet such a
-state of complete integration and complete equilibration, is that
-towards which the changes now going on throughout the Solar System
-inevitably tend.
-
- * * * * *
-
-§ 132. A spherical figure is the one which can alone equilibrate the
-forces of mutually-gravitating atoms. If the aggregate of such atoms has
-a rotatory motion, the form of equilibrium becomes a spheroid of greater
-or less oblateness, according to the rate of rotation; and it has been
-ascertained that the Earth is an oblate spheroid, diverging just as much
-from sphericity as is requisite to counterbalance the centrifugal force
-consequent on its velocity round its axis. That is to say, during the
-evolution of the Earth, there has been reached a complete equilibrium of
-those forces which affect its general outline. The only other
-process of equilibration which the Earth as a whole can exhibit, is the
-loss of its axial motion; and that any such loss is going on, we have no
-direct evidence. It has been contended, however, by Prof. Helmholtz,
-that inappreciable as may be its effect within known periods of time,
-the friction of the tidal wave must be slowly diminishing the Earth’s
-rotatory motion, and must eventually destroy it. Now though it seems an
-oversight to say that the Earth’s rotation can thus be destroyed, since
-the extreme effect, to be reached only in infinite time by such a
-process, would be an extension of the Earth’s day to the length of a
-lunation; yet it seems clear that this friction of the tidal wave is a
-real cause of decreasing rotation. Slow as its action is, we must
-recognize it as exemplifying, under another form, the universal progress
-towards equilibrium.
-
-It is needless to point out, in detail, how those movements which the
-Sun’s rays generate in the air and water on the Earth’s surface, and
-through them in the Earth’s solid substance,[20] one and all teach the
-same general truth. Evidently the winds and waves and streams, as well
-as the denudations and depositions they effect, perpetually illustrate
-on a grand scale, and in endless modes, that gradual dissipation of
-motions described in the first section; and the consequent tendency
-towards a balanced distribution of forces. Each of these sensible
-motions, produced directly or indirectly by integration of those
-insensible motions communicated from the Sun, becomes, as we have seen,
-divided and subdivided into motions less and less sensible; until it is
-finally reduced to insensible motions, and radiated from the Earth in
-the shape of thermal undulations. In their totality, these complex
-movements of aerial, liquid, and solid matter on the Earth’s crust,
-constitute a dependent moving equilibrium. As we before saw, there is
-traceable throughout them an involved combination of rhythms. The
-unceasing circulation of water from the ocean to the land, and from the
-land back to the ocean, is a type of these various compensating actions;
-which, in the midst of all the irregularities produced by their mutual
-interferences, maintain an average. And in this, as in other
-equilibrations of the third order, we see that the power from moment to
-moment in course of dissipation, is from moment to moment renewed from
-without: the rises and falls in the supply, being balanced by rises and
-falls in the expenditure; as witness the correspondence between the
-magnetic variations and the cycle of the solar spots. But the fact
-it chiefly concerns us to observe, is, that this process must go on
-bringing things ever nearer to complete rest. These mechanical
-movements, meteorologic and geologic, which are continually being
-equilibrated, both temporarily by counter-movements and permanently by
-the dissipation of such movements and counter-movements, will slowly
-diminish as the quantity of force received from the Sun diminishes. As
-the insensible motions propagated to us from the centre of our system
-become feebler, the sensible motions here produced by them must
-decrease; and at that remote period when the solar heat has ceased to be
-appreciable, there will no longer be any appreciable re-distributions of
-matter on the surface of our planet.
-
-Thus from the highest point of view, all terrestrial changes are
-incidents in the course of cosmical equilibration. It was before pointed
-out, (§ 80) that of the incessant alterations which the Earth’s crust
-and atmosphere undergo, those which are not due to the still-progressing
-motion of the Earth’s substance towards its centre of gravity, are due
-to the still-progressing motion of the Sun’s substance towards its
-centre of gravity. Here it is to be remarked, that this continuance of
-integration in the Earth and in the Sun, is a continuance of that
-transformation of sensible motion into insensible motion which we have
-seen ends in equilibration; and that the arrival in each case at the
-extreme of integration, is the arrival at a state in which no more
-sensible motion remains to be transformed into insensible motion—a state
-in which the forces producing integration and the forces opposing
-integration, have become equal.
-
- * * * * *
-
-§ 133. Every living body exhibits, in a four-fold form, the process we
-are tracing out—exhibits it from moment to moment in the balancing of
-mechanical forces; from hour to hour in the balancing of functions; from
-year to year in the changes of state that compensate changes of
-condition; and finally in the complete arrest of vital movements at
-death. Let us consider the facts under these heads.
-
-The sensible motion constituting each visible action of an organism, is
-soon brought to a close by some adverse force within or without the
-organism. When the arm is raised, the motion given to it is antagonized
-partly by gravity and partly by the internal resistances consequent on
-structure; and its motion, thus suffering continual deduction, ends when
-the arm has reached a position at which the forces are equilibrated. The
-limits of each systole and diastole of the heart, severally show us a
-momentary equilibrium between muscular strains that produce opposite
-movements; and each gush of blood requires to be immediately followed by
-another, because the rapid dissipation of its momentum would otherwise
-soon bring the mass of circulating fluid to a stand. As much in the
-actions and re-actions going on among the internal organs, as in the
-mechanical balancing of the whole body, there is at every instant a
-progressive equilibration of the motions at every instant produced.
- Viewed in their aggregate, and as forming a series, the organic
-functions constitute a dependent moving equilibrium—a moving
-equilibrium, of which the motive power is ever being dissipated through
-the special equilibrations just exemplified, and is ever being renewed
-by the taking in of additional motive power. Food is a store of force
-which continually adds to the momentum of the vital actions, as much as
-is continually deducted from them by the forces overcome. All the
-functional movements thus maintained, are, as we have seen, rhythmical
-(§ 96); by their union compound rhythms of various lengths and
-complexities are produced; and in these simple and compound rhythms, the
-process of equilibration, besides being exemplified at each extreme of
-every rhythm, is seen in the habitual preservation of a constant mean,
-and in the re-establishment of that mean when accidental causes have
-produced divergence from it. When, for instance, there is a great
-expenditure of motion through muscular activity, there arises a
-re-active demand on those stores of latent motion which are laid up in
-the form of consumable matter throughout the tissues: increased
-respiration and increased rapidity of circulation, are instrumental to
-an extra genesis of force, that counter-balances the extra dissipation
-of force. This unusual transformation of molecular motion into sensible
-motion, is presently followed by an unusual absorption of food—the
-source of molecular motion; and in proportion as there has been a
-prolonged draft upon the spare capital of the system, is there a
-tendency to a prolonged rest, during which that spare capital is
-replaced. If the deviation from the ordinary course of the functions has
-been so great as to derange them, as when violent exertion produces loss
-of appetite and loss of sleep, an equilibration is still eventually
-effected. Providing the disturbance is not such as to overturn the
-balance of the functions, and destroy life (in which case a complete
-equilibration is suddenly effected), the ordinary balance is by and by
-re-established: the returning appetite is keen in proportion as the
-waste has been large; while sleep, sound and prolonged, makes up for
-previous wakefulness. Not even in those extreme cases where some excess
-has wrought a derangement that is never wholly rectified, is there an
-exception to the general law; for in such cases the cycle of the
-functions is, after a time, equilibrated about a new mean state, which
-thenceforth becomes the normal state of the individual. Thus, among the
-involved rhythmical changes constituting organic life, any disturbing
-force that works an excess of change in some direction, is gradually
-diminished and finally neutralized by antagonistic forces; which
-thereupon work a compensating change in the opposite direction, and so,
-after more or less of oscillation, restore the medium condition. And
-this process it is, which constitutes what physicians call the _vis
-medicatrix naturæ_. The third form of equilibration displayed by
-organic bodies, is a necessary sequence of that just illustrated. When
-through a change of habit or circumstance, an organism is permanently
-subject to some new influence, or different amount of an old influence,
-there arises, after more or less disturbance of the organic rhythms, a
-balancing of them around the new average condition produced by this
-additional influence. As temporary divergences of the organic rhythms
-are counteracted by temporary divergences of a reverse kind; so there is
-an equilibration of their permanent divergences by the genesis of
-opposing divergences that are equally permanent. If the quantity of
-motion to be habitually generated by a muscle, becomes greater than
-before, its nutrition becomes greater than before. If the expenditure of
-the muscle bears to its nutrition, a greater ratio than expenditure
-bears to nutrition in other parts of the system; the excess of nutrition
-becomes such that the muscle grows. And the cessation of its growth is
-the establishment of a balance between the daily waste and the daily
-repair—the daily expenditure of force, and the amount of latent force
-daily added. The like must manifestly be the case with all organic
-modifications consequent on change of climate or food. This is a
-conclusion which we may safely draw without knowing the special
-re-arrangements that effect the equilibration. If we see that a
-different mode of life is followed, after a period of functional
-derangement, by some altered condition of the system—if we see that this
-altered condition, becoming by and by established, continues without
-further change; we have no alternative but to say, that the new forces
-brought to bear on the system, have been compensated by the opposing
-forces they have evoked. And this is the interpretation of the process
-which we call _adaptation_. Finally, each organism illustrates the
-law in the _ensemble_ of its life. At the outset it daily absorbs under
-the form of food, an amount of force greater than it daily expends; and
-the surplus is daily equilibrated by growth. As maturity is approached,
-this surplus diminishes; and in the perfect organism, the day’s
-absorption of potential motion balances the day’s expenditure of actual
-motion. That is to say, during adult life, there is continuously
-exhibited an equilibration of the third order. Eventually, the daily
-loss, beginning to out-balance the daily gain, there results a
-diminishing amount of functional action; the organic rhythms extend less
-and less widely on each side of the medium state; and there finally
-results that complete equilibration which we call death.
-
-The ultimate structural state accompanying that ultimate functional
-state towards which an organism tends, both individually and as a
-species, may be deduced from one of the propositions set down in the
-opening section of this chapter. We saw that the limit of heterogeneity
-is arrived at whenever the equilibration of any aggregate becomes
-complete—that the re-distribution of matter can continue so long only as
-there continues any motion unbalanced. Whence we found it to follow that
-the final structural arrangements, must be such as will meet all the
-forces acting on the aggregate, by equivalent antagonist forces. What is
-the implication in the case of organic aggregates; the equilibrium of
-which is a moving one? We have seen that the maintenance of such a
-moving equilibrium, requires the habitual genesis of internal forces
-corresponding in number, directions, and amounts to the external
-incident forces—as many inner functions, single or combined, as there
-are single or combined outer actions to be met. But functions are the
-correlatives of organs; amounts of functions are, other things equal,
-the correlatives of sizes of organs; and combinations of functions the
-correlatives of connections of organs. Hence the structural complexity
-accompanying functional equilibration, is definable as one in which
-there are as many specialized parts as are capable, separately and
-jointly, of counteracting the separate and joint forces amid which the
-organism exists. And this is the limit of organic heterogeneity; to
-which man has approached more nearly than any other creature.
-
-Groups of organisms display this universal tendency towards a balance
-very obviously. In § 96, every species of plant and animal was shown to
-be perpetually undergoing a rhythmical variation in number—now from
-abundance of food and absence of enemies rising above its average; and
-then by a consequent scarcity of food and abundance of enemies being
-depressed below its average. And here we have to observe that there is
-thus maintained an equilibrium between the sum of those forces which
-result in the increase of each race, and the sum of those forces which
-result in its decrease. Either limit of variation is a point at which
-the one set of forces, before in excess of the other, is counterbalanced
-by it. And amid these oscillations produced by their conflict, lies that
-average number of the species at which its expansive tendency is in
-equilibrium with surrounding repressive tendencies. Nor can it be
-questioned that this balancing of the preservative and destructive
-forces which we see going on in every race, must necessarily go on.
-Since increase of number cannot but continue until increase of mortality
-stops it; and decrease of number cannot but continue until it is either
-arrested by fertility or extinguishes the race entirely.
-
- * * * * *
-
-§ 134. The equilibrations of those nervous actions which constitute what
-we know as mental life, may be classified in like manner with those
-which constitute what we distinguish as bodily life. We may deal with
-them in the same order.
-
-Each pulse of nervous force from moment to moment generated, (and it was
-shown in § 97 that nervous currents are not continuous but rhythmical)
-is met by counteracting forces; in overcoming which it is dispersed and
-equilibrated. When tracing out the correlation and equivalence of
-forces, we saw that each sensation and emotion, or rather such part of
-it as remains after the excitation of associated ideas and feelings, is
-expended in working bodily changes—contractions of the involuntary
-muscles, the voluntary muscles, or both; as also in a certain
-stimulation of secreting organs. That the movements thus initiated are
-ever being brought to a close by the opposing forces they evoke, was
-pointed out above; and here it is to be observed that the like holds
-with the nervous changes thus initiated. Various facts prove that the
-arousing of a thought or feeling, always involves the overcoming of a
-certain resistance: instance the fact that where the association of
-mental states has not been frequent, a sensible effort is needed to call
-up the one after the other; instance the fact that during nervous
-prostration there is a comparative inability to think—the ideas will not
-follow one another with the habitual rapidity; instance the converse
-fact that at times of unusual energy, natural or artificial, the
-friction of thought becomes relatively small, and more numerous, more
-remote, or more difficult connections of ideas are formed. That is to
-say, the wave of nervous energy each instant generated, propagates
-itself throughout body and brain, along those channels which the
-conditions at the instant render lines of least resistance; and
-spreading widely in proportion to its amount, ends only when it is
-equilibrated by the resistances it everywhere meets. If we
-contemplate mental actions us extending over hours and days, we discover
-equilibrations analogous to those hourly and daily established among the
-bodily functions. In the one case as in the other, there are rhythms
-which exhibit a balancing of opposing forces at each extreme, and the
-maintenance of a certain general balance. This is seen in the daily
-alternation of mental activity and mental rest—the forces expended
-during the one being compensated by the forces acquired during the
-other. It is also seen in the recurring rise and fall of each desire:
-each desire reaching a certain intensity, is equilibrated either by
-expenditure of the force it embodies, in the desired actions, or, less
-completely, in the imagination of such actions: the process ending in
-that satiety, or that comparative quiescence, forming the opposite limit
-of the rhythm. And it is further manifest under a two-fold form, on
-occasions of intense joy or grief: each paroxysm of passion, expressing
-itself in vehement bodily actions, presently reaches an extreme whence
-the counteracting forces produce a return to a condition of moderate
-excitement; and the successive paroxysms finally diminishing in
-intensity, end in a mental equilibrium either like that before existing,
-or partially differing from it in its medium state. But the
-species of mental equilibration to be more especially noted, is that
-shown in the establishment of a correspondence between relations among
-our states of consciousness and relations in the external world. Each
-outer connection of phenomena which we are capable of perceiving,
-generates, through accumulated experiences, an inner connection of
-mental states; and the result towards which this process tends, is the
-formation of a mental connection having a relative strength that answers
-to the relative constancy of the physical connection represented. In
-conformity with the general law that motion pursues the line of least
-resistance, and that, other things equal, a line once taken by motion is
-made a line that will be more readily pursued by future motion; we have
-seen that the ease with which nervous impressions follow one another,
-is, other things equal, great in proportion to the number of times they
-have been repeated together in experience. Hence, corresponding to such
-an invariable relation as that between the resistance of an object and
-some extension possessed by it, there arises an indissoluble connection
-in consciousness; and this connection, being as absolute internally as
-the answering one is externally, undergoes no further change—the inner
-relation is in perfect equilibrium with the outer relation. Conversely,
-it hence happens that to such uncertain relations of phenomena as that
-between clouds and rain, there arise relations of ideas of a like
-uncertainty; and if, under given aspects of the sky, the tendencies to
-infer fair or foul weather, correspond to the frequencies with which
-fair or foul weather follow such aspects, the accumulation of
-experiences has balanced the mental sequences and the physical
-sequences. When it is remembered that between these extremes there are
-countless orders of external connections having different degrees of
-constancy, and that during the evolution of intelligence there arise
-answering internal associations having different degrees of cohesion; it
-will be seen that there is a progress towards equilibrium between the
-relations of thought and the relations of things. This equilibration can
-end only when each relation of things has generated in us a relation of
-thought, such that on the occurrence of the conditions, the relation in
-thought arises as certainly as the relation in things. Supposing this
-state to be reached (which however it can be only in infinite time)
-experience will cease to produce any further mental evolution—there will
-have been reached a perfect correspondence between ideas and facts; and
-the intellectual adaptation of man to his circumstances will be
-complete. The like general truths are exhibited in the process
-moral of adaptation; which is a continual approach to equilibrium
-between the emotions and the kinds of conduct necessitated by
-surrounding conditions. The connections of feelings and actions, are
-determined in the same way as the connections of ideas: just as
-repeating the association of two ideas, facilitates the excitement of
-the one by the other; so does each discharge of feeling into action,
-render the subsequent discharge of such feeling into such action more
-easy. Hence it happens that if an individual is placed permanently in
-conditions which demand more action of a special kind than has before
-been requisite, or than is natural to him—if the pressure of the painful
-feelings which these conditions entail when disregarded, impels him to
-perform this action to a greater extent—if by every more frequent or
-more lengthened performance of it under such pressure, the resistance is
-somewhat diminished; then, clearly, there is an advance towards a
-balance between the demand for this kind of action and the supply of it.
-Either in himself, or in his descendants continuing to live under these
-conditions, enforced repetition must eventually bring about a state in
-which this mode of directing the energies will be no more repugnant than
-the various other modes previously natural to the race. Hence the limit
-towards which emotional modification perpetually tends, and to which it
-must approach indefinitely near (though it can absolutely reach it only
-in infinite time) is a combination of desires that correspond to all the
-different orders of activity which the circumstances of life call
-for—desires severally proportionate in strength to the needs for these
-orders of activity; and severally satisfied by these orders of activity.
-In what we distinguish as acquired habits, and in the moral differences
-of races and nations produced by habits that are maintained through
-successive generations, we have countless illustrations of this
-progressive adaptation; which can cease only with the establishment of a
-complete equilibrium between constitution and conditions.
-
-Possibly some will fail to see how the equilibrations described in this
-section, can be classed with those preceding them; and will be inclined
-to say that what are here set down as facts, are but analogies.
-Nevertheless such equilibrations are as truly physical as the rest. To
-show this fully, would require a more detailed analysis than can now be
-entered on. For the present it must suffice to point out, as before (§
-82), that what we know subjectively as states of consciousness, are,
-objectively, modes of force; that so much feeling is the correlate of so
-much motion; that the performance of any bodily action is the
-transformation of a certain amount of feeling into its equivalent amount
-of motion; that this bodily action is met by forces which it is expended
-in overcoming; and that the necessity for the frequent repetition of
-this action, implies the frequent recurrence of forces to be so
-overcome. Hence the existence in any individual of an emotional stimulus
-that is in equilibrium with certain external requirements, is literally
-the habitual production of a certain specialized portion of nervous
-energy, equivalent in amount to a certain order of external resistances
-that are habitually met. And thus the ultimate state, forming the limit
-towards which Evolution carries us, is one in which the kinds and
-quantities of mental energy daily generated and transformed into
-motions, are equivalent to, or in equilibrium with, the various orders
-and degrees of surrounding forces which antagonize such motions.
-
- * * * * *
-
-§ 135. Each society taken as a whole, displays the process of
-equilibration in the continuous adjustment of its population to its
-means of subsistence. A tribe of men living on wild animals and fruits,
-is manifestly, like every tribe of inferior creatures, always
-oscillating about that average number which the locality can support.
-Though by artificial production, and by successive improvements in
-artificial production, a superior race continually alters the limit
-which external conditions put to population; yet there is ever a
-checking of population at the temporary limit reached. It is true that
-where the limit is being so rapidly changed as among ourselves, there is
-no actual stoppage: there is only a rhythmical variation in the rate of
-increase. But in noting the causes of this rhythmical variation—in
-watching how, during periods of abundance, the proportion of marriages
-increases, and how it decreases during periods of scarcity; it will be
-seen that the expansive force produces unusual advance whenever the
-repressive force diminishes, and _vice versâ_; and thus there is as near
-a balancing of the two as the changing conditions permit.
-
-The internal actions constituting social functions, exemplify the
-general principle no less clearly. Supply and demand are continually
-being adjusted throughout all industrial processes; and this
-equilibration is interpretable in the same way as preceding ones. The
-production and distribution of a commodity, is the expression of a
-certain aggregate of forces causing special kinds and amounts of motion.
-The price of this commodity, is the measure of a certain other aggregate
-of forces expended by the labourer who purchases it, in other kinds and
-amounts of motion. And the variations of price represent a rhythmical
-balancing of these forces. Every rise or fall in the rate of interest,
-or change in the value of a particular security, implies a conflict of
-forces in which some, becoming temporarily predominant, cause a movement
-that is presently arrested or equilibrated by the increase of opposing
-forces; and amid these daily and hourly oscillations, lies a more
-slowly-varying medium, into which the value ever tends to settle; and
-would settle but for the constant addition of new influences. As
-in the individual organism so in the social organism, functional
-equilibrations generate structural equilibrations. When on the workers
-in any trade there comes an increased demand, and when in return for the
-increased supply, there is given to them an amount of other commodities
-larger than was before habitual—when, consequently, the resistances
-overcome by them in sustaining life are less than the resistances
-overcome by other workers; there results a flow of other workers into
-this trade. This flow continues until the extra demand is met, and the
-wages so far fall again, that the total resistance overcome in obtaining
-a given amount of produce, is as great in this newly-adopted occupation
-as in the occupations whence it drew recruits. The occurrence of motion
-along lines of least resistance, was before shown to necessitate the
-growth of population in those places where the labour required for
-self-maintenance is the smallest; and here we further see that those
-engaged in any such advantageous locality, or advantageous business,
-must multiply till there arises an approximate balance between this
-locality or business and others accessible to the same citizens. In
-determining the career of every youth, we see an estimation by parents
-of the respective advantages offered by all that are available, and a
-choice of the one which promises best; and through the consequent influx
-into trades that are at the time most profitable, and the withholding of
-recruits from over-stocked trades, there is insured a general equipoise
-between the power of each social organ and the function it has to
-perform.
-
-The various industrial actions and re-actions thus continually
-alternating, constitute a dependent moving equilibrium like that which
-is maintained among the functions of an individual organism. And this
-dependent moving equilibrium parallels those already contemplated, in
-its tendency to become more complete. During early stages of social
-evolution, while yet the resources of the locality inhabited are
-unexplored, and the arts of production undeveloped, there is never
-anything more than a temporary and partial balancing of such actions,
-under the form of acceleration or retardation of growth. But when a
-society approaches the maturity of that type on which it is organized,
-the various industrial activities settle down into a comparatively
-constant state. Moreover, it is observable that advance in organization,
-as well as advance in growth, is conducive to a better equilibrium of
-industrial functions. While the diffusion of mercantile information is
-slow, and the means of transport deficient, the adjustment of supply to
-demand is extremely imperfect: great over-production of each commodity
-followed by great under-production, constitute a rhythm having extremes
-that depart very widely from the mean state in which demand and supply
-are equilibrated. But when good roads are made, and there is a rapid
-diffusion of printed or written intelligence, and still more when
-railways and telegraphs come into existence—when the periodical fairs of
-early days lapse into weekly markets, and these into daily markets;
-there is gradually produced a better balance of production and
-consumption. Extra demand is much more quickly followed by augmented
-supply; and the rapid oscillations of price within narrow limits on
-either side of a comparatively uniform mean, indicate a near approach to
-equilibrium. Evidently this industrial progress has for its limit,
-that which Mr. Mill has called “the stationary state.” When population
-shall have become dense over all habitable parts of the globe; when the
-resources of every region have been fully explored; and when the
-productive arts admit of no further improvements; there must result an
-almost complete balance, both between the fertility and mortality of
-each society, and between its producing and consuming activities. Each
-society will exhibit only minor deviations from its average number, and
-the rhythm of its industrial functions will go on from day to day and
-year to year with comparatively insignificant perturbations. This limit,
-however, though we are inevitably advancing towards it, is indefinitely
-remote; and can never indeed be absolutely reached. The peopling of the
-Earth up to the point supposed, cannot take place by simple spreading.
-In the future, as in the past, the process will be carried on
-rhythmically, by waves of emigration from new and higher centres of
-civilization successively arising; and by the supplanting of inferior
-races by the superior races they beget; and the process so carried on
-must be extremely slow. Nor does it seem to me that such an
-equilibration will, as Mr. Mill suggests, leave scope for further mental
-culture and moral progress; but rather that the approximation to it must
-be simultaneous with the approximation to complete equilibrium between
-man’s nature and the conditions of his existence.
-
-One other kind of social equilibration has still to be considered:—that
-which results in the establishment of governmental institutions, and
-which becomes complete as these institutions fall into harmony with the
-desires of the people. There is a demand and supply in political affairs
-as in industrial affairs; and in the one case as in the other, the
-antagonist forces produce a rhythm which, at first extreme in its
-oscillations, slowly settles down into a moving equilibrium of
-comparative regularity. Those aggressive impulses inherited from the
-pre-social state—those tendencies to seek self-satisfaction regardless
-of injury to other beings, which are essential to a predatory life,
-constitute an anti-social force, tending ever to cause conflict and
-eventual separation of citizens. Contrariwise, those desires whose ends
-can be achieved only by union, as well as those sentiments which find
-satisfaction through intercourse with fellow-men, and those resulting in
-what we call loyalty, are forces tending to keep the units of a society
-together. On the one hand, there is in each citizen, more or less of
-resistance against all restraints imposed on his actions by other
-citizens: a resistance which, tending continually to widen each
-individual’s sphere of action, and reciprocally to limit the spheres of
-action of other individuals, constitutes a repulsive force mutually
-exercised by the members of a social aggregate. On the other hand, the
-general sympathy of man for man, and the more special sympathy of each
-variety of man for others of the same variety, together with sundry
-allied feelings which the social state gratifies, act as an attractive
-force, tending ever to keep united those who have a common ancestry. And
-since the resistances to be overcome in satisfying the totality of their
-desires when living separately, are greater than the resistances to be
-overcome in satisfying the totality of their desires when living
-together, there is a residuary force that prevents their separation.
-Like all other opposing forces, those exerted by citizens on each other,
-are ever producing alternating movements, which, at first extreme,
-undergo a gradual diminution on the way to ultimate equilibrium. In
-small, undeveloped societies, marked rhythms result from these
-conflicting tendencies. A tribe whose members have held together for a
-generation or two, reaches a size at which it will not hold together;
-and on the occurrence of some event causing unusual antagonism among its
-members, divides. Each primitive nation, depending largely for its
-continued union on the character of its chief, exhibits wide
-oscillations between an extreme in which the subjects are under rigid
-restraint, and an extreme in which the restraint is not enough to
-prevent disorder. In more advanced nations of like type, we always find
-violent actions and reactions of the same essential nature—“despotism
-tempered by assassination,” characterizing a political state in which
-unbearable repression from time to time brings about a bursting of all
-bonds. In this familiar fact, that a period of tyranny is followed by a
-period of license and _vice versâ_, we see how these opposing forces are
-ever equilibrating each other; and we also see, in the tendency of such
-movements and counter-movements to become more moderate, how the
-equilibration progresses towards completeness. The conflicts between
-Conservatism (which stands for the restraints of society over the
-individual) and Reform (which stands for the liberty of the individual
-against society), fall within slowly approximating limits; so that the
-temporary predominance of either, produces a less marked deviation from
-the medium state. This process, now so far advanced among
-ourselves that the oscillations are comparatively unobtrusive, must go
-on till the balance between the antagonist forces approaches
-indefinitely near perfection. For, as we have already seen, the
-adaptation of man’s nature to the conditions of his existence, cannot
-cease until the internal forces which we know as feelings are in
-equilibrium with the external forces they encounter. And the
-establishment of this equilibrium, is the arrival at a state of human
-nature and social organization, such that the individual has no desires
-but those which may be satisfied without exceeding his proper sphere of
-action, while society maintains no restraints but those which the
-individual voluntarily respects. The progressive extension of the
-liberty of citizens, and the reciprocal removal of political
-restrictions, are the steps by which we advance towards this state. And
-the ultimate abolition of all limits to the freedom of each, save those
-imposed by the like freedom of all, must result from the complete
-equilibration between man’s desires and the conduct necessitated by
-surrounding conditions.
-
-Of course in this case, as in the preceding ones, there is thus involved
-a limit to the increase of heterogeneity. A few pages back, we reached
-the conclusion that each advance in mental evolution, is the
-establishment of some further internal action, corresponding to some
-further external action—some additional connection of ideas or feelings,
-answering to some before unknown or unantagonized connection of
-phenomena. We inferred that each such new function, involving some new
-modification of structure, implies an increase of heterogeneity; and
-that thus, increase of heterogeneity must go on, while there remain any
-outer relations affecting the organism which are unbalanced by inner
-relations. Whence we saw it to follow that increase of heterogeneity can
-come to an end only as equilibration is completed. Evidently the like
-must simultaneously take place with society. Each increment of
-heterogeneity in the individual, must directly or indirectly involve, as
-cause or consequence, some increment of heterogeneity in the
-arrangements of the aggregate of individuals. And the limit to social
-complexity can be arrived at, only with the establishment of the
-equilibrium, just described, between social and individual forces.
-
- * * * * *
-
-§ 136. Here presents itself a final question, which has probably been
-taking a more or less distinct shape in the minds of many, while reading
-this chapter. “If Evolution of every kind, is an increase in complexity
-of structure and function that is incidental to the universal process of
-equilibration—if equilibration, passing through the gradually-perfected
-forms of moving equilibrium, must end in complete rest; what is the fate
-towards which all things tend? If the bodies constituting our Solar
-System are slowly dissipating the forces they possess—if the Sun is
-losing his heat at a rate which, though insignificant as stated in terms
-of our chronology, will tell in millions of years—if geologic and
-meteorologic processes cannot but diminish in activity as the Sun’s
-radiations diminish—if with the diminution of these radiations there
-must also go on a diminution in the quantity of vegetal and animal
-existence—if Man and Society, however high the degree of evolution at
-which they arrive, are similarly dependent on this supply of force that
-is gradually coming to an end—if thus the highest, equally with the
-lowest, terrestrial life, must eventually dwindle and disappear; are we
-not manifestly progressing towards omnipresent death? And have we thus
-to contemplate, as the out-come of things, a universe of extinct suns
-round which circle planets devoid of life?”
-
-That such a state must be the proximate end of the processes everywhere
-going on, seems beyond doubt. But the further question tacitly involved,
-whether this state will continue eternally, is quite a different one. To
-give a positive answer to this further question would be quite
-illegitimate; since to affirm any proposition into which unlimited time
-enters as one of the terms, is to affirm a proposition of which one term
-cannot be represented in consciousness—is to affirm an unthinkable
-proposition. At a first glance it may appear that the reverse conclusion
-must be equally illegitimate; and that so the question is altogether
-insoluble. But further consideration will show that this is not true. So
-long as the terms to which we confine our reasonings are finite, the
-finite conclusions reached are not necessarily illegitimate. Though, if
-the general argument, when carried out, left no apparent escape from the
-inference that the state of rest to which Evolution is carrying things,
-must, when arrived at, last for ever, this inference would be invalid,
-as transcending the scope of human intelligence; yet if, on pushing
-further the general argument, we bring out the inference that such a
-state will not last for ever, this inference is not necessarily invalid:
-since, by the hypothesis, it contains no terms necessarily transcending
-the scope of human intelligence. It is permissible therefore, to
-inquire, what are the probable ulterior results of this process which
-must bring Evolution to a close in Universal Death. Without being so
-rash as to form anything like a positive conclusion on a matter so vast
-and so far beyond the boundaries of exact science; we may still inquire
-what _seems_ to be the remote future towards which the facts point.
-
-It has been already shown that all equilibration, so far as we can trace
-it, is relative. The dissipation of a body’s motion by communication of
-it to surrounding matter, solid, liquid, gaseous, and ethereal, tends to
-bring the body to a fixed position in relation to the matter that
-abstracts its motion. But all its other motions continue as before. The
-arrest of a cannon-shot does not diminish its movement towards the East
-at a thousand miles an hour, along with the wall it has struck; and a
-gradual dispersion of the Earth’s rotatory motion, would abstract
-nothing from the million and a half miles per day through which the
-Earth speeds in its orbit. Further, we have to bear in mind that this
-motion, the disappearance of which causes relative equilibration, is not
-lost but simply transferred; and by continual division and subdivision
-finally reduced to ethereal undulations and radiated through space.
-Whether the sensible motion dissipated during relative equilibration, is
-directly transformed into insensible motion, as happens in the case of
-the Sun; or whether, as in the sensible motions going on around us, it
-is directly transformed into smaller sensible motions, and these into
-still smaller, until they become insensible, matters not. In every
-instance the ultimate result is, that whatever motion of masses is lost,
-re-appears as molecular motion pervading space. Thus the questions we
-have to consider, are—Whether after the completion of all the relative
-equilibrations above contemplated as bringing Evolution to a close,
-there remain any further equilibrations to be effected?—Whether there
-are any other motions of masses that must eventually be transformed into
-molecular motion?—And if there are such other motions, what must be the
-consequence when the molecular motion generated by their transformation,
-is added to that which already exists?
-
-To the first of these questions the answer is, that there _do_ remain
-motions which are undiminished by all the relative equilibrations thus
-far considered; namely, the motions of translation possessed by those
-vast masses of incandescent matter called stars—masses now known to be
-suns that are in all probability, like our own, surrounded by circling
-groups of planets. The belief that the stars are literally fixed, has
-long since been exploded: observation has proved many of them to have
-sensible proper motions. Moreover, it has been ascertained by
-measurement, that in relation to the stars nearest to us, our own star
-is moving at the rate of about half a million miles per day; and if, as
-is admitted to be not improbable by sundry astronomers, our own star is
-traversing space in the same direction with adjacent stars, its absolute
-velocity may be, and most likely is, immensely greater than this. Now no
-such changes as those taking place within the Solar System, even when
-carried to the extent of integrating the whole of its matter into one
-mass, and diffusing all its relative movements in an insensible form
-through space, can affect these sidereal movements. Hence, there appears
-no alternative but to infer, that these sidereal movements must remain
-to be equilibrated by some subsequent process.
-
-The next question that arises, if we venture to inquire the probable
-nature of this process, is—To what law do sidereal motions conform? And
-to this question Astronomy replies—the law of gravitation. The relative
-motions of binary stars have proved this. When it was discovered that
-certain of the double stars are not optically double but physically
-double, and move round each other, it was at once suspected that their
-revolutions might be regulated by a mutual attraction like that which
-regulates the revolutions of planets and satellites. The requisite
-measurements having been from time to time made, the periodic times of
-sundry binary stars were calculated on this assumption; and the
-subsequent performances of their revolutions in the predicted periods,
-have completely verified the assumption. If, then, it is demonstrated
-that these remote bodies are centres of gravitation—if we infer that all
-other stars are centres of gravitation, as we may fairly do—and if we
-draw the unavoidable corollary, that this gravitative force which so
-conspicuously affects stars that are comparatively near each other, must
-affect remote stars; we find ourselves led to the conclusion that all
-the members of our Sidereal System gravitate, individually and as an
-aggregate.
-
-But if these widely-dispersed moving masses mutually gravitate, what
-must happen? There appears but one tenable answer. Even supposing they
-were all absolutely equal in weight, and arranged into an annulus with
-absolute regularity, and endowed with exactly the amounts of centrifugal
-force required to prevent nearer approach to their common centre of
-gravity; the condition would still be one which the slightest disturbing
-force would destroy. Much more then are we driven to the inference, that
-our actual Sidereal System cannot preserve its present arrangement: the
-irregularities of its distribution being such as to render even a
-temporary moving equilibrium impossible. If the stars are so many
-centres of an attractive force that varies inversely as the square of
-the distance, there appears to be no escape from the conclusion, that
-the structure of our galaxy must be undergoing change; and must continue
-to undergo change.
-
-Thus, in the absence of tenable alternatives, we are brought to the
-positions:—1, that the stars are in motion;—2, that they move in
-conformity with the law of gravitation;—3, that, distributed as they
-are, they cannot move in conformity with the law of gravitation, without
-undergoing change of arrangement. If now we permit ourselves to take a
-further step, and ask the nature of this change of arrangement, we find
-ourselves obliged to infer a progressive concentration. Whether we do or
-do not suppose the clustering which is now visible, to have been caused
-by mutual gravitation acting throughout past eras, as the hypothesis of
-Evolution implies, we are equally compelled to conclude that this
-clustering must increase throughout future eras. Stars at present
-dispersed, must become locally aggregated; existing aggregations, at the
-same time that they are enlarged by the drawing in of adjacent stars,
-must grow more dense; and aggregations must coalesce with each other:
-each greater degree of concentration augmenting the force by which
-further concentration is produced.
-
-And now what must be the limit of this concentration? The mutual
-attraction of two individual stars, when it so far predominates over
-other attractions as to cause approximation, almost certainly ends in
-the formation of a binary star; since the motions generated by other
-attractions, prevent the two stars from moving in straight lines to
-their common centre of gravity. Between small clusters, too, having also
-certain proper motions as clusters, mutual attraction may lead, not to
-complete union, but to the formation of binary clusters. As the process
-continues however, and the clusters become larger, it seems clear that
-they must move more directly towards each other, thus forming clusters
-of increasing density; and that eventually all clusters must unite into
-one comparatively close aggregation. While, therefore, during the
-earlier stages of concentration, the probabilities are immense against
-the actual contact of these mutually-gravitating masses; it is tolerably
-manifest, that as the concentration increases, collision must become
-probable, and ultimately certain. This is an inference not lacking the
-support of high authority. Sir John Herschel, treating of those numerous
-and variously-aggregated clusters of stars revealed by the telescope,
-and citing with apparent approval his father’s opinion, that the more
-diffused and irregular of these, are “globular clusters in a less
-advanced state of condensation;” subsequently remarks, that “among a
-crowd of solid bodies of whatever size, animated by independent and
-partially opposing impulses, motions opposite to each other _must_
-produce collision, destruction of velocity, and subsidence or near
-approach towards the centre of preponderant attraction; while those
-which conspire, or which remain outstanding after such conflicts, _must_
-ultimately give rise to circulation of a permanent character.” Now what
-is here alleged of these minor sidereal aggregations, cannot be denied
-of the large aggregations; and thus the above-described process of
-concentration, appears certain to bring about an increasingly-frequent
-integration of masses.
-
-We have next to consider the consequences of the accompanying loss of
-velocity. The sensible motion which disappears, cannot be destroyed; but
-must be transformed into insensible motion. What will be the effect of
-this insensible motion? Some approach to a conception of it, will be
-made by considering what would happen were the comparatively
-insignificant motion of our planet thus transformed. In his essay on
-“The Inter-action of Natural Forces,” Prof. Helmholtz states the thermal
-equivalent of the Earth’s movement through space; as calculated on the
-now received datum of Mr. Joule. “If our Earth,” he says, “were by a
-sudden shock brought to rest in her orbit,—which is not to be feared in
-the existing arrangement of our system—by such a shock a quantity of
-heat would be generated equal to that produced by the combustion of
-fourteen such Earths of solid coal. Making the most unfavourable
-assumption as to its capacity for heat, that is, placing it equal to
-that of water, the mass of the Earth would thereby be heated 11,200
-degrees; it would therefore be quite fused, and for the most part
-reduced to vapour. If then the Earth, after having been thus brought to
-rest, should fall into the Sun, which of course would be the case, the
-quantity of heat developed by the shock would be 400 times greater.” Now
-so relatively small a momentum as that acquired by the Earth in falling
-through 95,000,000 of miles to the Sun, being equivalent to a molecular
-motion such as would reduce the Earth to gases of extreme rarity; what
-must be the molecular motion generated by the mutually-arrested momenta
-of two stars, that have moved to their common centre of gravity through
-spaces immeasurably greater? There seems no alternative but to conclude,
-that this molecular motion must be so great, as to reduce the matter of
-the stars to an almost inconceivable tenuity—a tenuity like that which
-we ascribe to nebular matter. Such being the immediate effect of
-the integration of any two stars in a concentrating aggregate, what must
-be the ulterior effect on the aggregate as a whole? Sir John Herschel,
-in the passage above quoted, describing the collisions that must arise
-in a mutually-gravitating group of stars, adds that those stars “which
-remain outstanding after such conflicts, _must_ ultimately give rise to
-circulation of a permanent character.” The problem, however, is here
-dealt with purely as a mechanical one: the assumption being, that the
-mutually-arrested masses will continue as masses—an assumption to which
-no objection was apparent at the time when Sir John Herschel wrote this
-passage; since the doctrine of the correlation of forces was not then
-recognized. But obliged as we now are to conclude, that stars moving at
-the high velocities acquired during concentration, will, by mutual
-arrest, be dissipated into gases of great tenuity, the problem becomes
-different; and a different inference appears unavoidable. For the
-diffused matter produced by such conflicts, must form a resisting
-medium, occupying that central region of the aggregate through which its
-members from time to time pass in describing their orbits—a resisting
-medium which they cannot move through without having their velocities
-diminished. Every further such collision, by augmenting this resisting
-medium, and making the losses of velocity greater, must further aid in
-preventing the establishment of that equilibrium which would else arise;
-and so must conspire to produce more frequent collisions. And the
-nebulous matter thus formed, presently enveloping and extending beyond
-the whole aggregate, must, by continuing to shorten their gyrations,
-entail an increasingly-active integration and re-active disintegration
-of the moving masses; until they are all finally dissipated. This,
-indeed, is the conclusion which, leaving out all consideration of the
-process gone through, presents itself as a simple deduction from the
-persistence of force. If the stars have been, and still are,
-concentrating however indirectly on their common centre of gravity, and
-must eventually reach it; it is a corollary from the persistence of
-force, that the quantities of motion they have severally acquired, must
-suffice to carry them away from the common centre of gravity to those
-remote regions whence they originally began to move towards it. And
-since, by the conditions of the case, they cannot return to these remote
-regions in the shape of concrete masses, they must return in the shape
-of diffused masses. Action and reaction being equal and opposite, the
-momentum producing dispersion, must be as great as the momentum acquired
-by aggregation; and being spread over the same quantity of matter, must
-cause an equivalent distribution through space, whatever be the form of
-the matter. One condition, however, essential to the literal
-fulfilment of this result, must be specified; namely, that the quantity
-of molecular motion produced and radiated into space by each star in the
-course of its formation from diffused matter, shall be compensated by an
-equal quantity of molecular motion radiated from other parts of space
-into the space which our Sidereal System occupies. In other words, if we
-set out with that amount of molecular motion implied by the existence of
-the matter of our Sidereal System in a nebulous form; then it follows
-from the persistence of force, that if this matter undergoes the
-re-distribution constituting Evolution, the quantity of molecular motion
-given out during the integration of each mass, plus the quantity of
-molecular motion given out during the integration of all the masses,
-must suffice again to reduce it to the same nebulous form. Here
-indeed we arrive at an impassable limit to our reasonings; since we
-cannot know whether this condition is or is not fulfilled. On the
-hypothesis of an unlimited space, containing, at certain intervals,
-Sidereal Systems like our own, it may be that the quantity of molecular
-motion radiated into the region occupied by our Sidereal System, is
-equal to that which our Sidereal System radiates; in which case the
-quantity of motion possessed by it, remaining undiminished, our Sidereal
-System may continue during unlimited time, to repeat this alternate
-concentration and diffusion. But if, on the other hand, throughout
-boundless space there exist no other Sidereal Systems subject to like
-changes, or if such other Sidereal Systems exist at more than a certain
-average distance from each other; then it seems an unavoidable
-conclusion that the quantity of motion possessed, must diminish by
-radiation into unoccupied space; and that so, on each successive
-resumption of the nebulous form, the matter of our Sidereal System will
-occupy a less space; until at the end of an infinite time it reaches
-either a state in which its concentrations and diffusions are relatively
-small, or a state of complete aggregation and rest. Since, however, we
-have no evidence showing the existence or non-existence of Sidereal
-Systems throughout remote space; and since, even had we such evidence, a
-legitimate conclusion could not be drawn from premises of which one
-element (unlimited space) is inconceivable; we must be for ever without
-answer to this transcendent question. All we can say is, that so far as
-the data enable us to judge, the integration of our Sidereal System will
-be followed by disintegration; that such integration and disintegration
-will be repeated; and that, for anything we know to the contrary, the
-alternation of them may continue without limit.
-
-But leaving this ultimate insoluble problem, and confining ourselves to
-the proximate and not necessarily insoluble one, we find reason for
-thinking that after the completion of those various equilibrations which
-bring to a close all the forms of Evolution we have contemplated, there
-must still continue an equilibration of a far wider kind. When that
-integration everywhere in progress throughout our Solar System, has
-reached its climax, there will remain to be effected the immeasurably
-greater integration of our Solar System, with all other such systems. As
-in those minor forms now going on around us, this integration with its
-concomitant equilibration, involves the change of aggregate motion into
-diffused motion; so in those vaster forms hereafter to be carried out,
-there must similarly be gained in molecular motion what is lost in the
-motion of masses; and the inevitable transformation of this motion of
-masses into molecular motion, cannot take place without reducing the
-masses to a nebulous form. Thus we seem led to the conclusion that the
-entire process of things, as displayed in the aggregate of the visible
-Universe, is analogous to the entire process of things as displayed in
-the smallest aggregates. Where, as in organic bodies, the whole series
-of changes constituting Evolution can be traced, we saw that,
-dynamically considered, Evolution is a change from molecular motion to
-the motion of masses; and this change, becoming more active during the
-ascending phase of Evolution while the masses increase in bulk and
-heterogeneity, eventually begins to get less active; until, passing
-through stages in which the integration grows greater, and the
-equilibrium more definite, it finally ceases; whereupon there arises, by
-an ulterior process, an increase of molecular motion, ending in the more
-or less complete dissolution of the aggregate. And here we find reason
-to believe that, along with each of the thousands of similar ones
-dispersed through the heavens, our Solar System, after passing through
-stages during which the motion of masses is produced at the expense of
-lost molecular motion, and during which there goes on an increasingly
-active differentiation and integration, arrives at a climax whence these
-changes, beginning to decline in activity, slowly bring about that
-complete integration and equilibration which in other cases we call
-death; and that there afterwards comes a time, when the still-remaining
-motions of masses are transformed into a molecular motion which causes
-dissolution of the masses. Motion as well as Matter being fixed in
-quantity, it would seem that the change in the distribution of Matter
-which Motion effects, coming to a limit in whichever direction it is
-carried, the indestructible Motion thereupon necessitates a reverse
-distribution. Apparently, the universally-coexistent forces of
-attraction and repulsion, which, as we have seen, necessitate rhythm in
-all minor changes throughout the Universe, also necessitate rhythm in
-the totality of its changes—produce now an immeasurable period during
-which the attractive forces predominating, cause universal
-concentration, and then an immeasurable period during which the
-repulsive forces predominating, cause universal diffusion—alternate eras
-of Evolution and Dissolution. And thus there is suggested the conception
-of a past during which there have been successive Evolutions similar to
-that which is now going on; and a future during which successive other
-such Evolutions may go on.
-
-Let none suppose, however, that this is to be taken as anything more
-than a speculation. In dealing with times and spaces and forces so
-immensely transcending those of which we have definite experience, we
-are in danger of passing the limits to human intelligence. Though these
-times and spaces and forces cannot literally be classed as infinite; yet
-they are so utterly beyond the possibility of definite conception, as to
-be almost equally unthinkable with the infinite. What has been above
-said, should therefore be regarded simply as a possible answer to a
-possible doubt. When, pushing to its extreme the argument that Evolution
-must come to a close in complete equilibrium or rest, the reader
-suggests that for aught which appears to the contrary, the Universal
-Death thus implied will continue indefinitely; it is legitimate to point
-out how, on carrying the argument still further, we are led to infer a
-subsequent Universal Life. But while this last inference may fitly be
-accepted as a demurrer to the first, it would be unwise to accept it in
-any more positive sense.
-
- * * * * *
-
-§ 137. Returning from this parenthetical discussion, concerning the
-probable or possible state of things that may arise after Evolution has
-run its course; and confining ourselves to the changes constituting
-Evolution, with which alone we are immediately concerned; we have now to
-inquire whether the cessation of these changes, in common with all their
-transitional characteristics, admits of _à priori_ proof. It will soon
-become apparent that equilibration, not less than the preceding general
-principles, is deducible from the persistence of force.
-
-We have seen (§ 85) that phenomena are interpretable only as the results
-of universally-coexistent forces of attraction and repulsion. These
-universally-coexistent forces of attraction and repulsion, are, indeed,
-the complementary aspects of that absolutely persistent force which is
-the ultimate datum of consciousness. Just in the same way that the
-equality of action and re-action is a corollary from the persistence of
-force, since their inequality would imply the disappearance of the
-differential force into nothing, or its appearance out of nothing; so,
-we cannot become conscious of an attractive force without becoming
-simultaneously conscious of an equal and opposite repulsive force. For
-every experience of a muscular tension, (under which form alone we can
-immediately know an attractive force,) presupposes an equivalent
-resistance—a resistance shown in the counter-balancing pressure of the
-body against neighbouring objects, or in that absorption of force which
-gives motion to the body, or in both—a resistance which we cannot
-conceive as other than equal to the tension, without conceiving force to
-have either appeared or disappeared, and so denying the persistence of
-force. And from this necessary correlation, results our inability,
-before pointed out, of interpreting any phenomena save in terms of these
-correlatives—an inability shown alike in the compulsion we are under to
-think of the statical forces which tangible matter displays, as due to
-the attraction and repulsion of its atoms, and in the compulsion we are
-under to think of dynamical forces exercised through space, by regarding
-space as filled with atoms similarly endowed. Thus from the existence of
-a force that is for ever unchangeable in quantity, there follows, as a
-necessary corollary, the co-extensive existence of these opposite forms
-of force—forms under which the conditions of our consciousness oblige us
-to represent that absolute force which transcends our knowledge.
-
-But the forces of attraction and repulsion being universally
-co-existent, it follows, as before shown, that all motion is motion
-under resistance. Units of matter, solid, liquid, aëriform, or ethereal,
-filling the space which any moving body traverses, offer to such body
-the resistance consequent on their cohesion, or their inertia, or both.
-In other words, the denser or rarer medium which occupies the places
-from moment to moment passed through by such moving body, having to be
-expelled from them, as much motion is abstracted from the moving body as
-is given to the medium in expelling it from these places. This being the
-condition under which all motion occurs, two corollaries result. The
-first is, that the deductions perpetually made by the communication of
-motion to the resisting medium, cannot but bring the motion of the body
-to an end in a longer or shorter time. The second is, that the motion of
-the body cannot cease until these deductions destroy it. In other words,
-movement must continue till equilibration takes place; and equilibration
-must eventually take place. Both these are manifest deductions from the
-persistence of force. To say that the whole or part of a body’s motion
-can disappear, save by transfer to something which resists its motion,
-is to say that the whole or part of its motion can disappear without
-effect; which is to deny the persistence of force. Conversely, to say
-that the medium traversed can be moved out of the body’s path, without
-deducting from the body’s motion, is to say that motion of the medium
-can arise out of nothing; which is to deny the persistence of force.
-Hence this primordial truth is our immediate warrant for the
-conclusions, that the changes which Evolution presents, cannot end until
-equilibrium is reached; and that equilibrium must at last be reached.
-
-Equally necessary, because equally deducible from this same truth that
-transcends proof, are the foregoing propositions respecting the
-establishment and maintenance of moving equilibria, under their several
-aspects. It follows from the persistence of force, that the various
-motions possessed by any aggregate, either as a whole or among its
-parts, must be severally dissipated by the resistances they severally
-encounter; and that thus, such of them as are least in amount, or meet
-with greatest opposition, or both, will be brought to a close while the
-others continue. Hence in every diversely moving aggregate, there
-results a comparatively early dissipation of motions which are smaller
-and much resisted; followed by long-continuance of the larger and
-less-resisted motions; and so there arise dependent and independent
-moving equilibria. Hence also may be inferred the tendency to
-conservation of such moving equilibria; since, whenever the new motion
-given to the parts of a moving equilibrium by a disturbing force, is not
-of such kind and amount that it cannot be dissipated before the
-pre-existing motions (in which case it brings the moving equilibrium to
-an end) it must be of such kind and amount that it can be dissipated
-before the pre-existing motions (in which case the moving equilibrium is
-re-established).
-
-Thus from the persistence of force follow, not only the various direct
-and indirect equilibrations going on around, together with that cosmical
-equilibration which brings Evolution under all its forms to a close; but
-also those less manifest equilibrations shown in the re-adjustments of
-moving equilibria that have been disturbed. By this ultimate principle
-is proveable the tendency of every organism, disordered by some unusual
-influence, to return to a balanced state. To it also may be traced the
-capacity, possessed in a slight degree by individuals, and in a greater
-degree by species, of becoming adapted to new circumstances. And not
-less does it afford a basis for the inference, that there is a gradual
-advance towards harmony between man’s mental nature and the conditions
-of his existence. After finding that from it are deducible the various
-characteristics of Evolution, we finally draw from it a warrant for the
-belief, that Evolution can end only in the establishment of the greatest
-perfection and the most complete happiness.
-
------
-
-Footnote 18:
-
- Sir David Brewster has recently been citing with approval, a
- calculation by M. Babinet, to the effect that on the hypothesis of
- nebular genesis, the matter of the Sun, when it filled the Earth’s
- orbit, must have taken 3181 years to rotate; and that therefore the
- hypothesis cannot be true. This calculation of M. Babinet may pair-off
- with that of M. Comte, who, contrariwise, made the time of this
- rotation agree very nearly with the Earth’s period of revolution round
- the Sun; for if M. Comte’s calculation involved a _petitio principii_,
- that of M. Babinet is manifestly based on two assumptions, both of
- which are gratuitous, and one of them totally inconsistent with the
- doctrine to be tested. He has evidently proceeded on the current
- supposition respecting the Sun’s internal density, which is not
- proved, and from which there are reasons for dissenting; and he has
- evidently taken for granted that all parts of the nebulous spheroid,
- when it filled the Earth’s orbit, had the same angular velocity;
- whereas if (as is implied in the nebular hypothesis, rationally
- understood) this spheroid resulted from the concentration of far more
- widely-diffused matter, the angular velocity of its equatorial portion
- would obviously be immensely greater than that of its central portion.
-
-Footnote 19:
-
- See paper “On the Inter-action of Natural Forces,” by Prof. Helmholtz,
- translated by Prof. Tyndall, and published in the _Philosophical
- Magazine_, supplement to Vol. XI. fourth series.
-
-Footnote 20:
-
- Until I recently consulted his “Outlines of Astronomy” on another
- question, I was not aware that so far back as 1833, Sir John Herschel
- had enunciated the doctrine that “the sun’s rays are the ultimate
- source of almost every motion which takes place on the surface of the
- earth.” He expressly includes all geologic, meteorologic, and vital
- actions; as also those which we produce by the combustion of coal. The
- late George Stephenson appears to have been wrongly credited with this
- last idea.
-
-
-
-
- CHAPTER XVII.
- SUMMARY AND CONCLUSION.
-
-
-§ 138. In the chapter on “Laws in general,” after delineating the
-progress of mankind in recognizing uniformities of relation among
-surrounding phenomena—after showing how the actual succession in the
-establishment of different orders of co-existences and sequences,
-corresponds with the succession deducible _à priori_ from the conditions
-to human knowledge—after showing how, by the ever-multiplying
-experiences of constant connections among phenomena, there has been
-gradually generated the conception of universal conformity to law; it
-was suggested that this conception will become still clearer, when it is
-perceived that there are laws of wider generality than any of those at
-present accepted.
-
-The existence of such more general laws, is, indeed, almost implied by
-the _ensemble_ of the facts set forth in the above-named chapter; since
-they make it apparent, that the process hitherto carried on, of bringing
-phenomena under fewer and wider laws, has not ceased, but is advancing
-with increasing rapidity. Apart, however, from evidence of this kind,
-the man of science, hourly impressed with new proof of uniformity in the
-relations of things, until the conception of uniformity has become with
-him a necessity of thought, tacitly entertains the conclusion that the
-minor uniformities which Science has thus far established, will
-eventually be merged in uniformities that are universal. Taught as he is
-by every observation and experiment, to regard phenomena as
-manifestations of Force; and learning as he does to contemplate Force as
-unchangeable in amount; there tends to grow up in him a belief in
-unchangeable laws common to Force under all its manifestations. Though
-he may not have formulated it to himself, he is prepared to recognize
-the truth, that, being fixed in quantity, fixed in its two ultimate
-modes of presentation (Matter and Motion), and fixed in the conditions
-under which it is presented (Time and Space); Force must have certain
-equally fixed laws of action, common to all the changes it produces.
-
-Hence to the classes who alone are likely to read these pages, the
-hypothesis of a fundamental unity, extending from the simplest inorganic
-actions up to the most complex associations of thought and the most
-involved social processes, will have an _à priori_ probability. All
-things being recognized as having one source, will be expected to
-exhibit one method. Even in the absence of a clue to uniformities
-co-extensive with all modes of Force, as the mathematical uniformities
-are co-extensive with Space and Time, it will be inferred that such
-uniformities exist. And thus a certain presumption will result in favour
-of any formula, of a generality great enough to include concrete
-phenomena of every order.
-
- * * * * *
-
-§ 139. In the chapters on the “Law of Evolution,” there was set forth a
-principle, which, so far as accessible evidence enables us to judge,
-possesses this universality. The order of material changes, first
-perceived to have certain constant characteristics in cases where it
-could be readily traced from beginning to end, we found to have these
-same characteristics in cases where it could be less readily traced; and
-we saw numerous indications that these same characteristics were
-displayed during past changes of which we have no direct knowledge. The
-transformation of the homogeneous into the heterogeneous, first observed
-by naturalists to be exhibited during the development of every plant and
-animal, proved to be also exhibited during the development of every
-society; both in its political and industrial organization, and in all
-the products of social life,—language, science, art, and literature.
-From the disclosures of geology, we drew adequate support for the
-conclusion, that in the structure of the Earth there has similarly been
-a progress from uniformity, through ever-increasing degrees of
-multiformity, to the complex state which we now see. And on the
-assumption of that nebular origin to which so many facts point, we
-inferred that a like transition from unity to variety of distribution,
-must have been undergone by our Solar System; as well as by that vast
-assemblage of such systems constituting the visible Universe. This
-definition of the metamorphosis, first asserted by physiologists of
-organic aggregates only, but which we thus found reason to think, holds
-of all other aggregates, proved on further inquiry to be too wide. Its
-undue width was shown to arise from the omission of certain other
-characteristics, that are, not less than the foregoing one, displayed
-throughout all kinds of Evolution. We saw that simultaneously with the
-change from homogeneity to heterogeneity, there takes place a change
-from indefiniteness of arrangement to definiteness of arrangement—a
-change everywhere equally traceable with that which it accompanies.
-Further consideration made it apparent, that the increasing definiteness
-thus manifested along with increasing heterogeneity, necessarily results
-from increasing integration of the parts severally rendered unlike. And
-thus we finally reached the conclusion, that there has been going on
-throughout an immeasurable past, is still going on, and will continue to
-go on, an advance from a diffused, indeterminate, and uniform
-distribution of Matter, to a concentrated, determinate, and multiform
-distribution of it.
-
-At a subsequent stage of our inquiry, we discovered that this
-progressive change in the arrangement of Matter, is accompanied by a
-parallel change in the arrangement of Motion—that every increase in the
-structural complexity of things, involves a corresponding increase in
-their functional complexity. It was shown that along with the
-integration of molecules into masses, there arises an integration of
-molecular motion into the motion of masses; and that as fast as there
-results variety in the sizes and forms of aggregates and their relations
-to incident forces, there also results variety in their movements.
-Whence it became manifest, that the general process of things is from a
-confused simplicity to an orderly complexity, in the distribution of
-both Matter and Motion.
-
-It was pointed out, however, that though this species of transformation
-is universal, in the sense of holding throughout all classes of
-phenomena, it is not universal in the sense of being continued without
-limit in all classes of phenomena. Those aggregates which exhibit the
-entire change from uniformity to multiformity of structure and function,
-in comparatively short periods, eventually show us a reverse set of
-changes: Evolution is followed by Dissolution. The differentiations and
-integrations of Matter and Motion, finally reach a degree which the
-conditions do not allow them to pass; and there then sets in a process
-of disintegration and assimilation, of both the parts and the movements
-that were before growing more united and more distinct.
-
-But under one or the other of these processes, all observable
-modifications in the arrangement of things may be classed. Every change
-comes under the head of integration or disintegration, material or
-dynamical; or under the head of differentiation or assimilation,
-material or dynamical; or under both. Each inorganic mass is either
-undergoing increase by the combination with it of surrounding elements
-for which its parts have affinity; or undergoing decrease by the solvent
-and abraiding action of surrounding elements; or both one and the other
-in varied succession and combination. By perpetual additions and losses
-of heat, it is having its parts temporarily differentiated from each
-other, or temporarily assimilated to each other, in molecular state. And
-through the actions of divers agents, it is also undergoing certain
-permanent molecular re-arrangements; rendering it either more uniform or
-more multiform in structure. These opposite kinds of change, thus
-vaguely typified in every surrounding fragment of matter, are displayed
-in all aggregates with increasing distinctness in proportion as the
-conditions essential to re-arrangement of parts are fulfilled. So that
-universally, the process of things is either in the one direction or the
-other. There is in all cases going on that ever-complicating
-distribution of Matter and Motion which we call Evolution; save in those
-cases where it has been brought to a close and reversed by what we call
-Dissolution.
-
- * * * * *
-
-§ 140. Whether this omnipresent metamorphosis admits of interpretation,
-was the inquiry on which we next entered. Recognizing the changes thus
-formulated as consisting in Motions of Matter that are produced by
-Force, we saw that if they are interpretable at all, it must be by the
-affiliation of them on certain ultimate laws of Matter, Motion, and
-Force. We therefore proceeded to inquire what these ultimate laws are.
-
-We first contemplated under its leading aspects, the principle of
-correlation and equivalence among forces. The genesis of sensible motion
-by insensible motion, and of insensible motion by sensible motion, as
-well as the like reciprocal production of those forms of insensible
-motion which constitute Light, Heat, Electricity, Magnetism, and
-Chemical Action, was shown to be a now accepted doctrine, that involves
-certain corollaries respecting the processes everywhere going on around
-us. Setting out with the probability that the insensible motion radiated
-by the Sun, is the transformed product of the sensible motion lost
-during the progressive concentration of the solar mass; we saw that by
-this insensible motion, are in turn produced the various kinds of
-sensible motion on the Earth’s surface. Besides the inorganic
-terrestrial changes, we found that the changes constituting organic life
-are thus originated. We were obliged to conclude that within this
-category, come the vital phenomena classed as mental, as well as those
-classed as physical. And it appeared inevitably to follow that of social
-changes, too, the like must be said. We next saw that phenomena
-being cognizable by us only as products of Force, manifested under the
-two-fold form of attraction and repulsion, there results the general law
-that all Motion must occur in the direction of least resistance, or in
-the direction of greatest traction, or in the direction of their
-resultant. It was pointed out that this law is every instant illustrated
-in the movements of the celestial bodies. The innumerable transpositions
-of matter, gaseous, liquid, and solid, going on over the Earth’s
-surface, were shown to conform to it. Evidence was given that this same
-ultimate principle of motion underlies the structural and functional
-changes of organisms. Throughout the succession of those nervous actions
-which constitute thought and feeling, as also in the discharge of
-feeling into action, we no less found this principle conspicuous. Nor
-did we discover any exception to it in the movements, temporary and
-permanent, that go on in societies. From the universal coexistence
-of opposing forces, there also resulted the rhythm of motion. It was
-shown that this is displayed from the infinitesimal vibrations of
-molecules up to the enormous revolutions and gyrations of planets; that
-it is traceable throughout all meteorologic and geologic changes; that
-the functions of every organic body exemplify it in various forms; that
-mental activities too, intellectual and emotional, exhibit periodicities
-of sundry kinds; and that actions and reactions illustrating this law
-under a still more complex form, pervade social processes.
-
-Such being the principles to which conform all changes produced by
-Force on the distribution of Matter, and all changes re-actively
-produced by Matter on the distribution of Force, we proceeded to
-inquire what must be the consequent nature of any re-distributions
-produced: having first noted the limiting conditions between which
-such re-distributions are possible, and the medium conditions that are
-most favourable to them. The first conclusion arrived at, was,
-that any finite homogeneous aggregate must inevitably lose its
-homogeneity, through the unequal exposure of its parts to incident
-forces. We observed how this was shown in surrounding things, by the
-habitual establishment of differences between inner and outer parts,
-and parts otherwise dissimilarly circumstanced. It was pointed out
-that the production of diversities of structure by forces acting under
-diverse conditions, has been illustrated in astronomic evolution,
-supposing such evolution to have taken place; and that a like
-connection of cause and effect is seen in the large and small
-modifications undergone by our globe. In the early changes of organic
-germs, we discovered further evidence that unlikenesses of structure
-follow unlikenesses of relations to surrounding agencies—evidence
-enforced by the tendency of the differently-placed members of each
-species to diverge into varieties. We found that the principle is also
-conformed to in the establishment of distinctions among our ideas; and
-that the contrasts, political and industrial, that arise between the
-parts of societies are no less in harmony with it. The instability of
-the homogeneous thus caused, and thus everywhere exemplified, we also
-saw must hold of the unlike parts into which any uniform whole lapses;
-and that so the less heterogeneous must tend continually to become
-more heterogeneous—an inference which we also found to be everywhere
-confirmed by fact. Carrying a step further our inquiry into
-these actions and reactions between Force and Matter, there was
-disclosed a secondary cause of increasing multiformity. Every
-differentiated part becomes, we found, a parent of further
-differentiations; not only in the sense that it must lose its own
-homogeneity in heterogeneity, but also in the sense that it must, in
-growing unlike other parts, become a centre of unlike reactions on
-incident forces; and by so adding to the diversity of forces at work,
-must add to the diversity of effects produced. This multiplication of
-effects, likewise proved to be manifest throughout all Nature. That
-forces modified in kind and direction by every part of every
-aggregate, are gradually expended in working changes that grow more
-numerous and more varied as the forces are subdivided, is shown in the
-actions and reactions going on throughout the Solar System, in the
-never-ceasing geologic complications, in the involved symptoms
-produced in organisms by disturbing influences, in the many thoughts
-and feelings generated by single impressions, and in the
-ever-ramifying results of each new agency brought to bear on a
-society. To which add the corollary, confirmed by abundant facts, that
-the multiplication of effects must increase in a geometrical
-progression, as the heterogeneity increases. Completely to
-interpret the structural changes constituting Evolution, there
-remained to assign a reason for that increasingly-distinct demarcation
-of parts, which accompanies the production of differences between
-parts. This reason we discovered to be, the segregation of mixed units
-under the action of forces capable of moving them. We saw that when
-the parts of an aggregate have been made qualitatively unlike by
-unlike incident forces—that is, when they have become contrasted in
-the natures of their component units; there necessarily arises a
-tendency to separation of the dissimilar orders of units from each
-other, and to aggregation of those units which are similar. This cause
-of the integration that accompanies differentiation, turned out to be
-likewise exemplified by all kinds of Evolution—by the formation of
-celestial bodies, by the moulding of the Earth’s crust, by organic
-modifications, by the establishment of mental distinctions, by the
-genesis of social divisions. And we inferred, what we may everywhere
-see, that the segregation thus produced goes on so long as there
-remains a possibility of making it more complete. At length, to
-the query whether the processes thus traced out have any limit, there
-came the answer that they must end in equilibration. That continual
-division and subdivision of forces, which is instrumental in changing
-the uniform into the multiform and the multiform into the more
-multiform, we saw to be at the same time a process by which force is
-perpetually dissipated; and that dissipation, continuing as long as
-there remains any force unbalanced by an opposing force, must end in
-rest. It was shown that when, as happens with aggregates of various
-orders, a number of movements are going on in combination, the earlier
-dispersion of the smaller and more resisted movements, entails the
-establishment of different kinds of moving equilibria: forming
-transitional stages on the way to complete equilibrium. And further
-inquiry made it apparent that for the same reason, these moving
-equilibria have a certain self-conserving power; shown in the
-neutralization of perturbations, and the adjustment to new conditions.
-This general principle, like the preceding ones, proved to be
-traceable throughout all forms of Evolution—astronomic, geologic,
-biologic, mental and social. And our concluding inference was, that
-the penultimate stage of this process, in which the extremest degree
-of multiformity and completest form of moving equilibrium is
-established, must be one implying the highest conceivable state of
-humanity.
-
-Thus it became apparent that this transformation of on indefinite,
-incoherent homogeneity into a definite coherent heterogeneity, which
-goes on everywhere, until it brings about a reverse transformation, is
-consequent on certain simple laws of force. Given those universal modes
-of action which are from moment to moment illustrated in the commonest
-changes around us, and it follows that there cannot but result the
-observed metamorphosis of an indeterminate uniformity into a determinate
-multiformity.
-
- * * * * *
-
-§ 141. Finally, we have asked whether, for these universal modes of
-action, any common cause is assignable—whether these wide truths are
-dependent on any single widest truth. And to this question we found a
-positive answer. These several principles are corollaries from that
-primordial principle which transcends human intelligence by underlying
-it.
-
-In the first part of this work it was shown, by analysis of both our
-religious and our scientific ideas, that while knowledge of the cause
-which produces effects on our consciousness is impossible, the existence
-of a cause for these effects is a datum of consciousness. Though Being
-is cognizable by us only under limits of Time and Space, yet Being
-without limits of Time and Space was proved to be the indefinite
-cognition forming the necessary basis of our definite cognitions. We saw
-that the belief in an Omnipresent Power of which no commencement or
-cessation can be conceived, is that fundamental element in Religion
-which survives all its changes of form. We saw that all Philosophies
-avowedly or tacitly recognize this same ultimate truth:—that while the
-Relativist rightly repudiates those definite assertions which the
-Absolutist makes respecting real existence, he is yet at last compelled
-to unite with him in predicating real existence. And this inexpugnable
-consciousness in which Religion and Philosophy are at one with Common
-Sense, proved to be likewise that on which all exact Science is founded.
-We found that subjective Science can give no account of those
-conditioned modes of existence which constitute consciousness, without
-postulating unconditioned existence. And we found that objective Science
-can give no account of the existence which we know as external, without
-regarding its changes of form as manifestations of an existence that
-continues constant under all forms. Absolute Being, or Being which
-persists without beginning or end, was shown to be the common datum of
-all human thought; for the sufficient reason that the consciousness of
-it cannot be suppressed, without the suppression of consciousness
-itself.
-
-From this truth which transcends proof, we have seen that the general
-principles above set down, are deducible. That the power or force
-manifested to us in all phenomena, continues unaltered in quantity,
-however its mode of manifestation be altered, is a proposition in which
-these several propositions are involved. It was shown that on the
-Persistence of Force are based the demonstrations that Matter is
-indestructible and Motion continuous. When its proofs were examined, the
-correlation and equivalence of forces was found to follow from the
-Persistence of Force. The necessity we are under of conceiving Force
-under the two-fold form of attraction and repulsion, turns out to be but
-an implication of the necessity we are under of conceiving Force as
-persistent. On the Persistence of Force, we saw that the law of
-direction of Motion is dependent; and from it also we saw that the
-rhythm of Motion necessarily results. Passing to those changes of
-distribution which, by the Motion it generates, Force produces in
-Matter, it was pointed out that from the Persistence of Force are
-severally deducible, the instability of the homogeneous, the
-multiplication of effects, and that increasing definiteness of structure
-to which continuous differentiation and integration leads. And lastly we
-saw that Force being persistent, Evolution cannot cease until
-equilibrium is reached; and that equilibrium must eventually be reached.
-
-So that given Force manifested in Time and Space, under the forms of
-Matter and Motion; and it is demonstrable, _à priori_, that there must
-go on such transformations as we find going on.
-
- * * * * *
-
-§ 142. See then the accumulation of proofs. The advance of human
-intelligence in establishing laws continually wider in generality,
-raises the presumption that there are all-comprehensive laws. Turning to
-the facts, we discern a pervading uniformity in the general course of
-things where this can be watched, and indications of such uniformity
-where it cannot be watched. Considering this uniformity analytically, we
-find it to result from certain simpler uniformities in the actions of
-Force. And these uniformities prove to be so many necessary implications
-of that primordial truth which underlies all knowledge—the Persistence
-of Force. The aspect of things raises a presumption; extended
-observations lead to an induction that fulfils this presumption; this
-induction is deductively confirmed; and the laws whence it is deduced
-are corollaries from that datum without which thought is impossible.
-
-No higher degree of verification than this can be imagined. An induction
-based on facts so numerous and varied, and falling short of universality
-only where the facts are beyond observation, possesses of itself a
-validity greater than that of most scientific inductions. When it is
-shown that the proposition thus arrived at _à posteriori_, may also be
-arrived at _à priori_, starting from certain simple laws of force; it is
-raised to a level with those generalizations of concrete science which
-are accepted as proved. And when these simple laws of force are
-affiliated upon that ultimate truth which transcends proof; this
-dependent proposition takes rank with those propositions of abstract
-science which are our types of the greatest conceivable certainty.
-
-Let no one suppose that any such degree of certainty is alleged of the
-various minor propositions brought in illustration of the general
-argument. Such an assumption would be so manifestly absurd, that it
-seems scarcely needful to disclaim it. But the truth of the doctrine as
-a whole, is unaffected by errors in the details of its presentation. As
-the first principles of mathematics are not invalidated by mistakes made
-in working out particular equations; so the first principles set forth
-in the foregoing pages, do not stand or fall with each special statement
-made in them. If it can be shown that the Persistence of Force is not a
-datum of consciousness; or if it can be shown that the several laws of
-force above specified are not corollaries from it; then, indeed, it will
-be shown that the theory of Evolution has not the certainty here claimed
-for it. But nothing short of this can invalidate the general conclusions
-arrived at.
-
- * * * * *
-
-§ 143. If these conclusions be accepted—if it be admitted that they
-inevitably follow from the truth transcending all others in authority—if
-it be agreed that the phenomena going on everywhere are parts of the
-general process of Evolution, save where they are parts of the reverse
-process of Dissolution; then it must be inferred that all phenomena
-receive their complete interpretation, only when recognized as parts of
-these processes. Regarded from the point of view here reached, each
-change that takes place, is an incident in the course of the
-ever-complicating distribution of Matter and Motion, except where it is
-an incident in the course of the reverse distribution; and each such
-change is fully understood, only when brought under those universal
-principles of change, to which these transformations necessarily
-conform. Whence, indeed, it appears to be an unavoidable
-conclusion, that the limit towards which Science is advancing, must be
-reached when these formulæ are made all-comprehensive. Manifestly, the
-perfection of Science, is a state in which all phenomena are seen to be
-necessary implications of the Persistence of Force. In such a state, the
-dependence of each phenomenon on the Persistence of Force, must be
-proved either directly or indirectly—either by showing that it is a
-corollary of the Persistence of Force, or by showing that it is a
-corollary from some general proposition deduced from the Persistence of
-Force. And since all phenomena are incidents in the re-distributions of
-Matter and Motion; and since there are certain general principles,
-deducible from the Persistence of Force, to which all these
-re-distributions conform; it seems inferrable that ultimately all
-phenomena, where not classed as consequences of the Persistence of
-Force, must be classed as consequences of these derivative principles.
-
- * * * * *
-
-§ 144. Of course this development of Science into an organized aggregate
-of direct and indirect deductions from the Persistence of Force, can be
-achieved only in the remote future; and indeed cannot be completely
-achieved even then. Scientific progress, is progress in that
-equilibration of thought and things which we saw is going on, and must
-continue to go on; but which cannot arrive at perfection in any finite
-period, because it advances more slowly the further it advances. But
-though Science can never be entirely reduced to this form; and though
-only at a far distant time can it be brought nearly to this form; yet
-much may even now be done in the way of rude approximation. Those who
-are familiar with the present aspects of Science, must recognize in them
-the broken outlines of a general organization. The possibility of
-arranging the facts already accumulated, into the order rudely exhibited
-in the foregoing pages, will itself incline them to the belief that our
-knowledge may be put into a more connected shape than it at present has.
-They will see the probability that many now isolated inductions, may be
-reduced to the form of deductions from first principles. They will
-suspect that inferences drawn from the ultimate laws of force, will lead
-to the investigation and generalization of classes of facts hitherto
-unexamined. And they will feel, not only that a greater degree of
-certainty must be acquired by Science, as fast as its propositions are
-directly or indirectly deduced from the highest of all truths; but also
-that it must so be rendered a more efficient agent of further inquiry.
-
-To bring scientific knowledge to such degree of logical coherence as is
-at present possible, is a task to be achieved only by the combined
-efforts of many. No one man can possess that encyclopedic information
-required for rightly arranging even the truths already established. But
-as progress is effected by increments—as all organization, beginning in
-faint and blurred outlines, is completed by successive modifications and
-additions; advantage may accrue from an attempt, however rude, to reduce
-the facts already accumulated—or rather certain classes of them—to
-something like co-ordination. Such must be the plea for the several
-volumes which are to succeed this.
-
- * * * * *
-
-§ 145. A few closing words must be said, concerning the general bearings
-of the doctrines that are now to be further developed. Before proceeding
-to interpret the detailed phenomena of Life, and Mind, and Society, in
-terms of Matter, Motion, and Force, the reader must be reminded in what
-sense the interpretations are to be accepted. In spite of everything
-said at the outset, there are probably some who have gained the
-impression that those most general truths set forth in the preceding
-chapters, together with the truths deducible from them, claim to be
-something more than relative truths. And, notwithstanding all evidence
-to the contrary, there will probably have arisen in not a few minds, the
-conviction that the solutions which have been given, along with those to
-be derived from them, are essentially materialistic. Let none persist in
-these misconceptions.
-
-As repeatedly shown in various ways, the deepest truths we can reach,
-are simply statements of the widest uniformities in our experience of
-the relations of Matter, Motion, and Force; and Matter, Motion, and
-Force are but symbols of the Unknown Reality. That Power of which the
-nature remains for ever inconceivable, and to which no limits in Time or
-Space can be imagined, works in us certain effects. These effects have
-certain likenesses of kind, the most general of which we class together
-under the names of Matter, Motion, and Force; and between these effects
-there are likenesses of connection, the most constant of which we class
-as laws of the highest certainty. Analysis reduces these several kinds
-of effect to one kind of effect; and these several kinds of uniformity
-to one kind of uniformity. And the highest achievement of Science is the
-interpretation of all orders of phenomena, as differently-conditioned
-manifestations of this one kind of effect, under differently-conditioned
-modes of this one kind of uniformity. But when Science has done this, it
-has done nothing more than systematize our experience; and has in no
-degree extended the limits of our experience. We can say no more than
-before, whether the uniformities are as absolutely necessary, as they
-have become to our thought relatively necessary. The utmost possibility
-for us, is an interpretation of the process of things as it presents
-itself to our limited consciousness; but how this process is related to
-the actual process, we are unable to conceive, much less to know.
-
-Similarly, it must be remembered that while the connection between the
-phenomenal order and the ontological order is for ever inscrutable; so
-is the connection between the conditioned forms of being and the
-unconditioned form of being, for ever inscrutable. The interpretation of
-all phenomena in terms of Matter, Motion, and Force, is nothing more
-than the reduction of our complex symbols of thought, to the simplest
-symbols; and when the equation has been brought to its lowest terms the
-symbols remain symbols still. Hence the reasonings contained in the
-foregoing pages, afford no support to either of the antagonist
-hypotheses respecting the ultimate nature of things. Their implications
-are no more materialistic than they are spiritualistic; and no more
-spiritualistic than they are materialistic. Any argument which is
-apparently furnished to either hypothesis, is neutralized by as good an
-argument furnished to the other. The Materialist, seeing it to be a
-necessary deduction from the law of correlation, that what exists in
-consciousness under the form of feeling, is transformable into an
-equivalent of mechanical motion, and by consequence into equivalents of
-all the other forces which matter exhibits; may consider it therefore
-demonstrated that the phenomena of consciousness are material phenomena.
-But the Spiritualist, setting out with the same data, may argue with
-equal cogency, that if the forces displayed by matter are cognizable
-only under the shape of those equivalent amounts of consciousness which
-they produce, it is to be inferred that these forces, when existing out
-of consciousness, are of the same intrinsic nature as when existing in
-consciousness; and that so is justified the spiritualistic conception of
-the external world, as consisting of something essentially identical
-with what we call mind. Manifestly, the establishment of correlation and
-equivalence between the forces of the outer and the inner worlds, may be
-used to assimilate either to the other; according as we set out with one
-or other term. But he who rightly interprets the doctrine contained in
-this work, will see that neither of these terms can be taken as
-ultimate. He will see that though the relation of subject and object
-renders necessary to us these antithetical conceptions of Spirit and
-Matter; the one is no less than the other to be regarded as but a sign
-of the Unknown Reality which underlies both.
-
-
- THE END.
-
-
- JOHN CHILDS AND SON, PRINTERS.
-
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- TRANSCRIBER’S NOTES
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- 1. Changed “which takes place” to “which take place” on p. 315.
- 2. Duplicated the large spaces in the original text.
- 3. Silently corrected typographical errors.
- 4. Retained anachronistic and non-standard spellings as printed.
- 5. Enclosed italics font in _underscores_.
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-<pre>
-
-The Project Gutenberg EBook of First Principles, by Herbert Spencer
-
-This eBook is for the use of anyone anywhere in the United States and most
-other parts of the world at no cost and with almost no restrictions
-whatsoever. You may copy it, give it away or re-use it under the terms of
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-to check the laws of the country where you are located before using this ebook.
-
-Title: First Principles
-
-Author: Herbert Spencer
-
-Release Date: July 5, 2017 [EBook #55046]
-
-Language: English
-
-Character set encoding: UTF-8
-
-*** START OF THIS PROJECT GUTENBERG EBOOK FIRST PRINCIPLES ***
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-Proofreading Team at http://www.pgdp.net (This file was
-produced from images generously made available by The
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-
-
-<div class='tnotes covernote'>
-
-<p class='c000'><strong>Transcriber's Note:</strong></p>
-
-<p class='c000'>The cover image was created by the transcriber and is placed in the public domain.</p>
-
-</div>
-
-<div>
- <h1 class='c001'><span class='xlarge'>FIRST</span><br /> PRINCIPLES.</h1>
-</div>
-
-<div class='nf-center-c1'>
-<div class='nf-center c002'>
- <div><span class='xxsmall'>BY</span></div>
- <div class='c003'><span class='large'>HERBERT SPENCER,</span></div>
- <div class='c003'><span class='small'>AUTHOR OF “SOCIAL STATICS,” “THE PRINCIPLES OF PSYCHOLOGY,” “ESSAYS: SCIENTIFIC, POLITICAL, AND SPECULATIVE,” “EDUCATION,” ETC.</span></div>
- <div class='c002'><span class='small'>SECOND THOUSAND.</span></div>
- <div class='c002'>LONDON:</div>
- <div>WILLIAMS AND NORGATE, 14, HENRIETTA STREET,</div>
- <div><span class='small'>COVENT GARDEN.</span></div>
- <div>1863.</div>
- <div class='c003'><span class='xsmall'><em>The Right of Translation is reserved.</em></span></div>
- </div>
-</div>
-
-<div class='nf-center-c1'>
-<div class='nf-center c004'>
- <div>JOHN CHILDS AND SON, PRINTERS.</div>
- </div>
-</div>
-
-<div class='pbb'>
- <hr class='pb c003' />
-</div>
-
-<div class='chapter'>
- <span class='pageno' id='Page_v'>v</span>
- <h2 class='c005'>PREFACE.</h2>
-</div>
-
-<p class='c006'>This volume is the first of a series described in a prospectus
-originally distributed in March, 1860. Of that prospectus,
-the annexed is a reprint.</p>
-
-<h3 class='c007'><span class='large'>A SYSTEM OF PHILOSOPHY.</span></h3>
-
-<p class='c008'>Mr. Herbert Spencer proposes to issue in periodical parts a
-connected series of works which he has for several years been
-preparing. Some conception of the general aim and scope of
-this series may be gathered from the following Programme.</p>
-
-<h3 class='c007'><span class='large'>FIRST PRINCIPLES.</span></h3>
-
-<p class='c009'><span class='sc'>Part I. The Unknowable.</span>—Carrying a step further the doctrine
-put into shape by Hamilton and Mansel; pointing out the various directions
-in which Science leads to the same conclusions; and showing
-that in this united belief in an Absolute that transcends not only human
-knowledge but human conception, lies the only possible reconciliation
-of Science and Religion.</p>
-
-<p class='c010'><span class='sc'>Part II. Laws of the Knowable.</span>—A statement of the ultimate
-principles discernible throughout all manifestations of the Absolute—those
-highest generalizations now being disclosed by Science which are
-severally true not of one class of phenomena but of <em>all</em> classes of phenomena;
-and which are thus the keys to all classes of phenomena.<a id='r1' /><a href='#f1' class='c011'><sup>[1]</sup></a></p>
-
-<p class='c010'><span class='pageno' id='Page_vi'>vi</span>[<em>In logical order should here come the application of these First Principles
-to Inorganic Nature. But this great division it is proposed to pass
-over: partly because, even without it, the scheme is too extensive; and
-partly because the interpretation of Organic Nature after the proposed
-method, is of more immediate importance. The second work of the series
-will therefore be</em>—]</p>
-
-<h3 class='c007'><span class='large'>THE PRINCIPLES OF BIOLOGY.</span></h3>
-
-<h4 class='c012'><span class='sc'>Vol. I.</span></h4>
-
-<p class='c009'><span class='sc'>Part I. The Data of Biology.</span>—Including those general truths of
-Physics and Chemistry with which rational Biology must set out.</p>
-
-<p class='c010'><span class='sc'>II. The Inductions of Biology.</span>—A statement of the leading generalizations
-which Naturalists, Physiologists, and Comparative Anatomists,
-have established.</p>
-
-<p class='c010'><span class='sc'>III. The Evolution of Life.</span>—Concerning the speculation commonly
-known as “The Development Hypothesis”—its <i><span lang="fr" xml:lang="fr">à priori</span></i> and <i><span lang="fr" xml:lang="fr">à
-posteriori</span></i> evidences.</p>
-
-<h4 class='c012'><span class='sc'>Vol. II.</span></h4>
-
-<p class='c009'><span class='sc'>IV. Morphological Development.</span>—Pointing out the relations that
-are everywhere traceable between organic forms and the average of the
-various forces to which they are subject; and seeking in the cumulative
-effects of such forces a theory of the forms.</p>
-
-<p class='c010'><span class='sc'>V. Physiological Development.</span>—The progressive differentiation of
-functions similarly traced; and similarly interpreted as consequent upon
-the exposure of different parts of organisms to different sets of conditions.</p>
-
-<p class='c010'><span class='sc'>VI. The Laws of Multiplication.</span>—Generalizations respecting the
-rates of reproduction of the various classes of plants and animals; followed
-by an attempt to show the dependence of these variations upon
-certain necessary causes.<a id='r2' /><a href='#f2' class='c011'><sup>[2]</sup></a></p>
-
-<div>
- <span class='pageno' id='Page_vii'>vii</span>
- <h3 class='c007'><span class='large'>THE PRINCIPLES OF PSYCHOLOGY.</span></h3>
-</div>
-
-<h4 class='c012'><span class='sc'>Vol. I.</span></h4>
-
-<p class='c009'><span class='sc'>Part I. The Data of Psychology.</span>—Treating of the general connexions
-of Mind and Life and their relations to other modes of the
-Unknowable.</p>
-
-<p class='c010'><span class='sc'>II. The Inductions of Psychology.</span>—A digest of such generalizations
-respecting mental phenomena as have already been empirically
-established.</p>
-
-<p class='c010'><span class='sc'>III. General Synthesis.</span>—A republication, with additional chapters,
-of the same part in the already-published <cite>The Principles of Psychology</cite>.</p>
-
-<p class='c010'><span class='sc'>IV. Special Synthesis.</span>—A republication, with extensive revisions
-and additions, of the same part, &amp;c. &amp;c.</p>
-
-<p class='c010'><span class='sc'>V. Physical Synthesis.</span>—An attempt to show the manner in which
-the succession of states of consciousness conforms to a certain fundamental
-law of nervous action that follows from the First Principles laid
-down at the outset.</p>
-
-<h4 class='c012'><span class='sc'>Vol. II.</span></h4>
-
-<p class='c009'><span class='sc'>VI. Special Analysis.</span>—As at present published, but further elaborated
-by some additional chapters.</p>
-
-<p class='c010'><span class='sc'>VII. General Analysis.</span>—As at present published, with several
-explanations and additions.</p>
-
-<p class='c010'><span class='sc'>VIII. Corollaries.</span>—Consisting in part of a number of derivative
-principles which form a necessary introduction to Sociology.<a id='r3' /><a href='#f3' class='c011'><sup>[3]</sup></a></p>
-
-<h3 class='c007'><span class='large'>THE PRINCIPLES OF SOCIOLOGY.</span></h3>
-
-<h4 class='c012'><span class='sc'>Vol. I.</span></h4>
-
-<p class='c009'><span class='sc'>Part I. The Data of Sociology.</span>—A statement of the several sets
-of factors entering into social phenomena—human ideas and feelings
-considered in their necessary order of evolution; surrounding natural
-conditions; and those ever complicating conditions to which Society
-itself gives origin.</p>
-
-<p class='c010'><span class='sc'>II. The Inductions of Sociology.</span>—General facts, structural and
-functional, as gathered from a survey of Societies and their changes: in
-<span class='pageno' id='Page_viii'>viii</span>other words, the empirical generalizations that are arrived at by comparing
-different societies, and successive phases of the same society.</p>
-
-<p class='c010'><span class='sc'>III. Political Organization.</span>—The evolution of governments, general
-and local, as determined by natural causes; their several types and
-metamorphoses; their increasing complexity and specialization; and the
-progressive limitation of their functions.</p>
-
-<h4 class='c012'><span class='sc'>Vol. II.</span></h4>
-
-<p class='c009'><span class='sc'>IV. Ecclesiastical Organization.</span>—Tracing the differentiation of
-religious government from secular; its successive complications and the
-multiplication of sects; the growth and continued modification of religious
-ideas, as caused by advancing knowledge and changing moral
-character; and the gradual reconciliation of these ideas with the truths
-of abstract science.</p>
-
-<p class='c010'><span class='sc'>V. Ceremonial Organization.</span>—The natural history of that third
-kind of government which, having a common root with the others, and
-slowly becoming separate from and supplementary to them, serves to
-regulate the minor actions of life.</p>
-
-<p class='c010'><span class='sc'>VI. Industrial Organization.</span>—The development of productive and
-distributive agencies, considered, like the foregoing, in its necessary
-causes: comprehending not only the progressive division of labour, and
-the increasing complexity of each industrial agency, but also the successive
-forms of industrial government as passing through like phases
-with political government.</p>
-
-<h4 class='c012'><span class='sc'>Vol. III.</span></h4>
-
-<p class='c009'><span class='sc'>VII. Lingual Progress.</span>—The evolution of Languages regarded as
-a psychological process determined by social conditions.</p>
-
-<p class='c010'><span class='sc'>VIII. Intellectual Progress.</span>—Treated from the same point of
-view: including the growth of classifications; the evolution of science
-out of common knowledge; the advance from qualitative to quantitative
-prevision, from the indefinite to the definite, and from the concrete to
-the abstract.</p>
-
-<p class='c010'><span class='sc'>IX. Æsthetic Progress.</span>—The Fine Arts similarly dealt with:
-tracing their gradual differentiation from primitive institutions and from
-each other; their increasing varieties of development; and their advance
-in reality of expression and superiority of aim.</p>
-
-<p class='c010'><span class='sc'>X. Moral Progress.</span>—Exhibiting the genesis of the slow emotional
-modifications which human nature undergoes in its adaptation to the
-social state.</p>
-
-<p class='c010'><span class='pageno' id='Page_ix'>ix</span><span class='sc'>XI. The Consensus.</span>—Treating of the necessary interdependence of
-structures and of functions in each type of society, and in the successive
-phases of social development.<a id='r4' /><a href='#f4' class='c011'><sup>[4]</sup></a></p>
-
-<h3 class='c007'><span class='large'>THE PRINCIPLES OF MORALITY.</span></h3>
-
-<h4 class='c012'><span class='sc'>Vol. I.</span></h4>
-
-<p class='c009'><span class='sc'>Part I. The Data of Morality.</span>—Generalizations furnished by
-Biology, Psychology and Sociology, which underlie a true theory of
-right living: in other words, the elements of that equilibrium between
-constitution and conditions of existence, which is at once the moral
-ideal and the limit towards which we are progressing.</p>
-
-<p class='c010'><span class='sc'>II. The Inductions of Morality.</span>—Those empirically-established
-rules of human action which are registered as essential laws by all
-civilized nations: that is to say—the generalizations of expediency.</p>
-
-<p class='c010'><span class='sc'>III. Personal Morals.</span>—The principles of private conduct—physical,
-intellectual, moral and religious—that follow from the conditions to
-complete individual life: or, what is the same thing—those modes of
-private action which must result from the eventual equilibration of internal
-desires and external needs.</p>
-
-<h4 class='c012'><span class='sc'>Vol. II.</span></h4>
-
-<p class='c009'><span class='sc'>IV. Justice.</span>—The mutual limitations of men’s actions necessitated
-by their co-existence as units of a society—limitations, the perfect
-observance of which constitutes that state of equilibrium forming the
-goal of political progress.</p>
-
-<p class='c010'><span class='sc'>V. Negative Beneficence.</span>—Those secondary limitations, similarly
-necessitated, which, though less important and not cognizable by law,
-are yet requisite to prevent mutual destruction of happiness in various
-indirect ways: in other words—those minor self-restraints dictated by
-what may be called passive sympathy.</p>
-
-<p class='c010'><span class='pageno' id='Page_x'>x</span><span class='sc'>VI. Positive Beneficence.</span>—Comprehending all modes of conduct,
-dictated by active sympathy, which imply pleasure in giving pleasure—modes
-of conduct that social adaptation has induced and must render
-ever more general; and which, in becoming universal, must fill to the
-full the possible measure of human happiness.<a id='r5' /><a href='#f5' class='c011'><sup>[5]</sup></a></p>
-
-<p class='c010'>In anticipation of the obvious criticism that the scheme here
-sketched out is too extensive, it may be remarked that an exhaustive
-treatment of each topic is not intended; but simply the
-establishment of <em>principles</em>, with such illustrations as are needed
-to make their bearings fully understood. It may also be pointed
-out that, besides minor fragments, one large division (<cite>The Principles
-of Psychology</cite>) is already, in great part, executed. And a
-further reply is, that impossible though it may prove to execute
-the whole, yet nothing can be said against an attempt to set forth
-the First Principles and to carry their applications as far as circumstances
-permit.</p>
-
-<p class='c010'>The price per Number to be half-a-crown; that is to say, the
-four Numbers yearly issued to be severally delivered, post free,
-to all annual subscribers of Ten Shillings.</p>
-
-<hr class='c013' />
-
-<p class='c000'>This Programme I have thought well to reprint for two
-reasons:—the one being that readers may, from time to
-time, be able to ascertain what topics are next to be dealt
-with; the other being that an outline of the scheme may
-remain, in case it should never be completed.</p>
-
-<p class='c000'>The successive instalments of which this volume consists,
-were issued to the subscribers at the following dates:—Part
-I. (pp. 1–80) in October, 1860; Part II. (pp. 81–176) in
-January, 1861; Part III. (pp. 177–256) in April, 1861;
-Part IV. (pp. 257–334) in October, 1861; Part V. (pp.
-335–416) in March, 1862; and Part VI. (pp. 417–504)
-in June, 1862.</p>
-
-<p class='c014'><span class='small'><em>London, June 5th, 1862</em></span></p>
-
-<hr class='c015' />
-
-<div class='footnote' id='f1'>
-<p class='c000'><span class='label'><a href='#r1'>1</a>.&nbsp;&nbsp;</span>One of these generalizations is that currently known as “the Conservation of
-Force;” a second may be gathered from a published essay on “Progress: its Law
-and Cause;” a third is indicated in a paper on “Transcendental Physiology;”
-and there are several others.</p>
-</div>
-
-<div class='footnote' id='f2'>
-<p class='c000'><span class='label'><a href='#r2'>2</a>.&nbsp;&nbsp;</span>The ideas to be developed in the second volume of the <cite>Principles of Biology</cite>
-the writer has already briefly expressed in sundry Review-Articles. Part IV.
-will work out a doctrine suggested in a paper on “The Laws of Organic Form,”
-published in the <cite>Medico-Chirurgical Review</cite> for January, 1859. The germ of Part
-V. is contained in the essay on “Transcendental Physiology:” See <em>Essays</em>, pp.
-280–90. And in Part VI. will be unfolded certain views crudely expressed in a
-“Theory of Population,” published in the <cite>Westminster Review</cite> for April, 1852.</p>
-</div>
-
-<div class='footnote' id='f3'>
-<p class='c000'><span class='label'><a href='#r3'>3</a>.&nbsp;&nbsp;</span>Respecting the several additions to be made to the <cite>Principles of Psychology</cite>,
-it seems needful only to say that Part V. is the unwritten division named in the
-preface to that work—a division of which the germ is contained in a note on page
-544, and of which the scope has since been more definitely stated in a paper in
-the <cite>Medico-Chirurgical Review</cite> for Jan. 1859.</p>
-</div>
-
-<div class='footnote' id='f4'>
-<p class='c000'><span class='label'><a href='#r4'>4</a>.&nbsp;&nbsp;</span>Of this treatise on Sociology a few small fragments may be found in already-published
-essays. Some of the ideas to be developed in Part II. are indicated in
-an article on “The Social Organism,” contained in the last number of the <cite>Westminster
-Review</cite>; those which Part V. will work out, may be gathered from the
-first half of a paper written some years since on “Manners and Fashion;” of Part
-VIII. the germs are contained in an article on the “Genesis of Science;” two
-papers on “The Origin and Function of Music” and “The Philosophy of Style,”
-contain some ideas to be embodied in Part IX.; and from a criticism of Mr. Bain’s
-work on “The Emotions and the Will,” in the last number of the <cite>Medico-Chirurgical
-Review</cite>, the central idea to be developed in Part X. may be inferred.</p>
-</div>
-
-<div class='footnote' id='f5'>
-<p class='c000'><span class='label'><a href='#r5'>5</a>.&nbsp;&nbsp;</span>Part IV. of the <cite>Principles of Morality</cite> will be co-extensive (though not identical)
-with the first half of the writer’s <cite>Social Statics</cite>.</p>
-</div>
-
-<div class='chapter'>
- <span class='pageno' id='Page_xi'>xi</span>
- <h2 class='c005'>CONTENTS.</h2>
-</div>
-
-<table class='table0' summary='CONTENTS'>
- <tr><th class='c016' colspan='3'>PART I.—THE UNKNOWABLE.</th></tr>
- <tr><td>&nbsp;</td></tr>
- <tr>
- <th class='c017'>CHAP.</th>
- <th class='c018'>&nbsp;</th>
- <th class='c019'>PAGE</th>
- </tr>
- <tr><td>&nbsp;</td></tr>
- <tr>
- <td class='c020'>I.—</td>
- <td class='c018'>RELIGION AND SCIENCE</td>
- <td class='c021'><a href='#Page_3'>3</a></td>
- </tr>
- <tr><td>&nbsp;</td></tr>
- <tr>
- <td class='c020'>II.—</td>
- <td class='c018'>ULTIMATE RELIGIOUS IDEAS</td>
- <td class='c021'><a href='#Page_25'>25</a></td>
- </tr>
- <tr><td>&nbsp;</td></tr>
- <tr>
- <td class='c020'>III.—</td>
- <td class='c018'>ULTIMATE SCIENTIFIC IDEAS</td>
- <td class='c021'><a href='#Page_47'>47</a></td>
- </tr>
- <tr><td>&nbsp;</td></tr>
- <tr>
- <td class='c020'>IV.—</td>
- <td class='c018'>THE RELATIVITY OF ALL KNOWLEDGE</td>
- <td class='c021'><a href='#Page_68'>68</a></td>
- </tr>
- <tr><td>&nbsp;</td></tr>
- <tr>
- <td class='c020'>V.—</td>
- <td class='c018'>THE RECONCILIATION</td>
- <td class='c021'><a href='#Page_98'>98</a></td>
- </tr>
- <tr><td>&nbsp;</td></tr>
- <tr><td>&nbsp;</td></tr>
- <tr><th class='c016' colspan='3'>PART II.—LAWS OF THE KNOWABLE.</th></tr>
- <tr><td>&nbsp;</td></tr>
- <tr>
- <td class='c020'>I.—</td>
- <td class='c018'>LAWS IN GENERAL</td>
- <td class='c021'><a href='#Page_127'>127</a></td>
- </tr>
- <tr><td>&nbsp;</td></tr>
- <tr>
- <td class='c020'>II.—</td>
- <td class='c018'>THE LAW OF EVOLUTION</td>
- <td class='c021'><a href='#Page_146'>146</a></td>
- </tr>
- <tr><td>&nbsp;</td></tr>
- <tr>
- <td class='c020'>III.—</td>
- <td class='c018'>THE LAW OF EVOLUTION (CONTINUED)</td>
- <td class='c021'><a href='#Page_175'>175</a></td>
- </tr>
- <tr><td>&nbsp;</td></tr>
- <tr>
- <td class='c020'>IV.—</td>
- <td class='c018'>THE CAUSES OF EVOLUTION</td>
- <td class='c021'><a href='#Page_219'>219</a></td>
- </tr>
- <tr><td>&nbsp;</td></tr>
- <tr>
- <td class='c020'>V.—</td>
- <td class='c018'>SPACE, TIME, MATTER, MOTION, AND FORCE</td>
- <td class='c021'><a href='#Page_224'>224</a></td>
- </tr>
- <tr><td>&nbsp;</td></tr>
- <tr>
- <td class='c020'>VI.—</td>
- <td class='c018'>THE INDESTRUCTIBILITY OF MATTER</td>
- <td class='c021'><a href='#Page_238'>238</a></td>
- </tr>
- <tr><td>&nbsp;</td></tr>
- <tr>
- <td class='c020'>VII.—</td>
- <td class='c018'>THE CONTINUITY OF MOTION</td>
- <td class='c021'><a href='#Page_246'>246</a></td>
- </tr>
- <tr><td>&nbsp;</td></tr>
- <tr>
- <td class='c020'>VIII.—</td>
- <td class='c018'>THE PERSISTENCE OF FORCE</td>
- <td class='c021'><a href='#Page_251'>251</a></td>
- </tr>
- <tr><td>&nbsp;</td></tr>
- <tr>
- <td class='c020'>IX.—</td>
- <td class='c018'>THE CORRELATION AND EQUIVALENCE OF FORCES</td>
- <td class='c021'><a href='#Page_259'>259</a></td>
- </tr>
- <tr><td>&nbsp;</td></tr>
- <tr>
- <td class='c020'><span class='pageno' id='Page_xii'>xii</span>X.—</td>
- <td class='c018'>THE DIRECTION OF MOTION</td>
- <td class='c021'><a href='#Page_286'>286</a></td>
- </tr>
- <tr><td>&nbsp;</td></tr>
- <tr>
- <td class='c020'>XI.—</td>
- <td class='c018'>THE RHYTHM OF MOTION</td>
- <td class='c021'><a href='#Page_313'>313</a></td>
- </tr>
- <tr><td>&nbsp;</td></tr>
- <tr>
- <td class='c020'>XII.—</td>
- <td class='c018'>THE CONDITIONS ESSENTIAL TO EVOLUTION</td>
- <td class='c021'><a href='#Page_335'>335</a></td>
- </tr>
- <tr><td>&nbsp;</td></tr>
- <tr>
- <td class='c020'>XIII.—</td>
- <td class='c018'>THE INSTABILITY OF THE HOMOGENEOUS</td>
- <td class='c021'><a href='#Page_358'>358</a></td>
- </tr>
- <tr><td>&nbsp;</td></tr>
- <tr>
- <td class='c020'>XIV.—</td>
- <td class='c018'>THE MULTIPLICATION OF EFFECTS</td>
- <td class='c021'><a href='#Page_388'>388</a></td>
- </tr>
- <tr><td>&nbsp;</td></tr>
- <tr>
- <td class='c020'>XV.—</td>
- <td class='c018'>DIFFERENTIATION AND INTEGRATION</td>
- <td class='c021'><a href='#Page_416'>416</a></td>
- </tr>
- <tr><td>&nbsp;</td></tr>
- <tr>
- <td class='c020'>VI.—</td>
- <td class='c018'>EQUILIBRATION</td>
- <td class='c021'><a href='#Page_440'>440</a></td>
- </tr>
- <tr><td>&nbsp;</td></tr>
- <tr>
- <td class='c020'>XVII.—</td>
- <td class='c018'>SUMMARY AND CONCLUSION</td>
- <td class='c021'><a href='#Page_487'>487</a></td>
- </tr>
-</table>
-
-<div class='chapter'>
- <span class='pageno' id='Page_1'>1</span>
- <h2 class='c005'>PART I.<br /> <br /> <span class='large'>THE UNKNOWABLE.</span></h2>
-</div>
-
-<div>
- <span class='pageno' id='Page_3'>3</span>
- <h3 class='c001'>CHAPTER I.<br /> <span class='large'>RELIGION AND SCIENCE.</span></h3>
-</div>
-
-<p class='c006'>§ 1. We too often forget that not only is there “a soul of
-goodness in things evil,” but very generally also, a soul of
-truth in things erroneous. While many admit the abstract
-probability that a falsity has usually a nucleus of reality, few
-bear this abstract probability in mind, when passing judgment
-on the opinions of others. A belief that is finally
-proved to be grossly at variance with fact, is cast aside with
-indignation or contempt; and in the heat of antagonism
-scarcely any one inquires what there was in this belief which
-commended it to men’s minds. Yet there must have been
-something. And there is reason to suspect that this something
-was its correspondence with certain of their experiences:
-an extremely limited or vague correspondence perhaps; but
-still, a correspondence. Even the absurdest report may in
-nearly every instance be traced to an actual occurrence; and
-had there been no such actual occurrence, this preposterous
-misrepresentation of it would never have existed. Though
-the distorted or magnified image transmitted to us through
-the refracting medium of rumour, is utterly unlike the reality;
-yet in the absence of the reality there would have been no
-distorted or magnified image. And thus it is with human
-beliefs in general. Entirely wrong as they may appear, the
-implication is that they germinated out of actual experiences—originally
-contained, and perhaps still contain, some small
-amount of verity.</p>
-
-<p class='c000'><span class='pageno' id='Page_4'>4</span>More especially may we safely assume this, in the case of
-beliefs that have long existed and are widely diffused; and
-most of all so, in the case of beliefs that are perennial and
-nearly or quite universal. The presumption that any current
-opinion is not wholly false, gains in strength according to the
-number of its adherents. Admitting, as we must, that life is
-impossible unless through a certain agreement between internal
-convictions and external circumstances; admitting
-therefore that the probabilities are always in favour of the
-truth, or at least the partial truth, of a conviction; we must
-admit that the convictions entertained by many minds in
-common are the most likely to have some foundation. The
-elimination of individual errors of thought, must give to
-the resulting judgment a certain additional value. It
-may indeed be urged that many widely-spread beliefs
-are received on authority; that those entertaining them
-make no attempts at verification; and hence it may be inferred
-that the multitude of adherents adds but little to the
-probability of a belief. But this is not true. For a belief
-which gains extensive reception without critical examination,
-is thereby proved to have a general congruity with the various
-other beliefs of those who receive it; and in so far as these
-various other beliefs are based upon personal observation and
-judgment, they give an indirect warrant to one with which
-they harmonize. It may be that this warrant is of small
-value; but still it is of some value.</p>
-
-<p class='c000'>Could we reach definite views on this matter, they would
-be extremely useful to us. It is important that we should, if
-possible, form something like a general theory of current
-opinions; so that we may neither over-estimate nor under-estimate
-their worth. Arriving at correct judgments on disputed
-questions, much depends on the attitude of mind we
-preserve while listening to, or taking part in, the controversy;
-and for the preservation of a right attitude, it is needful that
-we should learn how true, and yet how untrue, are average
-human beliefs. On the one hand, we must keep free from
-<span class='pageno' id='Page_5'>5</span>that bias in favour of received ideas which expresses itself in
-such dogmas as “What every one says must be true,” or
-“The voice of the people is the voice of God.” On the other
-hand, the fact disclosed by a survey of the past, that majorities
-have usually been wrong, must not blind us to the complementary
-fact, that majorities have usually not been <em>entirely</em>
-wrong. And the avoidance of these extremes being a prerequisite
-to catholic thinking, we shall do well to provide
-ourselves with a safe-guard against them, by making a valuation
-of opinions in the abstract. To this end we must contemplate
-the kind of relation that ordinarily subsists between
-opinions and facts. Let us do so with one of those beliefs
-which under various forms has prevailed among all nations in
-all times.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 2. The earliest traditions represent rulers as gods or
-demigods. By their subjects, primitive kings were regarded
-as superhuman in origin, and superhuman in power. They
-possessed divine titles; received obeisances like those made
-before the altars of deities; and were in some cases actually
-worshipped. If there needs proof that the divine and half-divine
-characters originally ascribed to monarchs were
-ascribed literally, we have it in the fact that there are still
-existing savage races, among whom it is held that the chiefs
-and their kindred are of celestial origin, or, as elsewhere, that
-only the chiefs have souls. And of course along with beliefs
-of this kind, there existed a belief in the unlimited power of
-the ruler over his subjects—an absolute possession of them,
-extending even to the taking of their lives at will: as even
-still in Fiji, where a victim stands unbound to be killed at the
-word of his chief; himself declaring, “whatever the king says
-must be done.”</p>
-
-<p class='c000'>In times and among races somewhat less barbarous, we find
-these beliefs a little modified. The monarch, instead of being
-literally thought god or demigod, is conceived to be a man
-having divine authority, with perhaps more or less of divine
-<span class='pageno' id='Page_6'>6</span>nature. He retains however, as in the East to the present
-day, titles expressing his heavenly descent or relationships;
-and is still saluted in forms and words as humble as those addressed
-to the Deity. While the lives and properties of his
-people, if not practically so completely at his mercy, are still
-in theory supposed to be his.</p>
-
-<p class='c000'>Later in the progress of civilization, as during the middle
-ages in Europe, the current opinions respecting the relationship
-of rulers and ruled are further changed. For the theory
-of divine origin, there is substituted that of divine right. No
-longer god or demigod, or even god-descended, the king is
-now regarded as simply God’s vice-gerent. The obeisances
-made to him are not so extreme in their humility; and his
-sacred titles lose much of their meaning. Moreover his
-authority ceases to be unlimited. Subjects deny his right to
-dispose at will of their lives and properties; and yield allegiance
-only in the shape of obedience to his commands.</p>
-
-<p class='c000'>With advancing political opinion has come still greater
-restriction of imperial power. Belief in the supernatural
-character of the ruler, long ago repudiated by ourselves for
-example, has left behind it nothing more than the popular
-tendency to ascribe unusual goodness, wisdom, and beauty to
-the monarch. Loyalty, which originally meant implicit submission
-to the king’s will, now means a merely nominal profession
-of subordination, and the fulfilment of certain forms of
-respect. Our political practice, and our political theory, alike
-utterly reject those regal prerogatives which once passed unquestioned.
-By deposing some, and putting others in their
-places, we have not only denied the divine rights of certain
-men to rule; but we have denied that they have any rights
-beyond those originating in the assent of the nation. Though
-our forms of speech and our state-documents still assert the
-subjection of the citizens to the ruler, our actual beliefs and
-our daily proceedings implicitly assert the contrary. We
-obey no laws save those of our own making. We have entirely
-divested the monarch of legislative power; and should immediately
-<span class='pageno' id='Page_7'>7</span>rebel against his or her exercise of such power,
-even in matters of the smallest concern. In brief, the aboriginal
-doctrine is all but extinct among us.</p>
-
-<p class='c000'>Nor has the rejection of primitive political beliefs, resulted
-only in transferring the authority of an autocrat to a representative
-body. The views entertained respecting governments
-in general, of whatever form, are now widely different
-from those once entertained. Whether popular or despotic,
-governments were in ancient times supposed to have unlimited
-authority over their subjects. Individuals existed for the
-benefit of the State; not the State for the benefit of individuals.
-In our days, however, not only has the national will
-been in many cases substituted for the will of the king; but
-the exercise of this national will has been restricted to a much
-smaller sphere. In England, for instance, though there has
-been established no definite theory setting bounds to governmental
-authority; yet, in practice, sundry bounds have been
-set to it which are tacitly recognized by all. There is no
-organic law formally declaring that the legislature may not
-freely dispose of the citizens’ lives, as early kings did when
-they sacrificed hecatombs of victims; but were it possible for
-our legislature to attempt such a thing, its own destruction
-would be the consequence, rather than the destruction of
-citizens. How entirely we have established the personal
-liberties of the subject against the invasions of State-power,
-would be quickly demonstrated, were it proposed by Act of
-Parliament forcibly to take possession of the nation, or of any
-class, and turn its services to public ends; as the services of
-the people were turned by primitive rulers. And should any
-statesman suggest a re-distribution of property such as was
-sometimes made in ancient democratic communities, he would
-be met by a thousand-tongued denial of imperial power over
-individual possessions. Not only in our day have these fundamental
-claims of the citizen been thus made good against the
-State, but sundry minor claims likewise. Ages ago, laws
-regulating dress and mode of living fell into disuse; and
-<span class='pageno' id='Page_8'>8</span>any attempt to revive them would prove the current opinion
-to be, that such matters lie beyond the sphere of legal control.
-For some centuries we have been asserting in practice, and
-have now established in theory, the right of every man to
-choose his own religious beliefs, instead of receiving such
-beliefs on State-authority. Within the last few generations
-we have inaugurated complete liberty of speech, in spite of all
-legislative attempts to suppress or limit it. And still more
-recently we have claimed and finally obtained under a few
-exceptional restrictions, freedom to trade with whomsoever we
-please. Thus our political beliefs are widely different from
-ancient ones, not only as to the proper depositary of power to
-be exercised over a nation, but also as to the extent of that
-power.</p>
-
-<p class='c000'>Not even here has the change ended. Besides the average
-opinions which we have just described as current among
-ourselves, there exists a less widely-diffused opinion going
-still further in the same direction. There are to be found
-men who contend that the sphere of government should be
-narrowed even more than it is in England. The modern
-doctrine that the State exists for the benefit of citizens, which
-has now in a great measure supplanted the ancient doctrine
-that the citizens exist for the benefit of the State, they would
-push to its logical results. They hold that the freedom of the
-individual, limited only by the like freedom of other individuals,
-is sacred; and that the legislature cannot equitably put
-further restrictions upon it, either by forbidding any actions
-which the law of equal freedom permits, or taking away any
-property save that required to pay the cost of enforcing this
-law itself. They assert that the sole function of the State is
-the protection of persons against each other, and against a
-foreign foe. They urge that as, throughout civilization, the
-manifest tendency has been continually to extend the liberties
-of the subject, and restrict the functions of the State, there is
-reason to believe that the ultimate political condition must be
-one in which personal freedom is the greatest possible and
-<span class='pageno' id='Page_9'>9</span>governmental power the least possible: that, namely, in which
-the freedom of each has no limit but the like freedom of all;
-while the sole governmental duty is the maintenance of this
-limit.</p>
-
-<p class='c000'>Here then in different times and places we find concerning
-the origin, authority, and functions of government, a great
-variety of opinions—opinions of which the leading genera
-above indicated subdivide into countless species. What now
-must be said about the truth or falsity of these opinions?
-Save among a few barbarous tribes the notion that a monarch
-is a god or demigod is regarded throughout the world as an
-absurdity almost passing the bounds of human credulity.
-In but few places does there survive a vague notion that the
-ruler possesses any supernatural attributes. Most civilized
-communities, which still admit the divine right of governments,
-have long since repudiated the divine right of kings.
-Elsewhere the belief that there is anything sacred in legislative
-regulations is dying out: laws are coming to be considered
-as conventional only. While the extreme school
-holds that governments have neither intrinsic authority,
-nor can have authority given to them by convention;
-but can possess authority only as the administrators of those
-moral principles deducible from the conditions essential to
-social life. Of these various beliefs, with their innumerable
-modifications, must we then say that some one alone is
-wholly right and all the rest wholly wrong; or must we say
-that each of them contains truth more or less completely
-disguised by errors? The latter alternative is the one which
-analysis will force upon us. Ridiculous as they may severally
-appear to those not educated under them, every one of these
-doctrines has for its vital element the recognition of an
-unquestionable fact. Directly or by implication, each of
-them insists on a certain subordination of individual actions
-to social requirements. There are wide differences as to the
-power to which this subordination is due; there are wide
-differences as to the motive for this subordination; there are
-<span class='pageno' id='Page_10'>10</span>wide differences as to its extent; but that there must be <em>some</em>
-subordination all are agreed. From the oldest and rudest
-idea of allegiance, down to the most advanced political theory
-of our own day, there is on this point complete unanimity.
-Though, between the savage who conceives his life and
-property to be at the absolute disposal of his chief, and the
-anarchist who denies the right of any government, autocratic
-or democratic, to trench upon his individual freedom, there
-seems at first sight an entire and irreconcilable antagonism;
-yet ultimate analysis discloses in them this fundamental community
-of opinion; that there are limits which individual
-actions may not transgress—limits which the one regards as
-originating in the king’s will, and which the other regards as
-deducible from the equal claims of fellow-citizens.</p>
-
-<p class='c000'>It may perhaps at first sight seem that we here reach a
-very unimportant conclusion; namely, that a certain tacit
-assumption is equally implied in all these conflicting political
-creeds—an assumption which is indeed of self-evident
-validity. The question, however, is not the value or novelty
-of the particular truth in this case arrived at. My aim has
-been to exhibit the more general truth, which we are apt to
-overlook, that between the most opposite beliefs there is
-usually something in common,—something taken for granted
-by each; and that this something, if not to be set down
-as an unquestionable verity, may yet be considered to
-have the highest degree of probability. A postulate which,
-like the one above instanced, is not consciously asserted but
-unconsciously involved; and which is unconsciously involved
-not by one man or body of men, but by numerous bodies of
-men who diverge in countless ways and degrees in the rest of
-their beliefs; has a warrant far transcending any that can be
-usually shown. And when, as in this case, the postulate is
-abstract—is not based on some one concrete experience
-common to all mankind, but implies an induction from a
-great variety of experiences, we may say that it ranks next in
-certainty to the postulates of exact science.</p>
-
-<p class='c000'><span class='pageno' id='Page_11'>11</span>Do we not thus arrive at a generalization which may habitually
-guide us when seeking for the soul of truth in things
-erroneous? While the foregoing illustration brings clearly
-home the fact, that in opinions seeming to be absolutely and
-supremely wrong something right is yet to be found; it also
-indicates the method we should pursue in seeking the something
-right. This method is to compare all opinions of the
-same genus; to set aside as more or less discrediting one
-another those various special and concrete elements in which
-such opinions disagree; to observe what remains after the
-discordant constituents have been eliminated; and to find
-for this remaining constituent that abstract expression which
-holds true throughout its divergent modifications.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§3. A candid acceptance of this general principle and an
-adoption of the course it indicates, will greatly aid us in dealing
-with those chronic antagonisms by which men are
-divided. Applying it not only to current ideas with which
-we are personally unconcerned, but also to our own ideas and
-those of our opponents, we shall be led to form far more
-correct judgments. We shall be ever ready to suspect that
-the convictions we entertain are not wholly right, and that
-the adverse convictions are not wholly wrong. On the one
-hand we shall not, in common with the great mass of the
-unthinking, let our beliefs be determined by the mere accident
-of birth in a particular age on a particular part of the Earth’s
-surface; and, on the other hand, we shall be saved from that
-error of entire and contemptuous negation, which is fallen
-into by most who take up an attitude of independent criticism.</p>
-
-<p class='c000'>Of all antagonisms of belief, the oldest, the widest, the most
-profound and the most important, is that between Religion
-and Science. It commenced when the recognition of the
-simplest uniformities in surrounding things, set a limit to the
-previously universal fetishism. It shows itself everywhere
-throughout the domain of human knowledge: affecting men’s
-interpretations alike of the simplest mechanical accidents and
-<span class='pageno' id='Page_12'>12</span>of the most complicated events in the histories of nations.
-It has its roots deep down in the diverse habits of thought of
-different orders of minds. And the conflicting conceptions of
-nature and life which these diverse habits of thought severally
-generate, influence for good or ill the tone of feeling and the
-daily conduct.</p>
-
-<p class='c000'>An unceasing battle of opinion like this which has been
-carried on throughout all ages under the banners of Religion
-and Science, has of course generated an animosity fatal to a
-just estimate of either party by the other. On a larger scale,
-and more intensely than any other controversy, has it illustrated
-that perennially significant fable concerning the knights
-who fought about the colour of a shield of which neither
-looked at more than one face. Each combatant seeing clearly
-his own aspect of the question, has charged his opponent
-with stupidity or dishonesty in not seeing the same aspect of
-it; while each has wanted the candour to go over to his
-opponent’s side and find out how it was that he saw everything
-so differently.</p>
-
-<p class='c000'>Happily the times display an increasing catholicity of feeling,
-which we shall do well in carrying as far as our natures
-permit. In proportion as we love truth more and victory
-less, we shall become anxious to know what it is which leads
-our opponents to think as they do. We shall begin to suspect
-that the pertinacity of belief exhibited by them must result
-from a perception of something we have not perceived. And
-we shall aim to supplement the portion of truth we have
-found with the portion found by them. Making a more
-rational estimate of human authority, we shall avoid alike the
-extremes of undue submission and undue rebellion—shall not
-regard some men’s judgments as wholly good and others as
-wholly bad; but shall rather lean to the more defensible
-position that none are completely right and none are completely
-wrong.</p>
-
-<p class='c000'>Preserving, as far as may be, this impartial attitude, let us
-then contemplate the two sides of this great controversy.
-<span class='pageno' id='Page_13'>13</span>Keeping guard against the bias of education and shutting out
-the whisperings of sectarian feeling, let us consider what are
-the <i><span lang="fr" xml:lang="fr">à priori</span></i> probabilities in favour of each party.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§4. When duly realized, the general principle above
-illustrated must lead us to anticipate that the diverse forms
-of religious belief which have existed and which still exist,
-have all a basis in some ultimate fact. Judging by analogy
-the implication is, not that any one of them is altogether
-right; but that in each there is something right more or less
-disguised by other things wrong. It may be that the soul of
-truth contained in erroneous creeds is very unlike most, if not
-all, of its several embodiments; and indeed, if, as we have good
-reason to expect, it is much more abstract than any of them,
-its unlikeness necessarily follows. But however different
-from its concrete expressions, some essential verity must be
-looked for. To suppose that these multiform conceptions
-should be one and all <em>absolutely</em> groundless, discredits too
-profoundly that average human intelligence from which all
-our individual intelligences are inherited.</p>
-
-<p class='c000'>This most general reason we shall find enforced by other
-more special ones. To the presumption that a number of
-diverse beliefs of the same class have some common foundation
-in fact, must in this case be added a further presumption
-derived from the omnipresence of the beliefs. Religious ideas
-of one kind or other are almost if not quite universal. Even
-should it be true, as alleged, that there exist tribes of men
-who have nothing approaching to a theory of creation—even
-should it be true that only when a certain phase of intelligence
-is reached do the most rudimentary of such theories make their
-appearance; the implication is practically the same. Grant that
-among all races who have passed a certain stage of intellectual
-development there are found vague notions concerning the
-origin and hidden nature of surrounding things; and there
-arises the inference that such notions are necessary products
-of progressing intelligence. Their endless variety serves but
-<span class='pageno' id='Page_14'>14</span>to strengthen this conclusion: showing as it does a more or
-less independent genesis—showing how, in different places
-and times, like conditions have led to similar trains of
-thought, ending in analogous results. That these countless
-different, and yet allied, phenomena presented by all religions
-are accidental or factitious, is an untenable supposition. A
-candid examination of the evidence quite negatives the doctrine
-maintained by some, that creeds are priestly inventions.
-Even as a mere question of probabilities it cannot rationally
-be concluded that in every society, past and present, savage
-and civilized, certain members of the community have combined
-to delude the rest, in ways so analogous. To any who
-may allege that some primitive fiction was devised by some
-primitive priesthood, before yet mankind had diverged from
-a common centre, a reply is furnished by philology; for
-philology proves the dispersion of mankind to have commenced
-before there existed a language sufficiently organized
-to express religious ideas. Moreover, were it otherwise tenable,
-the hypothesis of artificial origin fails to account for the facts.
-It does not explain why, under all changes of form, certain
-elements of religious belief remain constant. It does not
-show us how it happens that while adverse criticism has from
-age to age gone on destroying particular theological dogmas,
-it has not destroyed the fundamental conception underlying
-these dogmas. It leaves us without any solution of the striking
-circumstance that when, from the absurdities and corruptions
-accumulated around them, national creeds have
-fallen into general discredit, ending in indifferentism or
-positive denial, there has always by and by arisen a re-assertion
-of them: if not the same in form, still the same in
-essence. Thus the universality of religious ideas, their independent
-evolution among different primitive races, and
-their great vitality, unite in showing that their source must
-be deep-seated instead of superficial. In other words, we
-are obliged to admit that if not supernaturally derived as
-<span class='pageno' id='Page_15'>15</span>the majority contend, they must be derived out of human
-experiences, slowly accumulated and organized.</p>
-
-<p class='c000'>Should it be asserted that religious ideas are products of
-the religious sentiment, which, to satisfy itself, prompts
-imaginations that it afterwards projects into the external
-world, and by and by mistakes for realities; the problem is
-not solved, but only removed further back. Whether the
-wish is father to the thought, or whether sentiment and idea
-have a common genesis, there equally arises the question—Whence
-comes the sentiment? That it is a constituent in
-man’s nature is implied by the hypothesis; and cannot indeed
-be denied by those who prefer other hypotheses. And
-if the religious sentiment, displayed habitually by the majority
-of mankind, and occasionally aroused even in those seemingly
-devoid of it, must be classed among human emotions, we
-cannot rationally ignore it. We are bound to ask its origin
-and its function. Here is an attribute which, to say the least,
-has had an enormous influence—which has played a conspicuous
-part throughout the entire past as far back as
-history records, and is at present the life of numerous institutions,
-the stimulus to perpetual controversies, and the
-prompter of countless daily actions. Any Theory of Things
-which takes no account of this attribute, must, then, be extremely
-defective. If with no other view, still as a question
-in philosophy, we are called on to say what this attribute
-means; and we cannot decline the task without confessing
-our philosophy to be incompetent.</p>
-
-<p class='c000'>Two suppositions only are open to us: the one that the
-feeling which responds to religious ideas resulted, along with
-all other human faculties, from an act of special creation; the
-other that it, in common with the rest, arose by a process of
-evolution. If we adopt the first of these alternatives, universally
-accepted by our ancestors and by the immense
-majority of our contemporaries, the matter is at once settled:
-man is directly endowed with the religious feeling by a
-<span class='pageno' id='Page_16'>16</span>creator; and to that creator it designedly responds. If we
-adopt the second alternative, then we are met by the questions—What
-are the circumstances to which the genesis of the religious
-feeling is due? and—What is its office? We are bound
-to entertain these questions; and we are bound to find
-answers to them. Considering all faculties, as we must on
-this supposition, to result from accumulated modifications
-caused by the intercourse of the organism with its environment,
-we are obliged to admit that there exist in the environment
-certain phenomena or conditions which have determined
-the growth of the feeling in question; and so are obliged to
-admit that it is as normal as any other faculty. Add to
-which that as, on the hypothesis of a development of lower
-forms into higher, the end towards which the progressive
-changes directly or indirectly tend, must be adaptation to
-the requirements of existence; we are also forced to infer
-that this feeling is in some way conducive to human welfare.
-Thus both alternatives contain the same ultimate implication.
-We must conclude that the religious sentiment is either directly
-created, or is created by the slow action of natural
-causes; and whichever of these conclusions we adopt, requires
-us to treat the religious sentiment with respect.</p>
-
-<p class='c000'>One other consideration should not be overlooked—a consideration
-which students of Science more especially need to
-have pointed out. Occupied as such are with established truths,
-and accustomed to regard things not already known as things
-to be hereafter discovered, they are liable to forget that information,
-however extensive it may become, can never satisfy
-inquiry. Positive knowledge does not, and never can, fill
-the whole region of possible thought. At the uttermost
-reach of discovery there arises, and must ever arise, the question—What
-lies beyond? As it is impossible to think of a
-limit to space so as to exclude the idea of space lying outside
-that limit; so we cannot conceive of any explanation profound
-enough to exclude the question—What is the explanation of
-that explanation? Regarding Science as a gradually increasing
-<span class='pageno' id='Page_17'>17</span>sphere, we may say that every addition to its surface
-does but bring it into wider contact with surrounding nescience.
-There must ever remain therefore two antithetical modes of
-mental action. Throughout all future time, as now, the
-human mind may occupy itself, not only with ascertained
-phenomena and their relations, but also with that unascertained
-something which phenomena and their relations
-imply. Hence if knowledge cannot monopolize
-consciousness—if it must always continue possible for the
-mind to dwell upon that which transcends knowledge; then
-there can never cease to be a place for something of the
-nature of Religion; since Religion under all its forms is distinguished
-from everything else in this, that its subject
-matter is that which passes the sphere of experience.</p>
-
-<p class='c000'>Thus, however untenable may be any or all the existing
-religious creeds, however gross the absurdities associated with
-them, however irrational the arguments set forth in their defence,
-we must not ignore the verity which in all likelihood
-lies hidden within them. The general probability that widely-spread
-beliefs are not absolutely baseless, is in this case enforced
-by a further probability due to the omnipresence of
-the beliefs. In the existence of a religious sentiment, whatever
-be its origin, we have a second evidence of great significance.
-And as in that nescience which must ever remain the
-antithesis to science, there is a sphere for the exercise of this
-sentiment, we find a third general fact of like implication.
-We may be sure therefore that religions, though even none
-of them be actually true, are yet all adumbrations of a truth.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 5. As, to the religious, it will seem absurd to set forth
-any justification for Religion; so, to the scientific, will it seem
-absurd to defend Science. Yet to do the last is certainly as
-needful as to do the first. If there exists a class who, in
-contempt of its follies and disgust at its corruptions, have
-contracted towards Religion a repugnance which makes them
-overlook the fundamental verity contained in it; so, too, is
-<span class='pageno' id='Page_18'>18</span>there a class offended to such a degree by the destructive
-criticisms men of science make on the religious tenets they
-regard as essential, that they have acquired a strong prejudice
-against Science in general. They are not prepared with any
-avowed reasons for their dislike. They have simply a remembrance
-of the rude shakes which Science has given to
-many of their cherished convictions, and a suspicion that it
-may perhaps eventually uproot all they regard as sacred; and
-hence it produces in them a certain inarticulate dread.</p>
-
-<p class='c000'>What is Science? To see the absurdity of the prejudice
-against it, we need only remark that Science is simply a
-higher development of common knowledge; and that if
-Science is repudiated, all knowledge must be repudiated
-along with it. The extremest bigot will not suspect any
-harm in the observation that the sun rises earlier and sets
-later in the summer than in the winter; but will rather
-consider such an observation as a useful aid in fulfilling the
-duties of life. Well, Astronomy is an organized body of
-similar observations, made with greater nicety, extended to a
-larger number of objects, and so analyzed as to disclose the
-real arrangements of the heavens, and to dispel our false conceptions
-of them. That iron will rust in water, that wood
-will burn, that long kept viands become putrid, the most
-timid sectarian will teach without alarm, as things useful to
-be known. But these are chemical truths: Chemistry is a
-systematized collection of such facts, ascertained with precision,
-and so classified and generalized as to enable us to say
-with certainty, concerning each simple or compound substance,
-what change will occur in it under given conditions. And
-thus is it with all the sciences. They severally germinate
-out of the experiences of daily life; insensibly as they grow
-they draw in remoter, more numerous, and more complex
-experiences; and among these, they ascertain laws of dependence
-like those which make up our knowledge of the
-most familiar objects. Nowhere is it possible to draw a line
-and say—here Science begins. And as it is the function of
-<span class='pageno' id='Page_19'>19</span>common observation to serve for the guidance of conduct; so,
-too, is the guidance of conduct the office of the most recondite
-and abstract inquiries of Science. Through the countless industrial
-processes and the various modes of locomotion which
-it has given to us, Physics regulates more completely our social
-life than does his acquaintance with the properties of surrounding
-bodies regulate the life of the savage. Anatomy
-and Physiology, through their effects on the practice of medicine
-and hygiene, modify our actions almost as much as does
-our acquaintance with the evils and benefits which common
-environing agencies may produce on our bodies. All Science
-is prevision; and all prevision ultimately aids us in greater or
-less degree to achieve the good and avoid the bad. As
-certainly as the perception of an object lying in our path
-warns us against stumbling over it; so certainly do those
-more complicated and subtle perceptions which constitute
-Science, warn us against stumbling over intervening obstacles
-in the pursuit of our distant ends. Thus being one in origin
-and function, the simplest forms of cognition and the most
-complex must be dealt with alike. We are bound in consistency
-to receive the widest knowledge which our faculties
-can reach, or to reject along with it that narrow knowledge
-possessed by all. There is no logical alternative between
-accepting our intelligence in its entirety, or repudiating even
-that lowest intelligence which we possess in common with
-brutes.</p>
-
-<p class='c000'>To ask the question which more immediately concerns our
-argument—whether Science is substantially true?—is much
-like asking whether the sun gives light. And it is because
-they are conscious how undeniably valid are most of its propositions,
-that the theological party regard Science with so much
-secret alarm. They know that during the two thousand
-years of its growth, some of its larger divisions—mathematics,
-physics, astronomy—have been subject to the rigorous
-criticism of successive generations; and have notwithstanding
-become ever more firmly established. They know
-<span class='pageno' id='Page_20'>20</span>that, unlike many of their own doctrines, which were once
-universally received but have age by age been more
-frequently called in question, the doctrines of Science, at first
-confined to a few scattered inquirers, have been slowly growing
-into general acceptance, and are now in great part admitted
-as beyond dispute. They know that men of science
-throughout the world subject each other’s results to the most
-searching examination; and that error is mercilessly exposed
-and rejected as soon as discovered. And, finally, they know
-that still more conclusive testimony is to be found in the
-daily verification of scientific predictions, and in the never-ceasing
-triumphs of those arts which Science guides.</p>
-
-<p class='c000'>To regard with alienation that which has such high
-credentials is a folly. Though in the tone which many of
-the scientific adopt towards them, the defenders of Religion
-may find some excuse for this alienation; yet the excuse is a
-very insufficient one. On the side of Science, as on their own
-side, they must admit that short-comings in the advocates do
-not tell essentially against that which is advocated. Science
-must be judged by itself: and so judged, only the most perverted
-intellect can fail to see that it is worthy of all reverence.
-Be there or be there not any other revelation, we have a
-veritable revelation in Science—a continuous disclosure,
-through the intelligence with which we are endowed, of the
-established order of the Universe. This disclosure it is the
-duty of every one to verify as far as in him lies; and having
-verified, to receive with all humility.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§6. On both sides of this great controversy, then, truth
-must exist. An unbiassed consideration of its general aspects
-forces us to conclude that Religion, everywhere present as a
-weft running through the warp of human history, expresses
-some eternal fact; while it is almost a truism to say of Science
-that it is an organised mass of facts, ever growing, and ever
-being more completely purified from errors. And if both
-have bases in the reality of things, then between them there
-<span class='pageno' id='Page_21'>21</span>must be a fundamental harmony. It is an incredible hypothesis
-that there are two orders of truth, in absolute and everlasting
-opposition. Only on some Manichean theory, which
-among ourselves no one dares openly avow however much his
-beliefs may be tainted by it, is such a supposition even conceivable.
-That Religion is divine and Science diabolical, is a
-proposition which, though implied in many a clerical declamation,
-not the most vehement fanatic can bring himself distinctly
-to assert. And whoever does not assert this, must
-admit that under their seeming antagonism lies hidden an
-entire agreement.</p>
-
-<p class='c000'>Each side, therefore, has to recognize the claims of the other
-as standing for truths that are not to be ignored. He who
-contemplates the Universe from the religious point of view,
-must learn to see that this which we call Science is one constituent
-of the great whole; and as such ought to be regarded
-with a sentiment like that which the remainder excites.
-While he who contemplates the universe from the scientific
-point of view, must learn to see that this which we call Religion
-is similarly a constituent of the great whole; and being
-such, must be treated as a subject of science with no more
-prejudice than any other reality. It behoves each party to
-strive to understand the other, with the conviction that the
-other has something worthy to be understood; and with the
-conviction that when mutually recognized this something
-will be the basis of a complete reconciliation.</p>
-
-<p class='c000'>How to find this something—how to reconcile them, thus
-becomes the problem which we should perseveringly try to
-solve. Not to reconcile them in any makeshift way—not to
-find one of those compromises we hear from time to time
-proposed, which their proposers must secretly feel are artificial
-and temporary; but to arrive at the terms of a real and
-permanent peace between them. The thing we have to seek
-out, is that ultimate truth which both will avow with absolute
-sincerity—with not the remotest mental reservation.
-There shall be no concession—no yielding on either side of
-<span class='pageno' id='Page_22'>22</span>something that will by and by be reasserted; but the common
-ground on which they meet shall be one which each will
-maintain for itself. We have to discover some fundamental
-verity which Religion will assert, with all possible emphasis,
-in the absence of Science; and which Science, with all possible
-emphasis, will assert in the absence of Religion—some fundamental
-verity in the defence of which each will find the
-other its ally.</p>
-
-<p class='c000'>Or, changing the point of view, our aim must be to co-ordinate
-the seemingly opposed convictions which Religion
-and Science embody. From the coalescence of antagonist
-ideas, each containing its portion of truth, there always arises
-a higher development. As in Geology when the igneous and
-aqueous hypotheses were united, a rapid advance took place;
-as in Biology we are beginning to progress through the
-fusion of the doctrine of types with the doctrine of adaptations;
-as in Psychology the arrested growth recommences
-now that the disciples of Kant and those of Locke have both
-their views recognized in the theory that organized experiences
-produce forms of thought; as in Sociology, now that
-it is beginning to assume a positive character, we find a recognition
-of both the party of progress and the party of order, as
-each holding a truth which forms a needful complement to
-that held by the other; so must it be on a grander scale with
-Religion and Science. Here too we must look for a conception
-which combines the conclusions of both; and here too we may
-expect important results from their combination. To understand
-how Science and Religion express opposite sides of
-the same fact—the one its near or visible side, and the other
-its remote or invisible side—this it is which we must attempt;
-and to achieve this must profoundly modify our general
-Theory of Things.</p>
-
-<p class='c000'>Already in the foregoing pages the method of seeking such
-a reconciliation has been vaguely foreshadowed. Before proceeding
-further, however, it will be well to treat the question
-of method more definitely. To find that truth in which
-<span class='pageno' id='Page_23'>23</span>Religion and Science coalesce, we must know in what direction
-to look for it, and what kind of truth it is likely
-to be.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 7. We have found <i><span lang="fr" xml:lang="fr">à priori</span></i> reason for believing that in
-all religions, even the rudest, there lies hidden a fundamental
-verity. We have inferred that this fundamental verity is
-that element common to all religions, which remains after
-their discordant peculiarities have been mutually cancelled.
-And we have further inferred that this element is almost
-certain to be more abstract than any current religious
-doctrine. Now it is manifest that only in some highly
-abstract proposition, can Religion and Science find a common
-ground. Neither such dogmas as those of the trinitarian and
-unitarian, nor any such idea as that of propitiation, common
-though it may be to all religions, can serve as the desired
-basis of agreement; for Science cannot recognize beliefs like
-these: they lie beyond its sphere. Hence we see not only
-that, judging by analogy, the essential truth contained in
-Religion is that most abstract element pervading all its forms;
-but also that this most abstract element is the only one in
-which Religion is likely to agree with Science.</p>
-
-<p class='c000'>Similarly if we begin at the other end, and inquire what
-scientific truth can unite Science and Religion. It is at once
-manifest that Religion can take no cognizance of special
-scientific doctrines; any more than Science can take cognizance
-of special religious doctrines. The truth which Science
-asserts and Religion indorses cannot be one furnished by
-mathematics; nor can it be a physical truth; nor can it be a
-truth in chemistry: it cannot be a truth belonging to any
-particular science. No generalization of the phenomena of
-space, of time, of matter, or of force, can become a Religious
-conception. Such a conception, if it anywhere exists in
-Science, must be more general than any of these—must be
-one underlying all of them. If there be a fact which
-Science recognizes in common with Religion, it must be that
-<span class='pageno' id='Page_24'>24</span>fact from which the several branches of Science diverge, as
-from their common root.</p>
-
-<p class='c000'>Assuming then, that since these two great realities are
-constituents of the same mind, and respond to different aspects
-of the same Universe, there must be a fundamental harmony
-between them; we see good reason to conclude that the most
-abstract truth contained in Religion and the most abstract
-truth contained in Science must be the one in which the two
-coalesce. The largest fact to be found within our mental
-range must be the one of which we are in search. Uniting
-these positive and negative poles of human thought, it must
-be the ultimate fact in our intelligence.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 8. Before proceeding in the search for this common
-datum let me bespeak a little patience. The next three
-chapters, setting out from different points and converging to
-the same conclusion, will be comparatively unattractive.
-Students of philosophy will find in them much that is more
-or less familiar; and to most of those who are unacquainted
-with the literature of modern metaphysics, they may prove
-somewhat difficult to follow.</p>
-
-<p class='c000'>Our argument however cannot dispense with these chapters;
-and the greatness of the question at issue justifies even
-a heavier tax on the reader’s attention. The matter is one
-which concerns each and all of us more than any other matter
-whatever. Though it affects us little in a direct way, the view
-we arrive at must indirectly affect us in all our relations—must
-determine our conception of the Universe, of Life, of Human
-Nature—must influence our ideas of right and wrong, and so
-modify our conduct. To reach that point of view from which
-the seeming discordance of Religion and Science disappears,
-and the two merge into one, must cause a revolution of
-thought fruitful in beneficial consequences, and must surely
-be worth an effort.</p>
-
-<p class='c000'>Here ending preliminaries, let us now address ourselves to
-this all-important inquiry.</p>
-
-<div>
- <span class='pageno' id='Page_25'>25</span>
- <h3 class='c001'>CHAPTER II.<br /> <span class='large'>ULTIMATE RELIGIOUS IDEAS.</span></h3>
-</div>
-
-<p class='c006'>§ 9. When, on the sea-shore, we note how the hulls of
-distant vessels are hidden below the horizon, and how, of still
-remoter vessels, only the uppermost sails are visible, we
-realize with tolerable clearness the slight curvature of that
-portion of the sea’s surface which lies before us. But when
-we seek in imagination to follow out this curved surface as it
-actually exists, slowly bending round until all its meridians
-meet in a point eight thousand miles below our feet, we find
-ourselves utterly baffled. We cannot conceive in its real
-form and magnitude even that small segment of our globe
-which extends a hundred miles on every side of us; much
-less the globe as a whole. The piece of rock on which we
-stand can be mentally represented with something like completeness:
-we find ourselves able to think of its top, its sides,
-and its under surface at the same time; or so nearly at the
-same time that they seem all present in consciousness together;
-and so we can form what we call a conception of the rock.
-But to do the like with the Earth we find impossible. If
-even to imagine the antipodes as at that distant place in
-space which it actually occupies, is beyond our power; much
-more beyond our power must it be at the same time to
-imagine all other remote points on the Earth’s surface as
-in their actual places. Yet we habitually speak as though
-we had an idea of the Earth—as though we could think of it
-in the same way that we think of minor objects.</p>
-
-<p class='c000'><span class='pageno' id='Page_26'>26</span>What conception, then, do we form of it? the reader may
-ask. That its name calls up in us some state of consciousness
-is unquestionable; and if this state of consciousness is not a
-conception, properly so called, what is it? The answer seems
-to be this:—We have learnt by indirect methods that the
-Earth is a sphere; we have formed models approximately
-representing its shape and the distribution of its parts;
-generally when the Earth is referred to, we either think of an
-indefinitely extended mass beneath our feet, or else, leaving
-out the actual Earth, we think of a body like a terrestrial
-globe; but when we seek to imagine the Earth as it really is,
-we join these two ideas as well as we can—such perception as
-our eyes give us of the Earth’s surface we couple with the
-conception of a sphere. And thus we form of the Earth, not
-a conception properly so called, but only a symbolic conception.<a id='r6' /><a href='#f6' class='c011'><sup>[6]</sup></a></p>
-
-<p class='c000'>A large proportion of our conceptions, including all those
-of much generality, are of this order. Great magnitudes,
-great durations, great numbers, are none of them actually
-conceived, but are all of them conceived more or less symbolically;
-and so, too, are all those classes of objects of which we
-predicate some common fact. When mention is made of any
-individual man, a tolerably complete idea of him is formed.
-If the family he belongs to be spoken of, probably but a part
-of it will be represented in thought: under the necessity of
-attending to that which is said about the family, we realize in
-imagination only its most important or familiar members,
-and pass over the rest with a nascent consciousness which we
-know could, if requisite, be made complete. Should something
-be remarked of the class, say farmers, to which this
-family belongs, we neither enumerate in thought all the individuals
-contained in the class, nor believe that we could do so
-if required; but we are content with taking some few samples
-<span class='pageno' id='Page_27'>27</span>of it, and remembering that these could be indefinitely multiplied.
-Supposing the subject of which something is predicated
-be Englishmen, the answering state of consciousness is
-a still more inadequate representative of the reality. Yet
-more remote is the likeness of the thought to the thing, if
-reference be made to Europeans or to human beings. And
-when we come to propositions concerning the mammalia, or
-concerning the whole of the vertebrata, or concerning animals
-in general, or concerning all organic beings, the unlikeness of
-our conceptions to the objects named reaches its extreme.
-Throughout which series of instances we see, that as the
-number of objects grouped together in thought increases, the
-concept, formed of a few typical samples joined with the
-notion of multiplicity, becomes more and more a mere symbol;
-not only because it gradually ceases to represent the size of
-the group, but also because as the group grows more heterogeneous,
-the typical samples thought of are less like the
-average objects which the group contains.</p>
-
-<p class='c000'>This formation of symbolic conceptions, which inevitably
-arises as we pass from small and concrete objects to large and
-to discrete ones, is mostly a very useful, and indeed necessary,
-process. When, instead of things whose attributes can be
-tolerably well united in a single state of consciousness, we
-have to deal with things whose attributes are too vast or
-numerous to be so united, we must either drop in thought
-part of their attributes, or else not think of them at all—either
-form a more or less symbolic conception, or no conception.
-We must predicate nothing of objects too great or too
-multitudinous to be mentally represented; or we must make
-our predications by the help of extremely inadequate representations
-of such objects—mere symbols of them.</p>
-
-<p class='c000'>But while by this process alone we are enabled to form
-general propositions, and so to reach general conclusions, we are
-by this process perpetually led into danger, and very often
-into error. We habitually mistake our symbolic conceptions
-for real ones; and so are betrayed into countless false inferences.
-<span class='pageno' id='Page_28'>28</span>Not only is it that in proportion as the concept we
-form of any thing or class of things, misrepresents the reality,
-we are apt to be wrong in any assertion we make respecting
-the reality; but it is that we are led to suppose we have truly
-conceived a great variety of things which we have conceived
-only in this fictitious way; and further to confound with
-these certain things which cannot be conceived in any way.
-How almost unavoidably we fall into this error it will be
-needful here to observe.</p>
-
-<p class='c000'>From objects readily representable in their totality, to those
-of which we cannot form even an approximate representation,
-there is an insensible transition. Between a pebble and the
-entire Earth a series of magnitudes might be introduced, each
-of which differed from the adjacent ones so slightly that it
-would be impossible to say at what point in the series our
-conceptions of them became inadequate. Similarly, there is
-a gradual progression from those groups of a few individuals
-which we can think of as groups with tolerable completeness,
-to those larger and larger groups of which we can form
-nothing like true ideas. Whence it is manifest that we pass
-from actual conceptions to symbolic ones by infinitesimal
-steps. Note next that we are led to deal with our symbolic
-conceptions as though they were actual ones, not only because
-we cannot clearly separate the two, but also because, in the
-great majority of cases, the first serve our purposes nearly or
-quite as well as the last—are simply the abbreviated signs
-we substitute for those more elaborate signs which are our
-equivalents for real objects. Those very imperfect representations
-of ordinary things which we habitually make in thinking,
-we know can be developed into adequate ones if needful. Those
-concepts of larger magnitudes and more extensive classes
-which we cannot make adequate, we still find can be verified
-by some indirect process of measurement or enumeration.
-And even in the case of such an utterly inconceivable object
-as the Solar System, we yet, through the fulfilment of predictions
-founded on our symbolic conception of it, gain the
-<span class='pageno' id='Page_29'>29</span>conviction that this symbolic conception stands for an actual
-existence, and, in a sense, truly expresses certain of its
-constituent relations. Thus our symbolic conceptions being
-in the majority of cases capable of development into complete
-ones, and in most other cases serving as steps to conclusions
-which are proved valid by their correspondence with observation,
-we acquire a confirmed habit of dealing with them as
-true conceptions—as real representations of actualities.
-Learning by long experience that they can, if needful, be
-verified, we are led habitually to accept them without verification.
-And thus we open the door to some which profess
-to stand for known things, but which really stand for things
-that cannot be known in any way.</p>
-
-<p class='c000'>To sum up, we must say of conceptions in general, that
-they are complete only when the attributes of the object
-conceived are of such number and kind that they can be
-represented in consciousness so nearly at the same time as to
-seem all present together; that as the objects conceived
-become larger and more complex, some of the attributes first
-thought of fade from consciousness before the rest have been
-represented, and the conception thus becomes imperfect; that
-when the size, complexity, or discreteness of the object
-conceived becomes very great, only a small portion of its
-attributes can be thought of at once, and the conception
-formed of it thus becomes so inadequate as to be a mere symbol;
-that nevertheless such symbolic conceptions, which are
-indispensable in general thinking, are legitimate, provided
-that by some cumulative or indirect process of thought, or by
-the fulfilment of predictions based on them, we can assure
-ourselves that they stand for actualities; but that when our
-symbolic conceptions are such that no cumulative or indirect
-processes of thought can enable us to ascertain that there are
-corresponding actualities, nor any predictions be made whose
-fulfilment can prove this, then they are altogether vicious and
-illusive, and in no way distinguishable from pure fictions.</p>
-
-<hr class='c013' />
-
-<p class='c000'><span class='pageno' id='Page_30'>30</span>§ 10. And now to consider the bearings of this general
-truth on our immediate topic—Ultimate Religious Ideas.</p>
-
-<p class='c000'>To the aboriginal man and to every civilized child the
-problem of the Universe suggests itself. What is it? and
-whence comes it? are questions that press for solution, when,
-from time to time, the imagination rises above daily trivialities.
-To fill the vacuum of thought, any theory that is
-proposed seems better than none. And in the absence of
-others, any theory that is proposed easily gains a footing and
-afterwards maintains its ground: partly from the readiness of
-mankind to accept proximate explanations; partly from the
-authority which soon accumulates round such explanations
-when given.</p>
-
-<p class='c000'>A critical examination, however, will prove not only that
-no current hypothesis is tenable, but also that no tenable
-hypothesis can be framed.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 11. Respecting the origin of the Universe three verbally
-intelligible suppositions may be made. We may assert that it
-is self-existent; or that it is self-created; or that it is created
-by an external agency. Which of these suppositions is most
-credible it is not needful here to inquire. The deeper question,
-into which this finally merges, is, whether any one of
-them is even conceivable in the true sense of the word. Let
-us successively test them.</p>
-
-<p class='c000'>When we speak of a man as self-supporting, of an apparatus
-as self-acting, or of a tree as self-developed, our expressions,
-however inexact, stand for things that can be
-realized in thought with tolerable completeness. Our conception
-of the self-development of a tree is doubtless
-symbolic. But though we cannot really represent in consciousness
-the entire series of complex changes through which
-the tree passes, yet we can thus represent the leading features
-of the series; and general experience teaches us that by long
-continued observation we could gain the power to realize in
-thought a series of changes more fully representing the actual
-<span class='pageno' id='Page_31'>31</span>series: that is, we know that our symbolic conception of self-development
-can be expanded into something like a real
-conception; and that it expresses, however inaccurately, an
-actual process in nature. But when we speak of self-existence,
-and, helped by the above analogies, form some vague symbolic
-conception of it, we delude ourselves in supposing that
-this symbolic conception is of the same order as the others. On
-joining the word <em>self</em> to the word <em>existence</em>, the force of
-association makes us believe we have a thought like that
-suggested by the compound word self-acting. An endeavour
-to expand this symbolic conception, however, will undeceive
-us. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;In the first place, it is clear that by self-existence
-we especially mean, an existence independent of any other—not
-produced by any other: the assertion of self-existence is
-simply an indirect denial of creation. In thus excluding the
-idea of any antecedent cause, we necessarily exclude the idea
-of a beginning; for to admit the idea of a beginning—to
-admit that there was a time when the existence had not commenced—is
-to admit that its commencement was determined
-by something, or was caused; which is a contradiction. Self-existence,
-therefore, necessarily means existence without a
-beginning; and to form a conception of self-existence is to
-form a conception of existence without a beginning. Now by
-no mental effort can we do this. To conceive existence
-through infinite past-time, implies the conception of infinite
-past-time, which is an impossibility. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;To this let us add,
-that even were self-existence conceivable, it would not in any
-sense be an explanation of the Universe. No one will say
-that the existence of an object at the present moment is
-made easier to understand by the discovery that it existed an
-hour ago, or a day ago, or a year ago; and if its existence
-now is not made in the least degree more comprehensible by
-its existence during some previous finite period of time, then
-no accumulation of such finite periods, even could we extend
-them to an infinite period, would make it more comprehensible.
-Thus the Atheistic theory is not only absolutely unthinkable,
-<span class='pageno' id='Page_32'>32</span>but, even if it were thinkable, would not be a solution. The
-assertion that the Universe is self-existent does not really carry
-us a step beyond the cognition of its present existence; and
-so leaves us with a mere re-statement of the mystery.</p>
-
-<p class='c000'>The hypothesis of self-creation, which practically amounts
-to what is called Pantheism, is similarly incapable of being
-represented in thought. Certain phenomena, such as the
-precipitation of invisible vapour into cloud, aid us in forming
-a symbolic conception of a self-evolved Universe; and there
-are not wanting indications in the heavens, and on the earth,
-which help us to render this conception tolerably definite.
-But while the succession of phases through which the
-Universe has passed in reaching its present form, may
-perhaps be comprehended as in a sense self-determined; yet
-the impossibility of expanding our symbolic conception of self-creation
-into a real conception, remains as complete as ever.
-Really to conceive self-creation, is to conceive potential
-existence passing into actual existence by some inherent
-necessity; which we cannot do. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;We cannot form
-any idea of a potential existence of the universe, as distinguished
-from its actual existence. If represented in
-thought at all, potential existence must be represented as
-<em>something</em>, that is as an actual existence; to suppose that it
-can be represented as nothing, involves two absurdities—that
-nothing is more than a negation, and can be positively
-represented in thought; and that one nothing is distinguished
-from all other nothings by its power to develope into something.
-Nor is this all. We have no state of consciousness
-answering to the words—an inherent necessity by which
-potential existence became actual existence. To render them
-into thought, existence, having for an indefinite period remained
-in one form, must be conceived as passing without
-any external or additional impulse, into another form; and
-this involves the idea of a change without a cause—a thing
-of which no idea is possible. Thus the terms of this hypothesis
-do not stand for real thoughts; but merely suggest the
-<span class='pageno' id='Page_33'>33</span>vaguest symbols incapable of any interpretation. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Moreover,
-even were it true that potential existence is conceivable
-as a different thing from actual existence; and that the transition
-from the one to the other can be mentally realized as a
-self-determined change; we should still be no forwarder: the
-problem would simply be removed a step back. For whence
-the potential existence? This would just as much require
-accounting for as actual existence; and just the same difficulties
-would meet us. Respecting the origin of such a latent
-power, no other suppositions could be made than those above
-named—self-existence, self-creation, creation by external
-agency. The self-existence of a potential universe is no
-more conceivable than we have found the self-existence of the
-actual universe to be. The self-creation of such a potential
-universe would involve over again the difficulties here
-stated—would imply behind this potential universe a more
-remote potentiality; and so on in an infinite series, leaving
-us at last no forwarder than at first. While to assign as the
-source of this potential universe an external agency, would be
-to introduce the notion of a potential universe for no purpose
-whatever.</p>
-
-<p class='c000'>There remains to be examined the commonly-received or
-theistic hypothesis—creation by external agency. Alike in
-the rudest creeds and in the cosmogony long current among
-ourselves, it is assumed that the genesis of the Heavens and
-the Earth is effected somewhat after the manner in which a
-workman shapes a piece of furniture. And this assumption
-is made not by theologians only, but by the immense majority
-of philosophers, past and present. Equally in the writings of
-Plato, and in those of not a few living men of science, we
-find it taken for granted that there is an analogy between the
-process of creation and the process of manufacture. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Now
-in the first place, not only is this conception one that cannot
-by any cumulative process of thought, or the fulfilment of
-predictions based on it, be shown to answer to anything
-actual; and not only is it that in the absence of all evidence
-<span class='pageno' id='Page_34'>34</span>respecting the process of creation, we have no proof of correspondence
-even between this limited conception and some
-limited portion of the fact; but it is that the conception
-is not even consistent with itself—cannot be realized in
-thought, when all its assumptions are granted. Though it is
-true that the proceedings of a human artificer may vaguely
-symbolize to us a method after which the Universe might be
-shaped, yet they do not help us to comprehend the real
-mystery; namely, the origin of the material of which the
-Universe consists. The artizan does not make the iron, wood,
-or stone, he uses; but merely fashions and combines them.
-If we suppose suns, and planets, and satellites, and all they
-contain to have been similarly formed by a “Great Artificer,”
-we suppose merely that certain pre-existing elements were
-thus put into their present arrangement. But whence the
-pre-existing elements? The comparison helps us not in the
-least to understand that; and unless it helps us to understand
-that, it is worthless. The production of matter out of nothing
-is the real mystery, which neither this simile nor any other
-enables us to conceive; and a simile which does not enable us
-to conceive this, may just as well be dispensed with. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Still
-more manifest does the insufficiency of this theory of creation
-become, when we turn from material objects to that which
-contains them—when instead of matter we contemplate space.
-Did there exist nothing but an immeasurable void, explanation
-would be needed as much as now. There would still arise the
-question—how came it so? If the theory of creation by external
-agency were an adequate one, it would supply an
-answer; and its answer would be—space was made in the same
-manner that matter was made. But the impossibility of conceiving
-this is so manifest, that no one dares to assert it. For
-if space was created, it must have been previously non-existent.
-The non-existence of space cannot, however, by any mental
-effort be imagined. It is one of the most familiar truths that
-the idea of space as surrounding us on all sides, is not for a moment
-to be got rid of—not only are we compelled to think of
-<span class='pageno' id='Page_35'>35</span>space as now everywhere present, but we are unable to conceive
-its absence either in the past or the future. And if the
-non-existence of space is absolutely inconceivable, then, necessarily,
-its creation is absolutely inconceivable. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Lastly,
-even supposing that the genesis of the Universe could really
-be represented in thought as the result of an external agency,
-the mystery would be as great as ever; for there would still
-arise the question—how came there to be an external agency?
-To account for this only the same three hypotheses are possible—self-existence,
-self-creation, and creation by external agency.
-Of these the last is useless: it commits us to an infinite series
-of such agencies, and even then leaves us where we were. By
-the second we are practically involved in the same predicament;
-since, as already shown, self-creation implies an infinite
-series of potential existences. We are obliged therefore to fall
-back upon the first, which is the one commonly accepted and
-commonly supposed to be satisfactory. Those who cannot
-conceive a self-existent universe; and who therefore assume
-a creator as the source of the universe; take for granted that
-they can conceive a self-existent creator. The mystery
-which they recognize in this great fact surrounding them on
-every side, they transfer to an alleged source of this great
-fact; and then suppose that they have solved the mystery.
-But they delude themselves. As was proved at the outset of
-the argument, self-existence is rigorously inconceivable; and
-this holds true whatever be the nature of the object of which
-it is predicated. Whoever agrees that the atheistic hypothesis
-is untenable because it involves the impossible idea of
-self-existence, must perforce admit that the theistic hypothesis
-is untenable if it contains the same impossible idea.</p>
-
-<p class='c000'>Thus these three different suppositions respecting the origin
-of things, verbally intelligible though they are, and severally
-seeming to their respective adherents quite rational, turn out,
-when critically examined, to be literally unthinkable. It is
-not a question of probability, or credibility, but of conceivability.
-Experiment proves that the elements of these hypotheses
-<span class='pageno' id='Page_36'>36</span>cannot even be put together in consciousness; and
-we can entertain them only as we entertain such pseud-ideas
-as a square fluid and a moral substance—only by abstaining
-from the endeavour to render them into actual thoughts.
-Or, reverting to our original mode of statement, we may say
-that they severally involve symbolic conceptions of the illegitimate
-and illusive kind. Differing so widely as they seem to
-do, the atheistic, the pantheistic, and the theistic hypotheses
-contain the same ultimate element. It is impossible to avoid
-making the assumption of self-existence somewhere; and
-whether that assumption be made nakedly, or under complicated
-disguises, it is equally vicious, equally unthinkable. Be
-it a fragment of matter, or some fancied potential form of
-matter, or some more remote and still less imaginable cause,
-our conception of its self-existence can be formed only by
-joining with it the notion of unlimited duration through past
-time. And as unlimited duration is inconceivable, all those
-formal ideas into which it enters are inconceivable; and indeed,
-if such an expression is allowable, are the more inconceivable
-in proportion as the other elements of the ideas are indefinite.
-So that in fact, impossible as it is to think of the actual universe
-as self-existing, we do but multiply impossibilities of
-thought by every attempt we make to explain its existence.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 12. If from the origin of the Universe we turn to its
-nature, the like insurmountable difficulties rise up before us
-on all sides—or rather, the same difficulties under new aspects.
-We find ourselves on the one hand obliged to make certain
-assumptions; and yet on the other hand we find these assumptions
-cannot be represented in thought.</p>
-
-<p class='c000'>When we inquire what is the meaning of the various effects
-produced upon our senses—when we ask how there come to
-be in our consciousness impressions of sounds, of colours, of
-tastes, and of those various attributes which we ascribe to
-bodies; we are compelled to regard them as the effects of
-some cause. We may stop short in the belief that this cause
-<span class='pageno' id='Page_37'>37</span>is what we call matter. Or we may conclude, as some do, that
-matter is only a certain mode of manifestation of spirit;
-which is therefore the true cause. Or, regarding matter and
-spirit as proximate agencies, we may attribute all the changes
-wrought in our consciousness to immediate divine power.
-But be the cause we assign what it may, we are obliged to
-suppose <em>some</em> cause. And we are not only obliged to suppose
-some cause, but also a first cause. The matter, or spirit, or
-whatever we assume to be the agent producing on us these
-various impressions, must either be the first cause of them or
-not. If it is the first cause, the conclusion is reached. If it
-is not the first cause, then by implication there must be a
-cause behind it; which thus becomes the real cause of the
-effect. Manifestly, however complicated the assumptions, the
-same conclusion must inevitably be reached. We cannot
-think at all about the impressions which the external world
-produces on us, without thinking of them as caused; and we
-cannot carry out an inquiry concerning their causation, without
-inevitably committing ourselves to the hypothesis of a
-First Cause.</p>
-
-<p class='c000'>But now if we go a step further, and ask what is the nature
-of this First Cause, we are driven by an inexorable logic to
-certain further conclusions. Is the First Cause finite or infinite?
-If we say finite we involve ourselves in a dilemma.
-To think of the First Cause as finite, is to think of it as
-limited. To think of it as limited, necessarily implies a conception
-of something beyond its limits: it is absolutely impossible
-to conceive a thing as bounded without conceiving a
-region surrounding its boundaries. What now must we say of
-this region? If the First Cause is limited, and there consequently
-lies something outside of it, this something must have
-no First Cause—must be uncaused. But if we admit that there
-can be something uncaused, there is no reason to assume a cause
-for anything. If beyond that finite region over which the First
-Cause extends, there lies a region, which we are compelled to
-regard as infinite, over which it does not extend—if we admit
-<span class='pageno' id='Page_38'>38</span>that there is an infinite uncaused surrounding the finite caused;
-we tacitly abandon the hypothesis of causation altogether. Thus
-it is impossible to consider the First Cause as finite. And if
-it cannot be finite it must be infinite.</p>
-
-<p class='c000'>Another inference concerning the First Cause is equally
-unavoidable. It must be independent. If it is dependent it
-cannot be the First Cause; for that must be the First
-Cause on which it depends. It is not enough to say that it is
-partially independent; since this implies some necessity which
-determines its partial dependence, and this necessity, be it
-what it may, must be a higher cause, or the true First Cause,
-which is a contradiction. But to think of the First Cause as
-totally independent, is to think of it as that which exists in
-the absence of all other existence; seeing that if the presence
-of any other existence is necessary, it must be partially dependent
-on that other existence, and so cannot be the First
-Cause. Not only however must the First Cause be a form of
-being which has no necessary relation to any other form of
-being, but it can have no necessary relation within itself.
-There can be nothing in it which determines change, and yet
-nothing which prevents change. For if it contains something
-which imposes such necessities or restraints, this something
-must be a cause higher than the First Cause, which is absurd.
-Thus the First Cause must be in every sense perfect, complete,
-total: including within itself all power, and transcending all
-law. Or to use the established word, it must be absolute.</p>
-
-<p class='c000'>Here then respecting the nature of the Universe, we seem
-committed to certain unavoidable conclusions. The objects
-and actions surrounding us, not less than the phenomena of
-our own consciousness, compel us to ask a cause; in our search
-for a cause, we discover no resting place until we arrive at the
-hypothesis of a First Cause; and we have no alternative but
-to regard this First Cause as Infinite and Absolute. These
-are inferences forced upon us by arguments from which there
-appears no escape. It is hardly needful however to show
-those who have followed thus far, how illusive are these
-<span class='pageno' id='Page_39'>39</span>reasonings and their results. But that it would tax the
-reader’s patience to no purpose, it might easily be proved
-that the materials of which the argument is built, equally
-with the conclusions based on them, are merely symbolic conceptions
-of the illegitimate order. Instead, however, of repeating
-the disproof used above, it will be desirable to pursue
-another method; showing the fallacy of these conclusions by
-disclosing their mutual contradictions.</p>
-
-<p class='c000'>Here I cannot do better than avail myself of the demonstration
-which Mr Mansel, carrying out in detail the doctrine of
-Sir William Hamilton, has given in his “Limits of Religious
-Thought.” And I gladly do this, not only because his mode
-of presentation cannot be improved, but also because, writing
-as he does in defence of the current Theology, his reasonings
-will be the more acceptable to the majority of readers.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 13. Having given preliminary definitions of the First
-Cause, of the Infinite, and of the Absolute, Mr Mansel says:—</p>
-
-<p class='c000'>“But these three conceptions, the Cause, the Absolute, the
-Infinite, all equally indispensable, do they not imply contradiction
-to each other, when viewed in conjunction, as attributes
-of one and the same Being? A Cause cannot, as such, be
-absolute: the Absolute cannot, as such, be a cause. The cause,
-as such, exists only in relation to its effect: the cause is a
-cause of the effect; the effect is an effect of the cause. On
-the other hand, the conception of the Absolute implies a possible
-existence out of all relation. We attempt to escape from
-this apparent contradiction, by introducing the idea of succession
-in time. The Absolute exists first by itself, and afterwards
-becomes a Cause. But here we are checked by the
-third conception, that of the Infinite. How can the Infinite
-become that which it was not from the first? If Causation is
-a possible mode of existence, that which exists without causing
-is not infinite; that which becomes a cause has passed beyond
-its former limits.” *&nbsp;*&nbsp;*</p>
-
-<p class='c000'>“Supposing the Absolute to become a cause, it will follow
-<span class='pageno' id='Page_40'>40</span>that it operates by means of freewill and consciousness. For
-a necessary cause cannot be conceived as absolute and infinite.
-If necessitated by something beyond itself, it is thereby limited
-by a superior power; and if necessitated by itself, it has in
-its own nature a necessary relation to its effect. The act of
-causation must therefore be voluntary; and volition is only
-possible in a conscious being. But consciousness again is
-only conceivable as a relation. There must be a conscious
-subject, and an object of which he is conscious. The subject
-is a subject to the object; the object is an object to the subject;
-and neither can exist by itself as the absolute. This
-difficulty, again, may be for the moment evaded, by distinguishing
-between the absolute as related to another and the
-absolute as related to itself. The Absolute, it may be said,
-may possibly be conscious, provided it is only conscious of itself.
-But this alternative is, in ultimate analysis, no less self-destructive
-than the other. For the object of consciousness,
-whether a mode of the subject’s existence or not, is either
-created in and by the act of consciousness, or has an existence
-independent of it. In the former case, the object depends
-upon the subject, and the subject alone is the true absolute.
-In the latter case, the subject depends upon the object, and
-the object alone is the true absolute. Or if we attempt a third
-hypothesis, and maintain that each exists independently of the
-other, we have no absolute at all, but only a pair of relatives;
-for coexistence, whether in consciousness or not, is itself a
-relation.”</p>
-
-<p class='c000'>“The corollary from this reasoning is obvious. Not only
-is the Absolute, as conceived, incapable of a necessary relation
-to anything else; but it is also incapable of containing, by
-the constitution of its own nature, an essential relation within
-itself; as a whole, for instance, composed of parts, or as a
-substance consisting of attributes, or as a conscious subject
-in antithesis to an object. For if there is in the absolute any
-principle of unity, distinct from the mere accumulation of
-parts or attributes, this principle alone is the true absolute.
-<span class='pageno' id='Page_41'>41</span>If, on the other hand, there is no such principle, then there is
-no absolute at all, but only a plurality of relatives. The
-almost unanimous voice of philosophy, in pronouncing that
-the absolute is both one and simple, must be accepted as the
-voice of reason also, so far as reason has any voice in the
-matter. But this absolute unity, as indifferent and containing
-no attributes, can neither be distinguished from the multiplicity
-of finite beings by any characteristic feature, nor be
-identified with them in their multiplicity. Thus we are landed
-in an inextricable dilemma. The Absolute cannot be conceived
-as conscious, neither can it be conceived as unconscious:
-it cannot be conceived as complex, neither can it be conceived
-as simple: it cannot be conceived by difference, neither can it
-be conceived by the absence of difference: it cannot be identified
-with the universe, neither can it be distinguished from
-it. The One and the Many, regarded as the beginning of
-existence, are thus alike incomprehensible.”</p>
-
-<p class='c000'>“The fundamental conceptions of Rational Theology being
-thus self-destructive, we may naturally expect to find the same
-antagonism manifested in their special applications. *&nbsp;*&nbsp;*
-How, for example, can Infinite Power be able to do all things,
-and yet Infinite Goodness be unable to do evil? How can Infinite
-Justice exact the utmost penalty for every sin, and yet
-Infinite Mercy pardon the sinner? How can Infinite Wisdom
-know all that is to come, and yet Infinite Freedom be at liberty
-to do or to forbear? How is the existence of Evil compatible
-with that of an infinitely perfect Being; for if he wills it, he
-is not infinitely good; and if he wills it not, his will is
-thwarted and his sphere of action limited?” *&nbsp;*&nbsp;*</p>
-
-<p class='c000'>“Let us, however, suppose for an instant that these difficulties
-are surmounted, and the existence of the Absolute securely
-established on the testimony of reason. Still we have not
-succeeded in reconciling this idea with that of a Cause: we
-have done nothing towards explaining how the absolute can
-give rise to the relative, the infinite to the finite. If the condition
-of casual activity is a higher state than that of quiescence,
-<span class='pageno' id='Page_42'>42</span>the Absolute, whether acting voluntarily or involuntarily,
-has passed from a condition of comparative imperfection
-to one of comparative perfection; and therefore was not
-originally perfect. If the state of activity is an inferior state
-to that of quiescence, the Absolute, in becoming a cause, has
-lost its original perfection. There remains only the supposition
-that the two states are equal, and the act of creation one of
-complete indifference. But this supposition annihilates the
-unity of the absolute, or it annihilates itself. If the act of
-creation is real, and yet indifferent, we must admit the possibility
-of two conceptions of the absolute, the one as productive,
-the other as non-productive. If the act is not real, the supposition
-itself vanishes.” *&nbsp;*&nbsp;*</p>
-
-<p class='c000'>“Again, how can the relative be conceived as coming into
-being? If it is a distinct reality from the absolute, it must be
-conceived as passing from non-existence into existence. But
-to conceive an object as non-existent, is again a self-contradiction;
-for that which is conceived exists, as an object of thought,
-in and by that conception. We may abstain from thinking of
-an object at all; but, if we think of it, we cannot but think of
-it as existing. It is possible at one time not to think of an
-object at all, and at another to think of it as already in being;
-but to think of it in the act of becoming, in the progress from
-not being into being, is to think that which, in the very
-thought, annihilates itself.” *&nbsp;*&nbsp;*</p>
-
-<p class='c000'>“To sum up briefly this portion of my argument. The
-conception of the Absolute and Infinite, from whatever side we
-view it, appears encompassed with contradictions. There is
-a contradiction in supposing such an object to exist, whether
-alone or in conjunction with others; and there is a contradiction
-in supposing it not to exist. There is a contradiction in
-conceiving it as one; and there is a contradiction in conceiving
-it as many. There is a contradiction in conceiving it as
-personal; and there is a contradiction in conceiving it as impersonal.
-It cannot, without contradiction, be represented as
-active; nor, without equal contradiction, be represented as
-<span class='pageno' id='Page_43'>43</span>inactive. It cannot be conceived as the sum of all existence;
-nor yet can it be conceived as a part only of that sum.”</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 14. And now what is the bearing of these results on the
-question before us? Our examination of Ultimate Religious
-Ideas has been carried on with the view of making manifest
-some fundamental verity contained in them. Thus far however
-we have arrived at negative conclusions only. Criticising
-the essential conceptions involved in the different
-orders of beliefs, we find no one of them to be logically
-defensible. Passing over the consideration of credibility, and
-confining ourselves to that of conceivability, we see that
-Atheism, Pantheism, and Theism, when rigorously analysed,
-severally prove to be absolutely unthinkable. Instead of
-disclosing a fundamental verity existing in each, our investigation
-seems rather to have shown that there is no fundamental
-verity contained in any. To carry away this
-conclusion, however, would be a fatal error; as we shall
-shortly see.</p>
-
-<p class='c000'>Leaving out the accompanying moral code, which is in all
-cases a supplementary growth, every Religion may be defined
-as an <i><span lang="fr" xml:lang="fr">à priori</span></i> theory of the Universe. The surrounding
-facts being given, some form of agency is alleged which, in
-the opinion of those alleging it, accounts for these facts. Be
-it in the rudest Fetishism, which assumes a separate personality
-behind every phenomenon; be it in Polytheism, in
-which these personalities are partially generalized; be it in
-Monotheism, in which they are wholly generalized; or be it
-in Pantheism, in which the generalized personality becomes
-one with the phenomena; we equally find an hypothesis
-which is supposed to render the Universe comprehensible.
-Nay, even that which is commonly regarded as the negation
-of all Religion—even positive Atheism, comes within the
-definition; for it, too, in asserting the self-existence of Space,
-Matter, and Motion, which it regards as adequate causes of
-every appearance, propounds an <i><span lang="fr" xml:lang="fr">à priori</span></i> theory from which
-<span class='pageno' id='Page_44'>44</span>it holds the facts to be deducible. Now every theory tacitly
-asserts two things: firstly, that there is something to be
-explained; secondly, that such and such is the explanation.
-Hence, however widely different speculators may disagree in
-the solutions they give of the same problem; yet by implication
-they agree that there is a problem to be solved. Here
-then is an element which all creeds have in common. Religions
-diametrically opposed in their overt dogmas, are
-yet perfectly at one in the tacit conviction that the existence
-of the world with all it contains and all which surrounds
-it, is a mystery ever pressing for interpretation. On this
-point, if on no other, there is entire unanimity.</p>
-
-<p class='c000'>Thus we come within sight of that which we seek. In the
-last chapter, reasons were given for inferring that human
-beliefs in general, and especially the perennial ones, contain,
-under whatever disguises of error, some soul of truth; and
-here we have arrived at a truth underlying even the grossest
-superstitions. We saw further that this soul of truth was
-most likely to be some constituent common to conflicting
-opinions of the same order; and here we have a constituent
-which may be claimed alike by all religions. It was pointed
-out that this soul of truth would almost certainly be more
-abstract than any of the beliefs involving it; and the truth
-we have arrived at is one exceeding in abstractness the most
-abstract religious doctrines. In every respect, therefore, our
-conclusion answers to the requirements. It has all the
-characteristics which we inferred must belong to that fundamental
-verity expressed by religions in general.</p>
-
-<p class='c000'>That this is the vital element in all religions is further
-proved by the fact, that it is the element which not only survives
-every change, but grows more distinct the more highly the
-religion is developed. Aboriginal creeds, though pervaded
-by the idea of personal agencies which are usually unseen,
-yet conceive these agencies under perfectly concrete and
-ordinary forms—class them with the visible agencies of men
-and animals; and so hide a vague perception of mystery in
-<span class='pageno' id='Page_45'>45</span>disguises as unmysterious as possible. The Polytheistic conceptions
-in their advanced phases, represent the presiding
-personalities in greatly idealized shapes, existing in a remote
-region, working in subtle ways, and communicating with men
-by omens or through inspired persons; that is, the ultimate
-causes of things are regarded as less familiar and comprehensible.
-The growth of a Monotheistic faith, accompanied
-as it is by a denial of those beliefs in which the divine nature
-is assimilated to the human in all its lower propensities, shows
-us a further step in the same direction; and however imperfectly
-this higher faith is at first realized, we yet see in altars
-“to the unknown and unknowable God,” and in the worship
-of a God that cannot by any searching be found out, that
-there is a clearer recognition of the inscrutableness of creation.
-Further developments of theology, ending in such assertions
-as that “a God understood would be no God at all,” and “to
-think that God is, as we can think him to be, is blasphemy,”
-exhibit this recognition still more distinctly; and it pervades
-all the cultivated theology of the present day. Thus while
-other constituents of religious creeds one by one drop away,
-this remains and grows even more manifest; and so is shown
-to be the essential constituent.</p>
-
-<p class='c000'>Nor does the evidence end here. Not only is the omnipresence
-of something which passes comprehension, that most
-abstract belief which is common to all religions, which becomes
-the more distinct in proportion as they develope, and
-which remains after their discordant elements have been
-mutually cancelled; but it is that belief which the most unsparing
-criticism of each leaves unquestionable—or rather
-makes ever clearer. It has nothing to fear from the most
-inexorable logic; but on the contrary is a belief which the
-most inexorable logic shows to be more profoundly true than
-any religion supposes. For every religion, setting out though
-it does with the tacit assertion of a mystery, forthwith proceeds
-to give some solution of this mystery; and so asserts
-that it is not a mystery passing human comprehension. But
-<span class='pageno' id='Page_46'>46</span>an examination of the solutions they severally propound,
-shows them to be uniformly invalid. The analysis of every
-possible hypothesis proves, not simply that no hypothesis is
-sufficient, but that no hypothesis is even thinkable. And
-thus the mystery which all religions recognize, turns out to
-be a far more transcendent mystery than any of them suspect—not
-a relative, but an absolute mystery.</p>
-
-<p class='c000'>Here, then, is an ultimate religious truth of the highest
-possible certainty—a truth in which religions in general are
-at one with each other, and with a philosophy antagonistic
-to their special dogmas. And this truth, respecting which
-there is a latent agreement among all mankind from the
-fetish-worshipper to the most stoical critic of human creeds,
-must be the one we seek. If Religion and Science are to be
-reconciled, the basis of reconciliation must be this deepest,
-widest, and most certain of all facts—that the Power which
-the Universe manifests to us is utterly inscrutable.</p>
-
-<hr class='c015' />
-
-<div class='footnote' id='f6'>
-<p class='c000'><span class='label'><a href='#r6'>6</a>.&nbsp;&nbsp;</span>Those who may have before met with this term, will perceive that it is here
-used in quite a different sense.</p>
-</div>
-
-<div>
- <span class='pageno' id='Page_47'>47</span>
- <h3 class='c001'>CHAPTER III.<br /> <span class='large'>ULTIMATE SCIENTIFIC IDEAS.</span></h3>
-</div>
-
-<p class='c006'>§ 15. What are Space and Time? Two hypotheses are
-current respecting them: the one that they are objective, and
-the other that they are subjective—the one that they are
-external to, and independent of, ourselves, the other that
-they are internal, and appertain to our own consciousness.
-Let us see what becomes of these hypotheses under analysis.</p>
-
-<p class='c000'>To say that Space and Time exist objectively, is to say that
-they are entities. The assertion that they are non-entities is
-self-destructive: non-entities are non-existences; and to allege
-that non-existences exist objectively, is a contradiction in
-terms. Moreover, to deny that Space and Time are things,
-and so by implication to call them nothings, involves the
-absurdity that there are two kinds of nothing. Neither can
-they be regarded as attributes of some entity; seeing, not
-only that it is impossible really to conceive any entity of
-which they are attributes, but seeing further that we cannot
-think of them as disappearing, even if everything else disappeared;
-whereas attributes necessarily disappear along with
-the entities they belong to. Thus as Space and Time cannot
-be either non-entities, nor the attributes of entities, we have
-no choice but consider them as entities. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;But while, on
-the hypothesis of their objectivity, Space and Time must be
-classed as things, we find, on experiment, that to represent
-them in thought as things is impossible. To be conceived
-at all, a thing must be conceived as having attributes. We
-<span class='pageno' id='Page_48'>48</span>can distinguish something from nothing, only by the power
-which the something has to act on our consciousness; the
-several affections it produces on our consciousness (or else the
-hypothetical causes of them), we attribute to it, and call
-its attributes; and the absence of these attributes is the
-absence of the terms in which the something is conceived,
-and involves the absence of a conception. What now are the
-attributes of Space? The only one which it is possible for a
-moment to think of as belonging to it, is that of extension;
-and to credit it with this implies a confusion of thought.
-For extension and Space are convertible terms: by extension,
-as we ascribe it to surrounding objects, we mean occupancy
-of Space; and thus to say that Space is extended, is to say
-that Space occupies Space. How we are similarly unable
-to assign any attribute to Time, scarcely needs pointing
-out. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Nor are Time and Space unthinkable as entities
-only from the absence of attributes; there is another peculiarity,
-familiar to readers of metaphysics, which equally excludes
-them from the category. All entities which we actually
-know as such, are limited; and even if we suppose ourselves
-either to know or to be able to conceive some unlimited
-entity, we of necessity in so classing it positively separate it
-from the class of limited entities. But of Space and Time
-we cannot assert either limitation or the absence of limitation.
-We find ourselves totally unable to form any mental image of
-unbounded Space; and yet totally unable to imagine bounds
-beyond which there is no Space. Similarly at the other
-extreme: it is impossible to think of a limit to the divisibility
-of Space; yet equally impossible to think of its infinite
-divisibility. And, without stating them, it will be seen that we
-labour under like impotencies in respect to Time. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Thus
-we cannot conceive Space and Time as entities, and are
-equally disabled from conceiving them as either the attributes
-of entities or as non-entities. We are compelled to think of
-them as existing; and yet cannot bring them within those
-conditions under which existences are represented in thought.</p>
-
-<p class='c000'><span class='pageno' id='Page_49'>49</span>Shall we then take refuge in the Kantian doctrine? shall
-we say that Space and Time are forms of the intellect,—“<i><span lang="fr" xml:lang="fr">à
-priori</span></i> laws or conditions of the conscious mind”? To do this
-is to escape from great difficulties by rushing into greater.
-The proposition with which Kant’s philosophy sets out,
-verbally intelligible though it is, cannot by any effort be
-rendered into thought—cannot be interpreted into an idea
-properly so called, but stands merely for a pseud-idea. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;In
-the first place, to assert that Space and Time, as we are conscious
-of them, are subjective conditions, is by implication
-to assert that they are not objective realities: if the Space
-and Time present to our minds belong to the <em>ego</em>, then of
-necessity they do not belong to the <em>non-ego</em>. Now it is absolutely
-impossible to think this. The very fact on which
-Kant bases his hypothesis—namely that our consciousness of
-Space and Time cannot be suppressed—testifies as much; for
-that consciousness of Space and Time which we cannot rid
-ourselves of, is the consciousness of them as existing objectively.
-It is useless to reply that such an inability must
-inevitably result if they are subjective forms. The question
-here is—What does consciousness directly testify? And the
-direct testimony of consciousness is, that Time and Space are
-not within but without the mind; and so absolutely independent
-of it that they cannot be conceived to become non-existent
-even were the mind to become non-existent. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Besides
-being positively unthinkable in what it tacitly denies,
-the theory of Kant is equally unthinkable in what it openly
-affirms. It is not simply that we cannot combine the thought
-of Space with the thought of our own personality, and contemplate
-the one as a property of the other—though our
-inability to do this would prove the inconceivableness of the
-hypothesis—but it is that the hypothesis carries in itself the
-proof of its own inconceivableness. For if Space and Time
-are forms of thought, they can never be thought of; since it
-is impossible for anything to be at once the <em>form</em> of thought
-and the <em>matter</em> of thought. That Space and Time are objects
-<span class='pageno' id='Page_50'>50</span>of consciousness, Kant emphatically asserts by saying
-that it is impossible to suppress the consciousness of them.
-How then, if they are <em>objects</em> of consciousness, can they at the
-same time be <em>conditions</em> of consciousness? If Space and Time
-are the conditions under which we think, then when we think
-of Space and Time themselves, our thoughts must be unconditioned;
-and if there can thus be unconditioned thoughts,
-what becomes of the theory?</p>
-
-<p class='c000'>It results therefore that Space and Time are wholly incomprehensible.
-The immediate knowledge which we seem
-to have of them, proves, when examined, to be total ignorance.
-While our belief in their objective reality is insurmountable,
-we are unable to give any rational account
-of it. And to posit the alternative belief (possible to state
-but impossible to realize) is merely to multiply irrationalities.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 16. Were it not for the necessities of the argument, it
-would be inexcusable to occupy the reader’s attention with
-the threadbare, and yet unended, controversy respecting the
-divisibility of matter. Matter is either infinitely divisible or
-it is not: no third possibility can be named. Which of the
-alternatives shall we accept? If we say that Matter is infinitely
-divisible, we commit ourselves to a supposition not
-realizable in thought. We can bisect and re-bisect a body,
-and continually repeating the act until we reduce its parts to
-a size no longer physically divisible, may then mentally continue
-the process without limit. To do this, however, is not
-really to conceive the infinite divisibility of matter, but to form
-a symbolic conception incapable of expansion into a real one,
-and not admitting of other verification. Really to conceive
-the infinite divisibility of matter, is mentally to follow out the
-divisions to infinity; and to do this would require infinite
-time. On the other hand, to assert that matter is not
-infinitely divisible, is to assert that it is reducible to parts
-which no conceivable power can divide; and this verbal
-<span class='pageno' id='Page_51'>51</span>supposition can no more be represented in thought than the
-other. For each of such ultimate parts, did they exist, must
-have an under and an upper surface, a right and a left side,
-like any larger fragment. Now it is impossible to imagine
-its sides so near that no plane of section can be conceived between
-them; and however great be the assumed force of
-cohesion, it is impossible to shut out the idea of a greater
-force capable of overcoming it. So that to human intelligence
-the one hypothesis is no more acceptable than the
-other; and yet the conclusion that one or other must agree
-with the fact, seems to human intelligence unavoidable.</p>
-
-<p class='c000'>Again, leaving this insoluble question, let us ask whether
-substance has, in reality, anything like that extended solidity
-which it presents to our consciousness. The portion of space
-occupied by a piece of metal, seems to eyes and fingers perfectly
-filled: we perceive a homogeneous, resisting mass,
-without any breach of continuity. Shall we then say that
-Matter is as actually solid as it appears? Shall we say that
-whether it consists of an infinitely divisible element or of
-ultimate units incapable of further division, its parts are
-everywhere in actual contact? To assert as much entangles
-us in insuperable difficulties. Were Matter thus absolutely
-solid, it would be, what it is not—absolutely incompressible;
-since compressibility, implying the nearer approach of constituent
-parts, is not thinkable unless there is unoccupied
-space between the parts. Nor is this all. It is an established
-mechanical truth, that if a body, moving at a given
-velocity, strikes an equal body at rest in such wise that the
-two move on together, their joint velocity will be but half
-that of the striking body. Now it is a law of which the
-negation is inconceivable, that in passing from any one
-degree of magnitude to any other, all intermediate degrees
-must be passed through. Or, in the case before us, a body
-moving at velocity 4, cannot, by collision, be reduced to
-velocity 2, without passing through all velocities between 4
-and 2. But were Matter truly solid—were its units absolutely
-<span class='pageno' id='Page_52'>52</span>incompressible and in absolute contact—this “law of
-continuity,” as it is called, would be broken in every case
-of collision. For when, of two such units, one moving at
-velocity 4 strikes another at rest, the striking unit must have
-its velocity 4 instantaneously reduced to velocity 2; must
-pass from velocity 4 to velocity 2 without any lapse of time,
-and without passing through intermediate velocities; must be
-moving with velocities 4 and 2 at the same instant, which is
-impossible.</p>
-
-<p class='c000'>The supposition that Matter is absolutely solid being
-untenable, there presents itself the Newtonian supposition,
-that it consists of solid atoms not in contact but acting on
-each other by attractive and repulsive forces, varying with
-the distances. To assume this, however, merely shifts the
-difficulty: the problem is simply transferred from the aggregated
-masses of matter to these hypothetical atoms. For
-granting that Matter, as we perceive it, is made up of such dense
-extended units surrounded by atmospheres of force, the
-question still arises—What is the constitution of these units?
-We have no alternative but to regard each of them as a
-small piece of matter. Looked at through a mental microscope,
-each becomes a mass of substance such as we have just
-been contemplating. Exactly the same inquiries may be
-made respecting the parts of which each atom consists; while
-exactly the same difficulties stand in the way of every answer.
-And manifestly, even were the hypothetical atom assumed to
-consist of still minuter ones, the difficulty would re-appear at
-the next step; nor could it be got rid of even by an infinite
-series of such assumptions.</p>
-
-<p class='c000'>Boscovich’s conception yet remains to us. Seeing that
-Matter could not, as Leibnitz suggested, be composed of unextended
-monads (since the juxtaposition of an infinity of
-points having no extension, could not produce that extension
-which matter possesses); and perceiving objections to the
-view entertained by Newton; Boscovich proposed an intermediate
-theory, uniting, as he considered, the advantages of
-<span class='pageno' id='Page_53'>53</span>both and avoiding their difficulties. His theory is, that the
-constituents of Matter are centres of force—points without
-dimensions, which attract and repel each other in suchwise as
-to be kept at specific distances apart. And he argues, mathematically,
-that the forces possessed by such centres might
-so vary with the distances, that under given conditions the
-centres would remain in stable equilibrium with definite
-interspaces; and yet, under other conditions, would maintain
-larger or smaller interspaces. This speculation however,
-ingeniously as it is elaborated, and eluding though it does
-various difficulties, posits a proposition which cannot by any
-effort be represented in thought: it escapes all the inconceivabilities
-above indicated, by merging them in the one
-inconceivability with which it sets out. A centre of force
-absolutely without extension is unthinkable: answering to
-these words we can form nothing more than a symbolic conception
-of the illegitimate order. The idea of resistance
-cannot be separated in thought from the idea of an extended
-body which offers resistance. To suppose that central forces
-can reside in points not infinitesimally small but occupying
-no space whatever—points having position only, with nothing
-to mark their position—points in no respect distinguishable
-from the surrounding points that are not centres of force;—to
-suppose this, is utterly beyond human power.</p>
-
-<p class='c000'>Here it may possibly be said, that though all hypotheses
-respecting the constitution of Matter commit us to inconceivable
-conclusions when logically developed, yet we have
-reason to think that one of them corresponds with the fact.
-Though the conception of Matter as consisting of dense indivisible
-units, is symbolic and incapable of being completely
-thought out, it may yet be supposed to find indirect verification
-in the truths of chemistry. These, it is argued, necessitate
-the belief that Matter consists of particles of specific
-weights, and therefore of specific sizes. The general law of
-definite proportions seems impossible on any other condition
-than the existence of ultimate atoms; and though the combining
-<span class='pageno' id='Page_54'>54</span>weights of the respective elements are termed by
-chemists their “equivalents,” for the purpose of avoiding a
-questionable assumption, we are unable to think of the combination
-of such definite weights, without supposing it to take
-place between definite numbers of definite particles. And
-thus it would appear that the Newtonian view is at any rate
-preferable to that of Boscovich. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;A disciple of Boscovich,
-however, may reply that his master’s theory is involved
-in that of Newton; and cannot indeed be escaped.
-“What,” he may ask, “is it that holds together the parts
-of these ultimate atoms?”. “A cohesive force,” his opponent
-must answer. “And what,” he may continue, “is it
-that holds together the parts of any fragments into
-which, by sufficient force, an ultimate atom might be
-broken?” Again the answer must be—a cohesive force.
-“And what,” he may still ask, “if the ultimate atom were,
-as we can imagine it to be, reduced to parts as small in proportion
-to it, as it is in proportion to a tangible mass of
-matter—what must give each part the ability to sustain itself,
-and to occupy space?” Still there is no answer but—a cohesive
-force. Carry the process in thought as far as we may,
-until the extension of the parts is less than can be imagined,
-we still cannot escape the admission of forces by which the
-extension is upheld; and we can find no limit until we
-arrive at the conception of centres of force without any
-extension.</p>
-
-<p class='c000'>Matter then, in its ultimate nature, is as absolutely incomprehensible
-as Space and Time. Frame what suppositions we
-may, we find on tracing out their implications that they leave
-us nothing but a choice between opposite absurdities.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 17. A body impelled by the hand is clearly perceived to
-move, and to move in a definite direction: there seems at first
-sight no possibility of doubting that its motion is real, or that
-it is towards a given point. Yet it is easy to show that we
-not only may be, but usually are, quite wrong in both these
-<span class='pageno' id='Page_55'>55</span>judgments. Here, for instance, is a ship which, for simplicity’s
-sake, we will suppose to be anchored at the equator
-with her head to the West. When the captain walks from
-stem to stern, in what direction does he move? East is the
-obvious answer—an answer which for the moment may pass
-without criticism. But now the anchor is heaved, and the
-vessel sails to the West with a velocity equal to that at which
-the captain walks. In what direction does he now move
-when he goes from stem to stern? You cannot say East, for
-the vessel is carrying him as fast towards the West as he
-walks to the East; and you cannot say West for the converse
-reason. In respect to surrounding space he is stationary;
-though to all on board the ship he seems to be moving. But
-now are we quite sure of this conclusion?—Is he really stationary?
-When we take into account the Earth’s motion round
-its axis, we find that instead of being stationary he is travelling
-at the rate of 1000 miles per hour to the East; so that
-neither the perception of one who looks at him, nor the inference
-of one who allows for the ship’s motion, is anything like
-the truth. Nor indeed, on further consideration, shall we find
-this revised conclusion to be much better. For we have forgotten
-to allow for the Earth’s motion in its orbit. This
-being some 68,000 miles per hour, it follows that, assuming
-the time to be midday, he is moving, not at the rate of 1000
-miles per hour to the East, but at the rate of 67,000 miles per
-hour to the West. Nay, not even now have we discovered
-the true rate and the true direction of his movement. With
-the Earth’s progress in its orbit, we have to join that of the
-whole Solar system towards the constellation Hercules; and
-when we do this, we perceive that he is moving neither East
-nor West, but in a line inclined to the plane of the Ecliptic,
-and at a velocity greater or less (according to the time of the
-year) than that above named. To which let us add, that
-were the dynamic arrangements of our sidereal system fully
-known to us, we should probably discover the direction and
-rate of his actual movement to differ considerably even from
-<span class='pageno' id='Page_56'>56</span>these. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;How illusive are our ideas of Motion, is thus made
-sufficiently manifest. That which seems moving proves to be
-stationary; that which seems stationary proves to be moving;
-while that which we conclude to be going rapidly in one
-direction, turns out to be going much more rapidly in the
-opposite direction. And so we are taught that what we are
-conscious of is not the real motion of any object, either in its
-rate or direction; but merely its motion as measured from an
-assigned position—either the position we ourselves occupy or
-some other. Yet in this very process of concluding that the
-motions we perceive are not the real motions, we tacitly
-assume that there are real motions. In revising our successive
-judgments concerning a body’s course or velocity, we take
-for granted that there is an actual course and an actual
-velocity—we take for granted that there are fixed points in
-space with respect to which all motions are absolute; and we
-find it impossible to rid ourselves of this idea. Nevertheless,
-absolute motion cannot even be imagined, much less known.
-Motion as taking place apart from those limitations of space
-which we habitually associate with it, is totally unthinkable.
-For motion is change of place; but in unlimited space, change
-of place is inconceivable, because place itself is inconceivable.
-Place can be conceived only by reference to other places; and
-in the absence of objects dispersed through space, a place
-could be conceived only in relation to the limits of space;
-whence it follows that in unlimited space, place cannot be
-conceived—all places must be equidistant from boundaries
-that do not exist. Thus while we are obliged to think that
-there is an absolute motion, we find absolute motion incomprehensible.</p>
-
-<p class='c000'>Another insuperable difficulty presents itself when we
-contemplate the transfer of Motion. Habit blinds us to the
-marvelousness of this phenomenon. Familiar with the fact
-from childhood, we see nothing remarkable in the ability of a
-moving thing to generate movement in a thing that is
-stationary. It is, however, impossible to understand it. In
-<span class='pageno' id='Page_57'>57</span>what respect does a body after impact differ from itself before
-impact? What is this added to it which does not sensibly
-affect any of its properties and yet enables it to traverse
-space? Here is an object at rest and here is the same object
-moving. In the one state it has no tendency to change its
-place; but in the other it is obliged at each instant to assume
-a new position. What is it which will for ever go on producing
-this effect without being exhausted? and how does it
-dwell in the object? The motion you say has been communicated.
-But how?—What has been communicated?
-The striking body has not transferred a <em>thing</em> to the body
-struck; and it is equally out of the question to say that it
-has transferred an <em>attribute</em>. What then has it transferred?</p>
-
-<p class='c000'>Once more there is the old puzzle concerning the connexion
-between Motion and Rest. We daily witness the gradual
-retardation and final stoppage of things projected from the
-hand or otherwise impelled; and we equally often witness
-the change from Rest to Motion produced by the application
-of force. But truly to represent these transitions in thought,
-we find impossible. For a breach of the law of continuity
-seems necessarily involved; and yet no breach of it is conceivable.
-A body travelling at a given velocity cannot be
-brought to a state of rest, or no velocity, without passing
-through all intermediate velocities. At first sight nothing
-seems easier than to imagine it doing this. It is quite possible
-to think of its motion as diminishing insensibly until
-it becomes infinitesimal; and many will think equally possible
-to pass in thought from infinitesimal motion to no
-motion. But this is an error. Mentally follow out the
-decreasing velocity as long as you please, and there still
-remains <em>some</em> velocity. Halve and again halve the rate of
-movement for ever, yet movement still exists; and the smallest
-movement is separated by an impassable gap from no
-movement. As something, however minute, is infinitely
-great in comparison with nothing; so is even the least conceivable
-motion, infinite as compared with rest. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The
-<span class='pageno' id='Page_58'>58</span>converse perplexities attendant on the transition from Rest to
-Motion, need not be specified. These, equally with the foregoing,
-show us that though we are obliged to think of such
-changes as actually occurring, their occurrence cannot be
-realized.</p>
-
-<p class='c000'>Thus neither when considered in connexion with Space,
-nor when considered in connexion with Matter, nor when
-considered in connexion with Rest, do we find that Motion is
-truly cognizable. All efforts to understand its essential
-nature do but bring us to alternative impossibilities of
-thought.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 18. On lifting a chair, the force exerted we regard as
-equal to that antagonistic force called the weight of the
-chair; and we cannot think of these as equal without thinking
-of them as like in kind; since equality is conceivable only
-between things that are connatural. The axiom that action
-and reaction are equal and in opposite directions, commonly
-exemplified by this very instance of muscular effort <i><span lang="la" xml:lang="la">versus</span></i>
-weight, cannot be mentally realized on any other condition.
-Yet, contrariwise, it is incredible that the force as existing in
-the chair really resembles the force as present to our minds.
-It scarcely needs to point out that the weight of the chair
-produces in us various feelings according as we support it by a
-single finger, or the whole hand, or the leg; and hence
-to argue that as it cannot be like all these sensations there is
-no reason to believe it like any. It suffices to remark that
-since the force as known to us is an affection of consciousness,
-we cannot conceive the force existing in the chair under the
-same form without endowing the chair with consciousness.
-So that it is absurd to think of Force as in itself like our
-sensation of it, and yet necessary so to think of it if we
-realize it in consciousness at all.</p>
-
-<p class='c000'>How, again, can we understand the connexion between
-Force and Matter? Matter is known to us only through its
-manifestations of Force: our ultimate test of Matter is the
-<span class='pageno' id='Page_59'>59</span>ability to resist: abstract its resistance and there remains
-nothing but empty extension. Yet, on the other hand, resistance
-is equally unthinkable apart from Matter—apart from
-something extended. Not only, as pointed out some pages
-back, are centres of force devoid of extension unimaginable;
-but, as an inevitable corollary, we cannot imagine either
-extended or unextended centres of force to attract and repel
-other such centres at a distance, without the intermediation
-of some kind of matter. We have here to remark, what
-could not without anticipation be remarked when treating of
-Matter, that the hypothesis of Newton, equally with that of
-Boscovich, is open to the charge that it supposes one thing to
-act upon another through a space which is absolutely empty—a
-supposition which cannot be represented in thought.
-This charge is indeed met by the introduction of a hypothetical
-fluid existing between the atoms or centres. But the
-problem is not thus solved: it is simply shifted, and re-appears
-when the constitution of this fluid is inquired into. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;How
-impossible it is to elude the difficulty presented by the transfer
-of Force through space, is best seen in the case of astronomical
-forces. The Sim acts upon us in such way as to produce the
-sensations of light and heat; and we have ascertained that
-between the cause as existing in the Sun, and the effect as
-experienced on the Earth, a lapse of about eight minutes
-occurs: whence unavoidably result in us, the conceptions of
-both a force and a motion. So that for the assumption of a
-luminiferous ether, there is the defence, not only that the
-exercise of force through 95,000,000 of miles of absolute
-vacuum is inconceivable, but also that it is impossible to conceive
-motion in the absence of something moved. Similarly
-in the case of gravitation. Newton described himself as
-unable to think that the attraction of one body for another at
-a distance, could be exerted in the absence of an intervening
-medium. But now let us ask how much the forwarder we
-are if an intervening medium be assumed. This ether whose
-undulations according to the received hypothesis constitute
-<span class='pageno' id='Page_60'>60</span>heat and light, and which is the vehicle of gravitation—how
-is it constituted? We must regard it, in the way that physicists
-do regard it, as composed of atoms which attract and
-repel each other—infinitesimal it may be in comparison with
-those of ordinary matter, but still atoms. And remembering
-that this ether is imponderable, we are obliged to conclude
-that the ratio between the interspaces of these atoms and the
-atoms themselves, is incommensurably greater than the like
-ratio in ponderable matter; else the densities could not be
-incommensurable. Instead then of a direct action by the Sun
-upon the Earth without anything intervening, we have to
-conceive the Sun’s action propagated through a medium
-whose molecules are probably as small relatively to their interspaces
-as are the Sun and Earth compared with the space
-between them: we have to conceive these infinitesimal molecules
-acting on each other through absolutely vacant spaces
-which are immense in comparison with their own dimensions.
-How is this conception easier than the other? We still have
-mentally to represent a body as acting where it is not, and in
-the absence of anything by which its action may be transferred;
-and what matters it whether this takes place on a large
-or a small scale? &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;We see therefore that the exercise of
-Force is altogether unintelligible. We cannot imagine it
-except through the instrumentality of something having
-extension; and yet when we have assumed this something,
-we find the perplexity is not got rid of but only postponed.
-We are obliged to conclude that matter, whether ponderable
-or imponderable, and whether aggregated or in its hypothetical
-units, acts upon matter through absolutely vacant space;
-and yet this conclusion is positively unthinkable.</p>
-
-<p class='c000'>Again, Light, Heat, Gravitation and all central forces, vary
-inversely as the squares of the distances; and physicists in
-their investigations assume that the units of matter act upon
-each other according to the same law—an assumption which
-indeed they are obliged to make; since this law is not simply
-an empirical one, but one deducible mathematically from the
-<span class='pageno' id='Page_61'>61</span>relations of space—one of which the negation is inconceivable.
-But now, in any mass of matter which is in internal equilibrium,
-what must follow? The attractions and repulsions of
-the constituent atoms are balanced. Being balanced, the
-atoms remain at their present distances; and the mass of
-matter neither expands nor contracts. But if the forces
-with which two adjacent atoms attract and repel each other
-both vary inversely as the squares of the distances, as they
-must; and if they are in equilibrium at their present distances,
-as they are; then, necessarily, they will be in equilibrium at all
-other distances. Let the atoms be twice as far apart, and
-their attractions and repulsions will both be reduced to one
-fourth of their present amounts. Let them be brought
-within half the distance, and their attractions and repulsions
-will both be quadrupled. Whence it follows that this matter
-will as readily as not assume any other density; and can
-offer no resistance to any external agents. Thus we are
-obliged to say that these antagonist molecular forces do not
-both vary inversely as the squares of the distances, which is
-unthinkable; or else that matter does not possess that attribute
-of resistance by which alone we distinguish it from
-empty space, which is absurd.</p>
-
-<p class='c000'>While then it is impossible to form any idea of Force
-in itself, it is equally impossible to comprehend either its
-mode of exercise or its law of variation.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 19. Turning now from the outer to the inner world, let
-us contemplate, not the agencies to which we ascribe our
-subjective modifications, but the subjective modifications
-themselves. These constitute a series. Difficult as we find
-it distinctly to separate and individualize them, it is nevertheless
-beyond question that our states of consciousness occur in
-succession.</p>
-
-<p class='c000'>Is this chain of states of consciousness infinite or finite?
-We cannot say infinite; not only because we have indirectly
-reached the conclusion that there was a period when it commenced,
-<span class='pageno' id='Page_62'>62</span>but also because all infinity is inconceivable—an
-infinite series included. We cannot say finite; for we have
-no knowledge of either of its ends. Go back in memory as
-far as we may, we are wholly unable to identify our first
-states of consciousness: the perspective of our thoughts
-vanishes in a dim obscurity where we can make out nothing.
-Similarly at the other extreme. We have no immediate
-knowledge of a termination to the series at a future time; and
-we cannot really lay hold of that temporary termination of
-the series reached at the present moment. For the state of
-consciousness recognized by us as our last, is not truly our
-last. That any mental affection may be contemplated as one
-of the series, it must be remembered—<em>represented</em> in thought,
-not <em>presented</em>. The truly last state of consciousness is that
-which is passing in the very act of contemplating a state
-just past—that in which we are thinking of the one before as
-the last. So that the proximate end of the chain eludes us,
-as well as the remote end.</p>
-
-<p class='c000'>“But,” it may be said, “though we cannot directly <em>know</em>
-consciousness to be finite in duration, because neither of its
-limits can be actually reached; yet we can very well <em>conceive</em>
-it to be so.” No: not even this is true. In the first place,
-we cannot <em>con</em>ceive the terminations of that consciousness
-which alone we really know—our own—any more than we
-can <em>per</em>ceive its terminations. For in truth the two acts are
-here one. In either case such terminations must be, as above
-said, not presented in thought, but represented; and they
-must be represented as in the act of occurring. Now to
-represent the termination of consciousness as occurring
-in ourselves, is to think of ourselves as contemplating the
-cessation of the last state of consciousness; and this implies
-a supposed continuance of consciousness after its last
-state, which is absurd. In the second place, if we regard
-the matter objectively—if we study the phenomena as
-occurring in others, or in the abstract, we are equally foiled.
-Consciousness implies perpetual change and the perpetual
-<span class='pageno' id='Page_63'>63</span>establishment of relations between its successive phases. To
-be known at all, any mental affection must be known as such or
-such—as like these foregoing ones or unlike those: if it is not
-thought of in connexion with others—not distinguished or
-identified by comparison with others, it is not recognized—is
-not a state of consciousness at all. A last state of consciousness,
-then, like any other, can exist only through a perception
-of its relations to previous states. But such perception of
-its relations must constitute a state later than the last, which
-is a contradiction. Or to put the difficulty in another form:—If
-ceaseless change of state is the condition on which alone
-consciousness exists, then when the supposed last state
-has been reached by the completion of the preceding change,
-change has ceased; therefore consciousness has ceased; therefore
-the supposed last state is not a state of consciousness at
-all; therefore there can be no last state of consciousness. In
-short, the perplexity is like that presented by the relations of
-Motion and Rest. As we found it was impossible really to
-conceive Rest becoming Motion or Motion becoming Rest; so
-here we find it is impossible really to conceive either the
-beginning or the ending of those changes which constitute
-consciousness.</p>
-
-<p class='c000'>Hence, while we are unable either to believe or to conceive
-that the duration of consciousness is infinite, we are equally
-unable either to know it as finite, or to conceive it as finite.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 20. Nor do we meet with any greater success when, instead
-of the extent of consciousness, we consider its substance.
-The question—What is this that thinks? admits of no better
-solution than the question to which we have just found none
-but inconceivable answers.</p>
-
-<p class='c000'>The existence of each individual as known to himself, has
-been always held by mankind at large, the most incontrovertible
-of truths. To say—“I am as sure of it as I am sure
-that I exist,” is, in common speech, the most emphatic expression
-of certainty. And this fact of personal existence,
-<span class='pageno' id='Page_64'>64</span>testified to by the universal consciousness of men, has been
-made the basis of sundry philosophies; whence may be drawn
-the inference, that it is held by thinkers, as well as by the
-vulgar, to be beyond all facts unquestionable.</p>
-
-<p class='c000'>Belief in the reality of self, is, indeed, a belief which no
-hypothesis enables us to escape. What shall we say of these
-successive impressions and ideas which constitute consciousness?
-Shall we say that they are the affections of something
-called mind, which, as being the subject of them, is the real
-<em>ego</em>? If we say this, we manifestly imply that the <em>ego</em> is an
-entity. Shall we assert that these impressions and ideas are not
-the mere superficial changes wrought on some thinking substance,
-but are themselves the very body of this substance—are
-severally the modified forms which it from moment to
-moment assumes? This hypothesis, equally with the foregoing,
-implies that the individual exists as a permanent and
-distinct being; since modifications necessarily involve something
-modified. Shall we then betake ourselves to the sceptic’s
-position, and argue that we know nothing more than our impressions
-and ideas themselves—that these are to us the only
-existences; and that the personality said to underlie them is a
-mere fiction? We do not even thus escape; since this proposition,
-verbally intelligible but really unthinkable, itself
-makes the assumption which it professes to repudiate. For
-how can consciousness be wholly resolved into impressions and
-ideas, when an impression of necessity implies something impressed?
-Or again, how can the sceptic who has decomposed
-his consciousness into impressions and ideas, explain the fact
-that he considers them as <em>his</em> impressions and ideas? Or
-once more, if, as he must, he admits that he has an impression
-of his personal existence, what warrant can he show for rejecting
-this impression as unreal while he accepts all his other
-impressions as real? Unless he can give satisfactory answers
-to these queries, which he cannot, he must abandon his conclusions;
-and must admit the reality of the individual mind.</p>
-
-<p class='c000'>But now, unavoidable as is this belief—established though
-<span class='pageno' id='Page_65'>65</span>it is, not only by the assent of mankind at large, endorsed by
-divers philosophers, but by the suicide of the sceptical argument—it
-is yet a belief admitting of no justification by reason:
-nay, indeed, it is a belief which reason, when pressed for a
-distinct answer, rejects. One of the most recent writers who
-has touched upon this question—Mr Mansel—does indeed
-contend that in the consciousness of self, we have a piece of
-real knowledge. The validity of immediate intuition he
-holds in this case unquestionable: remarking that “let
-system-makers say what they will, the unsophisticated sense
-of mankind refuses to acknowledge that mind is but a bundle
-of states of consciousness, as matter is (possibly) a bundle of
-sensible qualities.” On which position the obvious comment
-is, that it does not seem altogether a consistent one for a
-Kantist, who pays but small respect to “the unsophisticated
-sense of mankind” when it testifies to the objectivity of space.
-Passing over this, however, it may readily be shown that a
-cognition of self, properly so called, is absolutely negatived
-by the laws of thought. The fundamental condition to all
-consciousness, emphatically insisted upon by Mr Mansel in
-common with Sir William Hamilton and others, is the antithesis
-of subject and object. And on this “primitive dualism
-of consciousness,” “from which the explanations of philosophy
-must take their start,” Mr Mansel founds his refutation of the
-German absolutists. But now, what is the corollary from this
-doctrine, as bearing on the consciousness of self? The mental
-act in which self is known, implies, like every other mental
-act, a perceiving subject and a perceived object. If, then, the
-object perceived is self, what is the subject that perceives? or
-if it is the true self which thinks, what other self can it be
-that is thought of? Clearly, a true cognition of self implies
-a state in which the knowing and the known are one—in
-which subject and object are identified; and this Mr Mansel
-rightly holds to be the annihilation of both.</p>
-
-<p class='c000'>So that the personality of which each is conscious, and of
-which the existence is to each a fact beyond all others the most
-<span class='pageno' id='Page_66'>66</span>certain, is yet a thing which cannot truly be known at all:
-knowledge of it is forbidden by the very nature of thought.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 21. Ultimate Scientific Ideas, then, are all representative
-of realities that cannot be comprehended. After no matter
-how great a progress in the colligation of facts and the establishment
-of generalizations ever wider and wider—after the
-merging of limited and derivative truths in truths that are
-larger and deeper has been carried no matter how far; the
-fundamental truth remains as much beyond reach as ever. The
-explanation of that which is explicable, does but bring out
-into greater clearness the inexplicableness of that which remains
-behind. Alike in the external and the internal worlds,
-the man of science sees himself in the midst of perpetual changes
-of which he can discover neither the beginning nor the end.
-If, tracing back the evolution of things, he allows himself to
-entertain the hypothesis that the Universe once existed in a
-diffused form, he finds it utterly impossible to conceive how
-this came to be so; and equally, if he speculates on the
-future, he can assign no limit to the grand succession of phenomena
-ever unfolding themselves before him. In like
-manner if he looks inward, he perceives that both ends of the
-thread of consciousness are beyond his grasp; nay, even
-beyond his power to think of as having existed or as existing
-in time to come. When, again, he turns from the succession of
-phenomena, external or internal, to their intrinsic nature, he
-is just as much at fault. Supposing him in every case able to
-resolve the appearances, properties, and movements of things,
-into manifestations of Force in Space and Time; he still finds
-that Force, Space, and Time pass all understanding. Similarly,
-though the analysis of mental actions may finally bring
-him down to sensations, as the original materials out of which
-all thought is woven, yet he is little forwarder; for he can
-give no account either of sensations themselves or of that
-something which is conscious of sensations. Objective and
-subjective things he thus ascertains to be alike inscrutable in
-<span class='pageno' id='Page_67'>67</span>their substance and genesis. In all directions his investigations
-eventually bring him face to face with an insoluble
-enigma; and he ever more clearly perceives it to be an insoluble
-enigma. He learns at once the greatness and the littleness of
-the human intellect—its power in dealing with all that comes
-within the range of experience; its impotence in dealing
-with all that transcends experience. He realizes with a
-special vividness the utter incomprehensibleness of the simplest
-fact, considered in itself. He, more than any other, truly
-<em>knows</em> that in its ultimate essence nothing can be known.</p>
-
-<div>
- <span class='pageno' id='Page_68'>68</span>
- <h3 class='c001'>CHAPTER IV.<br /> <span class='large'>THE RELATIVITY OF ALL KNOWLEDGE.</span></h3>
-</div>
-
-<p class='c006'>§ 22. The same conclusion is thus arrived at, from whichever
-point we set out. If, respecting the origin and nature
-of things, we make some assumption, we find that through an
-inexorable logic it inevitably commits us to alternative impossibilities
-of thought; and this holds true of every assumption
-that can be imagined. If, contrariwise, we make no assumption,
-but set out from the sensible properties of surrounding
-objects, and, ascertaining their special laws of dependence, go
-on to merge these in laws more and more general, until we
-bring them all under some most general laws; we still find ourselves
-as far as ever from knowing what it is which manifests
-these properties to us: clearly as we seem to know it, our
-apparent knowledge proves on examination to be utterly irreconcilable
-with itself. Ultimate religious ideas and ultimate
-scientific ideas, alike turn out to be merely symbols of the
-actual, not cognitions of it.</p>
-
-<p class='c000'>The conviction, so reached, that human intelligence is
-incapable of absolute knowledge, is one that has been slowly
-gaining ground as civilization has advanced. Each new
-ontological theory, from time to time propounded in lieu of
-previous ones shown to be untenable, has been followed by a
-new criticism leading to a new scepticism. All possible conceptions
-have been one by one tried and found wanting; and
-<span class='pageno' id='Page_69'>69</span>so the entire field of speculation has been gradually exhausted
-without positive result: the only result arrived at being
-the negative one above stated—that the reality existing
-behind all appearances is, and must ever be, unknown. To
-this conclusion almost every thinker of note has subscribed.
-“With the exception,” says Sir William Hamilton, “of a few
-late Absolutist theorisers in Germany, this is, perhaps, the
-truth of all others most harmoniously re-echoed by every
-philosopher of every school.” And among these he names—Protagoras,
-Aristotle, St. Augustin, Boethius, Averroes,
-Albertus Magnus, Gerson, Leo Hebræus, Melancthon, Scaliger,
-Francis Piccolomini, Giordano Bruno, Campanella,
-Bacon, Spinoza, Newton, Kant.</p>
-
-<p class='c000'>It yet remains to point out how this belief may be established
-rationally, as well as empirically. Not only is it that,
-as in the earlier thinkers above named, a vague perception of
-the inscrutableness of things in themselves results from discovering
-the illusiveness of sense-impressions; and not only
-is it that, as shown in the foregoing chapters, definite experiments
-evolve alternative impossibilities of thought out of
-every ultimate conception we can frame; but it is that the
-relativity of our knowledge is demonstrable analytically.
-The induction drawn from general and special experiences,
-may be confirmed by a deduction from the nature of our
-intelligence. Two ways of reaching such a deduction exist.
-Proof that our cognitions are not, and never can be, absolute,
-is obtainable by analyzing either the <em>product</em> of thought, or
-the <em>process</em> of thought. Let us analyze each.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 23. If, when walking through the fields some day in
-September, you hear a rustle a few yards in advance, and
-on observing the ditch-side where it occurs, see the herbage
-agitated, you will probably turn towards the spot to learn by
-what this sound and motion are produced. As you approach
-there flutters into the ditch, a partridge; on seeing which
-<span class='pageno' id='Page_70'>70</span>your curiosity is satisfied—you have what you call an <em>explanation</em>
-of the appearances. The explanation, mark, amounts
-to this; that whereas throughout life you have had countless
-experiences of disturbance among small stationary bodies,
-accompanying the movement of other bodies among them,
-and have generalized the relation between such disturbances
-and such movements, you consider this particular disturbance
-explained, on finding it to present, an instance of the like
-relation. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Suppose you catch the partridge; and, wishing
-to ascertain why it did not escape, examine it, and find
-at one spot, a slight trace of blood upon its feathers. You
-now <em>understand</em>, as you say, what has disabled the partridge.
-It has been wounded by a sportsman—adds another case to
-the many cases already seen by you, of birds being killed or
-injured by the shot discharged at them from fowling-pieces.
-And in assimilating this case to other such cases, consists
-your understanding of it. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;But now, on consideration, a
-difficulty suggests itself. Only a single shot has struck the
-partridge, and that not in a vital place: the wings are uninjured,
-as are also those muscles which move them; and the
-creature proves by its struggles that it has abundant strength.
-Why then, you inquire of yourself, does it not fly? Occasion
-favouring, you put the question to an anatomist, who furnishes
-you with <em>a solution</em>. He points out that this solitary
-shot has passed close to the place at which the nerve supplying
-the wing-muscles of one side, diverges from the spine; and that
-a slight injury to this nerve, extending even to the rupture of
-a few fibres, may, by preventing a perfect co-ordination in the
-actions of the two wings, destroy the power of flight. You are
-no longer puzzled. But what has happened?—what has
-changed your state from one of perplexity to one of <em>comprehension</em>?
-Simply the disclosure of a class of previously
-known cases, along with which you can include this case.
-The connexion between lesions of the nervous system and
-paralysis of limbs has been already many times brought
-<span class='pageno' id='Page_71'>71</span>under your notice; and you here find a relation of cause and
-effect that is essentially similar.</p>
-
-<p class='c000'>Let us suppose you are led on to make further inquiries
-concerning organic actions, which, conspicuous and remarkable
-as they are, you had not before cared to understand. How
-is respiration effected? you ask—why does air periodically
-rush into the lungs? The answer is that in the higher vertebrata,
-as in ourselves, influx of air is caused by an enlargement
-of the thoracic cavity, due, partly to depression of the
-diaphragm, partly to elevation of the ribs. But how does
-elevation of the ribs enlarge the cavity? In reply the
-anatomist shows you that the plane of each pair of ribs
-makes an acute angle with the spine; that this angle widens
-when the moveable ends of the ribs are raised; and he makes
-you realize the consequent dilatation of the cavity, by pointing
-out how the area of a parallelogram increases as its angles
-approach to right angles—you understand this special fact
-when you see it to be an instance of a general geometrical
-fact. There still arises, however, the question—why does the
-air rush into this enlarged cavity? To which comes the
-answer that, when the thoracic cavity is enlarged, the contained
-air, partially relieved from pressure, expands, and so loses
-some of its resisting power; that hence it opposes to the pressure
-of the external air a less pressure; and that as air, like
-every other fluid, presses equally in all directions, motion must
-result along any line in which the resistance is less than
-elsewhere; whence follows an inward current. And this
-<em>interpretation</em> you recognize as one, when a few facts of like
-kind, exhibited more plainly in a visible fluid such as water,
-are cited in illustration. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Again, when it was pointed out
-that the limbs are compound levers acting in essentially the
-same way as levers of iron or wood, you might consider yourself
-as having obtained a partial <em>rationale</em> of animal movements.
-The contraction of a muscle, seeming before utterly
-unaccountable, would seem less unaccountable were you shown
-<span class='pageno' id='Page_72'>72</span>how, by a galvanic current, a series of soft iron magnets could
-be made to shorten itself, through the attraction of each
-magnet for its neighbours:—an alleged analogy which
-especially answers the purpose of our argument; since,
-whether real or fancied, it equally illustrates the mental
-illumination that results on finding a class of cases within
-which a particular case may possibly be included. And it
-may be further noted how, in the instance here named, an additional
-feeling of comprehension arises on remembering that
-the influence conveyed through the nerves to the muscles, is,
-though not positively electric, yet a form of force nearly
-allied to the electric. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Similarly when you learn that
-animal heat arises from chemical combination, and so is
-evolved as heat is evolved in other chemical combinations—when
-you learn that the absorption of nutrient fluids through
-the coats of the intestines, is an instance of osmotic action—when
-you learn that the changes undergone by food during
-digestion, are like changes artificially producible in the laboratory;
-you regard yourself as <em>knowing</em> something about the
-natures of these phenomena.</p>
-
-<p class='c000'>Observe now what we have been doing. Turning to the
-general question, let us note where these successive interpretations
-have carried us. We began with quite special and
-concrete facts. In explaining each, and afterwards explaining
-the more general facts of which they are instances, we
-have got down to certain highly general facts:—to a geometrical
-principle or property of space, to a simple law of mechanical
-action, to a law of fluid equilibrium—to truths in
-physics, in chemistry, in thermology, in electricity. The
-particular phenomena with which we set out, have been
-merged in larger and larger groups of phenomena; and as
-they have been so merged, we have arrived at solutions that
-we consider profound in proportion as this process has been
-carried far. Still deeper explanations are simply further
-steps in the same direction. When, for instance, it is asked
-<span class='pageno' id='Page_73'>73</span>why the law of action of the lever is what it is, or why fluid
-equilibrium and fluid motion exhibit the relations which they
-do, the answer furnished by mathematicians consists in the
-disclosure of the principle of virtual velocities—a principle
-holding true alike in fluids and solids—a principle under
-which the others are comprehended. And similarly, the insight
-obtained into the phenomena of chemical combination,
-heat, electricity, &amp;c., implies that a rationale of them, when
-found, will be the exposition of some highly general fact respecting
-the constitution of matter, of which chemical,
-electrical, and thermal facts, are merely different manifestations.</p>
-
-<p class='c000'>Is this process limited or unlimited? Can we go on for
-ever explaining classes of facts by including them in larger
-classes; or must we eventually come to a largest class? The
-supposition that the process is unlimited, were any one absurd
-enough to espouse it, would still imply that an ultimate
-explanation could not be reached; since infinite time would
-be required to reach it. While the unavoidable conclusion
-that it is limited (proved not only by the finite sphere of
-observation open to us, but also by the diminution in the
-number of generalizations that necessarily accompanies increase
-of their breadth) equally implies that the ultimate
-fact cannot be understood. For if the successively deeper interpretations
-of nature which constitute advancing knowledge,
-are merely successive inclusions of special truths in general
-truths, and of general truths in truths still more general; it
-obviously follows that the most general truth, not admitting
-of inclusion in any other, does not admit of interpretation.
-Manifestly, as the <em>most</em> general cognition at which we arrive
-cannot be reduced to a <em>more</em> general one, it cannot be understood.
-Of necessity, therefore, explanation must eventually
-bring us down to the inexplicable. The deepest truth which
-we can get at, must be unaccountable. Comprehension must
-become something other than comprehension, before the ultimate
-fact can be comprehended.</p>
-
-<hr class='c013' />
-
-<p class='c000'><span class='pageno' id='Page_74'>74</span>§ 24. The inference which we thus find forced upon us
-when we analyze the product of thought, as exhibited objectively
-in scientific generalizations, is equally forced upon us
-by an analysis of the process of thought, as exhibited subjectively
-in consciousness. The demonstration of the necessarily
-relative character of our knowledge, as deduced from
-the nature of intelligence, has been brought to its most
-definite shape by Sir William Hamilton. I cannot here do
-better than extract from his essay on the “Philosophy of
-the Unconditioned,” the passage containing the substance of
-his doctrine.</p>
-
-<p class='c000'>“The mind can conceive,” he argues, “and consequently
-can know,” only the <em>limited, and the conditionally limited</em>. The
-unconditionally unlimited, or the <em>Infinite</em>, the unconditionally
-limited, or the <em>Absolute</em>, cannot positively be construed to
-the mind; they can be conceived, only by a thinking away
-from, or abstraction of, those very conditions under which
-thought itself is realized; consequently, the notion of the
-Unconditioned is only negative,—negative of the conceivable
-itself. For example, on the one hand we can positively conceive,
-neither an absolute whole, that is, a whole so great, that we
-cannot also conceive it as a relative part of a still greater
-whole; nor an absolute part, that is, a part so small, that we
-cannot also conceive it as a relative whole, divisible into smaller
-parts. On the other hand, we cannot positively represent, or
-realize, or construe to the mind (as here understanding and
-imagination coincide), an infinite whole, for this could only
-be done by the infinite synthesis in thought of finite wholes,
-which would itself require an infinite time for its accomplishment;
-nor, for the same reason, can we follow out in thought
-an infinite divisibility of parts. The result is the same,
-whether we apply the process to limitation in <em>space</em>, in <em>time</em>,
-or in <em>degree</em>. The unconditional negation, and the unconditional
-affirmation of limitation; in other words, the <em>infinite</em>
-and <em>absolute, properly so called</em>, are thus equally inconceivable
-to us.</p>
-
-<p class='c000'><span class='pageno' id='Page_75'>75</span>As the conditionally limited (which we may briefly call
-the <em>conditioned</em>) is thus the only possible object of knowledge
-and of positive thought—thought necessarily supposes conditions.
-To <em>think</em> is to <em>condition</em>; and conditional limitation is
-the fundamental law of the possibility of thought. For, as
-the greyhound cannot outstrip his shadow, nor (by a more
-appropriate simile) the eagle outsoar the atmosphere in which
-he floats, and by which alone he may be supported; so the
-mind cannot transcend that sphere of limitation, within and
-through which exclusively the possibility of thought is
-realized. Thought is only of the conditioned; because, as we
-have said, to think is simply to condition. The <em>absolute</em> is
-conceived merely by a negation of conceivability; and all
-that we know, is only known as</p>
-
-<div class='lg-container-b c022'>
- <div class='linegroup'>
- <div class='group'>
- <div class='line'>——‘won from the void and formless <em>infinite</em>.’</div>
- </div>
- </div>
-</div>
-
-<p class='c000'>How, indeed, it could ever be doubted that thought is only of
-the conditioned, may well be deemed a matter of the profoundest
-admiration. Thought cannot transcend consciousness; consciousness
-is only possible under the antithesis of a subject
-and object of thought, known only in correlation, and mutually
-limiting each other; while, independently of this, all that we
-know either of subject or object, either of mind or matter, is
-only a knowledge in each of the particular, of the plural, of
-the different, of the modified, of the phenomenal. We admit
-that the consequence of this doctrine is,—that philosophy, if
-viewed as more than a science of the conditioned, is impossible.
-Departing from the particular, we admit, that we can
-never, in our highest generalizations, rise above the finite;
-that our knowledge, whether of mind or matter, can be
-nothing more than a knowledge of the relative manifestations
-of an existence, which in itself it is our highest wisdom to
-recognize as beyond the reach of philosophy,—in the language
-of St Austin,—‘<i><span lang="la" xml:lang="la">cognoscendo ignorari, et ignorando cognosci</span></i>.’</p>
-
-<p class='c000'>“The conditioned is the mean between two extremes,—two
-<span class='pageno' id='Page_76'>76</span>inconditionates, exclusive of each other, neither of which <em>can
-be conceived as possible</em>, but of which, on the principles of contradiction
-and excluded middle, one <em>must be admitted as
-necessary</em>. On this opinion, therefore, reason is shown to
-be weak, but not deceitful. The mind is not represented as
-conceiving two propositions subversive of each other, as
-equally possible; but only, as unable to understand as possible,
-either of two extremes; one of which, however, on
-the ground of their mutual repugnance, it is compelled
-to recognize as true. We are thus taught the salutary
-lesson, that the capacity of thought is not to be constituted
-into the measure of existence; and are warned from recognizing
-the domain of our knowledge as necessarily co-extensive
-with the horizon of our faith. And by a wonderful revelation,
-we are thus, in the very consciousness of our inability to
-conceive aught above the relative and finite, inspired with a
-belief in the existence of something unconditioned beyond the
-sphere of all comprehensible reality.”</p>
-
-<p class='c000'>Clear and conclusive as this statement of the case appears
-when carefully studied, it is expressed in so abstract a
-manner as to be not very intelligible to the general reader.
-A more popular presentation of it, with illustrative applications,
-as given by Mr Mansel in his “Limits of Religious
-Thought,” will make it more fully understood. The following
-extracts, which I take the liberty of making from his
-pages, will suffice.</p>
-
-<p class='c000'>“The very conception of consciousness, in whatever mode
-it may be manifested, necessarily implies <em>distinction between
-one object and another</em>. To be conscious, we must be conscious
-of something; and that something can only be known, as
-that which it is, by being distinguished from that which it is
-not. But distinction is necessarily limitation; for, if one
-object is to be distinguished from another, it must possess
-some form of existence which the other has not, or it must
-not possess some form which the other has. But it is obvious
-<span class='pageno' id='Page_77'>77</span>the Infinite cannot be distinguished, as such, from the Finite,
-by the absence of any quality which the Finite possesses; for
-such absence would be a limitation. Nor yet can it be distinguished
-by the presence of an attribute which the Finite
-has not; for, as no finite part can be a constituent of an
-infinite whole, this differential characteristic must itself be
-infinite; and must at the same time have nothing in common
-with the finite. We are thus thrown back upon our former
-impossibility; for this second infinite will be distinguished
-from the finite by the absence of qualities which the latter
-possesses. A consciousness of the Infinite as such thus necessarily
-involves a self-contradiction; for it implies the recognition,
-by limitation and difference, of that which can only be
-given as unlimited and indifferent. *&nbsp;*&nbsp;*</p>
-
-<p class='c000'>“This contradiction, which is utterly inexplicable on the
-supposition that the infinite is a positive object of human
-thought, is at once accounted for, when it is regarded as the
-mere negation of thought. If all thought is limitation;—if
-whatever we conceive is, by the very act of conception,
-regarded as finite,—<em>the infinite</em>, from a human point of view,
-is merely a name for the absence of those conditions under
-which thought is possible. To speak of a <em>Conception of the
-Infinite</em> is, therefore, at once to affirm those conditions and to
-deny them. The contradiction, which we discover in such a
-conception, is only that which we have ourselves placed there,
-by tacitly assuming the conceivability of the inconceivable.
-The condition of consciousness is distinction; and condition
-of distinction is limitation. We can have no consciousness of
-Being in general which is not some Being in particular: a
-<em>thing</em>, in consciousness, is one thing out of many. In assuming
-the possibility of an infinite object of consciousness, I
-assume, therefore, that it is at the same time limited and
-unlimited;—actually something, without which it could not
-be an object of consciousness, and actually nothing, without
-which it could not be infinite. *&nbsp;*&nbsp;*</p>
-
-<p class='c000'>“A second characteristic of Consciousness is, that it is only
-<span class='pageno' id='Page_78'>78</span>possible in the form of a <em>relation</em>. There must be a Subject,
-or person conscious, and an Object, or thing of which he is
-conscious. There can be no consciousness without the
-union of these two factors; and, in that union, each exists
-only as it is related to the other. The subject is a subject,
-only in so far as it is conscious of an object: the object is an
-object, only in so far as it is apprehended by a subject: and
-the destruction of either is the destruction of consciousness
-itself. It is thus manifest that a consciousness of the Absolute
-is equally self-contradictory with that of the Infinite.
-To be conscious of the Absolute as such, we must know that
-an object, which is given in relation to our consciousness, is
-identical with one which exists in its own nature, out of all
-relation to consciousness. But to know this identity, we
-must be able to compare the two together; and such a comparison
-is itself a contradiction. We are in fact required to
-compare that of which we are conscious with that of which
-we are not conscious; the comparison itself being an act of
-consciousness, and only possible through the consciousness of
-both its objects. It is thus manifest that, even if we could
-be conscious of the absolute, we could not possibly know that
-it is the absolute: and, as we can be conscious of an object as
-such, only by knowing it to be what it is, this is equivalent
-to an admission that we cannot be conscious of the absolute
-at all. As an object of consciousness, every thing is necessarily
-relative; and what a thing may be out of consciousness,
-no mode of consciousness can tell us.</p>
-
-<p class='c000'>“This contradiction, again, admits of the same explanation
-as the former. Our whole notion of existence is necessarily
-relative; for it is existence as conceived by us. But <em>Existence</em>,
-as we conceive it, is but a name for the several ways in which
-objects are presented to our consciousness,—a general term,
-embracing a variety of relations. <em>The Absolute</em>, on the other
-hand, is a term expressing no object of thought, but only a
-denial of the relation by which thought is constituted. To
-assume absolute existence as an object of thought, is thus to
-<span class='pageno' id='Page_79'>79</span>suppose a relation existing when the related terms exist no
-longer. An object of thought exists, as such, in and through
-its relation to a thinker; while the Absolute, as such, is independent
-of all relation. The <em>Conception of the Absolute</em> thus
-implies at the same time the presence and absence of the relation
-by which thought is constituted; and our various endeavours
-to represent it are only so many modified forms of
-the contradiction involved in our original assumption. Here,
-too, the contradiction is one which we ourselves have made.
-It does not imply that the Absolute cannot exist; but it implies,
-most certainly, that we cannot conceive it as existing.”</p>
-
-<p class='c000'>Here let me point out how the same general inference may
-be evolved from another fundamental condition of thought,
-omitted by Sir W. Hamilton, and not supplied by Mr Mansel;—a
-condition which, under its obverse aspect, we have already
-contemplated in the last section. Every complete act
-of consciousness, besides distinction and relation, also implies
-likeness. Before it can become an idea, or constitute a piece
-of knowledge, a mental state must not only be known as
-separate in kind from certain foregoing states to which it is
-known as related by succession; but it must further be known
-as of the same kind with certain other foregoing states.
-That organization of changes which constitutes thinking, involves
-continuous integration as well as continuous differentiation.
-Were each new affection of the mind perceived
-simply as an affection in some way contrasted with the
-preceding ones—were there but a chain of impressions, each
-of which as it arose was merely distinguished from its predecessors;
-consciousness would be an utter chaos. To produce
-that orderly consciousness which we call intelligence, there
-requires the assimilation of each impression to others,
-that occurred earlier in the series. Both the successive
-mental states, and the successive relations which they bear to
-each other, must be classified; and classification involves not
-only a parting of the unlike, but also a binding together of
-the like. In brief, a true cognition is possible only through
-<span class='pageno' id='Page_80'>80</span>an accompanying recognition. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Should it be objected
-that if so, there cannot be a first cognition, and hence there
-can be no cognition; the reply is, that cognition proper arises
-gradually—that during the first stage of incipient intelligence,
-before the feelings produced by intercourse with the outer world
-have been put into order, there <em>are</em> no cognitions, strictly so
-called; and that, as every infant shows us, these slowly
-emerge out of the confusion of unfolding consciousness as
-fast as the experiences are arranged into groups—as fast as
-the most frequently repeated sensations, and their relations to
-each other, become familiar enough to admit of their recognition
-as such or such, whenever they recur. Should it be
-further objected that if cognition pre-supposes recognition,
-there can be, no cognition, even by an adult, of an object
-never before seen; there is still the sufficient answer that in
-so far as it is not assimilated to previously-seen objects, it is
-<em>not</em> known, and that it <em>is</em> known in so far as it is assimilated
-to them. Of this paradox the interpretation is, that an object
-is classifiable in various ways, with various degrees of completeness.
-An animal hitherto <em>unknown</em> (mark the word),
-though not referable to any established species or genus, is
-yet <em>recognized</em> as belonging to one of the larger divisions—mammals,
-birds, reptiles, or fishes; or should it be so
-anomalous that its alliance with any of these is not determinable,
-it may yet be classed as vertebrate or invertebrate; or if
-it be one of those organisms of which it is doubtful whether
-the animal or vegetal characteristics predominate, it is still
-known as a living body; even should it be questioned
-whether it is organic, it remains beyond question that it is a
-material object, and it is cognized by being recognized as
-such. Whence it is manifest that a thing is perfectly known
-only when it is in all respects like certain things previously
-observed; that in proportion to the number of respects in
-which it is unlike them, is the extent to which it is unknown;
-and that hence when it has absolutely no attribute in common
-<span class='pageno' id='Page_81'>81</span>with anything else, it must be absolutely beyond the bounds
-of knowledge.</p>
-
-<p class='c000'>Observe the corollary which here concerns us. A cognition
-of the Real, as distinguished from the Phenomenal, must,
-if it exists, conform to this law of cognition in general. The
-First Cause, the Infinite, the Absolute, to be known at all,
-must be classed. To be positively thought of, it must be
-thought of as such or such—as of this or that kind. Can it
-be like in kind to anything of which we have sensible
-experience? Obviously not. Between the creating and the
-created, there must be a distinction transcending any of the
-distinctions existing between different divisions of the created.
-That which is uncaused cannot be assimilated to that which
-is caused: the two being, in the very naming, antithetically
-opposed. The Infinite cannot be grouped along with something
-that is finite; since, in being so grouped, it must be
-regarded as not-infinite. It is impossible to put the Absolute
-in the same category with anything relative, so long as
-the Absolute is defined as that of which no necessary relation
-can be predicated. Is it then that the Actual, though unthinkable
-by classification with the Apparent, is thinkable by
-classification with itself? This supposition is equally absurd
-with the other. It implies the plurality of the First Cause,
-the Infinite, the Absolute; and this implication is self-contradictory.
-There cannot be more than one First Cause; seeing
-that the existence of more than one would involve the existence
-of something necessitating more than one, which something
-would be the true First Cause. How self-destructive is the
-assumption of two or more Infinites, is manifest on remembering
-that such Infinites, by limiting each other, would become
-finite. And similarly, an Absolute which existed not alone
-but along with other Absolutes, would no longer be an absolute
-but a relative. The Unconditioned therefore, as class-able
-neither with any form of the conditioned nor with any other
-Unconditioned, cannot be classed at all. And to admit that
-it cannot be known as of such or such kind, is to admit that
-it is unknowable.</p>
-
-<p class='c000'><span class='pageno' id='Page_82'>82</span>Thus, from the very nature of thought, the relativity of our
-knowledge is inferable in three several ways. As we find by
-analyzing it, and as we see it objectively displayed in every
-proposition, a thought involves <em>relation</em>, <em>difference</em>, <em>likeness</em>.
-Whatever does not present each of these does not admit of
-cognition. And hence we may say that the Unconditioned, as
-presenting none of them, is trebly unthinkable.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 25. From yet another point of view we may discern the
-same great truth. If, instead of examining our intellectual
-powers directly as exhibited in the act of thought, or indirectly
-as exhibited in thought when expressed by words, we look at
-the connexion between the mind and the world, a like conclusion
-is forced upon us. In the very definition of Life, when
-reduced to its most abstract shape, this ultimate implication
-becomes visible.</p>
-
-<p class='c000'>All vital actions, considered not separately but in their
-ensemble, have for their final purpose the balancing of certain
-outer processes by certain inner processes. There are unceasing
-external forces tending to bring the matter of which organic
-bodies consist, into that state of stable equilibrium displayed
-by inorganic bodies; there are internal forces by which
-this tendency is constantly antagonized; and the perpetual
-changes which constitute Life, may be regarded as incidental
-to the maintenance of the antagonism. To preserve the
-erect posture, for instance, we see that certain weights have
-to be neutralized by certain strains: each limb or other organ,
-gravitating to the Earth and pulling down the parts to which
-it is attached, has to be preserved in position by the tension
-of sundry muscles; or in other words, the group of forces
-which would if allowed bring the body to the ground, has to
-be counterbalanced by another group of forces. Again, to
-keep up the temperature at a particular point, the external
-process of radiation and absorption of heat by the surrounding
-medium, must be met by a corresponding internal process
-of chemical combination, whereby more heat may be evolved;
-to which add, that if from atmospheric changes the loss
-<span class='pageno' id='Page_83'>83</span>becomes greater or less, the production must become greater or
-less. And similarly throughout the organic actions in general.</p>
-
-<p class='c000'>When we contemplate the lower kinds of life, we see that
-the correspondences thus maintained are direct and simple;
-as in a plant, the vitality of which mainly consists in osmotic
-and chemical actions responding to the co-existence of light,
-heat, water, and carbonic acid around it. But in animals, and
-especially in the higher orders of them, the correspondences
-become extremely complex. Materials for growth and
-repair not being, like those which plants require, everywhere
-present, but being widely dispersed and under special forms,
-have to be found, to be secured, and to be reduced to a fit state
-for assimilation. Hence the need for locomotion; hence the need
-for the senses; hence the need for prehensile and destructive
-appliances; hence the need for an elaborate digestive apparatus.
-Observe, however, that these successive complications
-are essentially nothing but aids to the maintenance of the
-organic balance in its integrity, in opposition to those physical,
-chemical, and other agencies which tend to overturn it. And
-observe, moreover, that while these successive complications
-subserve this fundamental adaptation of inner to outer actions,
-they are themselves nothing else but further adaptations of
-inner to outer actions. For what are those movements by
-which a predatory creature pursues its prey, or by which its
-prey seeks to escape, but certain changes in the organism
-fitted to meet certain changes in its environment? What is
-that compound operation which constitutes the perception of
-a piece of food, but a particular correlation of nervous modifications,
-answering to a particular correlation of physical properties?
-What is that process by which food when swallowed
-is reduced to a fit form for assimilation, but a set of mechanical
-and chemical actions responding to the mechanical and
-chemical actions which distinguish the food? Whence
-it becomes manifest, that while Life in its simplest form is the
-correspondence of certain inner physico-chemical actions with
-certain outer physico-chemical actions, each advance to a higher
-<span class='pageno' id='Page_84'>84</span>form of Life consists in a better preservation of this primary
-correspondence by the establishment of other correspondences.</p>
-
-<p class='c000'>Divesting this conception of all superfluities and reducing
-it to its most abstract shape, we see that Life is definable as
-the continuous adjustment of internal relations to external
-relations. And when we so define it, we discover that the
-physical and the psychial life are equally comprehended by
-the definition. We perceive that this which we call Intelligence,
-shows itself when the external relations to which the
-internal ones are adjusted, begin to be numerous, complex, and
-remote in time or space; that every advance in Intelligence
-essentially consists in the establishment of more varied, more
-complete, and more involved adjustments; and that even the
-highest achievements of science are resolvable into mental relations
-of co-existence and sequence, so co-ordinated as exactly to
-tally with certain relations of co-existence and sequence that
-occur externally. A caterpillar, wandering at random and at
-length finding its way on to a plant having a certain odour,
-begins to eat—has inside of it an organic relation between
-a particular impression and a particular set of actions, answering
-to the relation outside of it, between scent and nutriment.
-The sparrow, guided by the more complex correlation of impressions
-which the colour, form, and movements of the caterpillar
-gave it; and guided also by other correlations which measure
-the position and distance of the caterpillar; adjusts certain
-correlated muscular movements in such way as to seize the
-caterpillar. Through a much greater distance in space is the
-hawk, hovering above, affected by the relations of shape and
-motion which the sparrow presents; and the much more complicated
-and prolonged series of related nervous and muscular
-changes, gone through in correspondence with the sparrow’s
-changing relations of position, finally succeed when they are
-precisely adjusted to these changing relations. In the fowler,
-experience has established a relation between the appearance
-and flight of a hawk and the destruction of other birds, including
-game; there is also in him an established relation between
-<span class='pageno' id='Page_85'>85</span>those visual impressions answering to a certain distance in
-space, and the range of his gun; and he has learned, too,
-by frequent observation, what relations of position the
-sights must bear to a point somewhat in advance of the flying
-bird, before he can fire with success. Similarly if we
-go back to the manufacture of the gun. By relations of co-existence
-between colour, density, and place in the earth, a
-particular mineral is known as one which yields iron; and
-the obtainment of iron from it, results when certain correlated
-acts of ours, are adjusted to certain correlated affinities displayed
-by ironstone, coal, and lime, at a high temperature. If
-we descend yet a step further, and ask a chemist to explain the
-explosion of gunpowder, or apply to a mathematician for a
-theory of projectiles, we still find that special or general relations
-of co-existence and sequence between properties, motions,
-spaces &amp;c., are all they can teach us. And lastly, let it be
-noted that what we call <em>truth</em>, guiding us to successful action
-and the consequent maintenance of life, is simply the accurate
-correspondence of subjective to objective relations; while <em>error</em>,
-leading to failure and therefore towards death, is the absence
-of such accurate correspondence.</p>
-
-<p class='c000'>If, then, Life in all its manifestations, inclusive of Intelligence
-in its highest forms, consists in the continuous adjustment
-of internal relations to external relations, the necessarily
-relative character of our knowledge becomes obvious. The
-simplest cognition being the establishment of some connexion
-between subjective states, answering to some connexion between
-objective agencies; and each successively more complex
-cognition being the establishment of some more involved connexion
-of such states, answering to some more involved connexion
-of such agencies; it is clear that the process, no matter
-how far it be carried, can never bring within the reach of Intelligence,
-either the states themselves or the agencies themselves.
-Ascertaining which things occur along with which, and what
-things follow what, supposing it to be pursued exhaustively,
-must still leave us with co-existences and sequences only. If
-<span class='pageno' id='Page_86'>86</span>every act of knowing is the formation of a relation in consciousness
-parallel to a relation in the environment, then the relativity
-of knowledge is self-evident—becomes indeed a truism.
-Thinking being relationing, no thought can ever express more
-than relations.</p>
-
-<p class='c000'>And here let us not omit to mark how that to which our
-intelligence is confined, is that with which alone our intelligence
-is concerned. The knowledge within our reach, is the
-only knowledge that can be of service to us. This maintenance
-of a correspondence between internal actions and external
-actions, which both constitutes our life at each moment
-and is the means whereby life is continued through subsequent
-moments, merely requires that the agencies acting upon us
-shall be known in their co-existences and sequences, and not
-that they shall be known in themselves. If <em>x</em> and <em>y</em> are two
-uniformly connected properties in some outer object, while <em>a</em>
-and <em>b</em> are the effects they produce in our consciousness; and
-if while the property <em>x</em> produces in us the indifferent mental
-state <em>a</em>, the property <em>y</em> produces in us the painful mental state
-<em>b</em> (answering to a physical injury); then, all that is requisite
-for our guidance, is, that <em>x</em> being the uniform accompaniment
-of <em>y</em> externally, <em>a</em> shall be the uniform accompaniment of <em>b</em> internally;
-so that when, by the presence of <em>x</em>, <em>a</em> is produced in
-consciousness, <em>b</em>, or rather the idea of <em>b</em>, shall follow it, and
-excite the motions by which the effect of <em>y</em> may be escaped.
-The sole need is that <em>a</em> and <em>b</em> and the relation between them,
-shall always answer to <em>x</em> and <em>y</em> and the relation between them.
-It matters nothing to us if <em>a</em> and <em>b</em> are like <em>x</em> and <em>y</em> or not.
-Could they be exactly identical with them, we should not be
-one whit the better off; and their total dissimilarity is no
-disadvantage to us.</p>
-
-<p class='c000'>Deep down then in the very nature of Life, the relativity
-of our knowledge is discernible. The analysis of vital actions
-in general, leads not only to the conclusion that things in themselves
-cannot be known to us; but also to the conclusion that
-knowledge of them, were it possible, would be useless.</p>
-
-<hr class='c013' />
-
-<p class='c000'><span class='pageno' id='Page_87'>87</span>§ 26. There still remains the final question—What must
-we say concerning that which transcends knowledge? Are
-we to rest wholly in the consciousness of phenomena?—is the
-result of inquiry to exclude utterly from our minds everything
-but the relative? or must we also believe in something beyond
-the relative?</p>
-
-<p class='c000'>The answer of pure logic is held to be, that by the limits
-of our intelligence we are rigorously confined within the relative;
-and that anything transcending the relative can be
-thought of only as a pure negation, or as a non-existence.
-“The <em>absolute</em> is conceived merely by a negation of conceivability,”
-writes Sir William Hamilton. “The <em>Absolute</em> and
-the <em>Infinite</em>” says Mr Mansel, “are thus, like the <em>Inconceivable</em>
-and the <em>Imperceptible</em>, names indicating, not an object of
-thought or of consciousness at all, but the mere absence of the
-conditions under which consciousness is possible.” From each
-of which extracts may be deduced the conclusion, that since
-reason cannot warrant us in affirming the positive existence
-of what is cognizable only as a negation, we cannot rationally
-affirm the positive existence of anything beyond phenomena.</p>
-
-<p class='c000'>Unavoidable as this conclusion seems, it involves, I think,
-a grave error. If the premiss be granted, the inference must
-doubtless be admitted; but the premiss, in the form presented
-by Sir William Hamilton and Mr Mansel, is not strictly true.
-Though, in the foregoing pages, the arguments used by these
-writers to show that the Absolute is unknowable, have been
-approvingly quoted; and though these arguments have been
-enforced by others equally thoroughgoing; yet there remains
-to be stated a qualification, which saves us from that scepticism
-otherwise necessitated. It is not to be denied that so
-long as we confine ourselves to the purely logical aspect of the
-question, the propositions quoted above must be accepted in
-their entirety; but when we contemplate its more general, or
-psychological, aspect, we find that these propositions are imperfect
-statements of the truth: omitting, or rather excluding,
-as they do, an all-important fact. To speak specifically:—Besides
-<span class='pageno' id='Page_88'>88</span>that <em>definite</em> consciousness of which Logic formulates
-the laws, there is also an <em>indefinite</em> consciousness which cannot
-be formulated. Besides complete thoughts, and besides the
-thoughts which though incomplete admit of completion, there
-are thoughts which it is impossible to complete; and yet which
-are still real, in the sense that they are normal affections of
-the intellect.</p>
-
-<p class='c000'>Observe in the first place, that every one of the arguments
-by which the relativity of our knowledge is demonstrated,
-distinctly postulates the positive existence of something beyond
-the relative. To say that we cannot know the Absolute,
-is, by implication, to affirm that there <em>is</em> an Absolute. In the
-very denial of our power to learn <em>what</em> the Absolute is, there
-lies hidden the assumption <em>that</em> it is; and the making of
-this assumption proves that the Absolute has been present
-to the mind, not as a nothing, but as a something. Similarly
-with every step in the reasoning by which this doctrine is
-upheld. The Noumenon, everywhere named as the antithesis
-of the Phenomenon, is throughout necessarily thought of as
-an actuality. It is rigorously impossible to conceive that our
-knowledge is a knowledge of Appearances only, without at the
-same time conceiving a Reality of which they are appearances;
-for appearance without reality is unthinkable. Strike out
-from the argument the terms Unconditioned, Infinite, Absolute,
-with their equivalents, and in place of them write, “negation
-of conceivability,” or “absence of the conditions under which
-consciousness is possible,” and you find that the argument
-becomes nonsense. Truly to realize in thought any one of the
-propositions of which the argument consists, the Unconditioned
-must be represented as positive and not negative. How then can
-it be a legitimate conclusion from the argument, that our consciousness
-of it is negative? An argument, the very construction
-of which assigns to a certain term a certain meaning,
-but which ends in showing that this term has no such meaning,
-is simply an elaborate suicide. Clearly, then, the very
-demonstration that a <em>definite</em> consciousness of the Absolute
-<span class='pageno' id='Page_89'>89</span>is impossible to us, unavoidably presupposes an <em>indefinite</em> consciousness
-of it.</p>
-
-<p class='c000'>Perhaps the best way of showing that by the necessary
-conditions of thought, we are obliged to form a positive though
-vague consciousness of this which transcends distinct consciousness,
-is to analyze our conception of the antithesis
-between Relative and Absolute. It is a doctrine called in
-question by none, that such antinomies of thought as Whole
-and Part, Equal and Unequal, Singular and Plural, are
-necessarily conceived as correlatives: the conception of a part
-is impossible without the conception of a whole; there can
-be no idea of equality without one of inequality. And it is
-admitted that in the same manner, the Relative is itself conceivable
-as such, only by opposition to the Irrelative or Absolute.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Sir William Hamilton however, in his trenchant
-(and in most parts unanswerable) criticism on Cousin, contends,
-in conformity with his position above stated, that one of
-these correlatives is nothing whatever beyond the negation of
-the other. “Correlatives” he says “certainly suggest each
-other, but correlatives may, or may not, be equally real and
-positive. In thought contradictories necessarily imply each
-other, for the knowledge of contradictories is one. But the
-reality of one contradictory, so far from guaranteeing the reality
-of the other, is nothing else than its negation. Thus every
-positive notion (the concept of a thing by what it is) suggests
-a negative notion (the concept of a thing by what it is not);
-and the highest positive notion, the notion of the conceivable,
-is not without its corresponding negative in the notion of the
-inconceivable. But though these mutually suggest each
-other, the positive alone is real; the negative is only an abstraction
-of the other, and in the highest generality, even an
-abstraction of thought itself.” &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Now the assertion
-that of such contradictories “the negative is <em>only</em> an abstraction
-of the other”—“is <em>nothing</em> else than its negation,”—is
-not true. In such correlatives as Equal and Unequal, it is
-obvious enough that the negative concept contains something
-<span class='pageno' id='Page_90'>90</span>besides the negation of the positive one; for the things of
-which equality is denied are not abolished from consciousness
-by the denial. And the fact overlooked by Sir William
-Hamilton, is, that the like holds even with those correlatives
-of which the negative is inconceivable, in the strict sense of
-the word. Take for example the Limited and the Unlimited.
-Our notion of the Limited is composed, firstly of a consciousness
-of some kind of being, and secondly of a consciousness of
-the limits under which it is known. In the antithetical notion
-of the Unlimited, the consciousness of limits is abolished; but
-not the consciousness of some kind of being. It is quite true
-that in the absence of conceived limits, this consciousness ceases
-to be a concept properly so called; but it is none the less true
-that it remains as a mode of consciousness. If, in such cases,
-the negative contradictory were, as alleged, “<em>nothing else</em>”
-than the negation of the other, and therefore a mere nonentity,
-then it would clearly follow that negative contradictories
-could be used interchangeably: the Unlimited might be
-thought of as antithetical to the Divisible; and the Indivisible
-as antithetical to the Limited. While the fact that they
-cannot be so used, proves that in consciousness the Unlimited
-and the Indivisible are qualitatively distinct, and therefore
-positive or real; since distinction cannot exist between
-nothings. The error, (very naturally fallen into by philosophers
-intent on demonstrating the limits and conditions
-of consciousness,) consists in assuming that consciousness contains
-<em>nothing but</em> limits and conditions; to the entire neglect
-of that which is limited and conditioned. It is forgotten
-that there is something which alike forms the raw material
-of definite thought and remains after the definiteness which
-thinking gave to it has been destroyed. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Now all
-this applies by change of terms to the last and highest of
-these antinomies—that between the Relative and the Non-relative.
-We are conscious of the Relative as existence under
-conditions and limits; it is impossible that these conditions
-and limits can be thought of apart from something to which
-<span class='pageno' id='Page_91'>91</span>they give the form; the abstraction of these conditions and
-limits, is, by the hypothesis, the abstraction of them <em>only</em>; consequently
-there must be a residuary consciousness of something
-which filled up their outlines; and this indefinite something
-constitutes our consciousness of the Non-relative or
-Absolute. Impossible though it is to give to this consciousness
-any qualitative or quantitative expression whatever, it is
-not the less certain that it remains with us as a positive and
-indestructible element of thought.</p>
-
-<p class='c000'>Still more manifest will this truth become when it is observed
-that our conception of the Relative itself disappears, if
-our conception of the Absolute is a pure negation. It is admitted,
-or rather it is contended, by the writers I have quoted
-above, that contradictories can be known only in relation to
-each other—that Equality, for instance, is unthinkable apart
-from its correlative Inequality; and that thus the Relative can
-itself be conceived only by opposition to the Non-relative. It
-is also admitted, or rather contended, that the consciousness of
-a relation implies a consciousness of both the related members.
-If we are required to conceive the relation between the Relative
-and Non-relative without being conscious of both, “we
-are in fact” (to quote the words of Mr Mansel differently
-applied) “required to compare that of which we are conscious
-with that of which we are not conscious; the comparison
-itself being an act of consciousness, and only possible through
-the consciousness of both its objects.” What then becomes
-of the assertion that “the Absolute is conceived merely by a
-negation of conceivability,” or as “the mere absence of the
-conditions under which consciousness is possible?” If the Non-relative
-or Absolute, is present in thought only as a mere
-negation, then the relation between it and the Relative becomes
-unthinkable, because one of the terms of the relation is
-absent from consciousness. And if this relation is unthinkable,
-then is the Relative itself unthinkable, for want of its
-antithesis: whence results the disappearance of all thought
-whatever.</p>
-
-<p class='c000'><span class='pageno' id='Page_92'>92</span>Let me here point out that both Sir Wm Hamilton and
-Mr Mansel, do, in other places, distinctly imply that our
-consciousness of the Absolute, indefinite though it is, is
-positive and not negative. The very passage already quoted
-from Sir Wm Hamilton, in which he asserts that “the
-<em>absolute</em> is conceived merely by a negation of conceivability,”
-itself ends with the remark that, “by a wonderful revelation,
-we are thus, in the very consciousness of our inability to conceive
-aught above the relative and finite, inspired with a
-belief in the existence of something unconditioned beyond
-the sphere of all comprehensible reality.” The last of
-these assertions practically admits that which the other
-denies. By the laws of thought as Sir Wm Hamilton has
-interpreted them, he finds himself forced to the conclusion
-that our consciousness of the Absolute is a pure negation.
-He nevertheless finds that there does exist in consciousness
-an irresistible conviction of the real “existence of something
-unconditioned.” And he gets over the inconsistency
-by speaking of this conviction as “a wonderful revelation”—“a
-belief” with which we are “inspired:” thus apparently
-hinting that it is supernaturally at variance with the laws of
-thought. Mr Mansel is betrayed into a like inconsistency.
-When he says that “we are compelled, by the constitution of
-our minds, to believe in the existence of an Absolute and Infinite
-Being,—a belief which appears forced upon us, as the
-complement of our consciousness of the relative and the
-finite;” he clearly says by implication that this consciousness
-is positive, and not negative. He tacitly admits that
-we are obliged to regard the Absolute as something more
-than a negation—that our consciousness of it is <em>not</em> “the
-mere absence of the conditions under which consciousness is
-possible.”</p>
-
-<p class='c000'>The supreme importance of this question must be my
-apology for taxing the reader’s attention a little further, in
-the hope of clearing up the remaining difficulties. The necessarily
-positive character of our consciousness of the Unconditioned,
-<span class='pageno' id='Page_93'>93</span>which, as we have seen, follows from an ultimate
-law of thought, will be better understood on contemplating
-the process of thought.</p>
-
-<p class='c000'>One of the arguments used to prove the relativity of
-our knowledge, is, that we cannot conceive Space or Time as
-either limited or unlimited. It is pointed out that when we
-imagine a limit, there simultaneously arises the consciousness
-of a space or time existing beyond the limit. This remoter
-space or time, though not contemplated as definite, is yet contemplated
-as real. Though we do not form of it a conception
-proper, since we do not bring it within bounds, there is yet in
-our minds the unshaped material of a conception. Similarly
-with our consciousness of Cause. We are no more able to
-form a circumscribed idea of Cause, than of Space or Time;
-and we are consequently obliged to think of the Cause which
-transcends the limits of our thought as positive though indefinite.
-Just in the same manner that on conceiving any
-bounded space, there arises a nascent consciousness of space
-outside the bounds; so, when we think of any definite cause,
-there arises a nascent consciousness of a cause behind it: and
-in the one case as in the other, this nascent consciousness is
-in substance like that which suggests it, though without form.
-The momentum of thought inevitably carries us beyond conditioned
-existence to unconditioned existence; and this ever
-persists in us as the body of a thought to which we can give
-no shape.</p>
-
-<p class='c000'>Hence our firm belief in objective reality—a belief which
-metaphysical criticisms cannot for a moment shake. When
-we are taught that a piece of matter, regarded by us as existing
-externally, cannot be really known, but that we can
-know only certain impressions produced on us, we are yet, by
-the relativity of our thought, compelled to think of these in
-relation to a positive cause—the notion of a real existence
-which generated these impressions becomes nascent. If it be
-proved to us that every notion of a real existence which we
-can frame, is utterly inconsistent with itself—that matter,
-<span class='pageno' id='Page_94'>94</span>however conceived by us, cannot be matter as it actually is,
-our conception, though transfigured, is not destroyed: there
-remains the sense of reality, dissociated as far as possible from
-those special forms under which it was before represented in
-thought. Though Philosophy condemns successively each
-attempted conception of the Absolute—though it proves to us
-that the Absolute is not this, nor that, nor that—though in
-obedience to it we negative, one after another, each idea as it
-arises; yet, as we cannot expel the entire contents of consciousness,
-there ever remains behind an element which passes
-into new shapes. The continual negation of each particular
-form and limit, simply results in the more or less complete
-abstraction of all forms and limits; and so ends in an
-indefinite consciousness of the unformed and unlimited.</p>
-
-<p class='c000'>And here we come face to face with the ultimate difficulty—How
-can there possibly be constituted a consciousness
-of the unformed and unlimited, when, by its very nature, consciousness
-is possible only under forms and limits? If every
-consciousness of existence is a consciousness of existence as
-conditioned, then how, after the negation of conditions, can
-there be any residuum?. Though not directly withdrawn by
-the withdrawal of its conditions, must not the raw material of
-consciousness be withdrawn by implication? Must it not vanish
-when the conditions of its existence vanish? &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;That
-there must be a solution of this difficulty is manifest; since
-even those who would put it, do, as already shown, admit
-that we have some such consciousness; and the solution appears
-to be that above shadowed forth. Such consciousness
-is not, and cannot be, constituted by any single mental act;
-but is the product of many mental acts. In each concept there
-is an element which persists. It is alike impossible for this
-element to be absent from consciousness, and for it to be present
-in consciousness alone: either alternative involves unconsciousness—the
-one from the want of the substance; the
-other from the want of the form. But the persistence of this
-element under successive conditions, <em>necessitates</em> a sense of it as
-<span class='pageno' id='Page_95'>95</span>distinguished from the conditions, and independent of them.
-The sense of a something that is conditioned in every thought,
-cannot be got rid of, because the something cannot be got rid of.
-How then must the sense of this something be constituted?
-Evidently by combining successive concepts deprived of their
-limits and conditions. We form this indefinite thought, as
-we form many of our definite thoughts, by the coalescence of
-a series of thoughts. Let me illustrate this. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;A large
-complex object, having attributes too numerous to be represented
-at once, is yet tolerably well conceived by the union of
-several representations, each standing for part of its attributes.
-On thinking of a piano, there first rises in imagination its
-visual appearance, to which are instantly added (though by
-separate mental acts) the ideas of its remote side and of its
-solid substance. A complete conception, however, involves the
-strings, the hammers, the dampers, the pedals; and while
-successively adding these to the conception, the attributes first
-thought of lapse more or less completely out of consciousness.
-Nevertheless, the whole group constitutes a representation of
-the piano. Now as in this case we form a definite concept of
-a special existence, by imposing limits and conditions in successive
-acts; so, in the converse case, by taking away the
-limits and conditions in successive acts, we form an indefinite
-notion of general existence. By fusing a series of states of
-consciousness, in each of which, as it arises, the limitations
-and conditions are abolished, there is produced a consciousness
-of something unconditioned. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;To speak more rigorously:—this
-consciousness is not the abstract of any one
-group of thoughts, ideas, or conceptions; but it is the abstract
-of <em>all</em> thoughts, ideas, or conceptions. That which is common
-to them all, and cannot be got rid of, is what we predicate by
-the word existence. Dissociated as this becomes from each of
-its modes by the perpetual change of those modes, it remains
-as an indefinite consciousness of something constant under
-all modes—of being apart from its appearances. The distinction
-we feel between special and general existence, is the
-<span class='pageno' id='Page_96'>96</span>distinction between that which is changeable in us, and that
-which is unchangeable. The contrast between the Absolute
-and the Relative in our minds, is really the contrast between
-that mental element which exists absolutely, and those which
-exist relatively.</p>
-
-<p class='c000'>By its very nature, therefore, this ultimate mental element
-is at once necessarily indefinite and necessarily indestructible.
-Our consciousness of the unconditioned being literally the unconditioned
-consciousness, or raw material of thought to which
-in thinking we give definite forms, it follows that an ever-present
-sense of real existence is the very basis of our intelligence.
-As we can in successive mental acts get rid of all particular
-conditions and replace them by others, but cannot get rid of
-that undifferentiated substance of consciousness which is conditioned
-anew in every thought; there ever remains with us
-a sense of that which exists persistently and independently of
-conditions. At the same time that by the laws of thought
-we are rigorously prevented from forming a conception of absolute
-existence; we are by the laws of thought equally prevented
-from ridding ourselves of the consciousness of absolute
-existence: this consciousness being, as we here see, the obverse
-of our self-consciousness. And since the only possible measure
-of relative validity among our beliefs, is the degree of
-their persistence in opposition to the efforts made to change
-them, it follows that this which persists at all times, under all
-circumstances, and cannot cease until consciousness ceases, has
-the highest validity of any.</p>
-
-<p class='c000'>To sum up this somewhat too elaborate argument:—We
-have seen how in the very assertion that all our knowledge,
-properly so called, is Relative, there is involved the assertion
-that there exists a Non-relative. We have seen how, in each
-step of the argument by which this doctrine is established,
-the same assumption is made. We have seen how, from the
-very necessity of thinking in relations, it follows that the
-Relative is itself inconceivable, except as related to a real
-Non-relative. We have seen that unless a real Non-relative
-<span class='pageno' id='Page_97'>97</span>or Absolute be postulated, the Relative itself becomes absolute;
-and so brings the argument to a contradiction. And on
-contemplating the process of thought, we have equally seen
-how impossible it is to get rid of the consciousness of an
-actuality lying behind appearances; and how, from this impossibility,
-results our indestructible belief in that actuality.</p>
-
-<div>
- <span class='pageno' id='Page_98'>98</span>
- <h3 class='c001'>CHAPTER V.<br /> <span class='large'>THE RECONCILIATION.</span></h3>
-</div>
-
-<p class='c006'>§ 27. Thus do all lines of argument converge to the same
-conclusion. The inference reached <i><span lang="fr" xml:lang="fr">à priori</span></i>. in the last chapter,
-confirms the inferences which, in the two preceding chapters,
-were reached <i><span lang="fr" xml:lang="fr">à posteriori</span></i>. Those imbecilities of the understanding
-that disclose themselves when we try to answer the
-highest questions of objective science, subjective science proves
-to be necessitated by the laws of that understanding. We not
-only learn by the frustration of all our efforts, that the reality
-underlying appearances is totally and for ever inconceivable
-by us; but we also learn why, from the very nature of our
-intelligence, it must be so. Finally we discover that this
-conclusion, which, in its unqualified form, seems opposed to
-the instinctive convictions of mankind, falls into harmony
-with them when the missing qualification is supplied.
-Though the Absolute cannot in any manner or degree be
-known, in the strict sense of knowing, yet we find that its positive
-existence is a necessary datum of consciousness; that so
-long as consciousness continues, we cannot for an instant rid
-it of this datum; and that thus the belief which this datum
-constitutes, has a higher warrant than any other whatever.</p>
-
-<p class='c000'>Here then is that basis of agreement we set out to seek.
-This conclusion which objective science illustrates, and subjective
-science shows to be unavoidable,—this conclusion
-which, while it in the main expresses the doctrine of the English
-<span class='pageno' id='Page_99'>99</span>school of philosophy, recognizes also a soul of truth in the
-doctrine of the antagonist German school—this conclusion
-which brings the results of speculation into harmony with those
-of common sense; is also the conclusion which reconciles Religion
-with Science. Common Sense asserts the existence of a
-reality; Objective Science proves that this reality cannot be
-what we think it; Subjective Science shows why we cannot
-think of it as it is, and yet are compelled to think of it as existing;
-and in this assertion of a Reality utterly inscrutable
-in nature, Religion finds an assertion essentially coinciding
-with her own. We are obliged to regard every phenomenon
-as a manifestation of some Power by which we are acted upon;
-phenomena being, so far as we can ascertain, unlimited in
-their diffusion, we are obliged to regard this Power as omnipresent;
-and criticism teaches us that this Power is wholly
-incomprehensible. In this consciousness of an Incomprehensible
-Omnipresent Power, we have just that consciousness on
-which Religion dwells. And so we arrive at the point where
-Religion and Science coalesce.</p>
-
-<p class='c000'>To understand fully how real is the reconciliation thus
-reached, it will be needful to look at the respective attitudes
-that Religion and Science have all along maintained towards
-this conclusion. We must observe how, all along, the imperfections
-of each have been undergoing correction by the other;
-and how the final out-come of their mutual criticisms, can be
-nothing else than an entire agreement on this deepest and
-widest of all truths.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 28. In Religion let us recognize the high merit that from
-the beginning it has dimly discerned the ultimate verity, and
-has never ceased to insist upon it. In its earliest and crudest
-forms it manifested, however vaguely and inconsistently, an
-intuition forming the germ of this highest belief in which all
-philosophies finally unite. The consciousness of a mystery
-is traceable in the rudest fetishism. Each higher religious
-creed, rejecting those definite and simple interpretations of
-<span class='pageno' id='Page_100'>100</span>Nature previously given, has become more religious by doing
-this. As the quite concrete and conceivable agencies alleged
-as the causes of things, have been replaced by agencies less
-concrete and conceivable, the element of mystery has of necessity
-become more predominant. Through all its successive
-phases the disappearance of those positive dogmas by which
-the mystery was made unmysterious, has formed the essential
-change delineated in religious history. And so Religion has
-ever been approximating towards that complete recognition of
-this mystery which is its goal.</p>
-
-<p class='c000'>For its essentially valid belief, Religion has constantly done
-battle. Gross as were the disguises under which it first
-espoused this belief, and cherishing this belief, though it still
-does, under disfiguring vestments, it has never ceased to maintain
-and defend it. It has everywhere established and propagated
-one or other modification of the doctrine that all things
-are manifestations of a Power that transcends our knowledge.
-Though from age to age, Science has continually defeated it
-wherever they have come in collision, and has obliged it to
-relinquish one or more of its positions; it has still held the
-remaining ones with undiminished tenacity. No exposure of
-the logical inconsistency of its conclusions—no proof that each
-of its particular dogmas was absurd, has been able to weaken
-its allegiance to that ultimate verity for which it stands.
-After criticism has abolished all its arguments and reduced it
-to silence, there has still remained with it the indestructible
-consciousness of a truth which, however faulty the mode in
-which it had been expressed, was yet a truth beyond cavil.
-To this conviction its adherence has been substantially sincere.
-And for the guardianship and diffusion of it, Humanity has
-ever been, and must ever be, its debtor.</p>
-
-<p class='c000'>But while from the beginning, Religion has had the all-essential
-office of preventing men from being wholly absorbed
-in the relative or immediate, and of awakening them to a consciousness
-of something beyond it, this office has been but very
-imperfectly discharged. Religion has ever been more or less
-<span class='pageno' id='Page_101'>101</span>irreligious; and it continues to be partially irreligious even
-now. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;In the first place, as implied above, it has all
-along professed to have some knowledge of that which transcends
-knowledge; and has so contradicted its own teachings.
-While with one breath it has asserted that the Cause of all
-things passes understanding, it has, with the next breath,
-asserted that the Cause of all things possesses such or such
-attributes—can be in so far understood. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;In the second
-place, while in great part sincere in its fealty to the great
-truth it had had to uphold, it has often been insincere, and
-consequently irreligious, in maintaining the untenable doctrines
-by which it has obscured this great truth. Each assertion
-respecting the nature, acts, or motives of that Power
-which the Universe manifests to us, has been repeatedly called
-in question, and proved to be inconsistent with itself, or with
-accompanying assertions. Yet each of them has been age
-after age insisted on, in spite of a secret consciousness that it
-would not bear examination. Just as though unaware that
-its central position was impregnable, Religion has obstinately
-held every outpost long after it was obviously indefensible.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;And this naturally introduces us to the third and
-most serious form of irreligion which Religion has displayed;
-namely, an imperfect belief in that which it especially professes
-to believe. How truly its central position <em>is</em> impregnable, Religion
-has never adequately realized. In the devoutest faith
-as we habitually see it, there lies hidden an innermost core of
-scepticism; and it is this scepticism which causes that dread
-of inquiry displayed by Religion when face to face with Science.
-Obliged to abandon one by one the superstitions it once tenaciously
-held, and daily finding its cherished beliefs more and
-more shaken, Religion shows a secret fear that all things may
-some day be explained; and thus itself betrays a lurking
-doubt whether that Incomprehensible Cause of which it is
-conscious, is really incomprehensible.</p>
-
-<p class='c000'>Of Religion then, we must always remember, that amid its
-many errors and corruptions it has asserted and diffused a
-<span class='pageno' id='Page_102'>102</span>supreme verity. From the first, the recognition of this supreme
-verity, in however imperfect a manner, has been its vital element;
-and its various defects, once extreme but gradually diminishing,
-have been so many failures to recognize in full that which
-it recognized in part. The truly religious element of Religion
-has always been good; that which has proved untenable in
-doctrine and vicious in practice, has been its irreligious element;
-and from this it has been ever undergoing purification.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 29. And now observe that all along, the agent which has
-effected the purification has been Science. We habitually
-overlook the fact that this has been one of its functions.
-Religion ignores its immense debt to Science; and Science is
-scarcely at all conscious how much Religion owes it. Yet it
-is demonstrable that every step by which Religion has progressed
-from its first low conception to the comparatively
-high one it has now reached, Science has helped it, or rather
-forced it, to take; and that even now, Science is urging further
-steps in the same direction.</p>
-
-<p class='c000'>Using the word Science in its true sense, as comprehending all
-positive and definite knowledge of the order existing among
-surrounding phenomena, it becomes manifest that from the
-outset, the discovery of an established order has modified that
-conception of disorder, or undetermined order, which underlies
-every superstition. As fast as experience proves that
-certain familiar changes always happen in the same sequence,
-there begins to fade from the mind the conception of a special
-personality to whose variable will they were before ascribed.
-And when, step by step, accumulating observations do the like
-with the less familiar changes, a similar modification of
-belief takes place with respect to them.</p>
-
-<p class='c000'>While this process seems to those who effect, and those
-who undergo it, an anti-religious one, it is really the reverse.
-Instead of the specific comprehensible agency before assigned,
-there is substituted a less specific and less comprehensible
-agency; and though this, standing in opposition to the previous
-<span class='pageno' id='Page_103'>103</span>one, cannot at first call forth the same feeling, yet, as
-being less comprehensible, it must eventually call forth this
-feeling more fully. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Take an instance. Of old the Sun
-was regarded as the chariot of a god, drawn by horses. How
-far the idea thus grossly expressed, was idealized, we need not
-inquire. It suffices to remark that this accounting for the
-apparent motion of the Sun by an agency like certain visible
-terrestrial agencies, reduced a daily wonder to the level of the
-commonest intellect. When, many centuries after, Kepler discovered
-that the planets moved round the Sun in ellipses and
-described equal areas in equal times, he concluded that in
-each planet there must exist a spirit to guide its movements.
-Here we see that with the progress of Science, there had disappeared
-the idea of a gross mechanical traction, such as was
-first assigned in the case of the Sun; but that while for this
-there was substituted an indefinite and less-easily conceivable
-force, it was still thought needful to assume a special personal
-agent as a cause of the regular irregularity of motion. When,
-finally, it was proved that these planetary revolutions with
-all their variations and disturbances, conformed to one universal
-law—when the presiding spirits which Kepler conceived
-were set aside, and the force of gravitation put in their
-place; the change was really the abolition of an imaginable
-agency, and the substitution of an unimaginable one. For
-though the <em>law</em> of gravitation is within our mental grasp, it
-is impossible to realize in thought the <em>force</em> of gravitation.
-Newton himself confessed the force of gravitation to be incomprehensible
-without the intermediation of an ether; and,
-as we have already seen, (§ 18,) the assumption of an ether
-does not in the least help us. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Thus it is with
-Science in general. Its progress in grouping particular
-relations of phenomena under laws, and these special laws
-under laws more and more general, is of necessity a progress
-to causes that are more and more abstract. And
-causes more and more abstract, are of necessity causes less
-and less conceivable; since the formation of an abstract
-<span class='pageno' id='Page_104'>104</span>conception involves the dropping of certain concrete elements
-of thought. Hence the most abstract conception, to which
-Science is ever slowly approaching, is one that merges into
-the inconceivable or unthinkable, by the dropping of all concrete
-elements of thought. And so is justified the assertion,
-that the beliefs which Science has forced upon Religion, have
-been intrinsically more religious than those which they supplanted.</p>
-
-<p class='c000'>Science however, like Religion, has but very incompletely
-fulfilled its office. As Religion has fallen short of its function
-in so far as it has been irreligious; so has Science fallen short
-of its function in so far as it has been unscientific. Let us
-note the several parallelisms. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;In its earlier stages,
-Science, while it began to teach the constant relations of
-phenomena, and so discredited the belief in separate personalities
-as the causes of them, itself substituted the belief
-in causal agencies which, if not personal, were yet concrete.
-When certain facts were said to show “Nature’s abhorrence
-of a vacuum,” when the properties of gold were explained as
-due to some entity called “aureity,” and when the phenomena
-of life were attributed to “a vital principle;” there was set
-up a mode of interpreting the facts, which, while antagonistic
-to the religious mode, because assigning other agencies, was
-also unscientific, because it professed to know that about
-which nothing was known. Having abandoned these metaphysical
-agencies—having seen that they were not independent
-existences, but merely special combinations of general
-causes, Science has more recently ascribed extensive groups
-of phenomena to electricity, chemical affinity, and other like
-general powers. But in speaking of these as ultimate and
-independent entities, Science has preserved substantially
-the same attitude as before. Accounting thus for all phenomena,
-those of Life and Thought included, it has not only
-maintained its seeming antagonism to Religion, by alleging
-agencies of a radically unlike kind; but, in so far as it has
-tacitly assumed a knowledge of these agencies, it has continued
-<span class='pageno' id='Page_105'>105</span>unscientific. At the present time, however, the most advanced
-men of science are abandoning these later conceptions, as
-their predecessors abandoned the earlier ones. Magnetism,
-heat, light &amp;c, which were awhile since spoken of as so
-many distinct imponderables, physicists are now beginning
-to regard as different modes of manifestation of some one
-universal force; and in so doing are ceasing to think of
-this force as comprehensible. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;In each phase of its
-progress, Science has thus stopped short with superficial
-solutions—has unscientifically neglected to ask what was
-the nature of the agents it so familiarly invoked. Though
-in each succeeding phase it has gone a little deeper, and
-merged its supposed agents in more general and abstract
-ones, it has still, as before, rested content with these as
-if they were ascertained realities. And this, which has
-all along been the unscientific characteristic of Science, has
-all along been a part cause of its conflict with Religion.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 30. We see then that from the first, the faults of both
-Religion and Science have been the faults of imperfect development.
-Originally a mere rudiment, each has been
-growing into a more complete form; the vice of each has in
-all times been its incompleteness; the disagreements between
-them have throughout been nothing more than the consequences
-of their incompleteness; and as they reach their
-final forms, they come into entire harmony.</p>
-
-<p class='c000'>The progress of intelligence has throughout been dual.
-Though it has not seemed so to those who made it, every step
-in advance has been a step towards both the natural and the
-supernatural. The better interpretation of each phenomenon
-has been, on the one hand, the rejection of a cause that was
-relatively conceivable in its nature but unknown in the order
-of its actions, and, on the other hand, the adoption of a cause
-that was known in the order of its actions but relatively inconceivable
-in its nature. The first advance out of universal
-fetishism, manifestly involved the conception of agencies less
-<span class='pageno' id='Page_106'>106</span>assimilable to the familiar agencies of men and animals, and
-therefore less understood; while, at the same time, such newly-conceived
-agencies in so far as they were distinguished by
-their uniform effects, were better understood than those they
-replaced. All subsequent advances display the same double
-result. Every deeper and more general power arrived at as
-a cause of phenomena, has been at once less comprehensible
-than the special ones it superseded, in the sense of being less
-definitely representable in thought; while it has been more
-comprehensible in the sense that its actions have been more
-completely predicable. The progress has thus been as much
-towards the establishment of a positively unknown as towards
-the establishment of a positively known. Though as knowledge
-approaches its culmination, every unaccountable and
-seemingly supernatural fact, is brought into the category of
-facts that are accountable or natural; yet, at the same time,
-all accountable or natural facts are proved to be in their ultimate
-genesis unaccountable and supernatural. And so there
-arise two antithetical states of mind, answering to the opposite
-sides of that existence about which we think. While
-our consciousness of Nature under the one aspect constitutes
-Science, our consciousness of it under the other aspect constitutes
-Religion.</p>
-
-<p class='c000'>Otherwise contemplating the facts, we may say that Religion
-and Science have been undergoing a slow differentiation;
-and that their ceaseless conflicts have been due to the imperfect
-separation of their spheres and functions. Religion has,
-from the first, struggled to unite more or less science with its
-nescience; Science has, from the first, kept hold of more or
-less nescience as though it were a part of science. Each has
-been obliged gradually to relinquish that territory which it
-wrongly claimed, while it has gained from the other that to which
-it had a right; and the antagonism between them has been
-an inevitable accompaniment of this process. A more specific
-statement will make this clear. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Religion, though at
-the outset it asserted a mystery, also made numerous definite
-<span class='pageno' id='Page_107'>107</span>assertions respecting this mystery—professed to know its nature
-in the minutest detail; and in so far as it claimed positive
-knowledge, it trespassed upon the province of Science.
-From the times of early mythologies, when such intimate acquaintance
-with the mystery was alleged, down to our own
-days, when but a few abstract and vague propositions are
-maintained, Religion has been compelled by Science to give
-up one after another of its dogmas—of those assumed cognitions
-which it could not substantiate. In the mean time,
-Science substituted for the personalities to which Religion
-ascribed phenomena, certain metaphysical entities; and in
-doing this it trespassed on the province of Religion; since it
-classed among the things which it comprehended, certain
-forms of the incomprehensible. Partly by the criticisms of
-Religion, which has occasionally called in question its assumptions,
-and partly as a consequence of spontaneous growth,
-Science has been obliged to abandon these attempts to include
-within the boundaries of knowledge that which cannot be
-known; and has so yielded up to Religion that which of
-right belonged to it. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;So long as this process of
-differentiation is incomplete, more or less of antagonism
-must continue. Gradually as the limits of possible cognition
-are established, the causes of conflict will diminish. And
-a permanent peace will be reached when Science becomes
-fully convinced that its explanations are proximate and relative;
-while Religion becomes fully convinced that the
-mystery it contemplates is ultimate and absolute.</p>
-
-<p class='c000'>Religion and Science are therefore necessary correlatives.
-As already hinted, they stand respectively for those two antithetical
-modes of consciousness which cannot exist asunder.
-A known cannot be thought of apart from an unknown; nor
-can an unknown be thought of apart from a known. And by
-consequence neither can become more distinct without giving
-greater distinctness to the other. To carry further a metaphor
-before used,—they are the positive and negative poles of
-<span class='pageno' id='Page_108'>108</span>thought; of which neither can gain in intensity without increasing
-the intensity of the other.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 31. Thus the consciousness of an Inscrutable Power manifested
-to us through all phenomena, has been growing ever
-clearer; and must eventually be freed from its imperfections.
-The certainty that on the one hand such a Power exists, while
-on the other hand its nature transcends intuition and is beyond
-imagination, is the certainty towards which intelligence
-has from the first been progressing. To this conclusion
-Science inevitably arrives as it reaches its confines; while to
-this conclusion Religion is irresistibly driven by criticism.
-And satisfying as it does the demands of the most rigorous
-logic at the same time that it gives the religious sentiment
-the widest possible sphere of action, it is the conclusion we
-are bound to accept without reserve or qualification.</p>
-
-<p class='c000'>Some do indeed allege that though the Ultimate Cause of
-things cannot really be thought of by us as having specified
-attributes, it is yet incumbent upon us to assert these attributes.
-Though the forms of our consciousness are such that
-the Absolute cannot in any manner or degree be brought
-within them, we are nevertheless told that we must represent
-the Absolute to ourselves under these forms. As writes Mr
-Mansel, in the work from which I have already quoted largely—“It
-is our duty, then, to think of God as personal; and it
-is our duty to believe that He is infinite.”</p>
-
-<p class='c000'>That this is not the conclusion here adopted, needs hardly
-be said. If there be any meaning in the foregoing arguments,
-duty requires us neither to affirm nor deny personality.
-Our duty is to submit ourselves with all humility to the
-established limits of our intelligence; and not perversely to
-rebel against them. Let those who can, believe that there is
-eternal war set between our intellectual faculties and our moral
-obligations. I for one, admit no such radical vice in the
-constitution of things.</p>
-
-<p class='c000'><span class='pageno' id='Page_109'>109</span>This which to most will seem an essentially irreligious position,
-is an essentially religious one—nay is <em>the</em> religious one,
-to which, as already shown, all others are but approximations.
-In the estimate it implies of the Ultimate Cause, it does not
-fall short of the alternative position, but exceeds it. Those
-who espouse this alternative position, make the erroneous assumption
-that the choice is between personality and something
-lower than personality; whereas the choice is rather
-between personality and something higher. Is it not just
-possible that there is a mode of being as much transcending
-Intelligence and Will, as these transcend mechanical motion?
-It is true that we are totally unable to conceive any such
-higher mode of being. But this is not a reason for questioning
-its existence; it is rather the reverse. Have we not seen
-how utterly incompetent our minds are to form even an approach
-to a conception of that which underlies all phenomena?
-Is it not proved that this incompetency is the incompetency
-of the Conditioned to grasp the Unconditioned? Does
-it not follow that the Ultimate Cause cannot in any respect be
-conceived by us because it is in every respect greater than can
-be conceived? And may we not therefore rightly refrain
-from assigning to it any attributes whatever, on the ground
-that such attributes, derived as they must be from our own
-natures, are not elevations but degradations? Indeed it seems
-somewhat strange that men should suppose the highest worship
-to lie in assimilating the object of their worship to themselves.
-Not in asserting a transcendant difference, but in asserting
-a certain likeness, consists the element of their creed
-which they think essential. It is true that from the time
-when the rudest savages imagined the causes of all things to
-be creatures of flesh and blood like themselves, down to our
-own time, the degree of assumed likeness has been diminishing.
-But though a bodily form and substance similar to that of man,
-has long since ceased, among cultivated races, to be a literally-conceived
-attribute of the Ultimate Cause—though the grosser
-human desires have been also rejected as unfit elements of the
-<span class='pageno' id='Page_110'>110</span>conception—though there is some hesitation in ascribing even
-the higher human feelings, save in greatly idealized shapes;
-yet it is still thought not only proper, but imperative, to
-ascribe the most abstract qualities of our nature. To think of
-the Creative Power as in all respects anthropomorphous, is now
-considered impious by men who yet hold themselves bound to
-think of the Creative Power as in some respects anthropomorphous;
-and who do not see that the one proceeding is but an
-evanescent form of the other. And then, most marvellous of
-all, this course is persisted in even by those who contend that
-we are wholly unable to frame any conception whatever of
-the Creative Power. After it has been shown that every supposition
-respecting the genesis of the Universe commits us to
-alternative impossibilities of thought—after it has been
-shown that each attempt to conceive real existence ends in an
-intellectual suicide—after it has been shown why, by the very
-constitution of our minds, we are eternally debarred from
-thinking of the Absolute; it is still asserted that we ought
-to think of the Absolute thus and thus. In all imaginable
-ways we find thrust upon us the truth, that we are not permitted
-to know—nay are not even permitted to conceive—that
-Reality which is behind the veil of Appearance; and
-yet it is said to be our duty to believe (and in so far to conceive)
-that this Reality exists in a certain defined manner.
-Shall we call this reverence? or shall we call it the reverse?</p>
-
-<p class='c000'>Volumes might be written upon the impiety of the pious.
-Through the printed and spoken thoughts of religious teachers,
-may almost everywhere be traced a professed familiarity with
-the ultimate mystery of things, which, to say the least of it,
-seems anything but congruous with the accompanying expressions
-of humility. And surprisingly enough, those tenets which
-most clearly display this familiarity, are those insisted upon
-as forming the vital elements of religious belief. The attitude
-thus assumed, can be fitly represented only by further developing
-a simile long current in theological controversies—the
-simile of the watch. If for a moment we made the grotesque
-<span class='pageno' id='Page_111'>111</span>supposition that the tickings and other movements of a watch
-constituted a kind of consciousness; and that a watch possessed
-of such a consciousness, insisted on regarding the watchmaker’s
-actions as determined like its own by springs and escapements;
-we should simply complete a parallel of which religious
-teachers think much. And were we to suppose that a watch
-not only formulated the cause of its existence in these
-mechanical terms, but held that watches were bound out of
-reverence so to formulate this cause, and even vituperated, as
-atheistic watches, any that did not venture so to formulate it;
-we should merely illustrate the presumption of theologians by
-carrying their own argument a step further. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;A few
-extracts will bring home to the reader the justice of this
-comparison. We are told, for example, by one of high
-repute among religious thinkers, that the Universe is “the
-manifestation and abode of a Free Mind, like our own; embodying
-His personal thought in its adjustments, realizing
-His own ideal in its phenomena, just as we express own inner
-faculty and character through the natural language of an external
-life. In this view, we interpret Nature by Humanity;
-we find the key to her aspects in such purposes and affections
-as our own consciousness enables us to conceive; we look
-everywhere for physical signals of an ever-living Will; and
-decipher the universe as the autobiography of an Infinite
-Spirit, repeating itself in miniature within our Finite Spirit.”
-The same writer goes still further. He not only thus parallels
-the assimilation of the watchmaker to the watch,—he not only
-thinks the created can “decipher” “the autobiography” of
-the Creating; but he asserts that the necessary limits of the
-one are necessary limits of the other. The primary qualities
-of bodies, he says, “belong eternally to the material datum objective
-to God” and control his acts; while the secondary
-ones are “products of pure Inventive Reason and Determining
-Will”—constitute “the realm of Divine originality.” *&nbsp;*&nbsp;*
-“While on this Secondary field His Mind and ours are thus
-contrasted, they meet in resemblance again upon the Primary:
-<span class='pageno' id='Page_112'>112</span>for the evolutions of deductive Reason there is but one track
-possible to all intelligences; no <i><span lang="la" xml:lang="la">merum arbitrium</span></i> can interchange
-the false and true, or make more than one geometry,
-one scheme of pure Physics, for all worlds; and the Omnipotent
-Architect Himself, in realizing the Kosmical conception,
-in shaping the orbits out of immensity and determining seasons
-out of eternity, could but follow the laws of curvature, measure
-and proportion.” That is to say, the Ultimate Cause is like
-a human mechanic, not only as “shaping” the “material datum
-objective to” Him, but also as being obliged to conform to
-the necessary properties of that “datum.” Nor is this all.
-There follows some account of “the Divine psychology,” to
-the extent of saying that “we learn” “the character of God—the
-order of affections in Him” from “the distribution of
-authority in the hierarchy of our impulses.” In other words,
-it is alleged that the Ultimate Cause has desires that are to be
-classed as higher and lower like our own.<a id='r7' /><a href='#f7' class='c011'><sup>[7]</sup></a> &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Every
-one has heard of the king who wished he had been present at
-the creation of the world, that he might have given good advice.
-He was humble however compared with those who profess
-to understand not only the relation of the Creating to the
-created, but also how the Creating is constituted. And yet
-this transcendant audacity, which claims to penetrate the
-secrets of the Power manifested to us through all existence—nay
-even to stand behind that Power and note the conditions
-to its action—this it is which passes current as piety! May
-we not without hesitation affirm that a sincere recognition of
-the truth that our own and all other existence is a mystery
-absolutely and for ever beyond our comprehension, contains
-more of true religion than all the dogmatic theology ever
-written?</p>
-
-<p class='c000'>Meanwhile let us recognize whatever of permanent good
-there is in these persistent attempts to frame conceptions of
-that which cannot be conceived. From the beginning it has
-<span class='pageno' id='Page_113'>113</span>been only through the successive failures of such conceptions
-to satisfy the mind, that higher and higher ones have been
-gradually reached; and doubtless, the conceptions now current
-are indispensable as transitional modes of thought. Even
-more than this may be willingly conceded. It is possible,
-nay probable, that under their most abstract forms, ideas of
-this order will always continue to occupy the background of
-our consciousness. Very likely there will ever remain a need
-to give shape to that indefinite sense of an Ultimate Existence,
-which forms the basis of our intelligence. We shall always
-be under the necessity of contemplating it as <em>some</em> mode of being;
-that is—of representing it to ourselves in <em>some</em> form of
-thought, however vague. And we shall not err in doing this
-so long as we treat every notion we thus frame as merely a
-symbol, utterly without resemblance to that for which it
-stands. Perhaps the constant formation of such symbols and
-constant rejection of them as inadequate, may be hereafter,
-as it has hitherto been, a means of discipline. Perpetually to
-construct ideas requiring the utmost stretch of our faculties,
-and perpetually to find that such ideas must be abandoned as
-futile imaginations, may realize to us more fully than any other
-course, the greatness of that which we vainly strive to grasp.
-Such efforts and failures may serve to maintain in our minds
-a due sense of the incommensurable difference between the
-Conditioned and the Unconditioned. By continually seeking
-to know and being continually thrown back with a deepened
-conviction of the impossibility of knowing, we may keep alive
-the consciousness that it is alike our highest wisdom and our
-highest duty to regard that through which all things exist as
-The Unknowable.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 32. An immense majority will refuse with more or less of
-indignation, a belief seeming to them so shadowy and indefinite.
-Having always embodied the Ultimate Cause so far as was
-needful to its mental realization, they must necessarily resent
-the substitution of an Ultimate Cause which cannot be mentally
-<span class='pageno' id='Page_114'>114</span>realized at all. “You offer us,” they say, “an unthinkable
-abstraction in place of a Being towards whom we may
-entertain definite feelings. Though we are told that the Absolute
-is real, yet since we are not allowed to conceive it, it
-might as well be a pure negation. Instead of a Power which
-we can regard as having some sympathy with us, you would
-have us contemplate a Power to which no emotion whatever
-can be ascribed. And so we are to be deprived of the very
-substance of our faith.”</p>
-
-<p class='c000'>This kind of protest of necessity accompanies every change
-from a lower creed to a higher. The belief in a community
-of nature between himself and the object of his worship, has
-always been to man a satisfactory one; and he has always
-accepted with reluctance those successively less concrete conceptions
-which have been forced upon him. Doubtless, in all
-times and places, it has consoled the barbarian to think of his
-deities as so exactly like himself in nature, that they could be
-bribed by offerings of food; and the assurance that deities
-could not be so propitiated, must have been repugnant, because
-it deprived him of an easy method of gaining supernatural
-protection. To the Greeks it was manifestly a source
-of comfort that on occasions of difficulty they could obtain,
-through oracles, the advice of their gods,—nay, might even
-get the personal aid of their gods in battle; and it was probably
-a very genuine anger which they visited upon philosophers
-who called in question these gross ideas of their mythology.
-A religion which teaches the Hindoo that it is
-impossible to purchase eternal happiness by placing himself
-under the wheel of Juggernaut, can scarcely fail to seem a
-cruel one to him; since it deprives him of the pleasurable
-consciousness that he can at will exchange miseries for joys.
-Nor is it less clear that to our Catholic ancestors, the beliefs
-that crimes could be compounded for by the building of
-churches, that their own punishments and those of their relatives
-could be abridged by the saying of masses, and that
-divine aid or forgiveness might be gained through the intercession
-<span class='pageno' id='Page_115'>115</span>of saints, were highly solacing ones; and that Protestantism,
-in substituting the conception of a God so comparatively
-unlike ourselves as not to be influenced by such
-methods, must have appeared to them hard and cold.
-Naturally, therefore, we must expect a further step in the
-same direction to meet with a similar resistance from outraged
-sentiments. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;No mental revolution can be accomplished
-without more or less of laceration. Be it a change of habit or
-a change of conviction, it must, if the habit or conviction be
-strong, do violence to some of the feelings; and these must
-of course oppose it. For long-experienced, and therefore
-definite, sources of satisfaction, have to be substituted sources
-of satisfaction that have not been experienced, and are
-therefore indefinite. That which is relatively well known
-and real, has to be given up for that which is relatively
-unknown and ideal. And of course such an exchange cannot
-be made without a conflict involving pain. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Especially
-then must there arise a strong antagonism to
-any alteration in so deep and vital a conception as that
-with which we are here dealing. Underlying, as this
-conception does, all others, a modification of it threatens to
-reduce the superstructure to ruins. Or to change the
-metaphor—being the root with which are connected our
-ideas of goodness, rectitude, or duty, it appears impossible
-that it should be transformed without causing these to
-wither away and die. The whole higher part of the nature
-almost of necessity takes up arms against a change which, by
-destroying the established associations of thought, seems
-to eradicate morality.</p>
-
-<p class='c000'>This is by no means all that has to be said for such protests.
-There is a much deeper meaning in them. They do
-not simply express the natural repugnance to a revolution of
-belief, here made specially intense by the vital importance of
-the belief to be revolutionized; but they also express an
-instinctive adhesion to a belief that is in one sense the best—the
-best for those who thus cling to it, though not abstractedly
-<span class='pageno' id='Page_116'>116</span>the best. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;For here let me remark that
-what were above spoken of as the imperfections of Religion,
-at first great but gradually diminishing, have been imperfections
-only as measured by an absolute standard; and not as
-measured by a relative one. Speaking generally, the religion
-current in each age and among each people, has been as
-near an approximation to the truth as it was then and there
-possible for men to receive: the more or less concrete forms
-in which it has embodied the truth, have simply been the
-means of making thinkable what would otherwise have been
-unthinkable; and so have for the time being served to
-increase its impressiveness. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;If we consider the conditions
-of the case, we shall find this to be an unavoidable
-conclusion. During each stage of evolution, men must think
-in such terms of thought as they possess. While all the
-conspicuous changes of which they can observe the origins,
-have men and animals as antecedents, they are unable to
-think of antecedents in general under any other shapes; and
-hence creative agencies are of necessity conceived by them
-in these shapes. If during this phase, these concrete conceptions
-were taken from them, and the attempt made to
-give them comparatively abstract conceptions, the result
-would be to leave their minds with none at all; since the
-substituted ones could not be mentally represented. Similarly
-with every successive stage of religious belief, down to
-the last. Though, as accumulating experiences slowly modify
-the earliest ideas of causal personalities, there grow up
-more general and vague ideas of them; yet these cannot be
-at once replaced by others still more general and vague.
-Further experiences must supply the needful further abstractions,
-before the mental void left by the destruction of such
-inferior ideas can be filled by ideas of a superior order. And
-at the present time, the refusal to abandon a relatively concrete
-notion for a relatively abstract one, implies the inability to
-frame the relatively abstract one; and so proves that the
-change would be premature and injurious. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Still
-<span class='pageno' id='Page_117'>117</span>more clearly shall we see the injuriousness of any such
-premature change, on observing that the effects of a belief
-upon conduct must be diminished in proportion as the vividness
-with which it is realized becomes less. Evils and
-benefits akin to those which the savage has personally felt,
-or learned from those who have felt them, are the only evils
-and benefits he can understand; and these must be looked
-for as coming in ways, like those of which he has had experience.
-His deities must be imagined to have like motives
-and passions and methods with the beings around him;
-for motives and passions and methods of a higher character,
-being unknown to him, and in great measure unthinkable by
-him, cannot be so realized in thought as to influence his
-deeds. During every phase of civilization, the actions of
-the Unseen Reality, as well as the resulting rewards and
-punishments, being conceivable only in such forms as experience
-furnishes, to supplant them by higher ones before
-wider experiences have made higher ones conceivable, is to
-set up vague and uninfluential motives for definite and influential
-ones. Even now, for the great mass of men,
-unable through lack of culture to trace out with due clearness
-those good and bad consequences which conduct brings
-round through the established order of the Unknowable, it is
-needful that there should be vividly depicted future torments
-and future joys—pains and pleasures of a definite kind, produced
-in a manner direct and simple enough to be clearly imagined.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Nay still more must be conceded. Few if any
-are as yet fitted wholly to dispense with such conceptions as are
-current. The highest abstractions take so great a mental power
-to realize with any vividness, and are so inoperative upon conduct
-unless they are vividly realized, that their regulative effects
-must for a long period to come be appreciable on but a
-small minority. To see clearly how a right or wrong act
-generates consequences, internal and external, that go on
-branching out more widely as years progress, requires a rare
-power of analysis. To mentally represent even a single series
-<span class='pageno' id='Page_118'>118</span>of these consequences, as it stretches out into the remote future,
-requires an equally rare power of imagination. And to estimate
-these consequences in their totality, ever multiplying in
-number while diminishing in intensity, requires a grasp of
-thought possessed by none. Yet it is only by such analysis,
-such imagination, and such grasp, that conduct can be rightly
-guided in the absence of all other control: only so can ultimate
-rewards and penalties be made to outweigh proximate
-pains and pleasures. Indeed, were it not that throughout the
-progress of the race, men’s experiences of the effects of conduct
-have been slowly generalized into principles—were it not that
-these principles have been from generation to generation insisted
-on by parents, upheld by public opinion, sanctified by religion,
-and enforced by threats of eternal damnation for disobedience—were
-it not that under these potent influences,
-habits have been modified, and the feelings proper to them
-made innate—were it not, in short, that we have been
-rendered in a considerable degree organically moral; it is
-certain that disastrous results would ensue from the removal
-of those strong and distinct motives which the current belief
-supplies. Even as it is, those who relinquish the faith in
-which they have been brought up, for this most abstract faith
-in which Science and Religion unite, may not uncommonly
-fail to act up to their convictions. Left to their organic morality,
-enforced only by general reasonings imperfectly wrought
-out and difficult to keep before the mind, their defects of
-nature will often come out more strongly than they would
-have done under their previous creed. The substituted creed
-can become adequately operative only when it becomes, like
-the present one, an element in early education, and has the
-support of a strong social sanction. Nor will men be quite
-ready for it until, through the continuance of a discipline
-which has already partially moulded them to the conditions
-of social existence, they are completely moulded to those
-conditions.</p>
-
-<p class='c000'>We must therefore recognize the resistance to a change of
-<span class='pageno' id='Page_119'>119</span>theological opinion, as in great measure salutary. It is not
-simply that strong and deep-rooted feelings are necessarily
-excited to antagonism—it is not simply that the highest moral
-sentiments join in the condemnation of a change which seems
-to undermine their authority; but it is that a real adaptation
-exists between an established belief and the natures of those
-who defend it; and that the tenacity of the defence measures
-the completeness of the adaptation. Forms of religion, like forms
-of government, must be fit for those who live under them; and
-in the one case as in the other, that form which is fittest is that
-for which there is an instinctive preference. As certainly as a
-barbarous race needs a harsh terrestrial rule, and habitually
-shows attachment to a despotism capable of the necessary
-rigour; so certainly does such a race need a belief in a celestial
-rule that is similarly harsh, and habitually shows attachment
-to such a belief. And just in the same way that the sudden
-substitution of free institutions for tyrannical ones, is sure
-to be followed by a reaction; so, if a creed full of dreadful
-ideal penalties is all at once replaced by one presenting ideal
-penalties that are comparatively gentle, there will inevitably
-be a return to some modification of the old belief. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The
-parallelism holds yet further. During those early stages in
-which there is an extreme incongruity between the relatively
-best and the absolutely best, both political and religious changes,
-when at rare intervals they occur, are necessarily violent; and
-necessarily entail violent retrogressions. But as the incongruity
-between that which is and that which should be, diminishes, the
-changes become more moderate, and are succeeded by more moderate
-retrogressions; until, as these movements and counter-movements
-decrease in amount and increase in frequency,
-they merge into an almost continuous growth. That adhesion
-to old institutions and beliefs, which, in primitive societies,
-opposes an iron barrier to any advance, and which, after the
-barrier has been at length burst through, brings back the institutions
-and beliefs from that too-forward position to which
-the momentum of change had carried them, and so helps to
-<span class='pageno' id='Page_120'>120</span>re-adapt social conditions to the popular character—this adhesion
-to old institution and beliefs, eventually becomes the constant
-check by which the constant advance is prevented from
-being too rapid. This holds true of religious creeds and forms,
-as of civil ones. And so we learn that theological conservatism,
-like political conservatism, has an all-important function.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 33. That spirit of toleration which is so marked a characteristic
-of modern times, and is daily growing more conspicuous,
-has thus a far deeper meaning than is supposed. What
-we commonly regard simply as a due respect for the right of
-private judgment, is really a necessary condition to the balancing
-of the progressive and conservative tendencies—is a
-means of maintaining the adaptation between men’s beliefs
-and their natures. It is therefore a spirit to be fostered; and
-it is a spirit which the catholic thinker, who perceives the functions
-of these various conflicting creeds, should above all other
-men display. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Doubtless whoever feels the greatness
-of the error to which his fellows cling and the greatness of the
-truth which they reject, will find it hard to show a due patience.
-It is hard for him to listen calmly to the futile arguments
-used in support of irrational doctrines, and to the misrepresentation
-of antagonist doctrines. It is hard for him to
-bear the manifestation of that pride of ignorance which so far
-exceeds the pride of science. Naturally enough such a one
-will be indignant when charged with irreligion because he
-declines to accept the carpenter-theory of creation as the most
-worthy one. He may think it needless as it is difficult, to conceal
-his repugnance to a creed which tacitly ascribes to The
-Unknowable a love of adulation such as would be despised in
-a human being. Convinced as he is that all punishment, as
-we see it wrought out in the order of nature, is but a disguised
-beneficence, there will perhaps escape from him an angry condemnation
-of the belief that punishment is a divine vengeance,
-and that divine vengeance is eternal. He may be tempted to
-show his contempt when he is told that actions instigated by
-<span class='pageno' id='Page_121'>121</span>an unselfish sympathy or by a pure love of rectitude, are
-intrinsically sinful; and that conduct is truly good only
-when it is due to a faith whose openly-professed motive is
-other-worldliness. But he must restrain such feelings. Though
-he may be unable to do this during the excitement of controversy,
-or when otherwise brought face to face with current
-superstitions, he must yet qualify his antagonism in calmer
-moments; so that his mature judgment and resulting conduct
-may be without bias.</p>
-
-<p class='c000'>To this end let him ever bear in mind three cardinal
-facts—two of them already dwelt upon, and one still to be
-pointed out. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The first is that with which we set
-out; namely the existence of a fundamental verity under
-all forms of religion, however degraded. In each of them
-there is a soul of truth. Through the gross body of dogmas
-traditions and rites which contain it, it is always visible—dimly
-or clearly as the case may be. This it is which gives
-vitality even to the rudest creed; this it is which survives
-every modification; and this it is which we must not forget
-when condemning the forms under which it is presented.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The second of these cardinal facts, set forth at
-length in the foregoing section, is, that while those concrete
-elements in which each creed embodies this soul of truth,
-are bad as measured by an absolute standard, they are good
-as measured by a relative standard. Though from higher
-perceptions they hide the abstract verity within them; yet
-to lower perceptions they render this verity more appreciable
-than it would otherwise be. They serve to make real and
-influential over men, that which would else be unreal and uninfluential.
-Or we may call them the protective envelopes,
-without which the contained truth would die. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The
-remaining cardinal fact is, that these various beliefs are
-parts of the constituted order of things; and not accidental
-but necessary parts. Seeing how one or other of them is
-everywhere present; is of perennial growth; and when
-cut down, redevelops in a form but slightly modified; we
-<span class='pageno' id='Page_122'>122</span>cannot avoid the inference that they are needful accompaniments
-of human life, severally fitted to the societies in
-which they are indigenous. From the highest point of
-view, we must recognize them as elements in that great
-evolution of which the beginning and end are beyond our
-knowledge or conception—as modes of manifestation of The
-Unknowable; and as having this for their warrant.</p>
-
-<p class='c000'>Our toleration therefore should be the widest possible. Or
-rather, we should aim at something beyond toleration, as commonly
-understood. In dealing with alien beliefs, our endeavour
-must be, not simply to refrain from injustice of word or
-deed; but also to do justice by an open recognition of positive
-worth. We must qualify our disagreement with as much as
-may be of sympathy.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 34. These admissions will perhaps be held to imply, that
-the current theology should be passively accepted; or, at any
-rate, should not be actively opposed. “Why,” it may be
-asked, “if all creeds have an average fitness to their times and
-places, should we not rest content with that to which we are
-born? If the established belief contains an essential truth—if
-the forms under which it presents this truth, though
-intrinsically bad, are extrinsically good—if the abolition of
-these forms would be at present detrimental to the great majority—nay,
-if there are scarcely any to whom the ultimate
-and most abstract belief can furnish an adequate rule of life;
-surely it is wrong, for the present at least, to propagate this
-ultimate and most abstract belief.”</p>
-
-<p class='c000'>The reply is, that though existing religious ideas and institutions
-have an average adaptation to the characters of the
-people who live under them; yet, as these characters are ever
-changing, the adaptation is ever becoming imperfect; and the
-ideas and institutions need remodelling with a frequency proportionate
-to the rapidity of the change. Hence, while it is
-requisite that free play should be given to conservative thought
-and action, progressive thought and action must also have free
-<span class='pageno' id='Page_123'>123</span>play. Without the agency of both, there cannot be those continual
-re-adaptations which orderly progress demands.</p>
-
-<p class='c000'>Whoever hesitates to utter that which he thinks the highest
-truth, lest it should be too much in advance of the time,
-may reassure himself by looking at his acts from an impersonal
-point of view. Let him duly realize the fact that opinion
-is the agency through which character adapts external
-arrangements to itself—that his opinion rightly forms part of
-this agency—is a unit of force, constituting, with other such
-units, the general power which works out social changes; and
-he will perceive that he may properly give full utterance to
-his innermost conviction: leaving it to produce what effect it
-may. It is not for nothing that he has in him these sympathies
-with some principles and repugnance to others. He,
-with all his capacities, and aspirations, and beliefs, is not an
-accident, but a product of the time. He must remember that
-while he is a descendant of the past, he is a parent of the future;
-and that his thoughts are as children born to him,
-which he may not carelessly let die. He, like every other
-man, may properly consider himself as one of the myriad
-agencies through whom works the Unknown Cause; and
-when the Unknown Cause produces in him a certain belief,
-he is thereby authorized to profess and act out that belief.
-For, to render in their highest sense the words of the poet—</p>
-
-<div class='lg-container-b c022'>
- <div class='linegroup'>
- <div class='group'>
- <div class='line in6'>——Nature is made better by no mean,</div>
- <div class='line'>But nature makes that mean: over that art</div>
- <div class='line'>Which you say adds to nature, is an art</div>
- <div class='line'>That nature makes.</div>
- </div>
- </div>
-</div>
-
-<p class='c000'>Not as adventitious therefore will the wise man regard the
-faith which is in him. The highest truth he sees he will
-fearlessly utter; knowing that, let what may come of it, he is
-thus playing his right part in the world—knowing that if he
-can effect the change he aims at—well: if not—well also;
-though not <em>so</em> well.</p>
-
-<hr class='c015' />
-
-<div class='footnote' id='f7'>
-<p class='c000'><span class='label'><a href='#r7'>7</a>.&nbsp;&nbsp;</span><span class='pageno' id='Page_124'>124</span>These extracts are from an article entitled “Nature and God,” published in
-the <cite>National Review</cite> for October, 1860.</p>
-</div>
-
-<div class='chapter'>
- <span class='pageno' id='Page_125'>125</span>
- <h2 class='c005'>PART II.<br /> <br /> <span class='large'>LAWS OF THE KNOWABLE.</span></h2>
-</div>
-
-<div>
- <span class='pageno' id='Page_127'>127</span>
- <h3 class='c001'>CHAPTER I.<br /> <span class='large'>LAWS IN GENERAL.</span></h3>
-</div>
-
-<p class='c006'>§ 35. We have seen that intellectual advance has been
-dual—has been towards the establishment of both a positively
-unknown and a positively known. In making ever more
-certain the inaccessibility of one kind of truth, experience has
-made ever more certain the accessibility of another kind.
-The differentiation of the knowable from the unknowable, is
-shown as much in the reduction of the one to perfect clearness,
-as in the reduction of the other to impenetrable mystery.
-Progressing enlightenment discloses a definite limit to human
-intelligence; and while all which lies on the other side
-of the limit, is, with increasing distinctness, seen to transcend
-our finite faculties, it grows more and more obvious that all
-which lies on this side of the limit may become an indisputable
-possession.</p>
-
-<p class='c000'>To speak specifically—it has been shown that though we
-can never learn the <em>nature</em> of that which is manifested to us,
-we are daily learning more completely the <em>order</em> of its manifestations.
-We are conscious of effects produced in us by
-something separate from ourselves. The effects of which
-we are conscious—the changes of consciousness which make
-up our mental life, we ascribe to the forces of an external
-world. The intrinsic character of these forces—of this external
-world—of that which underlies all appearances, we
-find inscrutable; as is also the internal something whose
-changes constitute consciousness, but at the same time we
-<span class='pageno' id='Page_128'>128</span>find that among the changes of consciousness thus produced,
-there exist various constant relations; and we have no choice
-but to ascribe constancy to the relations which subsist among
-the inscrutable causes of these changes. Observation early
-discloses certain invariable connexions of coexistence and
-sequence among phenomena. Accumulating experiences
-tend continually to augment the number of invariable connexions
-recognized. When, as in the later stages of civilization,
-there arises not only a diligent gathering together of
-experiences but a critical comparison of them, more remote
-and complex connexions are added to the list. And gradually
-there grows up the habit of regarding these uniformities
-of relation as characterizing all manifestations of the
-Unknowable. Under the endless variety and seeming irregularity,
-there is ever more clearly discerned that “constant
-course of procedure” which we call Law.</p>
-
-<p class='c000'>The growing belief in the universality of Law, is so conspicuous
-to all cultivated minds as scarcely to need illustration.
-None who read these pages will ask for proof that this
-has been the central element of intellectual progress. But
-though the fact is sufficiently familiar, the philosophy of the
-fact is not so; and it will be desirable now to consider it.
-Partly because the development of our conception of Law will
-so be rendered more comprehensible; but chiefly because our
-subsequent course will thus be facilitated; I propose here to
-enumerate the several conditions that determine the order in
-which the various relations among phenomena are discovered.
-Seeing, as we shall, the consequent necessity of this order;
-and enabled, as we shall also be, to estimate the future by inference
-from the past; we shall perceive how inevitable is
-our advance towards the ultimatum that has been indicated.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 36. The recognition of Law, being the recognition of uniformity
-of relations among phenomena, it follows that the
-order in which different groups of phenomena are reduced to
-<span class='pageno' id='Page_129'>129</span>law, must depend on the frequency and distinctness with
-which the uniform relations they severally present, are experienced.
-At any given stage of progress, those uniformities
-will be most recognized with which men’s minds have been
-oftenest and most strongly impressed. In proportion partly
-to the number of times a relation has been presented to
-consciousness (not merely to the senses); and in proportion
-partly to the vividness with which the terms of the relation
-have been cognized; will be the degree in which the constancy
-of connexion is perceived.</p>
-
-<p class='c000'>The frequency and impressiveness with which different
-classes of relations are repeated in conscious experience, thus
-primarily determining the succession in which they are generalized,
-there result certain derivative principles to which
-this succession must more immediately and obviously conform.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;First in importance comes <em>the directness with
-which personal welfare is affected</em>. While, among surrounding
-things, many do not appreciably influence the body in any
-way, some act detrimentally and some beneficially, in various
-degrees; and manifestly, those things whose actions on the
-organism are most influential, will, <span lang="la" xml:lang="la">cæteris paribus</span>, be those
-whose laws of action are earliest observed. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Second
-in order, is <em>the conspicuousness of one or both the phenomena
-between which a relation is to be perceived</em>. On every side are
-countless phenomena so concealed as to be detected only by
-close observation; others not obtrusive enough to attract
-notice; others which moderately solicit the attention; others
-so imposing or vivid as to force themselves upon consciousness;
-and supposing incidental conditions to be the same, these
-last will of course be among the first to have their relations
-generalized. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;In the third place, we have <em>the absolute
-frequency with which the relations occur</em>. There are coexistences
-and sequences of all degrees of commonness, from those
-which are ever present to those which are extremely rare;
-and it is clear that the rare coexistences and sequences, as
-well as the sequences which are very long in taking place,
-<span class='pageno' id='Page_130'>130</span>will not be reduced to law so soon as those which are familiar
-and rapid. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Fourthly has to be added <em>the relative
-frequency of occurrence</em>. Many events and appearances are
-more or less limited to times and places; and as a relation
-which does not exist within the environment of an observer,
-cannot be cognized by him, however common it may be elsewhere
-or in another age, we have to take account of the surrounding
-physical circumstances, as well as the state of
-society, of the arts, and of the sciences—all of which affect
-the frequency with which certain groups of facts are exposed
-to observation. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The fifth corollary to be noticed, is,
-that the succession in which different classes of phenomena are
-reduced to law, depends in part on their <em>simplicity</em>. Phenomena
-presenting great composition of causes or conditions,
-have their essential relations so masked, that it requires accumulated
-experiences to impress upon consciousness the true
-connexion of antecedents and consequents they involve. Hence,
-other things equal, the progress of generalization will be
-from the simple to the complex; and this it is which M.
-Comte has wrongly asserted to be the sole regulative principle
-of the progress. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Sixth, and last, comes <em>the degree
-of abstractness</em>. Concrete relations are the earliest acquisitions.
-The colligation of any group of these into a general relation,
-which is the first step in abstraction, necessarily comes later
-than the discovery of the relations colligated. The union of a
-number of these lowest generalizations into a higher and
-more abstract generalization, is necessarily subsequent to the
-formation of such lowest generalizations. And so on continually,
-until the highest and most abstract generalizations
-have been reached.</p>
-
-<p class='c000'>These then are the several derivative principles. The frequency
-and vividness with which uniform relations are repeated
-in conscious experience, determining the recognition
-of their uniformity; and this frequency and vividness depending
-on the above conditions; it follows that the order in
-which different classes of facts are generalized, must depend
-<span class='pageno' id='Page_131'>131</span>on the extent to which the above conditions are fulfilled in
-each class. Let us mark how the facts harmonize with this
-conclusion: taking first a few that elucidate the general
-truth, and afterwards some that are illustrative of the several
-special truths which we here see follow from it.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 37. The relations earliest known as uniformities, are those
-subsisting between the common physical properties of matter—tangibility,
-visibility, cohesion, weight &amp;c. We have no
-trace of an era in human history when the resistance offered
-by every visible object, was regarded as caused by the will
-of the object; or when the pressure of a body on the hand
-supporting it, was ascribed to the direct agency of a living
-being. And accordingly, we see that these are the relations
-oftenest repeated in consciousness; being as they are, objectively
-frequent, conspicuous, simple, concrete, and of immediate
-personal concern.</p>
-
-<p class='c000'>Similarly with respect to the ordinary phenomena of motion.
-The fall of a mass on the withdrawal of its support, is a
-sequence which directly affects bodily welfare, is conspicuous,
-simple, concrete, and very often repeated. Hence it is one
-of the uniformities recognized before the dawn of tradition.
-We know of no time when movements due to terrestrial gravitation
-were attributed to volition. Only when the relation
-is obscured—only, as in the case of an aerolite, where the
-antecedent of the descent is unperceived, do we find the
-fetishistic conception persistent. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;On the other hand,
-motions of intrinsically the same order as that of a falling
-stone—those of the heavenly bodies—long remain ungeneralized;
-and until their uniformity is seen, are construed
-as results of will. This difference is clearly not dependent
-on comparative complexity or abstractness; since the motion
-of a planet in an ellipse, is as simple and concrete a phenomenon
-as the motion of a projected arrow in a parabola.
-But the antecedents are not conspicuous; the sequences are
-of long duration; and they are infrequently repeated.
-<span class='pageno' id='Page_132'>132</span>Hence in a given period, there cannot be the same multiplied
-experiences of them. And that this is the chief cause of their
-slow reduction to law, we see in the fact that they are severally
-generalized in the order of their frequency and conspicuousness—the
-moon’s monthly cycle, the sun’s annual
-change, the periods of the inferior planets, the periods of the
-superior planets.</p>
-
-<p class='c000'>While astronomical sequences were still ascribed to volition,
-certain terrestrial sequences of a different kind, but some
-of them equally without complication, were interpreted in like
-manner. The solidification of water at a low temperature, is
-a phenomenon that is simple, concrete, and of much personal
-concern. But it is neither so frequent as those which we
-saw are earliest generalized, nor is the presence of the antecedent
-so uniformly conspicuous. Though in all but tropical
-climates, mid-winter displays the relation between cold and
-freezing with tolerable constancy; yet, during the spring and
-autumn, the occasional appearance of ice in the mornings has
-no very manifest connexion with coldness of the weather.
-Sensation being so inaccurate a measure, it is not possible for
-the savage to experience the definite relation between a
-temperature of 32° and the congealing of water; and hence
-the long-continued conception of personal agency. Similarly,
-but still more clearly, with the winds. The absence of regularity
-and the inconspicuousness of the antecedents, allowed
-the mythological explanation to survive for a great period.</p>
-
-<p class='c000'>During the era in which the uniformity of many quite
-simple inorganic relations was still unrecognized, certain
-classes of organic relations, intrinsically very complex and
-special, were generalized. The constant coexistence of
-feathers and a beak, of four legs with a bony internal framework,
-of a particular leaf with poisonous berries, are facts
-which were, and are, familiar to every savage. Did a savage
-find a bird with teeth, or a mammal clothed with feathers, he
-would be as much surprised as an instructed naturalist; and
-would probably make a fetish of the anomalous form: so
-<span class='pageno' id='Page_133'>133</span>showing that while the exceptional relation suggested the
-notion of a personal cause, the habitual relation did not.
-Now these uniformities of organic structure which are so
-early perceived, are of exactly the same class as those more
-numerous ones later established by biology. The constant
-coexistence of mammary glands with two occipital condyles
-in the skull, of vertebræ with teeth lodged in sockets, of
-frontal horns with the habit of rumination, are generalizations
-as purely empirical as those known to the aboriginal
-hunter. The vegetal physiologist cannot in the least
-understand the complex relation between the kind of leaf
-and the kind of fruit borne by a particular plant: he
-knows these and like connexions simply in the same
-manner that the barbarian knows them. But the fact that
-sundry of the uniform relations which chiefly make up
-the organic sciences, were very early recognized, is due to
-the high degree of vividness and frequency with which they
-were presented to consciousness. Though the connexion between
-the form of a given creature and the sound it makes,
-or the quality of its fur, or the nature of its flesh, is extremely
-involved; yet the two terms of the relation are conspicuous;
-are usually observed in close juxtaposition in time and space;
-are so observed perhaps daily, or many times a day; and above
-all a knowledge of their connexion has a direct and obvious
-bearing on personal welfare. Meanwhile, we see that innumerable
-other relations of exactly the same order, which
-are displayed with even greater frequency by surrounding
-plants and animals, remain for thousands of years unrecognized,
-if they are unobtrusive or of no apparent moment.</p>
-
-<p class='c000'>When, passing from this primitive stage to a more advanced
-stage, we trace the discovery of those less familiar uniformities
-which constitute what is technically distinguished as Science,
-we find the order of discovery to be still determined in the
-same manner. We shall most clearly see this in contemplating
-separately the influence of each derivative condition; as
-was proposed in the last section.</p>
-
-<hr class='c013' />
-
-<p class='c000'><span class='pageno' id='Page_134'>134</span>§ 38. How relations that have an immediate bearing on the
-maintenance of life, are, other things equal, necessarily fixed
-in the mind before those which have no such immediate
-bearing, is abundantly illustrated in the history of Science.
-The habits of existing uncivilized races, who fix times by
-moons and barter so many of one article for so many of
-another, show us that numeration, which is the germ of
-mathematical science, commenced under the immediate pressure
-of personal wants; and it can scarcely be doubted that
-those laws of numerical relations which are embodied in the
-rules of arithmetic, were first brought to light through the
-practice of mercantile exchange. Similarly with Geometry.
-The derivation shows us that it originally included only certain
-methods of partitioning ground and laying out buildings.
-The properties of the scales and the lever, involving the first
-principle in mechanics, were early generalized under the
-stimulus of commercial and architectural needs. To fix the
-times of religious festivals and agricultural operations, were
-the motives which led to the establishment of the simpler
-astronomic periods. Such small knowledge of chemical relations
-as was involved in ancient metallurgy, was manifestly
-obtained in seeking how to improve tools and weapons. In
-the alchemy of later times, we see how greatly an intense hope
-of private benefit contributed to the disclosure of a certain
-class of uniformities. Nor is our own age barren of illustrations.
-“Here,” says Humboldt when in Guiana, “as in
-many parts of Europe, the sciences are thought worthy to
-occupy the mind, only so far as they confer some immediate
-and practical benefit on society.” “How is it possible to believe,”
-said a missionary to him, “that you have left your
-country to come and be devoured by mosquitoes on this
-river, and to measure lands that are not your own.” Our
-coasts furnish like instances. Every sea-side naturalist knows
-how great is the contempt with which fishermen regard the
-collection of objects for the microscope or aquarium: their
-incredulity as to the possible value of such things, being so
-<span class='pageno' id='Page_135'>135</span>great, that they can scarcely be induced even by bribes to
-preserve the refuse of their nets. Nay, we need not go for
-evidence beyond daily table-talk. The demand for “practical
-science”—for a knowledge that can be brought to bear on
-the business of life; joined to the ridicule commonly vented
-on pursuits that have no obvious use; suffice to show that the
-order in which different coexistences and sequences are discovered,
-greatly depends on the directness with which they
-affect our welfare.</p>
-
-<p class='c000'>That, when all other conditions are the same, obtrusive
-relations will be generalized before unobtrusive ones, is so
-nearly a truism that examples appear almost superfluous. If
-it be admitted that by the aboriginal man, as by the child,
-the co-existent properties of large surrounding objects are
-noticed before those of minute objects; and that the external
-relations which bodies present are generalized before their internal
-ones; it must be admitted that in all subsequent stages
-of progress, the comparative conspicuousness of relations has
-greatly affected the order in which they were recognized as
-uniform. Hence it happened that after the establishment of
-those very manifest sequences constituting a lunation, and those
-less manifest ones marking a year, and those still less manifest
-ones marking the planetary periods, Astronomy occupied itself
-with such inconspicuous sequences as those displayed in
-the repeating cycle of lunar eclipses, and those which suggested
-the theory of epicycles and eccentrics; while modern
-Astronomy deals with still more inconspicuous sequences: some
-of which, as the planetary rotations, are nevertheless the
-simplest which the heavens present. In Physics, the early
-use of canoes implied an empirical knowledge of certain
-hydrostatic relations that are intrinsically more complex than
-sundry static relations then unknown; but these hydrostatic
-relations were thrust upon observation. Or if we compare
-the solution of the problem of specific gravity by Archimedes,
-with the discovery of atmospheric pressure by Torricelli, (the
-two involving mechanical relations of exactly the same kind,)
-<span class='pageno' id='Page_136'>136</span>we perceive that the much earlier occurrence of the first than the
-last, was determined neither by a difference in their bearings
-on personal welfare, nor by a difference in the frequency with
-which illustrations of them come under observation, nor by
-relative simplicity; but solely by the greater obtrusiveness of
-the connexion between antecedent and consequent in the one
-case than in the other. Similarly with Chemistry. The
-burning of wood, the rusting of iron, the putrefaction of dead
-bodies, were early known as consequents uniformly related to
-certain antecedents; but not until long after was there reached
-a like empirical knowledge of the effect produced by air in
-the decomposition of soil: a phenomenon of equal simplicity,
-equal or greater importance, and greater frequency; but one
-that is extremely unobtrusive. Among miscellaneous illustrations,
-it may be pointed out that the connexions between lightning
-and thunder and between rain and clouds, were established
-long before others of the same order; simply because they
-thrust themselves on the attention. Or the long-delayed discovery
-of the microscopic forms of life, with all the phenomena
-they present, may be named as very clearly showing how
-certain groups of relations that are not ordinarily perceptible,
-though in all other respects like long-familiar relations, have
-to wait until changed conditions render them perceptible.
-But, without further details, it needs only to consider the inquiries
-which now occupy the electrician, the chemist, the
-physiologist, to see that Science has advanced and is advancing
-from the more conspicuous phenomena to the less
-conspicuous ones.</p>
-
-<p class='c000'>How the degree of absolute frequency of a relation affects
-the recognition of its uniformity, we see in contrasting certain
-biological facts. Death and disease are near akin in most
-of their relations to us; while in respect of complexity,
-conspicuousness, and the directness with which they personally
-concern us, diseases in general may be put pretty nearly
-on a level with each other. But there are great differences in
-the times at which the natural sequences they severally exhibit
-<span class='pageno' id='Page_137'>137</span>are recognized as such. The connexion between death and
-bodily injury, constantly displayed not only in men but in
-all inferior creatures, was known as an established uniformity
-while yet diseases were thought supernatural. Among diseases
-themselves, it is observable that comparatively unusual
-ones were regarded as of demoniacal origin during ages
-when the more frequent were ascribed to ordinary causes:
-a truth paralleled indeed among our own peasantry, who by the
-use of charms show a lingering superstition with respect to
-rare disorders, which they do not show with respect to common
-ones, such as colds. Passing to physical illustrations, we
-may note that within the historic period, whirlpools were accounted
-for by the agency of water-spirits; but we do not find
-that within the same period the disappearance of water on exposure
-either to the sun or to artificial heat was interpreted in
-an analogous way: though a much more marvellous occurrence,
-and a much more complex one, its great frequency
-led to the early establishment of it as a natural uniformity.
-Rainbows and comets do not differ greatly in conspicuousness,
-and a rainbow is intrinsically the more involved phenomenon;
-but chiefly because of their far greater commonness, rainbows
-were perceived to have a direct dependence on sun and rain
-while yet comets were regarded as supernatural appearances.</p>
-
-<p class='c000'>That races living inland must long have remained ignorant
-of the daily and monthly sequences of the tides, and that intertropical
-races could not early have comprehended the phenomena
-of northern winters, are extreme illustrations of the
-influence which relative frequency has on the recognition of
-uniformities. Animals which, where they are indigenous, call
-forth no surprise by their structure or habits, because these
-are so familiar, when taken to a part of the earth where they
-have never been seen, are looked at with an astonishment approaching
-to awe—are even thought supernatural: a fact
-which will suggest numerous others that show how the localization
-of phenomena, in part controls the order in which they
-<span class='pageno' id='Page_138'>138</span>are reduced to law. Not only however does their localization
-in space affect the progression, but also their localization
-in time. Facts which are rarely if ever manifested during
-one era, are rendered very frequent in another, simply through
-the changes wrought by civilization. The lever, of which the
-properties are illustrated in the use of sticks and weapons, is
-vaguely understood by every savage—on applying it in a
-certain way he rightly anticipates certain effects; but the action
-of the equally simple wedge, which is not commonly displayed
-till tool-making has made some progress, is less early
-generalized; while the wheel and axle, pulley, and screw,
-cannot have their powers either empirically or rationally
-known till the advance of the arts has more or less familiarized
-them. Through those various means of exploration which we
-have inherited and are ever increasing, we have become acquainted
-with a vast range of chemical relations that were relatively
-non-existent to the primitive man: to highly developed
-industries we owe both the substances and the apparatus that
-have disclosed to us countless uniformities which our ancestors
-had no opportunity of seeing, and therefore could not recognize.
-These and sundry like instances that will occur to the
-reader, show that the accumulated materials, and processes, and
-appliances, and products, which characterize the environments
-of complex societies, greatly increase the accessibility of various
-classes of relations; and by so multiplying the experiences
-of them, or making them relatively frequent, facilitate their
-generalization. To which add, that various classes of phenomena
-presented by society itself, as for instance those which
-political economy formulates, become relatively frequent and
-therefore recognizable in advanced social states; while in
-less advanced ones they are too rarely displayed to have their
-relations perceived, or, as in the least advanced ones, are not
-displayed at all.</p>
-
-<p class='c000'>That, where no other circumstances interfere, the order in
-which different uniformities are established varies as their complexity,
-is manifest. The geometry of straight lines was understood
-<span class='pageno' id='Page_139'>139</span>before the geometry of curved lines; the properties of
-the circle before the properties of the ellipse, parabola and hyperbola;
-and the equations of curves of single curvature were
-ascertained before those of curves of double curvature. Plane
-trigonometry comes in order of time and simplicity before
-spherical trigonometry; and the mensuration of plane surfaces
-and solids before the mensuration of curved surfaces and solids.
-Similarly with mechanics: the laws of simple motion were
-generalized before those of compound motion; and those of
-rectilinear motion before those of curvilinear motion. The
-properties of equal-armed levers, or scales, were understood before
-those of the lever with unequal arms; and the law of the
-inclined plane was formulated earlier than that of the screw,
-which involves it. In chemistry, the progress has been from
-the simple inorganic compounds, to the more involved organic
-ones. And where, as in most of the other sciences, the conditions
-of the exploration are more complicated, we still may
-clearly trace relative complexity as one of the determining
-circumstances.</p>
-
-<p class='c000'>The progression from concrete relations to abstract ones,
-and from the less abstract to the more abstract, is equally
-obvious. Numeration, which in its primary form concerned
-itself only with groups of actual objects, came earlier than
-simple arithmetic: the rules of which deal with numbers
-apart from objects. Arithmetic, limited in its sphere to
-concrete numerical relations, is alike earlier and less abstract
-than Algebra, which deals with the relations of these relations.
-And in like manner, the Infinitesimal Calculus comes after
-Algebra, both in order of evolution and in order of abstractness.
-In Astronomy, the progress has been from special
-generalizations, each expressing the motions of a particular
-planet, to the generalizations of Kepler, expressing the motions
-of the planets at large; and then to Newton’s generalization,
-expressing the motions of all heavenly bodies whatever.
-Similarly with Physics, Chemistry and Biology, there has
-ever been an advance from the relations of particular facts
-<span class='pageno' id='Page_140'>140</span>and particular classes of facts, to the relations presented by
-still wider classes—to truths of a high generality or greater
-abstractness.</p>
-
-<p class='c000'>Brief and rude as is this sketch of a mental development
-that has been long and complicated, it fulfils its end if it displays
-the several conditions that have regulated the course
-of the development. I venture to think it shows inductively,
-what was deductively inferred, that the order in which separate
-groups of uniformities are recognized, depends not on one
-circumstance but on several circumstances. A survey of the
-facts makes it manifest that the various classes of relations
-are generalized in a certain succession, not solely because of
-one particular kind of difference in their natures; but also
-because they are variously placed with respect to time, space,
-other relations, and our own constitutions: our perception of
-them being influenced by all these conditions in endless combinations.
-The comparative degrees of importance, of obtrusiveness,
-of absolute frequency, of relative frequency, of
-simplicity, of concreteness, are every one of them factors; and
-from their union in proportions that are more or less different
-in every case, there results a highly complex process of mental
-evolution. But while it thus becomes manifest that the
-proximate causes of the succession in which relations are
-reduced to law, are numerous and involved; it also becomes
-manifest that there is one ultimate cause to which these proximate
-ones are subordinate. As the several circumstances
-that determine the early or late recognition of uniformities,
-are circumstances that determine the number and strength of
-the impressions which these uniformities make on the mind;
-it follows that the progression conforms to a certain fundamental
-principle of psychology. We see <i><span lang="fr" xml:lang="fr">à posteriori</span></i>, what
-we concluded <i><span lang="fr" xml:lang="fr">à priori</span></i>, that the order in which relations are
-generalized, depends on the frequency and impressiveness with
-which they are repeated in conscious experience.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 39. And now to observe the bearings of these truths on
-<span class='pageno' id='Page_141'>141</span>our general argument. Having roughly analyzed the progress
-of the past, let us take advantage of the light thus
-thrown on the present, and consider what is implied respecting
-the future.</p>
-
-<p class='c000'>Note first that the likelihood of the universality of Law, has
-been ever growing greater. Out of the countless coexistences
-and sequences with which mankind are environed, they have
-been continually transferring some from the group whose order
-was supposed to be arbitrary, to the group whose order is
-known to be uniform. Age by age, the number of recognized
-connexions of phenomena has been increasing; and that of
-unrecognized connexions decreasing. And manifestly, as fast as
-the class of ungeneralized relations becomes smaller, the probability
-that among them there may be some that do not conform
-to law, becomes less. To put the argument numerically—It is
-clear that when out of surrounding phenomena a hundred of
-several kinds have been found to occur in constant connexions,
-there arises a slight presumption that all phenomena
-occur in constant connexions. When uniformity has been
-established in a thousand cases, more varied in their kinds,
-the presumption gains strength. And when the established
-cases of uniformity mount to myriads, including many of each
-variety, it becomes an ordinary induction that uniformity
-exists everywhere. Just as from the numerous observed cases
-in which heavenly bodies have been found to move in harmony
-with the law of gravitation, it is inferred that all
-heavenly bodies move in harmony with the law of gravitation;
-so, from the innumerable observed cases in which
-phenomena are found to stand in invariable connexions, it is
-inferred that in all cases phenomena stand in invariable connexions.</p>
-
-<p class='c000'>Silently and insensibly their experiences have been pressing
-men on towards the conclusion thus drawn. Not out of a
-conscious regard for these abstract reasons, but from a habit
-of thought which these abstract reasons formulate and justify,
-all minds have been advancing towards a belief in the constancy
-<span class='pageno' id='Page_142'>142</span>of surrounding coexistences and sequences. Familiarity
-with special uniformities, has generated the abstract conception
-of uniformity—the idea of <em>Law</em>; and this idea has been in
-successive generations slowly gaining fixity and clearness.
-Especially has it been thus among those whose knowledge of
-natural phenomena is the most extensive—men of science.
-The Mathematician, the Physicist, the Astronomer, the Chemist,
-severally acquainted with the vast accumulations of uniformities
-established by their predecessors, and themselves daily
-adding new ones as well as verifying the old, acquire a far
-stronger faith in Law than is ordinarily possessed. With them
-this faith, ceasing to be merely passive, becomes an active
-stimulus to inquiry. Wherever there exist phenomena of
-which the dependence is not yet ascertained, these most cultivated
-intellects, impelled by the conviction that here too there
-is some invariable connexion, proceed to observe, compare, and
-experiment; and when they discover the law to which the
-phenomena conform, as they eventually do, their general belief
-in the universality of law is further strengthened. So overwhelming
-is the evidence, and such the effect of this discipline,
-that to the advanced student of nature, the proposition
-that there are lawless phenomena, has become not only incredible
-but almost inconceivable.</p>
-
-<p class='c000'>Hence we may see how inevitably there must spread among
-mankind at large, this habitual recognition of law which already
-distinguishes modern thought from ancient thought. Not
-only is it that each conquest of generalization over a region of
-fact hitherto ungeneralized, and each merging of lower generalizations
-in a higher one, adds to the distinctness of this recognition
-among those immediately concerned—not only is it
-that the fulfilment of the predictions made possible by every new
-step, and the further command so gained of nature’s forces,
-prove to the uninitiated the validity of these generalizations
-and the doctrine they illustrate; but it is that widening education
-is daily diffusing among the mass of men, that knowledge
-of generalizations which has been hitherto confined to
-<span class='pageno' id='Page_143'>143</span>the few. And as fast as this diffusion goes on, must the belief
-of the scientific become the belief of the world at large. The
-simple accumulation of instances, must inevitably establish in
-the general mind, a conviction of the universality of law;
-even were the influence of this accumulation to be aided
-by no other.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 40. But it will be aided by another. From the evidence
-above set forth, it may be inferred that a secondary influence
-will by and by enforce this primary one. That law is universal,
-will become an irresistible conclusion when it is perceived that
-<em>the progress in the discovery of laws itself conforms to law</em>;
-and when it is hence understood why certain groups of phenomena
-have been reduced to law, while other groups are still
-unreduced. When it is seen that the order in which uniformities
-are recognized, must depend upon the frequency and
-vividness with which they are repeated in conscious experience;
-when it is seen that, as a matter of fact, the most
-common, important, conspicuous, concrete and simple uniformities
-were the earliest recognized, because they were experienced
-oftenest and most distinctly; when it is further seen that
-from the beginning the advance has been to the recognition of
-uniformities which, from one or other circumstance, were less
-often experienced; it will by implication be seen that long
-after the great mass of phenomena have been generalized,
-there must remain phenomena which, from their rareness, or
-unobtrusiveness, or seeming unimportance, or complexity, or
-abstractness, are still ungeneralized. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Thus will be
-furnished a solution to a difficulty sometimes raised. When it
-is asked why the universality of law is not already fully established,
-there will be the answer that the directions in which
-it is not yet established are those in which its establishment
-must necessarily be latest. That state of things which is
-inferable beforehand, is just the state which we find to exist.
-If such coexistences and sequences as those of Biology and
-Sociology are not yet reduced to law, the presumption is not
-<span class='pageno' id='Page_144'>144</span>that they are irreducible to law, but that their laws elude our
-present means of analysis. Having long ago proved uniformity
-throughout all the lower classes of relations; and having
-been step by step proving uniformity throughout classes of
-relations successively higher and higher; if we have not at
-present succeeded with the highest classes, it may be fairly concluded
-that our powers are at fault, rather than that the uniformity
-does not exist. And unless we make the absurd assumption
-that the process of generalization, now going on with
-unexampled rapidity, has reached its limit, and will suddenly
-cease, we must infer that ultimately mankind will discover a
-constant order of manifestation even in the most involved,
-obscure, and abstract phenomena.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 41. Not even yet, however, have we exhausted the evidence.
-The foregoing arguments have to be merged in another, still
-more cogent, which fuses all fragmentary proofs into one
-general proof.</p>
-
-<p class='c000'>Thus far we have spoken of laws that are more or less special;
-and from the still-continuing disclosure of special laws,
-each formulating some new class of phenomena, have inferred
-that eventually all classes of phenomena will be formulated.
-If, now, we find that there are laws of far higher generality,
-to which those constituting the body of Science are
-subordinate; the fact must greatly strengthen the proof that
-Law is universal. If, underneath different groups of concrete
-phenomena, Mechanical, Chemical, Thermal, Electric, &amp;c., we
-discern certain uniformities of action common to them all; we
-have a new and weighty reason for believing that uniformity
-of action pervades the whole of nature. And if we also see that
-these most general laws hold not only of the inorganic but of
-the organic worlds—if we see that the phenomena of Life, of
-Mind, of Society, whose special laws are yet unestablished,
-nevertheless conform to these most general laws; the proof
-of the universality of Law amounts to demonstration.</p>
-
-<p class='c000'>That there are laws of this transcendant generality, has now
-<span class='pageno' id='Page_145'>145</span>to be shown. To specify and illustrate them, will be the purpose
-of the succeeding chapters. And while, in contemplating
-them, we shall perceive how irresistible is the conclusion that
-the workings of the Unknowable are distinguished from those
-of finite agents by their absolute uniformity; we shall at the
-same time familiarize ourselves with those primary facts
-through which all other facts are to be interpreted.</p>
-
-<div>
- <span class='pageno' id='Page_146'>146</span>
- <h3 class='c001'>CHAPTER II.<br /> <span class='large'>THE LAW OF EVOLUTION.<a id='r8' /><a href='#f8' class='c011'><sup>[8]</sup></a></span></h3>
-</div>
-
-<p class='c006'>§ 42. The class of phenomena to be considered under the
-title of Evolution, is in a great measure co-extensive with the
-class commonly indicated by the word Progress. But the word
-Progress is here inappropriate, for several reasons. To specify
-these reasons will perhaps be the best way of showing
-what is to be understood by Evolution.</p>
-
-<p class='c000'>In the first place, the current conception of Progress is
-shifting and indefinite. Sometimes it comprehends little more
-than simple growth—as of a nation in the number of its
-members and the extent of territory over which it has spread.
-At other times it has reference to quantity of material products—as
-when the advance of agriculture and manufactures
-is the topic. Now the superior quality of these products is
-contemplated; and then the new or improved appliances by
-which they are produced. When, again, we speak of moral
-or intellectual progress, we refer to the state of the individual
-or people exhibiting it; while, when the progress of Knowledge,
-of Science, of Art, is commented upon, we have in view
-certain abstract results of human thought and action. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;In
-the second place, besides being more or less vague, the
-<span class='pageno' id='Page_147'>147</span>ordinary idea of Progress is in great measure erroneous. It
-takes in not so much the reality as its accompaniments—not
-so much the substance as the shadow. That progress in intelligence
-seen during the growth of the child into the man,
-or the savage into the philosopher, is commonly regarded as
-consisting in the greater number of facts known and laws
-understood; whereas the actual progress consists in those
-internal modifications of which this increased knowledge is
-the expression. Social progress is supposed to consist in the
-produce of a greater quantity and variety of the articles
-required for satisfying men’s wants—in the increasing security
-of person and property—in widening freedom of action;
-whereas, rightly understood, social progress consists in those
-changes of structure in the social organism which have entailed
-these consequences. The interpretation is a teleological one.
-The phenomena are contemplated solely as bearing on human
-happiness. Only those changes are held to constitute progress,
-which directly or indirectly tend to heighten human
-happiness. And they are thought to constitute progress simply
-<em>because</em> they tend to heighten human happiness. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;In
-the third place, in consequence of its teleological implications,
-the term Progress is rendered scarcely applicable to a wide
-range of phenomena which are intrinsically of the same nature
-as those included under it. The metamorphoses of an insect
-are only by analogy admitted within the scope of the word, as
-popularly accepted; though, considered in themselves, they
-have as much right there as the changes which constitute
-civilization. Having no apparent bearing on human interests,
-an increasing complication in the arrangement of ocean-currents,
-would not ordinarily be regarded as progress; though
-really of the same character as phenomena which are so
-regarded.</p>
-
-<p class='c000'>Hence the need for another word. Our purpose here is to
-analyze the various class of changes usually considered as
-Progress, together with others like them which are not so
-considered; and to see what is their intrinsic peculiarity—what
-<span class='pageno' id='Page_148'>148</span>is their essential nature apart from their bearings on our
-welfare. And that we may avoid the confusion of thought
-likely to result from pre-established associations, it will be
-best to substitute for the term Progress, the term Evolution.
-Our question is then—what is Evolution?</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 43. In respect to that evolution which individual organisms
-display, this question has been answered. Pursuing an
-idea which Harvey set afloat, Wolff, Goethe, and Von Baer,
-have established the truth that the series of changes gone
-through during the development of a seed into a tree, or
-an ovum into an animal, constitute an advance from homogeneity
-of structure to heterogeneity of structure. In its primary
-stage, every germ consists of a substance that is uniform
-throughout, both in texture and chemical composition. The
-first step is the appearance of a difference between two parts
-of this substance; or, as the phenomenon is called in physiological
-language, a differentiation. Each of these differentiated
-divisions presently begins itself to exhibit some contrast of
-parts; and by and by these secondary differentiations become
-as definite as the original one. This process is continuously
-repeated—is simultaneously going on in all parts of the growing
-embryo; and by endless such differentiations there is
-finally produced that complex combination of tissues and
-organs, constituting the adult animal or plant. This is the
-history of all organisms whatever. It is settled beyond dispute
-that organic evolution consists in a change from the
-homogeneous to the heterogeneous.</p>
-
-<p class='c000'>Now I propose in the first place to show, that this law of
-organic evolution is the law of all evolution. Whether it be
-in the development of the Earth, in the development of Life
-upon its surface, in the development of Society, of Government,
-of Manufactures, of Commerce, of Language, Literature,
-Science, Art, this same advance from the simple to the complex,
-through successive differentiations, holds uniformly.
-From the earliest traceable cosmical changes down to the
-<span class='pageno' id='Page_149'>149</span>latest results of civilization, we shall find that the transformation
-of the homogeneous into the heterogeneous, is that in
-which Evolution essentially consists.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 44. With the view of showing that <em>if</em> the Nebular Hypothesis
-be true, the genesis of the solar system supplies one
-illustration of this law, let us assume that the matter of which
-the sun and planets consist was once in a diffused form; and
-that from the gravitation of its atoms there resulted a gradual
-concentration. By the hypothesis, the solar system in its
-nascent state existed as an indefinitely extended and nearly
-homogeneous medium—a medium almost homogeneous in
-density, in temperature, and in other physical attributes.
-The first advance towards consolidation resulted in a differentiation
-between the occupied space which the nebulous mass
-still filled, and the unoccupied space which it previously filled.
-There simultaneously resulted a contrast in density and a contrast
-in temperature, between the interior and the exterior of
-this mass. And at the same time there arose throughout it,
-rotatory movements, whose velocities varied according to their
-distances from its centre. These differentiations increased in
-number and degree until there was evolved the organized
-group of sun, planets, and satellites, which we now know—a
-group which presents numerous contrasts of structure and
-action among its members. There are the immense contrasts
-between the sun and the planets, in bulk and in weight; as
-well as the subordinate contrasts between one planet and another,
-and between the planets and their satellites. There is
-the similarly marked contrast between the sun as almost stationary,
-and the planets as moving round him with great
-velocity; while there are the secondary contrasts between the
-velocities and periods of the several planets, and between
-their simple revolutions and the double ones of their satellites,
-which have to move round their primaries while moving
-round the sun. There is the yet further strong contrast between
-the sun and the planets in respect of temperature; and
-<span class='pageno' id='Page_150'>150</span>there is reason to suppose that the planets and satellites differ
-from each other in their proper heat, as well as in the heat
-they receive from the sun. When we bear in mind that, in
-addition to these various contrasts, the planets and satellites
-also differ in respect to their distances from each other and
-their primary; in respect to the inclinations of their orbits,
-the inclinations of their axes, their times of rotation on their
-axes, their specific gravities, and their physical constitutions;
-we see what a high degree of heterogeneity the solar system
-exhibits, when compared with the almost complete homogeneity
-of the nebulous mass out of which it is supposed to
-have originated.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 45. Passing from this hypothetical illustration, which
-must be taken for what it is worth, without prejudice to the
-general argument, let us descend to a more certain order of
-evidence.</p>
-
-<p class='c000'>It is now generally agreed among geologists that the Earth
-was at first a mass of molten matter; and that it is still fluid
-and incandescent at the distance of a few miles beneath its
-surface. Originally, then, it was homogeneous in consistence,
-and, because of the circulation that takes place in heated fluids,
-must have been comparatively homogeneous in temperature;
-and it must have been surrounded by an atmosphere consisting
-partly of the elements of air and water, and partly of
-those various other elements which assume a gaseous form at
-high temperatures. That slow cooling by radiation which is
-still going on at an inappreciable rate, and which, though
-originally far more rapid than now, necessarily required an
-immense time to produce any decided change, must ultimately
-have resulted in the solidification of the portion most able to
-part with its heat; namely, the surface. In the thin crust
-thus formed, we have the first marked differentiation. A still
-further cooling, a consequent thickening of this crust, and an
-accompanying deposition of all solidifiable elements contained
-in the atmosphere, must finally have been followed by the
-<span class='pageno' id='Page_151'>151</span>condensation of the water previously existing as vapour. A
-second marked differentiation must thus have arisen; and as
-the condensation must have taken place on the coolest parts
-of the surface—namely, about the poles—there must thus
-have resulted the first geographical distinction of parts.</p>
-
-<p class='c000'>To these illustrations of growing heterogeneity, which,
-though deduced from the known laws of matter, may be regarded
-as more or less hypothetical, Geology adds an extensive
-series that have been inductively established. Its investigations
-show that the Earth has been continually becoming more
-heterogeneous through the multiplication of the strata which
-form its crust; further, that it has been becoming more
-heterogeneous in respect of the composition of these strata,
-the latter of which, being made from the detritus of the older
-ones, are many of them rendered highly complex by the mixture
-of materials they contain; and that this heterogeneity
-has been vastly increased by the action of the Earth’s still
-molten nucleus upon its envelope: whence have resulted not
-only a great variety of igneous rocks, but the tilting up of
-sedimentary strata at all angles, the formation of faults and
-metallic veins, the production of endless dislocations and irregularities.
-Yet again, geologists teach us that the Earth’s
-surface has been growing more varied in elevation—that the
-most ancient mountain systems are the smallest, and the Andes
-and Himalayas the most modern; while, in all probability,
-there have been corresponding changes in the bed of the ocean.
-As a consequence of these ceaseless differentiations, we now
-find that no considerable portion of the Earth’s exposed surface
-is like any other portion, either in contour, in geologic
-structure, or in chemical composition; and that in most
-parts it changes from mile to mile in all these characteristics.</p>
-
-<p class='c000'>Moreover, it must not be forgotten that there has been
-simultaneously going on a gradual differentiation of climates.
-As fast as the Earth cooled and its crust solidified, there arose
-appreciable differences in temperature between those parts of
-its surface most exposed to the sun and those less exposed.
-<span class='pageno' id='Page_152'>152</span>Gradually, as the cooling progressed, these differences became
-more pronounced; until there finally resulted the marked
-contrasts between regions of perpetual ice and snow, regions
-where winter and summer alternately reign for periods varying
-according to the latitude, and regions where summer
-follows summer with scarcely an appreciable variation. At
-the same time, the successive elevations and subsidences of
-different portions of the Earth’s crust, tending as they have
-done to the present irregular distribution of land and sea,
-have entailed various modifications of climate beyond those
-dependent on latitude; while a yet further series of such
-modifications have been produced by increasing differences of
-elevation in the land, which have in sundry places brought
-arctic, temperate, and tropical climates to within a few miles
-of each other. And the general result of these changes is,
-that not only has every extensive region its own meteorologic
-conditions, but that every locality in each region differs more
-or less from others in those conditions: as in its structure,
-its contour, its soil.</p>
-
-<p class='c000'>Thus, between our existing Earth, the phenomena of whose
-varied crust neither geographers, geologists, mineralogists
-nor meteorologists have yet enumerated, and the molten globe
-out of which it was evolved, the contrast in heterogeneity is
-sufficiently striking.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 46. When from the Earth itself we turn to the plants
-and animals that have lived, or still live, upon its surface, we
-find ourselves in some difficulty from lack of facts. That
-every existing organism has been developed out of the simple
-into the complex, is indeed the first established truth of all;
-and that every organism which has existed was similarly developed,
-is an inference that no physiologist will hesitate to draw.
-But when we pass from individual forms of life to Life in
-general, and inquire whether the same law is seen in the
-<em>ensemble</em> of its manifestations,—whether modern plants and
-animals are of more heterogeneous structure than ancient ones,
-<span class='pageno' id='Page_153'>153</span>and whether the Earth’s present Flora and Fauna are more
-heterogeneous than the Flora and Fauna of the past,—we find
-the evidence so fragmentary, that every conclusion is open to
-dispute. Two-thirds of the Earth’s surface being covered
-by water; a great part of the exposed land being inaccessible
-to, or untravelled by, the geologist; the greater part of the
-remainder having been scarcely more than glanced at; and
-even the most familiar portions, as England, having been so
-imperfectly explored, that a new series of strata has been
-added within these few years,—it is manifestly impossible for
-us to say with any certainty what creatures have, and what
-have not, existed at any particular period. Considering the
-perishable nature of many of the lower organic forms, the
-metamorphosis of many sedimentary strata, and the gaps that
-occur among the rest, we shall see further reason for distrusting
-our deductions. On the one hand, the repeated discovery
-of vertebrate remains in strata previously supposed to contain
-none,—of reptiles where only fish were thought to exist,—of
-mammals where it was believed there were no creatures higher
-than reptiles; renders it daily more manifest how small is the
-value of negative evidence. On the other hand, the worthlessness
-of the assumption that we have discovered the earliest,
-or anything like the earliest, organic remains, is becoming
-equally clear. That the oldest known aqueous formations have
-been greatly changed by igneous action, and that still older
-ones have been totally transformed by it, is becoming undeniable.
-And the fact that sedimentary strata earlier than any
-we know, have been melted up, being admitted, it must also
-be admitted that we cannot say how far back in time this
-destruction of sedimentary strata has been going on. Thus it
-is manifest that the title <em>Palæozoic</em>, as applied to the earliest
-known fossiliferous strata, involves a <i><span lang="la" xml:lang="la">petitio principii</span></i>; and
-that, for aught we know to the contrary, only the last few
-chapters of the Earth’s biological history may have come down
-to us.</p>
-
-<p class='c000'>All inferences drawn from such scattered facts as we find,
-<span class='pageno' id='Page_154'>154</span>must thus be extremely questionable. If, looking at the
-general aspect of evidence, a progressionist argues that the
-earliest known vertebrate remains are those of Fishes, which
-are the most homogeneous of the vertebrata; that Reptiles,
-which are more heterogeneous, are later; and that later still,
-and more heterogeneous still, are Mammals and Birds; it may
-be replied that the Palæozoic deposits, not being estuary deposits,
-are not likely to contain the remains of terrestrial vertebrata,
-which may nevertheless have existed at that era.
-The same answer may be made to the argument that the
-vertebrate fauna of the Palæozoic period, consisting so far as
-we know, entirely of Fishes, was less heterogeneous than the
-modern vertebrate fauna, which includes Reptiles, Birds and
-Mammals, of multitudinous genera; or the uniformitarian
-may contend with great show of truth, that this appearance
-of higher and more varied forms in later geologic eras, was
-due to progressive immigration—that a continent slowly
-upheaved from the ocean at a point remote from pre-existing
-continents, would necessarily be peopled from them in a succession
-like that which our strata display. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;At the
-same time the counter-arguments may be proved equally inconclusive.
-When, to show that there cannot have been a continuous
-evolution of the more homogeneous organic forms
-into the more heterogeneous ones, the uniformitarian points
-to the breaks that occur in the succession of these forms; there
-is the sufficient answer that current geological changes show
-us why such breaks must occur, and why, by subsidences and
-elevations of large area, there must be produced such marked
-breaks as those which divide the three great geologic epochs.
-Or again, if the opponent of the development hypothesis cites
-the facts set forth by Professor Huxley in his lecture on
-“Persistent Types”—if he points out that “of some two
-hundred known orders of plants, not one is exclusively fossil,”
-while “among animals, there is not a single totally extinct
-class; and of the orders, at the outside not more than seven
-per cent. are unrepresented in the existing creation”—if he
-<span class='pageno' id='Page_155'>155</span>urges that among these some have continued from the
-Silurian epoch to our own day with scarcely any change—and
-if he infers that there is evidently a much greater average
-resemblance between the living forms of the past and those of
-the present, than consists with this hypothesis; there is still
-a satisfactory reply, on which in fact Prof. Huxley insists;
-namely, that we have evidence of a “pre-geologic era” of
-unknown duration. And indeed, when it is remembered,
-that the enormous subsidences of the Silurian period show
-the Earth’s crust to have been approximately as thick then as
-it is now—when it is concluded that the time taken to form
-so thick a crust, must have been immense as compared with
-the time which has since elapsed—when it is assumed, as it
-must be, that during this comparatively immense time the
-geologic and biologic changes went on at their usual rates;
-it becomes manifest, not only that the palæontological
-records which we find, do not negative the theory of
-evolution, but that they are such as might rationally be
-looked for.</p>
-
-<p class='c000'>Moreover, it must not be forgotten that though the evidence
-suffices neither for proof nor disproof, yet some of its most
-conspicuous facts support the belief, that the more heterogeneous
-organisms and groups of organisms, have been evolved
-from the less heterogeneous ones. The average community
-of type between the fossils of adjacent strata, and still more
-the community that is found between the latest tertiary
-fossils and creatures now existing, is one of these facts. The
-discovery in some modern deposits of such forms as the
-Palæotherium and Anaplotherium, which, if we may rely on
-Prof. Owen, had a type of structure intermediate between
-some of the types now existing, is another of these facts. And
-the comparatively recent appearance of Man, is a third fact of
-this kind, which possesses still greater significance. Hence
-we may say, that though our knowledge of past life upon the
-Earth, is too scanty to justify us in asserting an evolution of
-the simple into the complex, either in individual forms or in
-<span class='pageno' id='Page_156'>156</span>the aggregate of forms; yet the knowledge we have, not only
-consists with the belief that there has been such an evolution,
-but rather supports it than otherwise.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 47. Whether an advance from the homogeneous to the
-heterogeneous is or is not displayed in the biological history
-of the globe, it is clearly enough displayed in the progress of
-the latest and most heterogeneous creature—Man. It is alike
-true that, during the period in which the Earth has been
-peopled, the human organism has grown more heterogeneous
-among the civilized divisions of the species; and that the
-species, as a whole, has been made more heterogeneous by
-the multiplication of races and the differentiation of these
-races from each other. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;In proof of the first of these
-positions, we may cite the fact that, in the relative development
-of the limbs, the civilized man departs more widely
-from the general type of the placental mammalia, than do the
-lower human races. Though often possessing well-developed
-body and arms, the Papuan has extremely small legs: thus
-reminding us of the quadrumana, in which there is no great
-contrast in size between the hind and fore limbs. But in the
-European, the greater length and massiveness of the legs has
-become very marked—the fore and hind limbs are relatively
-more heterogeneous. Again, the greater ratio which the
-cranial bones bear to the facial bones, illustrates the same
-truth. Among the vertebrata in general, evolution is marked
-by an increasing heterogeneity in the vertebral column, and
-more especially in the segments constituting the skull: the
-higher forms being distinguished by the relatively larger size
-of the bones which cover the brain, and the relatively smaller
-size of those which form the jaws, &amp;c. Now, this characteristic,
-which is stronger in Man than in any other creature, is
-stronger in the European than in the savage. Moreover,
-judging from the greater extent and variety of faculty he exhibits,
-we may infer that the civilized man has also a more
-complex or heterogeneous nervous system than the uncivilized
-<span class='pageno' id='Page_157'>157</span>man; and indeed the fact is in part visible in the increased
-ratio which his cerebrum bears to the subjacent
-ganglia. If further elucidation be needed, we may find it in
-every nursery. The infant European has sundry marked
-points of resemblance to the lower human races; as in the
-flatness of the alæ of the nose, the depression of its bridge, the
-divergence and forward opening of the nostrils, the form of
-the lips, the absence of a frontal sinus, the width between the
-eyes, the smallness of the legs. Now, as the developmental
-process by which these traits are turned into those of the
-adult European, is a continuation of that change from the
-homogeneous to the heterogeneous displayed during the previous
-evolution of the embryo, which every physiologist will
-admit; it follows that the parallel developmental process by
-which the like traits of the barbarous races have been turned
-into those of the civilized races, has also been a continuation
-of the change from the homogeneous to the heterogeneous.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The truth of the second position—that Mankind,
-as a whole, have become more heterogeneous—is so obvious as
-scarcely to need illustration. Every work on Ethnology, by
-its divisions and subdivisions of races, bears testimony to it.
-Even were we to admit the hypothesis that Mankind originated
-from several separate stocks, it would still remain true
-that as, from each of these stocks, there have sprung many
-now widely different tribes, which are proved by philological
-evidence to have had a common origin, the race as a whole
-is far less homogeneous than it once was. Add to which,
-that we have, in the Anglo-Americans, an example of a new
-variety arising within these few generations; and that, if we
-may trust to the descriptions of observers, we are likely soon
-to have another such example in Australia.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 48. On passing from Humanity under its individual form,
-to Humanity as socially embodied, we find the general law still
-more variously exemplified. The change from the homogeneous
-to the heterogeneous, is displayed equally in the
-<span class='pageno' id='Page_158'>158</span>progress of civilization as a whole, and in the progress of
-every tribe or nation; and is still going on with increasing
-rapidity.</p>
-
-<p class='c000'>As we see in existing barbarous tribes, society in its first
-and lowest form is a homogeneous aggregation of individuals
-having like powers and like functions: the only marked difference
-of function being that which accompanies difference
-of sex. Every man is warrior, hunter, fisherman, tool-maker,
-builder; every woman performs the same drudgeries; every
-family is self-sufficing, and, save for purposes of aggression
-and defence, might as well live apart from the rest. Very
-early, however, in the process of social evolution, we find an
-incipient differentiation between the governing and the governed.
-Some kind of chieftainship seems coeval with the
-first advance from the state of separate wandering families to
-that of a nomadic tribe. The authority of the strongest
-makes itself felt among a body of savages, as in a herd of animals,
-or a posse of school-boys. At first, however, it is indefinite,
-uncertain; is shared by others of scarcely inferior power;
-and is unaccompanied by any difference in occupation or style
-of living: the first ruler kills his own game, makes his own
-weapons, builds his own hut, and, economically considered,
-does not differ from others of his tribe. Gradually, as the
-tribe progresses, the contrast between the governing and the
-governed grows more decided. Supreme power becomes hereditary
-in one family; the head of that family, ceasing to provide
-for his own wants, is served by others; and he begins to
-assume the sole office of ruling. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;At the same time
-there has been arising a co-ordinate species of government—that
-of Religion. As all ancient records and traditions
-prove, the earliest rulers are regarded as divine personages.
-The maxims and commands they uttered during their lives
-are held sacred after their deaths, and are enforced by their
-divinely-descended successors; who in their turns are promoted
-to the pantheon of the race, there to be worshipped
-and propitiated along with their predecessors: the most ancient
-<span class='pageno' id='Page_159'>159</span>of whom is the supreme god, and the rest subordinate
-gods. For a long time these connate forms of government—civil
-and religious—continue closely associated. For many generations
-the king continues to be the chief priest, and the
-priesthood to be members of the royal race. For many ages
-religious law continues to contain more or less of civil regulation,
-and civil law to possess more or less of religious sanction;
-and even among the most advanced nations these two
-controlling agencies are by no means completely differentiated
-from each other. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Having a common root with these,
-and gradually diverging from them, we find yet another controlling
-agency—that of Manners or ceremonial usages. All
-titles of honour are originally the names of the god-king;
-afterwards of God and the king; still later of persons of high
-rank; and finally come, some of them, to be used between
-man and man. All forms of complimentary address were at
-first the expressions of submission from prisoners to their
-conqueror, or from subjects to their ruler, either human or
-divine—expressions that were afterwards used to propitiate
-subordinate authorities, and slowly descended into ordinary
-intercourse. All modes of salutation were once obeisances
-made before the monarch and used in worship of him after
-his death. Presently others of the god-descended race were
-similarly saluted; and by degrees some of the salutations
-have become the due of all.<a id='r9' /><a href='#f9' class='c011'><sup>[9]</sup></a> Thus, no sooner does the originally
-homogeneous social mass differentiate into the governed
-and the governing parts, than this last exhibits an incipient
-differentiation into religious and secular—Church and State;
-while at the same time there begins to be differentiated from
-both, that less definite species of government which rides
-our daily intercourse—a species of government which, as we
-may see in heralds’ colleges, in books of the peerage, in masters
-of ceremonies, is not without a certain embodiment of its
-own. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Each of these kinds of government is itself subject
-to successive differentiations. In the course of ages, there
-<span class='pageno' id='Page_160'>160</span>arises, as among ourselves, a highly complex political organization
-of monarch, ministers, lords and commons, with their
-subordinate administrative departments, courts of justice,
-revenue offices, &amp;c., supplemented in the provinces by municipal
-governments, county governments, parish or union
-governments—all of them more or less elaborated. By its
-side there grows up a highly complex religious organization,
-with its various grades of officials from archbishops down to
-sextons, its colleges, convocations, ecclesiastical courts, &amp;c.;
-to all which must be added the ever-multiplying independent
-sects, each with its general and local authorities. And at the
-same time there is developed a highly complex aggregation
-of customs, manners, and temporary fashions, enforced by
-society at large, and serving to control those minor transactions
-between man and man which are not regulated by
-civil and religious law. Moreover, it is to be observed that
-this ever-increasing heterogeneity in the governmental appliances
-of each nation, has been accompanied by an increasing
-heterogeneity in the governmental appliances of different
-nations: all of which are more or less unlike in their political
-systems and legislation, in their creeds and religious institutions,
-in their customs and ceremonial usages.</p>
-
-<p class='c000'>Simultaneously there has been going on a second differentiation
-of a more familiar kind; that, namely, by which the
-mass of the community has been segregated into distinct
-classes and orders of workers. While the governing part has
-undergone the complex development above detailed, the governed
-part has undergone an equally complex development;
-which has resulted in that minute division of labour characterizing
-advanced nations. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;It is needless to trace
-out this progress from its first stages, up through the caste
-divisions of the East and the incorporated guilds of Europe,
-to the elaborate producing and distributing organization existing
-among ourselves. Political economists have long since
-indicated the evolution which, beginning with a tribe whose
-members severally perform the same actions, each for himself
-<span class='pageno' id='Page_161'>161</span>ends with a civilized community whose members severally
-perform different actions for each other; and they have further
-pointed out the changes through which the solitary producer
-of any one commodity, is transformed into a combination
-of producers who, united under a master, take separate parts
-in the manufacture of such commodity. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;But there
-are yet other and higher phases of this advance from the
-homogeneous to the heterogeneous in the industrial organization
-of society. Long after considerable progress has been
-made in the division of labour among the different classes of
-workers, there is still little or no division of labour among the
-widely separated parts of the community: the nation continues
-comparatively homogeneous in the respect that in each district
-the same occupations are pursued. But when roads and other
-means of transit become numerous and good, the different
-districts begin to assume different functions, and to become
-mutually dependent. The calico-manufacture locates itself in
-this county, the woollen-manufacture in that; silks are produced
-here, lace there; stockings in one place, shoes in another;
-pottery, hardware, cutlery, come to have their special
-towns; and ultimately every locality grows more or less distinguished
-from the rest by the leading occupation carried on
-in it. Nay, more, this subdivision of functions shows itself
-not only among the different parts of the same nation, but
-among different nations. That exchange of commodities
-which free-trade promises so greatly to increase, will ultimately
-have the effect of specializing, in a greater or less
-degree, the industry of each people. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;So that beginning
-with a barbarous tribe, almost if not quite homogeneous
-in the functions of its members, the progress has been, and
-still is, towards an economic aggregation of the whole human
-race; growing ever more heterogeneous in respect of the
-separate functions assumed by separate nations, the separate
-functions assumed by the local sections of each nation, the
-separate functions assumed by the many kinds of makers
-and traders in each town, and the separate functions assumed
-<span class='pageno' id='Page_162'>162</span>by the workers united in producing each commodity.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 49. Not only is the law thus clearly exemplified in the
-evolution of the social organism, but it is exemplified with
-equal clearness in the evolution of all products of human
-thought and action; whether concrete or abstract, real or
-ideal. Let us take Language as our first illustration.</p>
-
-<p class='c000'>The lowest form of language is the exclamation, by which
-an entire idea is vaguely conveyed through a single sound; as
-among the lower animals. That human language ever consisted
-solely of exclamations, and so was strictly homogeneous
-in respect of its parts of speech, we have no evidence. But
-that language can be traced down to a form in which nouns
-and verbs are its only elements, is an established fact. In
-the gradual multiplication of parts of speech out of these
-primary ones—in the differentiation of verbs into active and
-passive, of nouns into abstract and concrete—in the rise of
-distinctions of mood, tense, person, of number and case—in
-the formation of auxiliary verbs, of adjectives, adverbs, pronouns,
-prepositions, articles—in the divergence of those orders,
-genera, species, and varieties of parts of speech by which
-civilized races express minute modifications of meaning—we
-see a change from the homogeneous to the heterogeneous.
-And it may be remarked, in passing, that it is more especially
-in virtue of having carried this subdivision of functions
-to a greater extent and completeness, that the English
-language is superior to all others. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Another aspect
-under which we may trace the development of language, is
-the differentiation of words of allied meanings. Philology
-early disclosed the truth that in all languages words
-may be grouped into families having a common ancestry.
-An aboriginal name, applied indiscriminately to each of
-an extensive and ill-defined class of things or actions, presently
-undergoes modifications by which the chief divisions
-of the class are expressed. These several names springing
-<span class='pageno' id='Page_163'>163</span>from the primitive root, themselves become the parents of
-other names still further modified. And by the aid of those
-systematic modes which presently arise, of making derivatives
-and forming compound terms expressing still smaller distinctions,
-there is finally developed a tribe of words so
-heterogeneous in sound and meaning, that to the uninitiated
-it seems incredible they should have had a common origin.
-Meanwhile, from other roots there are being evolved other
-such tribes, until there results a language of some sixty
-thousand or more unlike words, signifying as many unlike
-objects, qualities, acts. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Yet another way in which
-language in general advances from the homogeneous to the
-heterogeneous, is in the multiplication of languages. Whether,
-as Max Müller and Bunsen think, all languages have
-grown from one stock, or whether, as some philologists say,
-they have grown from two or more stocks, it is clear that
-since large families of languages, as the Indo-European, are
-of one parentage, they have become distinct through a process
-of continuous divergence. The same diffusion over the
-Earth’s surface which has led to the differentiation of the
-race, has simultaneously led to a differentiation of their
-speech: a truth which we see further illustrated in each
-nation by the peculiarities of dialect found in separate districts.
-Thus the progress of Language conforms to the
-general law, alike in the evolution of languages, in the
-evolution of families of words, and in the evolution of parts
-of speech.</p>
-
-<p class='c000'>On passing from spoken to written language, we come upon
-several classes of facts, all having similar implications.
-Written language is connate with Painting and Sculpture;
-and at first all three are appendages of Architecture, and
-have a direct connexion with the primary form of all Government—the
-theocratic. Merely noting by the way the fact
-that sundry wild races, as for example the Australians and
-the tribes of South Africa, are given to depicting personages
-and events upon the walls of caves, which are probably regarded
-<span class='pageno' id='Page_164'>164</span>as sacred places, let us pass to the case of the Egyptians.
-Among them, as also among the Assyrians, we find
-mural paintings used to decorate the temple of the god and
-the palace of the king (which were, indeed, originally identical);
-and as such they were governmental appliances in the
-same sense that state-pageants and religious feasts were.
-Further, they were governmental appliances in virtue of
-representing the worship of the god, the triumphs of the
-god-king, the submission of his subjects, and the punishment
-of the rebellious. And yet again they were governmental,
-as being the products of an art reverenced by the people as a
-sacred mystery. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;From the habitual use of this
-pictorial representation, there naturally grew up the but
-slightly-modified practice of picture-writing—a practice
-which was found still extant among the Mexicans at the time
-they were discovered. By abbreviations analogous to those
-still going on in our own written and spoken language, the
-most familiar of these pictured figures were successively
-simplified; and ultimately there grew up a system of symbols,
-most of which had but a distant resemblance to the things
-for which they stood. The inference that the hieroglyphics
-of the Egyptians were thus produced, is confirmed by the fact
-that the picture-writing of the Mexicans was found to have
-given birth to a like family of ideographic forms; and among
-them, as among the Egyptians, these had been partially
-differentiated into the <em>kuriological</em> or imitative, and the
-<em>tropical</em> or symbolic: which were, however, used together in
-the same record. In Egypt, written language underwent a
-further differentiation; whence resulted the <em>hieratic</em> and the
-<em>epistolographic</em> or <em>enchorial</em>: both of which are derived from
-the original hieroglyphic. At the same time we find that
-for the expression of proper names, which could not be otherwise
-conveyed, phonetic symbols were employed; and though
-it is alleged that the Egyptians never actually achieved complete
-alphabetic writing, yet it can scarcely be doubted that
-these phonetic symbols occasionally used in aid of their
-<span class='pageno' id='Page_165'>165</span>ideographic ones, were the germs out of which alphabetic
-writing grew. Once having become separate from hieroglyphics,
-alphabetic writing itself underwent numerous differentiations—multiplied
-alphabets were produced: between
-most of which, however, more or less connexion can still be
-traced. And in each civilized nation there has now grown
-up, for the representation of one set of sounds, several sets of
-written signs, used for distinct purposes. Finally, through a
-yet more important differentiation came printing; which, uniform
-in kind as it was at first, has since become multiform.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 50. While written language was passing through its
-earlier stages of development, the mural decoration which
-formed its root was being differentiated into Painting and
-Sculpture. The gods, kings, men, and animals represented,
-were originally marked by indented outlines and coloured.
-In most cases these outlines were of such depth, and the
-object they circumscribed so far rounded and marked out in
-its leading parts, as to form a species of work intermediate
-between intaglio and bas-relief. In other cases we see an
-advance upon this: the raised spaces between the figures
-being chiselled off, and the figures themselves appropriately
-tinted, a painted bas-relief was produced. The restored
-Assyrian architecture at Sydenham, exhibits this style of art
-carried to greater perfection—the persons and things represented,
-though still barbarously coloured, are carved out
-with more truth and in greater detail; and in the winged
-lions and bulls used for the angles of gateways, we may see
-a considerable advance towards a completely sculptured
-figure; which, nevertheless, is still coloured, and still forms
-part of the building. But while in Assyria the production
-of a statue proper, seems to have been little, if at all, attempted,
-we may trace in Egyptian art the gradual separation
-of the sculptured figure from the wall. A walk through the
-collection in the British Museum will clearly show this;
-while it will at the same time afford an opportunity of observing
-<span class='pageno' id='Page_166'>166</span>the evident traces which the independent statues bear
-of their derivation from bas-relief: seeing that nearly all of
-them not only display that union of the limbs with the body
-which is the characteristic of bas-relief, but have the back of
-the statue united from head to foot with a block which
-stands in place of the original wall. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Greece repeated
-the leading stages of this progress. As in Egypt and
-Assyria, these twin arts were at first united with each other
-and with their parent, Architecture; and were the aids of
-Religion and Government. On the friezes of Greek temples,
-we see coloured bas-reliefs representing sacrifices, battles,
-processions, games—all in some sort religious. On the pediments
-we see painted sculptures more or less united with the
-tympanum, and having for subjects the triumphs of gods or
-heroes. Even when we come to statues that are definitely
-separated from the buildings to which they pertain, we still
-find them coloured; and only in the later periods of Greek
-civilization, does the differentiation of sculpture from painting
-appear to have become complete. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;In Christian
-art we may clearly trace a parallel re-genesis. All early
-paintings and sculptures throughout Europe, were religious
-in subject—represented Christs, crucifixions, virgins, holy
-families, apostles, saints. They formed integral parts of
-church architecture, and were among the means of exciting
-worship: as in Roman Catholic countries they still are.
-Moreover, the early sculptures of Christ on the cross, of
-virgins, of saints, were coloured; and it needs but to call to
-mind the painted madonnas and crucifixes still abundant in
-continental churches and highways, to perceive the significant
-fact that painting and sculpture continue in closest connexion
-with each other, where they continue in closest connexion
-with their parent. Even when Christian sculpture was
-pretty clearly differentiated from painting, it was still religious
-and governmental in its subjects—was used for tombs in
-churches and statues of kings; while, at the same time,
-painting, where not purely ecclesiastical, was applied to the
-<span class='pageno' id='Page_167'>167</span>decoration of palaces, and besides representing royal personages,
-was almost wholly devoted to sacred legends. Only in
-quite recent times have painting and sculpture become
-entirely secular arts. Only within these few centuries has
-painting been divided into historical, landscape, marine,
-architectural, genre, animal, still-life, &amp;c., and sculpture
-grown heterogeneous in respect of the variety of real and
-ideal subjects with which it occupies itself.</p>
-
-<p class='c000'>Strange as it seems then, we find it no less true, that all
-forms of written language, of painting, and of sculpture, have
-a common root in the politico-religious decorations of ancient
-temples and palaces. Little resemblance as they now have,
-the bust that stands on the console, the landscape that hangs
-against the wall, and the copy of the <em>Times</em> lying upon the
-table, are remotely akin; not only in nature, but by extraction.
-The brazen face of the knocker which the postman has just
-lifted, is related not only to the woodcuts of the <cite>Illustrated London
-News</cite> which he is delivering, but to the characters of the
-<i><span lang="fr" xml:lang="fr">billet-doux</span></i> which accompanies it. Between the painted window,
-the prayer-book on which its light falls, and the adjacent
-monument, there is consanguinity. The effigies on our coins,
-the signs over shops, the figures that fill every ledger, the coat
-of arms outside the carriage-panel, and the placards inside the
-omnibus, are, in common with dolls, blue-books and paper-hangings,
-lineally descended from the rude sculpture-paintings in
-which the Egyptians represented the triumphs and worship
-of their god-kings. Perhaps no example can be given which
-more vividly illustrates the multiplicity and heterogeneity
-of the products that in course of time may arise by successive
-differentiations from a common stock.</p>
-
-<p class='c000'>Before passing to other classes of facts, it should be observed
-that the evolution of the homogeneous into the heterogeneous
-is displayed not only in the separation of Painting
-and Sculpture from Architecture and from each other, and in
-the greater variety of subjects they embody; but it is further
-shown in the structure of each work. A modern picture or
-<span class='pageno' id='Page_168'>168</span>statue is of far more heterogeneous nature than an ancient
-one. An Egyptian sculpture-fresco represents all its figures
-as on one plane—that is, at the same distance from the eye;
-and so is less heterogeneous than a painting that represents
-them as at various distances from the eye. It exhibits all objects
-as exposed to the same degree of light; and so is less
-heterogeneous than a painting which exhibits different objects,
-and different parts of each object, as in different degrees
-of light. It uses scarcely any but the primary colours, and
-these in their full intensity; and so is less heterogeneous than
-a painting which, introducing the primary colours but sparingly,
-employs an endless variety of intermediate tints, each of
-heterogeneous composition, and differing from the rest not
-only in quality but in intensity. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Moreover, we see
-in these earliest works a great uniformity of conception. The
-same arrangement of figures is perpetually reproduced—the
-same actions, attitudes, faces, dresses. In Egypt the modes of
-representation were so fixed that it was sacrilege to introduce
-a novelty; and indeed it could have been only in consequence
-of a fixed mode of representation that a system of hieroglyphics
-became possible. The Assyrian bas-reliefs display parallel
-characters. Deities, kings, attendants, winged-figures
-and animals, are severally depicted in like positions, holding
-like implements, doing like things, and with like expression or
-non-expression of face. If a palm-grove is introduced, all the
-trees are of the same height, have the same number of leaves,
-and are equidistant. When water is imitated, each wave is
-a counterpart of the rest; and the fish, almost always of one
-kind, are evenly distributed over the surface. The beards of
-the kings, the gods, and the winged-figures, are everywhere
-similar; as are the manes of the lions, and equally so those of
-the horses. Hair is represented throughout by one form of
-curl. The king’s beard is quite architecturally built up of compound
-tiers of uniform curls, alternating with twisted tiers
-placed in a transverse direction, and arranged with perfect
-regularity; and the terminal tufts of the bulls’ tails are represented
-<span class='pageno' id='Page_169'>169</span>in exactly the same manner. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Without
-tracing out analogous facts in early Christian art, in which,
-though less striking, they are still visible, the advance in
-heterogeneity will be sufficiently manifest on remembering that
-in the pictures of our own day the composition is endlessly
-varied; the attitudes, faces, expressions, unlike; the subordinate
-objects different in size, form, position, texture; and
-more or less of contrast even in the smallest details. Or, if
-we compare an Egyptian statue, seated bolt upright on a
-block, with hands on knees, fingers outspread and parallel,
-eyes looking straight forward, and the two sides perfectly symmetrical
-in every particular, with a statue of the advanced
-Greek or the modern school, which is asymmetrical in respect
-of the position of the head, the body, the limbs, the arrangement
-of the hair, dress, appendages, and in its relations to
-neighbouring objects, we shall see the change from the homogeneous
-to the heterogeneous clearly manifested.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 51. In the co-ordinate origin and gradual differentiation
-of Poetry, Music, and Dancing, we have another series of illustrations.
-Rhythm in speech, rhythm in sound, and rhythm
-in motion, were in the beginning, parts of the same thing;
-and have only in process of time become separate things.
-Among various existing barbarous tribes we find them still
-united. The dances of savages are accompanied by some kind
-of monotonous chant, the clapping of hands, the striking of
-rude instruments: there are measured movements, measured
-words, and measured tones; and the whole ceremony, usually
-having reference to war or sacrifice, is of governmental character.
-In the early records of the historic races we similarly
-find these three forms of metrical action united in religious
-festivals. In the Hebrew writings we read that the triumphal
-ode composed by Moses on the defeat of the Egyptians, was
-sung to an accompaniment of dancing and timbrels. The
-Israelites danced and sung “at the inauguration of the golden
-calf. And as it is generally agreed that this representation
-<span class='pageno' id='Page_170'>170</span>of the Deity was borrowed from the mysteries of Apis, it is
-probable that the dancing was copied from that of the Egyptians
-on those occasions.” There was an annual dance in
-Shiloh on the sacred festival; and David danced before the
-ark. Again, in Greece the like relation is everywhere seen:
-the original type being there, as probably in other cases, a
-simultaneous chanting and mimetic representation of the life
-and adventures of the god. The Spartan dances were accompanied
-by hymns and songs; and in general the Greeks
-had “no festivals or religious assemblies but what were accompanied
-with songs and dances”—both of them being
-forms of worship used before altars. Among the Romans,
-too, there were sacred dances: the Salian and Lupercalian
-being named as of that kind. And even in Christian countries,
-as at Limoges in comparatively recent times, the people have
-danced in the choir in honour of a saint. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The incipient
-separation of these once united arts from each other
-and from religion, was early visible in Greece. Probably
-diverging from dances partly religious, partly warlike, as the
-Corybantian, came the war-dances proper, of which there
-were various kinds; and from these resulted secular dances.
-Meanwhile Music and Poetry, though still united, came to
-have an existence separate from dancing. The aboriginal
-Greek poems, religious in subject, were not recited but
-chanted; and though at first the chant of the poet was accompanied
-by the dance of the chorus, it ultimately grew
-into independence. Later still, when the poem had been
-differentiated into epic and lyric—when it became the custom
-to sing the lyric and recite the epic—poetry proper was born.
-As during the same period musical instruments were being
-multiplied, we may presume that music came to have an existence
-apart from words. And both of them were beginning
-to assume other forms besides the religious. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Facts
-having like implications might be cited from the histories of
-later times and peoples; as the practices of our own early
-minstrels, who sang to the harp heroic narratives versified
-<span class='pageno' id='Page_171'>171</span>by themselves to music of their own composition: thus
-uniting the now separate offices of poet, composer, vocalist,
-and instrumentalist. But, without further illustration, the
-common origin and gradual differentiation of Dancing, Poetry,
-and Music will be sufficiently manifest.</p>
-
-<p class='c000'>The advance from the homogeneous to the heterogeneous
-is displayed not only in the separation of these arts from
-each other and from religion, but also in the multiplied
-differentiations which each of them afterwards undergoes.
-Not to dwell upon the numberless kinds of dancing that
-have, in course of time, come into use; and not to occupy
-space in detailing the progress of poetry, as seen in the development
-of the various forms of metre, of rhyme, and of
-general organization; let us confine our attention to music
-as a type of the group. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;As argued by Dr. Burney,
-and as implied by the customs of still extant barbarous races,
-the first musical instruments were, without doubt, percussive—sticks,
-calabashes, tom-toms—and were used simply to
-mark the time of the dance; and in this constant repetition
-of the same sound, we see music in its most homogeneous
-form. The Egyptians had a lyre with three
-strings. The early lyre of the Greeks had four, constituting
-their tetrachord. In course of some centuries lyres of seven
-and eight strings were employed. And, by the expiration of
-a thousand years, they had advanced to their “great system”
-of the double octave. Through all which changes there of
-course arose a greater heterogeneity of melody. Simultaneously
-there came into use the different modes—Dorian,
-Ionian, Phrygian, Æolian, and Lydian—answering to our
-keys: and of these there were ultimately fifteen. As yet,
-however, there was but little heterogeneity in the time of
-their music. Instrumental music during this period being
-merely the accompaniment of vocal music, and vocal music
-being completely subordinated to words,—the singer being
-also the poet, chanting his own compositions and making the
-lengths of his notes agree with the feet of his verses; there
-<span class='pageno' id='Page_172'>172</span>unavoidably arose a tiresome uniformity of measure, which,
-as Dr Burney says, “no resources of melody could disguise.”
-Lacking the complex rhythm obtained by our equal bars and
-unequal notes, the only rhythm was that produced by the
-quantity of the syllables, and was of necessity comparatively
-monotonous. And further, it may be observed that the chant
-thus resulting, being like recitative, was much less clearly
-differentiated from ordinary speech than is our modern song.
-Nevertheless, considering the extended range of notes in use,
-the variety of modes, the occasional variations of time consequent
-on changes of metre, and the multiplication of instruments,
-we see that music had, towards the close of Greek
-civilization, attained to considerable heterogeneity: not indeed
-as compared with our music, but as compared with that
-which preceded it. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;As yet, however, there existed
-nothing but melody: harmony was unknown. It was not
-until Christian church-music had reached some development,
-that music in parts was evolved; and then it came into existence
-through a very unobtrusive differentiation. Difficult as
-it may be to conceive, <i><span lang="fr" xml:lang="fr">à priori</span></i>, how the advance from melody
-to harmony could take place without a sudden leap, it is none
-the less true that it did so. The circumstance which prepared
-the way for it, was the employment of two choirs singing alternately
-the same air. Afterwards it became the practice
-(very possibly first suggested by a mistake) for the second
-choir to commence before the first had ceased; thus producing
-a fugue. With the simple airs then in use, a partially harmonious
-fugue might not improbably thus result; and a very
-partially harmonious fugue satisfied the ears of that age, as
-we know from still preserved examples. The idea having
-once been given, the composing of airs productive of fugal
-harmony would naturally grow up; as in some way it <em>did</em>
-grow up out of this alternate choir-singing. And from the
-fugue to concerted music of two, three, four, and more parts,
-the transition was easy. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Without pointing out in
-detail the increasing complexity that resulted from introducing
-<span class='pageno' id='Page_173'>173</span>notes of various lengths, from the multiplication of keys,
-from the use of accidentals, from varieties of time, from modulations
-and so forth, it needs but to contrast music as it is,
-with music as it was, to see how immense is the increase of
-heterogeneity. We see this if, looking at music in its <em>ensemble</em>,
-we enumerate its many different genera and species—if
-we consider the divisions into vocal, instrumental, and mixed;
-and their subdivisions into music for different voices and different
-instruments—if we observe the many forms of sacred
-music, from the simple hymn, the chant, the canon, motet,
-anthem, &amp;c., up to the oratorio; and the still more numerous
-forms of secular music, from the ballad up to the serenata,
-from the instrumental solo up to the symphony. Again, the
-same truth is seen on comparing any one sample of aboriginal
-music with a sample of modern music—even an ordinary
-song for the piano; which we find to be relatively highly
-heterogeneous, not only in respect of the varieties in the pitch
-and in the length of the notes, the number of different notes
-sounding at the same instant in company with the voice, and
-the variations of strength with which they are sounded and
-sung, but in respect of the changes of key, the changes of
-time, the changes of <em>timbre</em> of the voice, and the many other
-modifications of expression. While between the old monotonous
-dance-chant and a grand opera of our own day, with
-its endless orchestral complexities and vocal combinations,
-the contrast in heterogeneity is so extreme that it seems
-scarcely credible that the one should have been the ancestor of
-the other.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 52. Were they needed, many further illustrations might
-be cited. Going back to the early time when the deeds of the
-god-king, chanted and mimetically represented in dances
-round his altar, were further narrated in picture-writings on
-the walls of temples and palaces, and so constituted a rude
-literature, we might trace the development of Literature
-through phases in which, as in the Hebrew Scriptures it presents
-<span class='pageno' id='Page_174'>174</span>in one work, theology, cosmogony, history, biography,
-civil law, ethics, poetry; through other phases in which, as in
-the Iliad, the religious, martial, historical, the epic, dramatic,
-and lyric elements are similarly commingled; down to its present
-heterogeneous development, in which its divisions and
-subdivisions are so numerous and varied as to defy complete
-classification. Or we might track the evolution of Science:
-beginning with the era in which it was not yet differentiated
-from Art, and was, in union with Art, the handmaid of Religion;
-passing through the era in which the sciences were so
-few and rudimentary, as to be simultaneously cultivated by
-the same philosophers; and ending with the era in which the
-genera and species are so numerous that few can enumerate
-them, and no one can adequately grasp even one genus. Or
-we might do the like with Architecture, with the Drama, with
-Dress. But doubtless the reader is already weary of illustrations;
-and my promise has been amply fulfilled. I believe it
-has been shown beyond question, that that which the German
-physiologists have found to be the law of organic development,
-is the law of all development. The advance from
-the simple to the complex, through a process of successive
-differentiations, is seen alike in the earliest changes
-of the Universe to which we can reason our way back, and
-in the earliest changes which we can inductively establish;
-it is seen in the geologic and climatic evolution of the Earth,
-and of every single organism on its surface; it is seen in the
-evolution of Humanity, whether contemplated in the civilized
-individual, or in the aggregation of races; it is seen in
-the evolution of Society, in respect alike of its political, its religious,
-and its economical organization; and it is seen in the
-evolution of all those endless concrete and abstract products
-of human activity, which constitute the environment of our
-daily life. From the remotest past which Science can fathom,
-up to the novelties of yesterday, that in which Evolution
-essentially consists, is the transformation of the homogeneous
-into the heterogeneous.</p>
-
-<hr class='c015' />
-
-<div class='footnote' id='f8'>
-<p class='c000'><span class='label'><a href='#r8'>8</a>.&nbsp;&nbsp;</span>The substance of this chapter is nearly identical with the first half of an
-essay on “Progress: its Law and Cause,” which was originally published in the
-<cite>Westminster Review</cite> for April 1857: only a few unimportant additions and alterations
-have been made. The succeeding chapter, however, in which the subject
-is continued, is, with the exception of a fragment embodied in it, wholly new.</p>
-</div>
-
-<div class='footnote' id='f9'>
-<p class='c000'><span class='label'><a href='#r9'>9</a>.&nbsp;&nbsp;</span>For detailed proof of these assertions see essay on <cite>Manners and Fashion</cite>.</p>
-</div>
-
-<div>
- <span class='pageno' id='Page_175'>175</span>
- <h3 class='c001'>CHAPTER III.<br /> <span class='large'>THE LAW OF EVOLUTION, CONTINUED.</span></h3>
-</div>
-
-<p class='c006'>§ 53. But now, does this generalization express the whole
-truth? Does it include all the phenomena of Evolution? and
-does it exclude all other phenomena? A careful consideration
-of the facts, will show that it does neither.</p>
-
-<p class='c000'>That there are changes from the less heterogeneous to the
-more heterogeneous, which do not come within what we call
-Evolution, is proved in every case of local disease. A portion
-of the body in which there arises a cancer, or other
-morbid growth, unquestionably displays a new differentiation.
-Whether this morbid growth be, or be not, more heterogeneous
-than the tissues in which it is seated, is not the question.
-The question is, whether the structure of the organism as a
-whole, is, or is not, rendered more heterogeneous by the addition
-of a part unlike every pre-existing part, both in form and
-composition. And to this question there can be none but an
-affirmative answer. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Again, it might with apparent
-truth be contended, that the earlier stages of decomposition
-in a dead body, similarly involve an increase of heterogeneity.
-Supposing the chemical changes to commence in some parts
-of the body earlier than in other parts, as they commonly
-do; and to affect different tissues in different, ways, as they
-must; it seems to be a necessary admission that the entire
-body, made up of undecomposed parts and parts decomposed
-in different ways and degrees, has become more heterogeneous
-than it was. Though greater homogeneity will be the
-<span class='pageno' id='Page_176'>176</span>eventual result, the immediate result is the opposite. And yet
-this immediate result is certainly not evolution. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;But
-perhaps of all illustrations the least debatable are those furnished
-by social disorders and disasters. When in any nation
-there occurs a rebellion, which, while leaving some provinces
-undisturbed, developes itself here in secret societies,
-there in public demonstrations, and elsewhere in actual appeal
-to arms, leading probably to conflict and bloodshed; it
-must be admitted that the society, regarded as a whole, has
-so been rendered more heterogeneous. Or when a dearth
-causes commercial panic with its entailed bankruptcies,
-closed factories, discharged operatives, political agitations,
-food riots, incendiarisms; it is manifest that as, throughout
-the rest of society, there still exists the ordinary organization
-displaying the usual phenomena, these new phenomena must
-be regarded as adding to the complexity previously existing.
-Nevertheless, it is clear that such changes so far from constituting
-a further stage of evolution, are steps towards dissolution.</p>
-
-<p class='c000'>There is good reason to think then, that the definition
-arrived at in the last chapter, is an imperfect one. We may
-suspect, not that the process of evolution is different from the
-process there described; but that the description did not contain
-all that it should. The changes above instanced as coming
-within the formula as it now stands, are so obviously
-different from the rest, that the inclusion of them implies
-some oversight—some distinction hitherto overlooked. Such
-further distinction we shall find really exists.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 54. At the same time that all evolution is a change from
-the homogeneous to the heterogeneous, it is also a change from
-the indefinite to the definite. As well as an advance from
-simplicity to complexity, there is an advance from confusion
-to order—from undetermined arrangement to determined
-arrangement. In the process of development, no matter
-what sphere it is displayed in, there is not only a gradual
-<span class='pageno' id='Page_177'>177</span>multiplication of unlike parts; but there is a gradual increase
-in the distinctness with which these parts are marked off from
-each other. And so is that increase of heterogeneity which
-characterizes Evolution, distinguished from that increase of
-heterogeneity which does not. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;For proof of this, it
-needs only to reconsider the instances given above. The
-structural changes constituting a disease, have no such definiteness,
-either in locality, extent, or outline, as the structural
-changes constituting development. Though certain morbid
-growths arise much more commonly in some parts of the
-body than in others (as warts on the hands, cancer on the
-breasts, tubercle in the lungs), yet they are not confined to
-these parts; nor, when found on them, are they anything like
-so precise in their relative positions as are the normal parts
-around them. In size, again, they are extremely variable—they
-bear no such constant proportion to the body as
-organs do. Their forms, too, are far less specific than organic
-forms. And they are extremely irregular or confused in
-their internal structures. That is to say, they are in all respects
-comparatively indefinite. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The like peculiarity
-may be traced in decomposition. That state of total indefiniteness
-to which a dead body is finally reduced, is a state towards
-which the putrefactive changes have tended from their commencement.
-Each step in the destruction of the organic compounds,
-is accompanied by a blurring of the minute structure—diminishes
-its distinctness. From the portions that have undergone
-most decomposition, there is a gradual transition to the
-less decomposed portions. And step by step the lines of organization,
-once so precise, disappear. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Similarly with
-social changes of an abnormal kind. A political outbreak
-rising finally to a rebellion, tends from the very first to
-obliterate the specializations, governmental and industrial,
-which previously existed. The disaffection which originates
-such an outbreak, itself implies a loosening of those ties by
-which the citizens are bound up into distinct classes and
-sub-classes. Agitation, growing into revolutionary meetings,
-<span class='pageno' id='Page_178'>178</span>shows us a decided tendency towards the fusion of ranks that
-are usually separated. Acts of open insubordination exhibit a
-breaking through of those definite limits to individual conduct
-which were previously observed; and a disappearance of the
-lines previously existing between those in authority and those
-beneath them. At the same time, by the arrest of trade,
-artizans and others lose their occupations; and in so ceasing
-to be functionally distinguished, become fused into a mass
-from which the demarcations in great part vanish.
-And when at last there comes positive insurrection, all
-magisterial and official powers, all class distinctions, and all
-industrial differences, at once cease: organized society lapses
-into an unorganized aggregation of social units. How the
-like holds true of such social disasters as are entailed by
-famine, needs not be pointed out. On calling to mind that
-in cases of this kind the changes are from order towards
-disorder, it will at once be seen that like the foregoing they
-are changes from definite arrangements to indefinite arrangements.</p>
-
-<p class='c000'>Thus then is that increase of heterogeneity which constitutes
-Evolution, distinguished from that increase of heterogeneity
-which does not do so. Though in disease and death,
-individual or social, the earliest modifications may be construed
-as additions to the heterogeneity previously existing;
-yet they cannot be construed as additions to the definiteness
-previously existing. They begin from the very outset to destroy
-this definiteness; and so, gradually produce a heterogeneity
-that is indeterminate instead of determinate. Just in
-the same way that a city, already multiform in its variously
-arranged structures of various architecture, may be made
-more multiform by an earthquake, which leaves part of it
-standing and overthrows other parts in different ways and
-degrees, and yet is at the same time reduced from definite
-arrangement to indefinite arrangement; so may organized
-bodies be made for a time more multiform by changes which
-are nevertheless disorganizing changes. And in the one case
-<span class='pageno' id='Page_179'>179</span>as in the other, it is the absence of definiteness which distinguishes
-the multiformity of regression from the multiformity
-of progression.</p>
-
-<p class='c000'>If the advance from the indefinite to the definite is an
-essential characteristic of Evolution, we shall of course find it
-everywhere displayed; as in the last Chapter we found the
-advance from the homogeneous to the heterogeneous. With
-a view of showing that it is so, let us now briefly reconsider
-the same several classes of facts.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 55. Beginning as before with a hypothetical illustration,
-we have to note that each further stage in the evolution of
-the Solar System, supposing it to have originated from diffused
-matter, was an advance towards more definite forms,
-and times, and forces. At first irregular in shape and with
-indistinct margins, the attenuated substance, as it concentrated
-and acquired a rotatory motion, must have assumed the shape
-of an oblate spheroid; which, with every increase of density,
-became more specific in general outline, and had its surface
-more sharply marked off from the surrounding void. At the
-same time, the constituent portions of nebulous matter, instead
-of independently moving towards their common centre
-of gravity from all points, and tending to revolve round it in
-various planes, as they would at first do, must have had these
-planes more and more merged into a single plane; and this
-plane must have gained greater precision as the concentration
-progressed. To which add that in the gradual establishment
-of a common and determinate angular velocity, instead
-of the various and conflicting angular velocities of different
-parts, we have a further change of like nature. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;According
-to the hypothesis, change from indistinct characteristics
-to distinct ones, was repeated in the evolution of each
-planet and satellite; and may in them be traced to a much
-greater extent. A gaseous spheroid is less definitely marked
-off from the space around it than a fluid spheroid, since it is
-subject to larger and more rapid undulations of surface,
-<span class='pageno' id='Page_180'>180</span>and to much greater distortions of general form; and similarly
-a fluid spheroid, covered as it must be with waves of
-various magnitudes, is less definite than a solid spheroid.
-Nor is it only in greater fixity of surface that a planet in its
-last stage, is distinguished from a planet in its earlier stages.
-Its general form, too, is more precise. The sphere, to which in
-the end it very closely approximates, is a perfectly specific
-figure; while the spheroid, under which figure it previously
-existed, being infinitely variable in oblateness, is an imperfectly
-specific figure. And further, a planet having an
-axis inclined to the plane of its orbit, must, while its form
-is very oblate, have its plane of rotation greatly disturbed by
-the attraction of external bodies; whereas its approach to a
-spherical form, involving a less extreme precessional motion,
-implies less marked variations in the direction of its
-axis. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Nor is it only in respect of space-relations
-that the Solar System in general and in detail has become
-more precise. The like is true of time-relations. During
-the process of concentration the various portions of the
-nebulous mass must not only differ more or less from each
-other in their angular velocities, but each of them must
-gradually change the period in which it moves round the
-general axis. In every detached ring however, and in the
-resulting planet, this progressive alteration ceases: there
-results a determinate period of revolution. And similarly
-the time of axial rotation, which, during the formation of
-each planet, is continually diminishing, becomes at last practically
-fixed: as in the case of the Earth, whose day is not a
-second less than it was 2000 years ago. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;It is scarcely
-needful to point out that the force-relations have simultaneously
-become more and more settled. The exact calculations
-of physical astronomy, show us how definite these
-force-relations now are; while the great indefiniteness which
-once characterized them, is implied in the extreme difficulty,
-if not impossibility, of subjecting the nebular hypothesis to
-mathematical treatment.</p>
-
-<p class='c000'><span class='pageno' id='Page_181'>181</span>From that originally molten state of the Earth inferable
-from established geological data—a state in harmony with
-the nebular hypothesis but inexplicable on any other—the
-transition to its existing state has been through stages in
-which the characters became more determinate. Besides
-being, as above pointed out, comparatively unstable in surface
-and contour, a fluid spheroid is less definite than a solid
-spheroid in having no fixed distribution of parts. Currents
-of molten matter, though kept to certain general circuits by
-the conditions of equilibrium, cannot in the absence of solid
-boundaries be precise or permanent in direction: all parts
-must be in motion with respect to other parts. But a solidification
-of the surface, even though but partial, is manifestly
-a step towards the establishment of definite relations of position.
-In a thin crust however, frequently ruptured as it
-must be by disturbing forces, and moved by every tidal undulation,
-such fixity of relative position can be but temporary.
-Only as the crust slowly increases in thickness, can there arise
-distinct and settled geographical relations. Observe too that
-when, on a crust that has cooled to the requisite degree, there
-begins to precipitate the water floating above as vapour, the
-water which is precipitated cannot maintain any definiteness
-either of state or place. Falling on a surface not thick
-enough to preserve anything beyond slight variations of
-level, it must form small shallow deposits over areas sufficiently
-cool to permit condensation; which areas must not
-only pass insensibly into others that are too hot for this, but
-must themselves from time to time be so raised in temperature
-as to drive off the water lying on them. With progressive
-refrigeration, however,—with an increasing thickness
-of crust, a consequent formation of larger elevations and
-depressions, and the condensation of more atmospheric water,
-there comes an arrangement of parts that is comparatively
-fixed in both time and space; and the definiteness of state
-and position increases, until there results such a distribution
-of continents and oceans as we now see—a distribution
-<span class='pageno' id='Page_182'>182</span>that is not only topographically precise, but also in its cliff-marked
-coast-lines presents a more definite division of land
-from water than could have existed during the period when
-islands of low elevation had shelving beaches up which the
-tide ebbed and flowed to great distances. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Respecting
-the characteristics technically classed as geological, we may
-draw parallel inferences. While the Earth’s crust was thin,
-mountain-chains were impossibilities: there could not have
-been long and well-defined axes of elevation, with distinct
-water-sheds and areas of drainage. Moreover, from small
-islands admitting of but small rivers, and tidal streams both
-feeble and narrow, there would result no clearly-marked sedimentary
-strata. Confused and varying masses of detritus,
-such as those now found at the mouths of brooks, must have
-been the prevailing formations. And these could give place
-to distinct strata, only as there arose continents and oceans,
-with their great rivers, long coast-lines, and wide-spreading
-marine currents. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;How there must simultaneously
-have resulted more definite meteorological characters, need
-not be pointed out in detail. That differences of climates
-and seasons must have grown relatively decided as the heat of
-the Sun became distinguishable from the proper heat of the
-Earth; that the establishment through this cause of comparatively
-constant atmospheric currents, must have similarly
-produced more specific conditions in each locality; and
-that these effects must have been aided by increasing permanence
-in the distribution of land and sea and of ocean
-currents; are conclusions which are sufficiently obvious.</p>
-
-<p class='c000'>Let us turn now to the evidence furnished by organic
-bodies. In place of deductive illustrations like the foregoing,
-we shall here find numerous illustrations which, as
-being inductively established, are less open to criticism. The
-process of mammalian development, for example, will supply
-us with numerous proofs ready-described by embryologists.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The first change which the ovum of a
-mammal undergoes, after continued segmentation has reduced
-<span class='pageno' id='Page_183'>183</span>its yelk to a mulberry-like mass, is the appearance of
-a greater definiteness in the peripheral cells of this mass:
-each of which acquires a distinct enveloping membrane.
-These peripheral cells, vaguely distinguished from the internal
-ones both by their greater completeness and by
-their minuter subdivision, coalesce to form the blastoderm
-or germinal membrane. One portion of the blastoderm
-presently becomes contrasted with the rest, through
-the accumulation of cells still more subdivided, which, together,
-form an opaque roundish spot. This <i><span lang="it" xml:lang="it">area germinativa</span></i>,
-as it is called, is not sharply delineated, but shades off
-gradually into the surrounding parts of the blastoderm;
-and the <i><span lang="it" xml:lang="it">area pellucida</span></i>, subsequently formed in the midst of
-this germinal area, is similarly without any precise margin.
-The “primitive trace,” which makes its appearance in the
-centre of the <i><span lang="it" xml:lang="it">area pellucida</span></i>, and is the rudiment of that vertebrate
-axis which is to be the fundamental characteristic of
-the mature animal, is shown by its name to be at first indefinite—a
-mere trace. Beginning as a shallow groove, this
-becomes slowly more pronounced: its sides grow higher,
-their summits overlap, and at last unite; and so the indefinite
-groove passes into a definite tube, forming the vertebral
-canal. In this vertebral canal the leading divisions of the
-brain are at first discernible only as slight bulgings; while
-the vertebræ commence as indistinct modifications of the tissue
-bounding the canal. Simultaneously, the outer portion of the
-blastoderm has been undergoing separation from the inner portion:
-there has been a division into the serous and mucous
-layers—a division at the outset indistinct, and traceable only
-about the germinal area, but which insensibly spreads throughout
-nearly the whole germinal membrane, and becomes definite.
-From the mucous layer, the development of the alimentary
-canal proceeds as that of the vertebral canal does from
-the serous layer. Originally a simple channel along the under
-surface of the embryonic mass, the intestine is rendered step by
-step more distinct by the bending down, on each side, of ridges
-<span class='pageno' id='Page_184'>184</span>which finally join to form a tube—the permanent absorbing
-surface is by degrees clearly cut off from that temporary absorbing
-surface of which it was at first a part like all the rest.
-And in an analogous manner the entire embryo, which at first
-lies outspread upon the surface of the yelk-sack, gradually rises
-up from it, and, by the infolding of its ventral surface, becomes
-a separate mass, connected with the yelk-sack only by a narrow
-duct. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;These changes through which the general
-structure of the embryo is marked out with slowly-increasing
-precision, are paralleled in the evolution of each organ.
-The heart is at first a mere aggregation of cells, of which the
-inner liquify to form the cavity, while the outer are transformed
-into the walls; and when thus sketched out, the heart
-is indefinite not only as being unlined by limiting membrane,
-but also as being but vaguely distinguishable from
-the great blood-vessels: of which it is little more than a
-dilatation. By and by the receiving portion of the cavity
-becomes distinct from the propelling portion. Afterwards
-there begins to be formed across the ventricle, a septum,
-which, however, is some time before it completely shuts off
-the two halves from each other; while the later-formed
-septum of the auricle remains incomplete during the whole
-of fœtal life. Again, the liver commences as a multiplication
-of certain cells in the wall of the intestine. The thickening
-produced by this multiplication “increases so as to form a
-projection upon the exterior of the canal;” and at the same
-time that the organ grows and becomes distinct from the intestine,
-the channels which permeate it are transformed into
-ducts having clearly-marked walls. Similarly, by the increase
-of certain cells of the external coat of the alimentary
-canal at its upper portion, are produced buds from which
-the lungs are developed; and these, in their general outlines
-and detailed structure, acquire distinctness step by
-step. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Changes of this order continue long after
-birth; and, in the human being, are some of them not completed
-till middle life. During youth, most of the articular
-<span class='pageno' id='Page_185'>185</span>surfaces of the bones remain rough and fissured—the calcareous
-deposit ending irregularly in the surrounding cartilage.
-But between puberty and the age of thirty, the articular
-surfaces are finished off by the addition of smooth, hard,
-sharply-cut “epiphyses.” Thus we may say that during
-Evolution, an increase of definiteness continues long after
-there ceases to be any appreciable increase of heterogeneity.
-And, indeed, there is reason to think that those structural
-modifications which take place after maturity, ending in
-old age and death, are modifications of this nature; since
-they result in a growing rigidity of structure, a consequent
-restriction of movement and of functional pliability, a
-gradual narrowing of the limits within which the vital
-processes go on, ending at length in an organic adjustment
-too precise—too narrow in its margin of possible variation to
-permit the requisite adaptation to external changes of condition.</p>
-
-<p class='c000'>To demonstrate that the Earth’s Flora and Fauna, regarded
-either as wholes or in their separate species, have progressed
-in definiteness, is of course no more possible than it was to
-demonstrate that they have progressed in heterogeneity: lack
-of facts being an obstacle to the one conclusion as to the other.
-If, however, we allow ourselves to reason from the hypothesis,
-now daily rendered more probable, that every species of
-organic form up to the most complex, has arisen out of the
-simplest through the accumulation of modifications upon
-modifications, just as every individual organic form arises;
-we shall see that in such case there must have been a progress
-from the indeterminate to the determinate, both in the
-particular forms and in the groups of forms. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;We
-may set out with the significant fact that many of the lowest
-living organisms (which are analogous in structure to the
-germs of all higher ones) are so indefinite in character that
-it is difficult, if not impossible, to decide whether they are
-plants or animals. Respecting sundry of them there are unsettled
-disputes between zoologists and botanists; and it has
-<span class='pageno' id='Page_186'>186</span>even been proposed to group them into a separate kingdom,
-forming a common basis to the animal and vegetal kingdoms.
-Note next that among the <em>Protozoa</em>, extreme indefiniteness
-of shape is very general. In the shell-less Rhizopods
-and their allies, not only is the form so irregular as to admit
-of no description, but it is neither alike in any two individuals
-nor in the same individual at successive moments. By the
-aggregation of such creatures, are produced, among other indefinite
-bodies, the sponges—bodies that are indefinite in size,
-in contour, in internal arrangement, and in the absence of an
-external limiting membrane. As further showing the relatively
-indeterminate character of the simplest organisms,
-it may be mentioned that their structures vary very greatly
-with surrounding conditions: so much so that, among the
-<em>Protozoa</em> and <em>Protophyta</em>, many forms which were once
-classed as distinct species, and even as distinct genera, are
-found to be merely varieties of one species. If now we
-call to mind how precise in their attributes are the highest
-organisms—how sharply cut their outlines, how invariable
-their proportions, and how comparatively constant their structures
-under changed conditions, we cannot deny that greater
-definiteness is one of their characteristics; and that if they
-have been evolved out of lower organisms, an increase of
-definiteness has been an accompaniment of their evolution.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;That in course of time, species have become
-more sharply marked off from other species, genera from
-genera, and orders from orders, is a conclusion not admitting
-of a more positive establishment than the foregoing; and
-must, indeed, stand or fall with it. If, however, species and
-genera and orders have resulted from the process of “natural
-selection,” then, as Mr. Darwin shows, there must have been
-a tendency to divergence, causing the contrasts between
-groups to become more and more pronounced. By the disappearance
-of intermediate forms, less fitted for special
-spheres of existence than the extreme forms they connected,
-the differences between the extreme forms must be rendered
-<span class='pageno' id='Page_187'>187</span>more decided; and so, from indistinct and unstable varieties,
-must slowly be produced distinct and stable species. Of
-which inference it may be remarked, not only that it follows
-from a process to which the organic creation is of necessity
-ever subject, but also that it is in harmony with what we
-know respecting races of men and races of domestic animals.</p>
-
-<p class='c000'>Evidence that in the course of psychial development,
-there is a change from the vague to the distinct, may be
-seen in every nursery. The confusion of the infant’s perceptions
-is shown by its inability to distinguish persons.
-The dimness of its ideas of direction and distance, may be
-inferred from the ill-guided movements of its hands, and from
-its endeavours to grasp objects far out of reach. Only by
-degrees does the sense of equilibrium, needful for safe standing
-and moving, gain the requisite precision. Through the
-insensible steps that end in comprehensible speech, we may
-trace an increase in the accuracy with which sounds are discriminated
-and in the nicety with which they are imitated.
-And similarly during education, the change is towards the
-establishment of internal relations more perfectly corresponding
-to external ones—to exactness in calculations, to a better
-representation of objects drawn, to a more correct spelling, to
-a completer conformity to the rules of speech, to clearer ideas
-respecting the affairs of life. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;How in the further
-progress to maturity the law still holds, needs not here be
-pointed out; more especially as it will presently be shown in
-treating of the evolution of intelligence during the advance
-of civilization. The only further fact calling for remark, is,
-that this increase of mental definiteness is, in some ways,
-manifested even during the advance from maturity to old
-age. The habits of life grow more and more fixed; the
-character becomes less capable of change; the quantity of
-knowledge previously acquired ceases to have its limits alterable
-by additions; and the opinions upon every point admit
-of no modification.</p>
-
-<p class='c000'>Still more manifestly do the successive phases through
-<span class='pageno' id='Page_188'>188</span>which societies pass, display the progress from indeterminate
-arrangement to determinate arrangement. A wandering
-tribe of savages, as being fixed neither in its locality nor in
-the relative positions of its parts, is far less definite than a
-nation, covering a territory clearly marked out, and formed
-of individuals grouped together in towns and villages. In
-such a tribe the social relations are similarly confused and
-unsettled. Political authority is neither well established nor
-precise. Distinctions of rank are neither clearly marked nor
-impassable. “Medicine-men” and “rain-makers” form a
-class by no means as distinct from the rest of the community
-as eventually becomes the priesthood they foreshadow. And
-save in the different occupations of men and women, there are
-no complete industrial divisions. Only in tribes of considerable
-size, which have enslaved other tribes, is the economical differentiation
-decided. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Any one of these primitive
-societies however that developes, becomes step by step more
-specific. Increasing in size, consequently ceasing to be so
-nomadic, and restricted in its range by neighbouring tribes,
-it acquires, after prolonged border warfare, a more settled
-territorial boundary. The distinction between the royal
-race and the people, grows so extreme as to amount in the
-popular apprehension to a difference of nature. The warrior-class
-attains a perfect separation from classes devoted to the
-cultivation of the soil or other occupations regarded as servile.
-And there arises a priesthood that is defined in its rank, its
-functions, its privileges. This sharpness of definition, growing
-both greater and more variously exemplified as societies
-advance to maturity, is extremest in those that have reached
-their full development or are declining. Of ancient Egypt
-we read that its social divisions were strongly-marked and its
-customs rigid. Recent investigations make it more than ever
-clear, that among the Assyrians and surrounding peoples, not
-only were the laws unalterable, but even the minor habits,
-down to those of domestic routine, possessed a sacredness which
-insured their permanence. In India at the present day, the
-<span class='pageno' id='Page_189'>189</span>unchangeable distinctions of caste, not less than the constancy
-in modes of dress, industrial processes, and religious observances,
-show us how fixed are the arrangements where the
-antiquity is great. Nor does China with its long-settled
-political organization, its elaborate and precise conventions,
-and its unprogressive literature, fail to exemplify the same
-truth. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The successive phases of our own and neighbouring
-societies, furnish facts somewhat different in kind but
-similar in meaning. After our leading class-divisions had
-become tolerably well-established, it was long before they
-acquired their full precision. Originally, monarchical authority
-was more baronial, and baronial authority more monarchical,
-than they afterwards became. Between modern
-priests and the priests of old times, who while officially
-teachers of religion were also warriors, judges, architects,
-there is a marked difference in definiteness of function. And
-among the people engaged in productive occupations, the like
-contrast would be found to hold: the industrial office has
-become more distinct from the military; and its various divisions
-from each other. A history of our constitution, reminding
-us how, after prolonged struggles, the powers of
-King, Lords, and Commons, have been gradually settled,
-would clearly exhibit analogous changes. Countless facts
-bearing the like construction would meet us, were we to
-trace the development of legislation: in the successive
-stages of which, we should find statutes made more precise
-in their provisions—more specific in their applications to
-particular cases. Even at the present time we see that each
-new law, beginning as a vague proposition, is, in the
-course of enactment, elaborated into specific clauses; and
-further that only after its interpretation has been established
-by judges’ decisions in courts of justice, does it reach its final
-definiteness. From the history of minor institutions like
-evidence may be gathered. Religious, charitable, literary,
-and all other societies, beginning with ends and methods
-roughly sketched out and easily modifiable, show us how, by
-<span class='pageno' id='Page_190'>190</span>the accumulation of rules and precedents, the purposes become
-more distinct and the modes of action more restricted; until
-at last death often results from a fixity which admits of
-no adaptation to new conditions. Should it be objected that
-among civilized nations there are examples of decreasing
-definiteness, (instance the breaking down of limits between
-ranks,) the reply is, that such apparent exceptions are the accompaniments
-of a social metamorphosis—a change from the
-military or predatory type of social structure, to the industrial
-or mercantile type, during which the old lines of organization
-are disappearing and the new ones becoming more
-marked.</p>
-
-<p class='c000'>That all organized results of social action, pass in the
-course of civilization through parallel phases, is demonstrable.
-Being, as they are, objective products of subjective
-processes, they must display corresponding changes; and
-that they do this, the cases of Language, of Science, of Art,
-clearly prove.</p>
-
-<p class='c000'>If we strike out from our sentences everything but nouns
-and verbs, we shall perceive how extremely vague is the expression
-of ideas in undeveloped tongues. When we note
-how each inflection of a verb or addition by which the case
-of a noun is marked, serves to limit the conditions of action
-or of existence, we see that these constituents of speech enable
-men more precisely to communicate their thoughts.
-That the application of an adjective to a noun or an adverb
-to a verb, narrows the class of things or changes indicated,
-implies that these additional words serve further to
-define the meaning. And similarly with other parts of
-speech. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The like effect results from the multiplication
-of words of each order. When the names for objects,
-and acts, and qualities, are but few, the range of each is proportionately
-wide, and its meaning therefore unspecific. The
-similes and metaphors so abundantly used by aboriginal races,
-are simply vehicles for indirectly and imperfectly conveying
-ideas, which lack of words disables them from conveying directly
-<span class='pageno' id='Page_191'>191</span>and perfectly. In contrasting these figurative expressions,
-interpretable in various senses, with the expressions
-which we should use in place of them, the increase of exactness
-which wealth of language gives, is rendered very obvious.
-Or to take a case from ordinary life, if we compare the
-speech of the peasant, who, out of his limited vocabulary, can
-describe the contents of the bottle he carries, only as “doctor’s-stuff”
-which he has got for his “sick” wife, with the
-speech of the physician, who tells those educated like himself
-the particular composition of the medicine, and the particular
-disorder for which he has prescribed it; we have vividly
-brought home to us, the precision which language gains by the
-multiplication of terms. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Again, in the course of its
-evolution, each tongue acquires a further accuracy through
-processes which fix the meaning of each word. Intellectual
-intercourse tends gradually to diminish laxity of expression.
-By and by dictionaries give definitions. And eventually,
-among the most cultivated, indefiniteness is not tolerated,
-either in the terms used or in their grammatical combinations.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Once more, languages considered as wholes,
-become gradually more distinct from each other, and from
-their common parent: as witness in early times the divergence
-from the same root of two languages so unlike as Greek
-and Latin, and in later times the development of three Latin
-dialects into Italian, French, and Spanish.</p>
-
-<p class='c000'>In his “History of the Inductive Sciences,” Dr. Whewell
-says that the Greeks failed in physical philosophy because
-their “ideas were not distinct, and appropriate to the facts.”
-I do not quote this remark for its luminousness; since it
-would be equally proper to ascribe the indistinctness and inappropriateness
-of their ideas to the imperfection of their physical
-philosophy; but I quote it because it serves as good evidence
-of the indefiniteness of primitive science. The same
-work and its fellow on “The Philosophy of the Inductive
-Sciences,” supply other evidences equally good, because
-equally independent of any such hypothesis as is here to be
-<span class='pageno' id='Page_192'>192</span>established. Respecting mathematics we have the fact that
-geometrical theorems grew out of empirical methods; and that
-these theorems, at first isolated, did not acquire the clearness
-which complete demonstration gives, until they were arranged
-by Euclid into a series of dependent propositions. At a later
-period the same general truth was exemplified in the progress
-from the “method of exhaustions” and the “method of indivisibles”
-to the “method of limits;” which is the central idea
-of the infinitesimal calculus. In early mechanics, too, may be
-traced a dim perception that action and re-action are equal and
-opposite; though for ages after, this truth remained unformulated.
-And similarly, the property of inertia, though not
-distinctly comprehended until Kepler lived, was vaguely recognized
-long previously. “The conception of statical force,”
-“was never presented in a distinct form till the works of
-Archimedes appeared;” and “the conception of accelerating
-force was confused, in the mind of Kepler and his contemporaries,
-and did not become clear enough for purposes of sound
-scientific reasoning before the succeeding century.” To which
-specific assertions may be added the general remark, that
-“terms which originally, and before the laws of motion were
-fully known, were used in a very vague and fluctuating
-sense, were afterwards limited and rendered precise.” When
-we turn from abstract scientific conceptions to the concrete
-previsions of science, of which astronomy furnishes us with
-numerous examples, the like contrast is visible. The times
-at which celestial phenomena will occur, have been predicted
-with ever-increasing accuracy: errors once amounting to
-days, have been reduced down to seconds. The correspondence
-between the real and supposed forms of orbits, has
-been growing gradually more precise. Originally thought
-circular, then epicyclical, then elliptical, orbits are now
-ascertained to be curves which always deviate more or
-less from perfect ellipses, and which are ever undergoing
-change. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;But the general advance of Science in definiteness,
-is best shown by the contrast between its qualitative
-<span class='pageno' id='Page_193'>193</span>stage, and its quantitative stage. At first, the facts ascertained
-were, that between such and such phenomena some
-connexion existed—that the appearances <em>a</em> and <em>b</em> always
-occurred together or in succession; but it was neither
-known what was the nature of the relation between <em>a</em> and <em>b</em>,
-nor how much of <em>a</em> accompanied so much of <em>b</em>. The development
-of Science has in part been the reduction of these vague
-connexions to distinct ones. Most relations have been determined
-as belonging to the classes mechanical, chemical,
-thermal, electric, magnetic, &amp;c.; and we have learnt to
-infer the amounts of the antecedents and consequents from
-each other with an exactness that becomes ever greater.
-Were there space to state them, illustrations of this truth
-might be cited from all departments of physics; but it must
-suffice here to instance the general progress of chemistry.
-Besides the conspicuous fact that we have positively ascertained
-the constituent elements of an immense number of
-compounds which our ancestors could not analyze, and of a
-far greater number which they never even saw, there is the
-still more conspicuous fact that the combining equivalents of
-these elements are accurately calculated. The beginnings
-of a like advance from qualitative to quantitative prevision,
-may be traced even in some of the higher sciences. Physiology
-shows it in the weighing and measuring of organic products,
-and of the materials consumed. By Pathology it is
-displayed in the use of the statistical method of determining
-the sources of diseases, and the effects of treatment. In
-Zoology and Botany, the numerical comparisons of Floras
-and Faunas, leading to specific conclusions respecting their
-sources and distributions, illustrate it. And in Sociology,
-questionable as are the conclusions usually drawn from the
-classified sum-totals of the census, from Board-of-Trade
-tables, and from criminal returns, it must be admitted that
-these imply a progress towards more accurate conceptions of
-social phenomena. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;That an essential characteristic
-of advancing Science is increase in definiteness, appears indeed
-<span class='pageno' id='Page_194'>194</span>almost a truism, when we remember that Science may
-be described as definite knowledge, in contradistinction to
-that indefinite knowledge possessed by the uncultured. And
-if, as we cannot question, Science has, in the slow course of
-ages, been evolved out of this indefinite knowledge of the
-uncultured; then, the gradual acquirement of that great definiteness
-which now distinguishes it, must have been a leading
-trait in its evolution.</p>
-
-<p class='c000'>The Arts, industrial and æsthetic, furnish illustrations
-perhaps still more striking. Flint implements of the kind
-recently found in certain of the later geologic deposits—implements
-so rude that some have held them to be of natural
-rather than of artificial origin—show the extreme want of
-precision in men’s first handyworks. Though a great advance
-on these is seen in the tools and weapons of existing
-savage tribes, yet an inexactness in forms and fittings, more
-than anything else distinguishes such tools and weapons
-from those of civilized races. In a less degree, the productions
-of semi-barbarous nations are characterized by like defects.
-A Chinese junk with all its contained furniture and
-appliances, nowhere presents a perfectly straight line, a uniform
-curve, or a true surface. Nor do the utensils and
-machines of our ancestors fail to exhibit a similar inferiority
-to our own. An antique chair, an old fireplace, a lock of the
-last century, or almost any article of household use that has
-been preserved for a few generations, will prove by contrast
-how greatly the industrial products of our time excel those
-of the past in their accuracy. Since planing machines have
-been invented, it has become possible to produce absolutely
-straight lines, and surfaces so truly level as to be air-tight
-when applied to each other. While in the dividing-engine
-of Troughton, in the micrometer of Whitworth, and in microscopes
-that show fifty thousand divisions to the inch, we
-have an exactness as far exceeding that reached in the works
-of our great-grandfathers, as theirs exceeded that of the
-aboriginal celt-makers. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;In the Fine Arts there has
-<span class='pageno' id='Page_195'>195</span>been a parallel process. From the rudely carved and painted
-idols of savages, through the early sculptures characterized
-by limbs having no muscular detail, wooden-looking drapery,
-and faces devoid of individuality, up to the later statues of
-the Greeks or some of those now produced, the increased
-accuracy of representation is conspicuous. Compare the
-mural paintings of the Egyptians with the paintings of
-medieval Europe, or these with modern paintings, and the
-more precise rendering of the appearances of objects is manifest.
-So too is it with the delineations of fiction and the
-drama. In the marvellous tales current among Eastern
-nations, in the romantic legends of feudal Europe, as well as
-in the mystery-plays and those immediately succeeding them,
-we see great want of correspondence to the realities of life;
-not only in the predominance of supernatural events and extremely
-improbable coincidences, but also in the vaguely-indicated
-personages, who are nothing more than embodiments
-of virtue and vice in general, or at best of particular
-virtues and vices. Through transitions that need not be
-specified, there has been a progressive diminution, in both
-fiction and the drama, of whatever is unnatural—whatever
-does not answer to real life. And now, novels and plays are
-applauded in proportion to the fidelity with which they exhibit
-individual characters with their motives and consequent
-actions; improbabilities, like the impossibilities which preceded
-them, are disallowed; and there is even an incipient
-abandonment of those elaborate plots which the realities of
-life rarely if ever furnish.</p>
-
-<p class='c000'>Were it needful, it would be easy to accumulate evidences
-of various other kinds. The progress from myths and
-legends, extreme in their misrepresentations, to a history
-that has slowly become, and is still becoming, more accurate;
-the establishment of settled systematic methods of doing
-things, instead of the indeterminate ways at first pursued;
-and the great increase in the number of points on which
-conflicting opinion has settled down into exact knowledge;
-<span class='pageno' id='Page_196'>196</span>might severally be used further to exemplify the general
-truth enunciated. The basis of induction is, however, already
-sufficiently wide. Proof that all Evolution is from
-the indefinite to the definite, we find to be not less abundant
-than proof that all Evolution is from the homogeneous to
-the heterogeneous. The one kind of change is co-extensive
-with the other—is equally with it exhibited throughout
-Nature.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 56. To form a complete conception of Evolution, we
-have to contemplate it under yet another aspect. This advance
-from the indefinite to the definite, is obviously not
-primary but secondary—is an incidental result attendant on
-the finishing of certain changes. The transformation of a
-whole that was originally uniform, into a combination of
-multiform parts, implies a progressive separation. While
-this is going on there must be indistinctness. Only as each
-separated division draws into its general mass those diffused
-peripheral portions which are at first imperfectly disunited
-from the peripheral portions of neighbouring divisions, can
-it acquire anything like a precise outline. And it cannot
-become perfectly definite until its units are aggregated into
-a compact whole. That is to say, the acquirement of definiteness
-is simply a concomitant of complete union of the elements
-constituting each component division. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Thus,
-Evolution is characterized not only by a continuous multiplication
-of parts, but also by a growing oneness in each part.
-And while an advance in heterogeneity results from progressive
-differentiation, an advance in definiteness results
-from progressive integration. The two changes are simultaneous;
-or are rather opposite aspects of the same change.
-This change, however, cannot be rightly comprehended without
-looking at both its sides. Let us then once more consider
-Evolution under its several manifestations; for the purpose
-of noting how it is throughout a process of integration.</p>
-
-<p class='c000'>The illustrations furnished by the Solar System, supposing
-<span class='pageno' id='Page_197'>197</span>it to have had a nebular origin, are so obvious as scarcely to
-need indicating. That as a whole, it underwent a gradual
-concentration while assuming its present distribution of
-parts; and that there subsequently took place a like concentration
-of the matter forming each planet and satellite, is the
-leading feature of the hypothesis. The process of integration
-is here seen in its simplest and most decided form.</p>
-
-<p class='c000'>Geologic evolution, if we trace it up from that molten
-state of the Earth’s substance which we are obliged to postulate,
-supplies us with more varied facts of like meaning.
-The advance from a thin crust, at first everywhere fissured
-and moveable, to a crust so solid and thick as to be but now
-and then very partially dislocated by disturbing forces,
-exemplifies the unifying process; as does likewise the advance
-from a surface covered with small patches of land and
-water, to one divided into continents and oceans—an advance
-also resulting from the Earth’s gradual solidification. Moreover,
-the collection of detritus into strata of great extent, and
-the union of such strata into extensive “systems,” becomes
-possible only as surfaces of land and water become wide, and
-subsidences great, in both area and depth; whence it follows
-that integrations of this order must have grown more pronounced
-as the Earth’s crust thickened. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Different
-and simpler instances of the process through which mixed
-materials are separated, and the kindred units aggregated
-into masses, are exhibited in the detailed structure of the
-Earth. The phenomena of crystallization may be cited <i><span lang="fr" xml:lang="fr">en
-masse</span></i>, as showing how the unifications of similar elements
-take place wherever the conditions permit. Not only do we
-see this where there is little or no hindrance to the approach
-of the particles, as in the cases of crystals formed from
-solutions, or by sublimation; but it is also seen where there
-are great obstacles to their approach. The flints and the
-nodules of iron pyrites that are found in chalk, as well as
-the silicious concretions which occasionally occur in limestone,
-can be interpreted only as aggregations of atoms of
-<span class='pageno' id='Page_198'>198</span>silex or sulphuret of iron, originally diffused almost uniformly
-through the deposit, but gradually collected round
-certain centres, notwithstanding the solid or semi-solid state
-of the surrounding matter. Iron-stone as it ordinarily occurs,
-presents a similar phenomenon to be similarly explained;
-and what is called bog iron-ore supplies the conditions and
-the result in still more obvious correlation.</p>
-
-<p class='c000'>During the evolution of an organism, there occurs, as
-every physiologist knows, not only separation of parts, but
-coalescence of parts. In the mammalian embryo, the heart, at
-first a long pulsating blood-vessel, by and by twists upon
-itself and becomes integrated. The layer of bile-cells constituting
-the rudimentary liver, do not simply become different
-from the wall of the intestine in which they at first lie; but
-they simultaneously diverge from it and consolidate into an
-organ. The anterior segments of the cerebro-spinal axis,
-which are at first continuous with the rest, and distinguished
-only by their larger size, undergo a gradual union; and at
-the same time the resulting head consolidates into a mass
-clearly marked off from the rest of the vertebral column. The
-like process, variously exemplified in other organs, is meanwhile
-exhibited by the body as a whole; which becomes
-integrated, somewhat in the same way that the contents of
-an outspread handkerchief become integrated when its edges
-are drawn in and fastened to make a bundle. Analogous
-changes go on long after birth, and continue even up to old
-age. In the human being that gradual solidification of the
-bony framework, which, during childhood, is seen in the coalescence
-of portions of the same bone ossified from different
-centres, is afterwards seen in the coalescence of bones that
-were originally distinct. The appendages of the vertebræ unite
-with the vertebral centres to which they belong—a change not
-completed until towards thirty. At the same time the epiphyses,
-formed separately from the main bodies of their respective
-bones, have their cartilaginous connexions turned into
-osseous ones—are fused to the masses beneath them. The component
-<span class='pageno' id='Page_199'>199</span>vertebræ of the sacrum, which remain separate till about
-the sixteenth year, then begin to unite; and in ten or a dozen
-years more their union is complete. Still later occurs the coalescence
-of the coccygeal vertebræ; and there are some other
-bony unions which are not completed until advanced age.
-To which add that the increase of density and toughness,
-going on throughout the tissues in general during life, may
-be regarded as the formation of a more highly integrated substance.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The species of change thus illustrated under
-its several aspects in the unfolding of the human body, may
-be traced in all animals. That mode of it which consists in
-the union of homogeneous parts originally separate, has been
-described by Milne-Edwards and others, as exhibited in various
-of the invertebrata; though it does not seem to have been
-included by them as an essential peculiarity in the process of
-organic development. We shall, however, be led strongly to
-suspect that progressive integration should form part of the
-definition of this process, when we find it displayed not only
-in tracing up the stages passed through by every embryo, but
-also in ascending from the lower living creatures to the higher.
-And here, as in the evolution of individual organisms, it goes
-on both longitudinally and transversely: under which different
-forms we may indeed most conveniently consider
-it. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Of <em>longitudinal integration</em>, the sub-kingdom <em>Annulosa</em>
-supplies abundant examples. Its lower members, such
-as worms and myriapods, are mostly characterized by the great
-number of segments composing them: reaching in some cases
-to several hundreds. But in the higher divisions—crustaceans,
-insects, and spiders—we find this number reduced down
-to twenty-two, thirteen, or even fewer; while, accompanying
-the reduction, there is a shortening or integration of the
-whole body, reaching its extreme in the crab and the spider.
-The significance of these contrasts, as bearing upon the general
-doctrine of Evolution, will be seen when it is pointed out that
-they are parallel to those which arise during the development
-of individual <em>Annulosa</em>. In the lobster, the head and
-<span class='pageno' id='Page_200'>200</span>thorax form one compact box, made by the union of a number
-of segments which in the embryo were separable. Similarly,
-the butterfly shows us segments so much more closely
-united than they were in the caterpillar, as to be, some of
-them, no longer distinguishable from each other. The
-<em>Vertebrata</em> again, throughout their successively higher classes,
-furnish like instances of longitudinal union. In most fishes,
-and in reptiles that have no limbs, the only segments of the
-spinal column that coalesce, are those forming the skull. In
-most mammals and in birds, a variable number of vertebræ become
-fused together to form the sacrum; and in the higher
-quadrumana and man, the caudal vertebræ also lose their separate
-individualities in a single <i><span lang="la" xml:lang="la">os coccygis</span></i>. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;That which
-we may distinguish as <em>transverse integration</em>, is well illustrated
-among the <em>Annulosa</em> in the development of the nervous
-system. Leaving out those most degraded forms which do
-not present distinct ganglia, it is to be observed that the
-lower annulose animals, in common with the larvæ of the
-higher, are severally characterized by a double chain of
-ganglia running from end to end of the body; while in the
-more perfectly formed annulose animals, this double chain becomes
-more or less completely united into a single chain.
-Mr. Newport has described the course of this concentration
-as exhibited in insects; and by Rathke it has been traced in
-crustaceans. During the early stages of the <em>Astacus fluviatilis</em>,
-or common cray-fish, there is a pair of separate ganglia
-to each ring. Of the fourteen pairs belonging to the head
-and thorax, the three pairs in advance of the mouth consolidate
-into one mass to form the brain, or cephalic ganglion.
-Meanwhile, out of the remainder, the first six pairs severally
-unite in the median line, while the rest remain more or less
-separate. Of these six double ganglia thus formed, the
-anterior four coalesce into one mass; the remaining two
-coalesce into another mass; and then these two masses
-coalesce into one. Here we see longitudinal and transverse
-integration going on simultaneously; and in the highest
-<span class='pageno' id='Page_201'>201</span>crustaceans they are both carried still further. The <em>Vertebrata</em>
-clearly exhibit transverse integration in the development
-of the generative system. The lowest of the mammalia—the
-<em>Monotremata</em>—in common with birds, to which
-they are in many respects allied, have oviducts which towards
-their lower extremities are dilated into cavities, severally
-performing in an imperfect way the function of a uterus.
-“In the <em>Marsupialia</em> there is a closer approximation of the
-two lateral sets of organs on the median line; for the oviducts
-converge towards one another and meet (without coalescing)
-on the median line; so that their uterine dilatations are in
-contact with each other, forming a true ‘double uterus....’
-As we ascend the series of ‘placental’ mammals, we find the
-lateral coalescence becoming more and more complete....
-In many of the <em>Rodentia</em> the uterus still remains completely
-divided into two lateral halves; whilst in others these coalesce
-at their lower portions, forming a rudiment of the true ‘body’
-of the uterus in the human subject. This part increases at
-the expense of the lateral ‘cornua’ in the higher herbivora
-and carnivora; but even in the lower quadrumana the uterus
-is somewhat cleft at its summit.”<a id='r10' /><a href='#f10' class='c011'><sup>[10]</sup></a></p>
-
-<p class='c000'>In the social organism integrative changes are not less
-clearly and abundantly exemplified. Uncivilized societies
-display them when wandering families, such as the bushmen
-show us, unite into tribes of considerable numbers. Among
-these we see a further progress of like nature everywhere
-manifested in the subjugation of weaker tribes by stronger
-ones; and in the subordination of their respective chiefs to
-the conquering chief. The partial combinations thus resulting,
-which among aboriginal races are being continually formed
-and continually broken up, become, among the superior races,
-both more complete and more permanent. If we trace the
-metamorphoses through which our own society, or any adjacent
-one, has passed, we see this unification from time to time
-<span class='pageno' id='Page_202'>202</span>repeated on a larger scale and with increasing stability. The
-aggregation of juniors and the children of juniors under
-elders and the children of elders; the consequent establishment
-of groups of vassals bound to their respective nobles;
-the subordination afterwards established of groups of inferior
-nobles to dukes or earls; and the still later establishment of
-the kingly power over dukes or earls; are so many instances
-of increasing consolidation. This process through which petty
-tenures are combined into feuds, feuds into provinces, provinces
-into kingdoms, and finally contiguous kingdoms into
-a single one, slowly completes itself by destroying the original
-lines of demarcation. And it may be further remarked of
-the European nations as a whole, that in the tendency to
-form alliances more or less lasting, in the restraining influences
-exercised by the several governments over each other,
-in the system that is gradually establishing itself of settling
-international disputes by congresses, as well as in the
-breaking down of commercial barriers and the increasing
-facilities of communication, we may trace the incipient stage
-of a European confederation—a still larger integration than
-any now established. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;But it is not only in these external
-unions of groups with groups, and of the compound
-groups with each other, that the general law is exemplified.
-It is exemplified also in unions that take place internally, as
-the groups become more highly organized. These, of which
-the most conspicuous are commercial in their origin and function,
-are well illustrated in our own society. We have integrations
-consequent on the simple growth of adjacent parts
-performing like functions: as, for instance, the junction of
-Manchester with its calico-weaving suburbs. We have other
-integrations that arise when, out of several places producing
-a particular commodity, one monopolizes more and more of
-the business, and leaves the rest to dwindle: as witness the
-growth of the Yorkshire cloth-districts at the expense of
-those in the west of England; or the absorption by Staffordshire
-of the pottery-manufacture, and the consequent decay
-<span class='pageno' id='Page_203'>203</span>of the establishments that once flourished at Worcester,
-Derby, and elsewhere. And we have those yet other integrations
-produced by the actual approximation of the similarly-occupied
-parts: whence result such facts as the concentration
-of publishers in Paternoster Row; of lawyers in
-the Temple and neighbourhood; of corn-merchants about
-Mark Lane; of civil engineers in Great George Street; of
-bankers in the centre of the city. Industrial combinations
-that consist, not in the approximation or fusion of parts, but
-in the establishment of common centres of connexion, are exhibited
-in the Bank clearing-house and the Railway clearing-house.
-While of yet another genus are those unions which
-bring into relation the more or less dispersed citizens who are
-occupied in like ways: as traders are brought by the Exchange
-and the Stock-Exchange; and as are professional men
-by institutes, like those of Civil Engineers, Architects, &amp;c.</p>
-
-<p class='c000'>Here, as before, it is manifest that a law of Evolution
-which holds of organisms, must hold too of all objective results
-of their activity; and that hence Language, and Science,
-and Art, must not only in the course of their development
-display increasing heterogeneity and definiteness, but also increasing
-integration. We shall find this conclusion to be in
-harmony with the facts.</p>
-
-<p class='c000'>Among uncivilized races, the many-syllabled terms used for
-not uncommon objects, as well as the descriptive character of
-proper names, show us that the words used for the less familiar
-things are formed by compounding the words used for the
-more familiar things. This process of composition is sometimes
-found in its incipient stage—a stage in which the component
-words are temporarily united to signify some unnamed object,
-and do not (from lack of frequent use) permanently cohere.
-But in the majority of inferior languages, the process of “agglutination,”
-as it is called, has gone far enough to produce
-considerable stability in the compound words: there is a manifest
-integration. How small is the degree of this integration,
-however, when compared with that reached in well-developed
-<span class='pageno' id='Page_204'>204</span>languages is shown both by the great length of the compound
-words used for things and acts of constant occurrence, and
-by the separableness of their elements. Certain North-American
-tongues very well illustrate this. In a Ricaree vocabulary
-extending to fifty names of common objects, which in
-English are nearly all expressed by single syllables, there is
-not one monosyllabic word; and in the nearly-allied vocabulary
-of the Pawnees, the names for these same common
-objects are monosyllabic in but two instances. Things so
-familiar to these hunting tribes as <em>dog</em> and <em>bow</em>, are, in the
-Pawnee language, <em>ashakish</em> and <em>teeragish</em>; the <em>hand</em> and the
-<em>eyes</em> are respectively <em>iksheeree</em> and <em>keereekoo</em>; for <em>day</em> the
-term is <em>shakoorooeeshairet</em>, and for <em>devil</em> it is <em>tsaheekshkakooraiwah</em>;
-while the numerals are composed of from two syllables
-up to five, and in Ricaree up to seven. That the great
-length of these familiar words implies a low degree of development,
-and that in the formation of higher languages out
-of lower there is a progressive integration, which reduces the
-polysyllables to dissyllables and monosyllables, is an inference
-fully confirmed by the history of our own language.
-Anglo-Saxon <i><span lang="ang" xml:lang="ang">steorra</span></i> has been in course of time consolidated
-into English <em>star</em>, <i><span lang="ang" xml:lang="ang">mona</span></i> into <em>moon</em>, and <i><span lang="ang" xml:lang="ang">nama</span></i> into <em>name</em>. The
-transition through the intermediate semi-Saxon is clearly
-traceable. <i><span lang="osx" xml:lang="osx">Sunu</span></i> became in semi-Saxon <i><span lang="osx" xml:lang="osx">sune</span></i>, and in English
-<em>son</em>: the final <em>e</em> of <i><span lang="osx" xml:lang="osx">sune</span></i> being an evanescent form of the
-original <em>u</em>. The change from the Anglo-Saxon plural, formed
-by the distinct syllable <em>as</em>, to our plural formed by the appended
-consonant <em>s</em>, shows us the same thing: <i><span lang="osx" xml:lang="osx">smithas</span></i> in becoming
-<em>smiths</em>, and <i><span lang="osx" xml:lang="osx">endas</span></i> in becoming <em>ends</em>, illustrate progressive
-coalescence. So too does the disappearance of the
-terminal <em>an</em> in the infinitive mood of verbs; as shown in the
-transition from the Anglo-Saxon <i><span lang="ang" xml:lang="ang">cuman</span></i> to the semi-Saxon
-<i><span lang="osx" xml:lang="osx">cumme</span></i>, and to the English <em>come</em>. Moreover the process has
-been slowly going on, even since what we distinguish as English
-was formed. In Elizabeth’s time, verbs were still very
-frequently pluralized by the addition of <em>en</em>—we <em>tell</em> was we
-<span class='pageno' id='Page_205'>205</span><em>tellen</em>; and in some rural districts this form of speech may
-even now be heard. In like manner the terminal <em>ed</em> of the
-past tense, has united with the word it modifies. <em>Burn-ed</em> has
-in pronunciation become <em>burnt</em>; and even in writing the
-terminal <em>t</em> has in some cases taken the place of the <em>ed</em>. Only
-where antique forms in general are adhered to, as in the
-church-service, is the distinctness of this inflection still maintained.
-Further, we see that the compound vowels have
-been in many cases fused into single vowels. That in <em>bread</em>
-the <em>e</em> and <em>a</em> were originally both sounded, is proved by the
-fact that they are still so sounded in parts where old habits
-linger. We, however, have contracted the pronunciation into
-<em>bred</em>; and we have made like changes in many other common
-words. Lastly, let it be noted that where the frequency
-of repetition is greatest, the process is carried furthest; as
-instance the contraction of <em>lord</em> (originally <em>laford</em>) into <em>lud</em>
-in the mouths of Barristers; and still better the coalescence
-of <em>God be with you</em> into <em>Good bye</em>. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Besides exhibiting
-in this way the integrative process, Language equally
-exhibits it throughout all grammatical development. The
-lowest kinds of human speech, having merely nouns and
-verbs without inflections to them, manifestly permit no such
-close union of the elements of a proposition as results when
-the relations are either marked by inflections or by words
-specially used for purposes of connexion. Such speech is
-necessarily what we significantly call “incoherent.” To a considerable
-extent, incoherence is seen in the Chinese language.
-“If, instead of saying <em>I go</em> to <em>London</em>, <em>figs come</em> from <em>Turkey</em>,
-<em>the sun shines</em> through <em>the air</em>, we said, <em>I go</em> end <em>London</em>,
-<em>figs come</em> origin <em>Turkey</em>, <em>the sun shines</em> passage <em>air</em>, we should
-discourse of the manner of the Chinese.” From this “aptotic”
-form, there is clear evidence of a transition by coalescence
-to a form in which the connexions of words are expressed
-by the addition to them of certain inflectional words.
-“In Languages like the Chinese,” remarks Dr Latham, “the
-separate words most in use to express relation may become
-<span class='pageno' id='Page_206'>206</span>adjuncts or annexes.” To this he adds the fact that “the
-numerous inflexional languages fall into two classes. In one,
-the inflexions have no appearance of having been separate
-words. In the other, their origin as separate words is demonstrable.”
-From which the inference drawn is, that the
-“aptotic” languages, by the more and more constant use of
-adjuncts, gave rise to the “agglutinate” languages, or those
-in which the original separateness of the inflexional parts can
-be traced; and that out of these, by further use, arose the
-“amalgamate” languages, or these in which the original
-separateness of the inflexional parts can no longer be traced.
-Strongly corroborative of this inference is the unquestionable
-fact, that by such a process there have grown out of the
-amalgamate languages, the “anaptotic” languages; of which
-our own is the most perfect example—languages in which, by
-further consolidation, inflexions have almost disappeared,
-while, to express the verbal relations, certain new kinds of
-words have been developed. When we see the Anglo-Saxon
-inflexions gradually lost by contraction during the development
-of English, and, though to a less degree, the Latin inflexions
-dwindling away during the development of French,
-we cannot deny that grammatical structure is modified by integration;
-and seeing how clearly the earlier stages of grammatical
-structure are explained by it, we can scarcely doubt
-that it has been going on from the first. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;And now
-mark that in proportion to the degree of the integration above
-described, is the extent to which integration of another order
-is shown. Aptotic languages are, as already pointed out,
-necessarily incoherent—the elements of a proposition cannot
-be tied into a definite and complete whole. But as fast as
-coalescence produces inflected words, it becomes possible to
-unite them into sentences of which the parts are so mutually
-dependent that no considerable change can be made without
-destroying the meaning. Yet a further stage in this process
-may be noted. After the development of those grammatical
-forms which make definite statements possible, we do not at
-<span class='pageno' id='Page_207'>207</span>first find them used to express anything beyond statements
-of a simple kind. A single subject with a single predicate,
-accompanied by but few qualifying terms, are usually all. If
-we compare, for instance, the Hebrew scriptures with writings
-of modern times, a marked difference of aggregation among
-the groups of words, is visible. In the number of subordinate
-propositions which accompany the principal one; in the various
-complements to subjects and predicates; and in the
-numerous qualifying clauses—all of them united into one
-complex whole—many sentences in modern composition exhibit
-a degree of integration not to be found in ancient ones.</p>
-
-<p class='c000'>The history of Science presents facts of the same meaning
-at every step. Indeed the integration of groups of like
-entities and like relations, may be said to constitute the most
-conspicuous part of scientific progress. A glance at the classificatory
-sciences, shows us not only that the confused aggregations
-which the vulgar make of natural objects, are differentiated
-into groups that are respectively more homogeneous,
-but also that these groups are gradually rendered complete
-and compact. While, instead of considering all marine
-creatures as fish, shell-fish, and jelly-fish, Zoology establishes
-divisions and sub-divisions under the heads <em>Vertebrata</em>,
-<em>Annulosa</em>, <em>Mollusca</em>, &amp;c.—while in place of the wide and
-vague assemblage popularly described as “creeping things,”
-it makes the specific classes <em>Annelida</em>, <em>Myriopoda</em>, <em>Insecta</em>,
-<em>Arachnida</em>; it at the same time gives to these an increasing
-consolidation. The several orders and genera of which each
-consists, are arranged according to their affinities and bound
-together under common definitions; at the same time that,
-by extended observation and rigorous criticism, the previously
-unknown and undetermined forms are integrated with their
-respective congeners. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Nor is the same process less
-clearly manifested in those sciences which have for their
-subject-matter, not classified objects, but classified relations.
-Under one of its chief aspects, the advance of Science
-is the advance of generalization; and generalization is the
-<span class='pageno' id='Page_208'>208</span>uniting into groups all like co-existencies and sequences
-among phenomena. Not only, however, does the colligation
-of a number of concrete relations into a generalization of the
-lowest order, exemplify the principle enunciated; but it is
-again and again exemplified in the colligation of these lowest
-generalizations into higher ones, and these into still higher
-ones. Year by year are established certain connexions
-among orders of phenomena that seem wholly unallied; and
-these connexions, multiplying and strengthening, gradually
-bring the seemingly unallied orders under a common bond.
-When, for example, Humboldt quotes the saying of the Swiss—“it
-is going to rain because we hear the murmur of the
-torrents nearer,”—when he remarks the relation between this
-and an observation of his own, that the cataracts of the Orinoco
-are heard at a greater distance by night than by day—when
-he notes the essential parallelism existing between these
-facts and the fact that the unusual visibility of remote objects
-is also an indication of coming rain—and when he
-points out that the common cause of these variations is the
-smaller hindrance offered to the passage of both light and
-sound, by media which are comparatively homogeneous,
-either in temperature or hygrometric state; he helps in
-bringing under one generalization the phenomena of light
-and those of sound. Experiment having shown that these
-conform to like laws of reflection and refraction, the conclusion
-that they are both produced by undulations gains probability:
-there is an incipient integration of two great orders
-of phenomena, between which no connexion was suspected in
-times past. A still more decided integration has been of late
-taking place between the once independent sub-sciences of
-Electricity, Magnetism, and Light. And indeed it must be
-obvious to those who are familiar with the present state of
-Science, that there will eventually take place a far wider
-integration, by which all orders of phenomena will be combined
-as differently conditioned forms of one ultimate fact.</p>
-
-<p class='c000'>Nor do the industrial and æsthetic Arts fail to supply us
-<span class='pageno' id='Page_209'>209</span>with equally conclusive evidence. The progress from rude,
-small, and simple tools, to perfect, complex, and large machines,
-illustrates not only a progress in heterogeneity and
-in definiteness, but also in integration. Among what are
-classed as the mechanical powers, the advance from the lever
-to the wheel-and-axle is an advance from a simple agent to an
-agent made up of several simple ones combined together. On
-comparing the wheel-and-axle, or any of the machines used
-in early times with those used now, we find an essential
-difference to be, that in each of our machines several of the
-primitive machines are united into one. A modern apparatus
-for spinning or weaving, for making stockings or lace,
-contains not simply a lever, an inclined plane, a screw, a
-wheel-and-axle, united together; but several of each integrated
-into one complex whole. Again, in early ages, when
-horse-power and man-power were alone employed, the motive
-agent was not bound up with the tool moved; but the two
-have now become in many cases fused together: the fire-box
-and boiler of a locomotive are combined with the machinery
-which the steam works. Nor is this the most extreme case.
-A still more extensive integration is exhibited in every
-large factory. Here we find a large number of complicated
-machines, all connected by driving shafts with the same
-steam-engine—all united with it into one vast apparatus.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Contrast the mural decorations of the
-Egyptians and Assyrians with modern historical paintings,
-and there becomes manifest a great advance in unity of composition—in
-the subordination of the parts to the whole.
-One of these ancient frescoes is in truth made up of a number
-of pictures that have little mutual dependence. The
-several figures of which each group consists, show very imperfectly
-by their attitudes, and not at all by their expressions,
-the relations in which they stand to each other; the
-respective groups might be separated with but little loss of
-meaning; and the centre of chief interest, which should link
-all parts together, is often inconspicuous. The same trait
-<span class='pageno' id='Page_210'>210</span>may be noted in the tapestries of medieval days. Representing
-perhaps a hunting scene, one of these exhibits men,
-horses, dogs, beasts, birds, trees, and flowers, miscellaneously
-dispersed: the living objects being variously occupied, and
-mostly with no apparent consciousness of each other’s proximity.
-But in the paintings since produced, faulty as many
-of them are in this respect, there is always a more or less
-manifest co-ordination of parts—an arrangement of attitudes,
-expressions, lights, and colours, such as to combine the picture
-into an organic whole; and the success with which unity
-of effect is educed from variety of components, is a chief test
-of merit. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;In music, progressive integration is displayed
-in still more numerous ways. The simple cadence
-embracing but a few notes, which in the chants of savages is
-monotonously repeated, becomes among civilized races, a long
-series of different musical phrases combined into one whole;
-and so complete is the integration, that the melody cannot be
-broken off in the middle, nor shorn of its final note, without
-giving us a painful sense of incompleteness. When to the
-air, a bass, a tenor, and an alto are added; and when to the
-harmony of different voice-parts there is added an accompaniment;
-we see exemplified integrations of another order, which
-grow gradually more elaborate. And the process is carried
-a stage higher when these complex solos, concerted pieces,
-choruses, and orchestral effects, are combined into the vast
-ensemble of a musical drama; of which, be it remembered,
-the artistic perfection largely consists in the subordination of
-the particular effects to the total effect. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Once more
-the Arts of literary delineation, narrative and dramatic, furnish
-us with parallel illustrations. The tales of primitive times,
-like those with which the story-tellers of the East still daily
-amuse their listeners, are made up of successive occurrences
-that are not only in themselves unnatural, but have no
-natural connexion: they are but so many separate adventures
-put together without necessary sequence. But in a
-good modern work of imagination, the events are the proper
-<span class='pageno' id='Page_211'>211</span>products of the characters working under given conditions;
-and cannot at will be changed in their order or kind, without
-injuring or destroying the general effect. And further, the
-characters themselves, which in early fictions play their respective
-parts without showing us how their minds are modified
-by each other or by the events, are now presented to us
-as held together by complex moral relations, and as acting
-and re-acting upon each other’s natures.</p>
-
-<p class='c000'>Evolution, then, is in all cases a change from a more diffused
-or incoherent form, to a more consolidated or coherent
-form. This proves to be a characteristic displayed equally
-in those earliest changes which the Universe as a whole is
-supposed to have undergone, and in those latest changes
-which we trace in society and the products of social life.
-Nor is it only that in the development of a planet, of an
-organism, of a society, of a science, of an art, the process
-of integration is seen in a more complete aggregation of each
-whole and of its constituent parts; but it is also shown in an
-increasing mutual dependence of the parts. Dimly foreshadowed
-as this mutual dependence is among inorganic
-phenomena, both celestial and terrestrial, it becomes distinct
-among organic phenomena. From the lowest living forms
-upwards, the degree of development is marked by the degree
-in which the several parts constitute a mutually-dependent
-whole. The advance from those creatures which live on in
-each part when cut in pieces, up to those creatures which
-cannot lose any considerable part without death, nor any inconsiderable
-part without great constitutional disturbance, is
-clearly an advance to creatures which are not only more integrated
-in respect of their solidification, but are also more
-integrated as consisting of organs that live for and by each
-other. The like contrast between undeveloped and developed
-societies, need not be shown in detail: the ever-increasing
-co-ordination of parts, is conspicuous to all. And it must
-suffice just to indicate that the same thing holds true of
-social products: as, for instance, of Science; which has become
-<span class='pageno' id='Page_212'>212</span>highly integrated not only in the sense that each division
-is made up of mutually-dependent propositions, but
-also in the sense that the several divisions are mutually-dependent—cannot
-carry on their respective investigations
-without aid from each other.</p>
-
-<p class='c000'>It seems proper to remark that the generalization here
-variously illustrated, is akin to one enunciated by Schelling,
-that Life is the tendency to individuation. Struck by the
-fact that an aggregative process is traceable throughout
-nature, from the growth of a crystal up to the development
-of a man; and by the fact that the wholes resulting from this
-process, completer in organic than in inorganic bodies, are
-completest where the vital manifestations are the highest;
-Schelling concluded that this characteristic was the essential
-one. According to him, the formation of individual bodies
-is not incident to Life, but is that in which Life fundamentally
-consists. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;This position is, for several reasons,
-untenable. In the first place, it requires the conception of
-Life to be extended so as to embrace inorganic phenomena;
-since in crystallization, and even in the formation of amorphous
-masses of matter, this tendency to individuation is
-displayed. Schelling, fully perceiving this, did indeed accept
-the implication; and held that inorganic bodies had life
-lower only in degree than that of organic bodies—their
-degree of life being measured by their degree of individuation.
-This bold assumption, which Schelling evidently
-made to save his definition, is inadmissible. Rational philosophy
-cannot ignore those broad distinctions which the
-general sense of mankind has established. If it transcends
-them, it must at the same time show what is their origin;
-how far only they are valid; and why they disappear from
-a higher point of view. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Note next that the more
-complete individuality which Schelling pointed out as
-characterizing bodies having the greatest amount of life,
-is only <em>one</em> of their structural traits. The greater degree of
-heterogeneity which they exhibit, is, as we have seen, a
-<span class='pageno' id='Page_213'>213</span>much more conspicuous peculiarity; and though it might
-possibly be contended that greater heterogeneity is remotely
-implied by greater individuality, it must be admitted that in
-defining Life as the tendency to individuation, no hint is given
-that the bodies which live most are the most heterogeneous
-bodies. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Moreover it is to be remarked that this
-definition of Schelling, refers much more to the structures of
-living bodies than to the processes which constitute Life. Not
-Life, but the invariable accompaniment of Life, is that which
-his formula alone expresses. The formation of a completer
-organic whole, a more fully individuated body, is truly a
-necessary concomitant of a higher life; and the development
-of a higher life must therefore be accompanied by a tendency
-to greater individuation. But to represent this tendency as
-Life itself, is to mistake an incidental result for an original
-cause. Life, properly so called, consists of multiform changes
-united together in various ways; and is not expressed either
-by an anatomical description of the organism which manifests
-it, or by a history of the modifications through which such
-organism has reached its present structure. Yet it is only
-in such description and such history that the tendency to
-individuation is seen. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Lastly, this definition which
-Schelling gave of Life is untenable, not only because it refers
-rather to the organism than to the actions going on in it;
-but also because it wholly ignores that connexion between
-the organism and the external world, on which Life depends.
-All organic processes, physical and psychial, having for their
-object the maintenance of certain relations with environing
-agencies and objects; it is impossible that there should be a
-true definition of Life, in which the environment is not
-named. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Nevertheless, Schelling’s conception was
-not a baseless one. Though not a truth, it was yet the
-adumbration of a truth. In defining Life as the tendency to
-individuation, he had in view that formation of a more compact,
-complete, and mutually-dependent whole, which, as we
-have seen, is one characteristic of Evolution in general. His
-<span class='pageno' id='Page_214'>214</span>error was, firstly, in regarding it as a characteristic of Life,
-instead of a characteristic of living bodies, displayed, though
-in a less degree, by other bodies; and, secondly, in regarding
-it as the sole characteristic of such bodies. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;It remains
-only to add, that for expressing this aspect of the process
-of Evolution, the word integration is for several reasons
-preferable to the word individuation. Integration is the true
-antithesis of differentiation; it has not that tacit reference to
-living bodies which the word individuation cannot be wholly
-freed from; it expresses the aggregative tendency not only
-as displayed in the formation of more complete wholes, but
-also as displayed in the consolidation of the several parts of
-which such wholes are made up; and it has not the remotest
-teleological implication. In short, it simply formulates in the
-most abstract manner, a wide induction untainted by any
-hypothesis.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 57. Thus we find that to complete the definition arrived
-at in the last chapter, much has to be added. What
-was there alleged is true; but it is not the whole truth.
-Evolution is unquestionably a change from a homogeneous
-state to a heterogeneous state; but, as we have seen, there
-are some advances in heterogeneity which cannot be included
-in the idea of Evolution. This undue width of the definition,
-implies the omission of some further peculiarity by which
-Evolution is distinguished; and this peculiarity we find to
-be that the more highly developed things become, the more
-definite they become. Advance from the indefinite to the
-definite, is as constantly and variously displayed as advance
-from the homogeneous to the heterogeneous. And we are
-thus obliged to regard it as an essential characteristic of
-Evolution. Further analysis, however, shows us that this
-increase of definiteness is not an independent process; but
-is rather the necessary concomitant of another process. A
-very little consideration of the facts proves that a change
-from the indefinite to the definite, can arise only through a
-<span class='pageno' id='Page_215'>215</span>completer consolidation of the respective parts, and of the
-whole which they constitute. And so we find that while
-Evolution is a transformation of the homogeneous into the
-heterogeneous, and of the indefinite into the definite, it is also
-a transformation of the incoherent into the coherent. Along
-with the differentiation shown in increasing contrasts of
-parts with each other, there goes on an integration, by which
-the parts are rendered distinct units, as well as closely united
-components of one whole. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;These clauses here added
-to the definition, are essential ones; not only as being needful
-to distinguish Evolution from that which is not Evolution,
-but likewise as being needful to express all which the idea of
-Evolution includes. Progressive integration with the growing
-definiteness necessarily resulting from it, is of co-ordinate
-importance with the progressive differentiation before dwelt
-upon—nay, from one point of view, may be held of greater
-importance. For organization, in which what we call Evolution
-is most clearly and variously displayed, consists even
-more in the union of many parts into one whole, than in the
-formation of many parts. The Evolution which we see throughout
-inorganic nature, is lower than that which organic nature
-exhibits to us, for the especial reason that the mutual dependence
-of parts is extremely indefinite, even when traceable at
-all. In an amorphous mass of matter, you may act mechanically
-or chemically upon one part without appreciably affecting
-the other parts. Though their electrical or thermal states
-may be for the moment altered, their original states are soon
-resumed. Even in the highest inorganic aggregation—a
-crystal—the apex may be broken off and leave the rest intact:
-the only clear evidence of mutual dependence of parts, being,
-the ability of the crystal to regenerate its apex if replaced in
-the solution from which it was formed. But the constituent
-parts of organic bodies can severally maintain their existing
-states, only while remaining in connexion. Even in the lowest
-living forms, mutilation cannot be carried beyond a certain
-point without decomposition ensuing. As we advance through
-<span class='pageno' id='Page_216'>216</span>the higher up to the highest forms, we see a gradual narrowing
-of the limits within which the mutilation does not
-cause destruction: a progressive increase of mutual dependence
-or integration which is, at the same time, the condition
-to greater functional perfection. In societies this truth is
-equally manifest. That the component units slowly segregate
-into groups of different ranks and occupations, is a fact
-scarcely more conspicuous than is the fact that these groups
-are necessary to each other’s existence. And we cannot contemplate
-the still-progressing division of labour, without seeing
-that the interdependence becomes ever greater as the
-evolution becomes higher. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;It remains only to point
-out definitely, what has been already implied, that these
-several forms of change which have been successively described
-as making up the process of Evolution, are not in
-reality separate forms of change, but different aspects of the
-same change. Intrinsically the transformation is one and indivisible.
-The establishment of differences that become gradually
-more decided, is evidently but the beginning of an
-action which cannot be pushed to its extreme without producing
-definite divisions between the parts, and reducing
-each part to a separate mass. But with our limited faculties,
-it is not possible to take in the entire process at one view;
-nor have we any single terms by which the process can be
-described. Hence we are obliged to contemplate each of its
-aspects separately, and to find a separate expression for its
-characteristic.</p>
-
-<p class='c000'>Having done this, we are now in a position to frame a
-true idea of Evolution. Combining these partial definitions
-we get a complete definition, which may be most conveniently
-expressed thus—<em>Evolution is a change from an indefinite, incoherent
-homogeneity, to a definite, coherent heterogeneity;
-through continuous differentiations and integrations.</em></p>
-
-<p class='c000'>It may perhaps be remarked that the last of these clauses
-is superfluous; since the differentiation and integration are
-implied in the first clause. This is true: the transition which
-<span class='pageno' id='Page_217'>217</span>the first clause specifies, is impossible save through the process
-specified in the second. Nevertheless, a mere statement
-of the two extreme stages with which Evolution begins
-and ends, omitting all reference to changes connecting them,
-leaves the mind with but an incomplete idea. The idea becomes
-much more concrete when these changes are described.
-Hence, though not logically necessary, the second clause of
-the definition is practically desirable.</p>
-
-<p class='c000'>Before closing the chapter, a few words must be added
-respecting certain other modes of describing Evolution. Organic
-bodies, from the changes of which the idea of Evolution
-has arisen, and to the changes of which alone it is usually
-applied, are often said to progress from simplicity to complexity.
-The transformation of the simple into the complex,
-and of the homogeneous into the heterogeneous, are used as
-equivalent phrases; or, if any difference is recognized between
-them, it is to the advantage of the first, which is held
-to be the more specific. After what has been said, however,
-it must be obvious that Evolution cannot be thus adequately
-formulated. No hint is given of that increased definiteness
-which we have found to be a concomitant of development.
-Nor is there anything implying the greater mutual dependence
-of parts. Nevertheless, the brevity of the expression
-gives it a value for ordinary purposes; and I shall probably
-hereafter frequently use it, both in those cases where more
-precise language is not demanded, and in those cases
-where it indicates the particular aspect of Evolution referred
-to. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Another description frequently given of Evolution,
-is, that it is a change from the general to the special.
-The more or less spherical germ from which every organism,
-animal and vegetal, proceeds, is comparatively general: alike
-in the sense that in appearance and chemical nature it is very
-similar to all other germs; and also in the sense that its form
-is less markedly distinguished from the average forms of objects
-at large, than is that of the mature organism—a contrast
-which equally holds of internal structure. But this progress
-<span class='pageno' id='Page_218'>218</span>from the more general to the more special, is rather a derivative
-than an original characteristic. An increase of speciality
-being really an increase in the number of attributes—an addition
-of traits not possessed by bodies that are in other respects
-similar—is a necessary result of multiplying differentiations.
-In other words, general and special are subjective
-or ideal distinctions involved in our conceptions of classes,
-rather than objective or real distinctions presented in the
-bodies classified. Nevertheless, this abstract formula is not
-without its use. It expresses a fact of much significance;
-and one which we shall have constantly to refer to when
-dealing with the relations between organic bodies and their
-surrounding conditions.</p>
-
-<p class='c000'>The law of Evolution however, be it expressed in full as
-above, or in these shorter but less specific phrases, is essentially
-that which has been exhibited in detail throughout the
-foregoing pages. So far as we can ascertain, this law is universal.
-It is illustrated with endless repetition, and in countless
-ways, wherever the facts are abundant; and where the
-facts do not suffice for induction, deduction goes far to supply
-its place. Among all orders of phenomena that lie within
-the sphere of observation, we see ever going on the process
-of change above defined; and many significant indications
-warrant us in believing, that the same process of change went
-on throughout that remote past which lies beyond the sphere
-of observation. If we must form any conclusion respecting
-the general course of things, past, present, and future, the
-one which the evidence as far as it goes justifies, and the
-only one for which there is any justification, is, that the
-change from an indeterminate uniformity to a determinate
-multiformity which we everywhere see going on, has been
-going on from the first, and will continue to go on.</p>
-
-<hr class='c015' />
-
-<div class='footnote' id='f10'>
-<p class='c000'><span class='label'><a href='#r10'>10</a>.&nbsp;&nbsp;</span>Carpenter’s Prin. of Comp. Phys., p. 617.</p>
-</div>
-
-<div>
- <span class='pageno' id='Page_219'>219</span>
- <h3 class='c001'>CHAPTER IV.<br /> <span class='large'>THE CAUSES OF EVOLUTION.</span></h3>
-</div>
-
-<p class='c006'>§ 58. Is this law ultimate or derivative? Must we rest
-satisfied with the conclusion that throughout all classes of
-concrete phenomena such is the mode of evolution? Or is it
-possible for us to ascertain <em>why</em> such is the mode of evolution?
-May we seek for some all-pervading principle which underlies
-this all-pervading process? Can we by a further step
-reduce our empirical generalization to a rational generalization?</p>
-
-<p class='c000'>Manifestly this community of result implies community of
-causation. It may be that of such causation no account can
-be given, further than that the Unknowable is manifested to
-us after this manner. Or, it may be, that the mode of manifestation
-is reducible to simpler ones, from which these
-many complex consequences follow. Analogy suggests the
-latter inference. At present, the conclusion that every kind
-of Evolution is from a state of indefinite incoherent homogeneity
-to a state of definite coherent heterogeneity, stands
-in the same position as did the once ultimate conclusion that
-every kind of organized body undergoes, when dead, a more
-or less rapid decay. And as, for the various kinds of decomposition
-through which animal and vegetal products pass, we
-have now discovered a rationale in the chemical affinities of
-their constituent elements; so, possibly, this universal transformation
-of the simple into the complex may be affiliated
-upon certain simple primordial principles.</p>
-
-<p class='c000'><span class='pageno' id='Page_220'>220</span>Such cause or causes of Evolution, may be sought for without
-in the least assuming that the ultimate mystery can be
-fathomed. Fully conscious that an absolute solution is for
-ever beyond us, we may still look for a relative solution—may
-try to reduce the problem to its lowest terms. Just as
-it was possible to interpret Kepler’s laws as necessary consequences
-of the law of gravitation, and then to admit that
-gravitation transcends analysis; so it may be possible to
-interpret the law of Evolution as the necessary consequence
-of some deeper law, beyond which we may nevertheless be
-unable to go.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 59. The probability of common causation, and the possibility
-of formulating it, being granted, it will be well before
-going further, to consider what must be the general characteristics
-of such causation, and in what direction we ought to
-look for it. We can with certainty predict that be it simple
-or compound, the cause has a high degree of generality; seeing
-that it is common to such infinitely varied phenomena:
-in proportion to the universality of its application must be
-the abstractness of its character. Whatever be the agency
-and the conditions under which it acts, we need not expect
-to see in them an obvious explanation of this or that species of
-Evolution, because they equally underlie species of Evolution
-of quite a different order. Determining Evolution of every
-kind—astronomic, geologic, organic, ethnologic, social, economic,
-artistic, &amp;c.—they must be concerned with something
-common to all these; and to see what these possess in common,
-will therefore be the best method of guiding ourselves
-towards the desired solution.</p>
-
-<p class='c000'>The only obvious respect in which all kinds of Evolution
-are alike, is, that they are modes of <em>change</em>. Every phenomenon
-to which we apply the term, presents us with a succession
-of states; and when such succession ceases, we no longer
-predicate Evolution. Equally in those past forms of it which
-are more or less hypothetical, and in those forms of it which
-<span class='pageno' id='Page_221'>221</span>we see going on around, this is the common characteristic.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Note next, that the kind of change which
-constitutes Evolution, is broadly distinguished from change
-of an equally general kind, in this, that it is change of internal
-relations instead of change of external relations. All
-things in motion through space are the subjects of change;
-but while in this which we call mechanical motion, the relative
-position as measured from surrounding objects is continually
-altered, there is not implied any alteration in the
-positions of the parts of the moving body in respect to each
-other. Conversely, a body exhibiting what we call Evolution,
-while it either may or may not display new relations
-of position to the things around it, <em>must</em> display new relations
-of position among the parts of which it is made up. Thus
-we narrow the field of inquiry by recognizing the change in
-which Evolution consists, as <em>a change in the arrangement of
-parts</em>: of course using the word parts in its most extended
-sense, as signifying both ultimate units and masses of such
-units. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Further, we have to remember that this
-change in the arrangement of parts which constitutes Evolution,
-is a certain order of such change. As we saw in the
-last chapter, there is a change in the arrangement of parts
-which is not Evolution but Dissolution—a destructive change
-as opposed to a constructive change—a change by which the
-definite is gradually rendered indefinite, the coherent slowly
-becomes incoherent, and the heterogeneous eventually lapses
-into comparative homogeneity. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Thus then we reduce
-that which we have to investigate to its most abstract
-shape. Our task is to find the cause or causes of a certain
-order of change that takes place in the arrangement of parts.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 60. Evidently the problem, as thus expressed, brings us
-face to face with the ultimate elements of phenomena in general.
-It is impossible to account for a certain change in
-the arrangement of the parts of any mass, without involving—first,
-the <em>matter</em> which makes up the parts thus re-arranged;
-<span class='pageno' id='Page_222'>222</span>next, the <em>motion</em> exhibited during the re-arrangement; and
-then, the <em>force</em> producing this motion. The problem is a
-dynamical one; and there can be no truly scientific solution
-of it, save one given in terms of Matter, Motion, and Force—terms
-in which all other dynamical problems are expressed
-and solved.</p>
-
-<p class='c000'>The proposal thus to study the question from a purely physical
-point of view, will most likely, notwithstanding what
-has been said in the first part of this work, raise in some
-minds either alarm or prejudice. Having, throughout life,
-constantly heard the charge of materialism made against
-those who ascribed the more involved phenomena to agencies
-like those seen in the simplest phenomena, most persons have
-acquired a repugnance to such methods of interpretation;
-and when it is proposed to apply them universally, even
-though it is premised that the solution they give can be but
-relative, more or less of the habitual feeling will probably
-arise. Such an attitude of mind, however, is significant,
-not so much of a reverence for the Unknown Cause, as of an
-irreverence for those omnipresent forms in which the Unknown
-Cause is manifested to us. Men who have not risen
-above that vulgar conception which unites with Matter the
-contemptuous epithets “gross” and “brute,” may naturally
-enough feel dismay at the proposal to reduce the phenomena
-of Life, of Mind, and of Society, to a level with those which
-they think so degraded. But whoever remembers that the
-forms of existence which the uncultivated speak of with so
-much scorn, are not only shown by the man of science to be
-the more marvellous in their attributes the more they are
-investigated, but are also proved to be in their ultimate
-nature absolutely incomprehensible—as absolutely incomprehensible
-as sensation, or the conscious something which
-perceives it—whoever fully realizes this truth, I say, will
-see that the course proposed does not imply a degradation
-of the so-called higher, but an elevation of the so-called
-lower. Perceiving, as he will, that the Materialist and
-<span class='pageno' id='Page_223'>223</span>Spiritualist controversy is a mere war of words, in which
-the disputants are equally absurd—each thinking he understands
-that which it is impossible for any man to understand—he
-will perceive how utterly groundless is the fear referred
-to. Being fully convinced that whatever nomenclature is
-used, the ultimate mystery must remain the same, he will be
-as ready to formulate all phenomena in terms of Matter, Motion,
-and Force, as in any other terms; and will rather indeed
-anticipate, that only in a doctrine which recognizes the Unknown
-Cause as co-extensive with all orders of phenomena,
-can there be a consistent Religion, or a consistent Science.</p>
-
-<p class='c000'>On the other hand, the conclusion that Evolution, considered
-under its most abstract form, is a certain change in the
-arrangement of parts; and that the causes of this change can
-be expressed only in terms of Matter, Motion, and Force;
-may in critical minds raise the question—What are Matter,
-Motion, and Force? Referring back in thought to the reasonings
-contained in the chapter on “Ultimate Scientific Ideas;”
-and remembering how it was there shown that absolute knowledge
-of Matter, Motion, and Force, is impossible; some
-readers will perhaps conclude that any such interpretation as
-the one above proposed, must be visionary. It may be asked—How
-can a comprehensible account of Evolution be given
-in terms that are themselves incomprehensible?</p>
-
-<p class='c000'>Before proceeding, this question must be met. There can
-be no sound philosophy without clearly defined terms; and
-as, on the meanings of the terms to be here used, doubts have
-probably been cast by the reasonings contained in the chapter
-referred to, such doubts must be removed. If, as was shown,
-our ideas of things do not correspond with things in themselves,
-it becomes necessary to inquire in what way they are
-to be accepted. If they are not absolutely true, then what is
-the exact meaning of the assertion that they are relatively
-true? To this question let us now address ourselves.</p>
-
-<div>
- <span class='pageno' id='Page_224'>224</span>
- <h3 class='c001'>CHAPTER V.<br /> <span class='large'>SPACE, TIME, MATTER, MOTION, AND FORCE.</span></h3>
-</div>
-
-<p class='c006'>§ 61. That sceptical state of mind which the criticisms of
-Philosophy usually produce, is, in great measure, caused by
-the misinterpretation of words. A sense of universal illusion
-ordinarily follows the reading of metaphysics; and is strong
-in proportion as the argument has appeared conclusive. This
-sense of universal illusion would probably never have arisen,
-had the terms used been always rightly construed. Unfortunately,
-these terms have by association acquired meanings
-that are quite different from those given to them in philosophical
-discussions; and the ordinary meanings being unavoidably
-suggested, there results more or less of that dreamlike
-idealism which is so incongruous with our instinctive
-convictions. The word <em>phenomenon</em> and its equivalent word
-<em>appearance</em>, are in great part to blame for this. In ordinary
-speech, these are uniformly employed in reference to visual
-perceptions. Habit, almost, if not quite, disables us from
-thinking of <em>appearance</em> except as something seen; and though
-<em>phenomenon</em> has a more generalized meaning, yet we cannot
-rid it of associations with <em>appearance</em>, which is its verbal
-equivalent. When, therefore, Philosophy proves that our
-knowledge of the external world can be but phenomenal—when
-it concludes that the things of which we are conscious
-are appearances; it inevitably arouses in us the notion of an
-illusiveness like that to which our visual perceptions are so
-liable in comparison with our tactual perceptions. Good pictures
-<span class='pageno' id='Page_225'>225</span>show us that the aspects of things may be very nearly
-simulated by colours on canvass. The looking-glass still more
-distinctly proves how deceptive is sight when unverified by
-touch. And the frequent cases in which we misinterpret the
-impressions made on our eyes, and think we see something
-which we do not see, further shake our faith in vision. So
-that the implication of uncertainty has infected the very word
-<em>appearance</em>. Hence, Philosophy, by giving it an extended
-meaning, leads us to think of all our senses as deceiving us in
-the same way that the eyes do; and so makes us feel ourselves
-floating in a world of phantasms. Had <em>phenomenon</em> and <em>appearance</em>
-no such misleading associations, little, if any, of this
-mental confusion would result. Or did we in place of them
-use the term <em>effect</em>, which is equally applicable to all impressions
-produced on consciousness through any of the senses,
-and which carries with it in thought the necessary correlative
-<em>cause</em>, with which it is equally real, we should be in little
-danger of falling into the insanities of idealism.</p>
-
-<p class='c000'>Such danger as there might still remain, would disappear
-on making a further verbal correction. At present, the confusion
-resulting from the above misinterpretation, is made
-greater by an antithetical misinterpretation. We increase
-the seeming unreality of that phenomenal existence which
-we can alone know, by contrasting it with a noumenal existence
-which we imagine would, if we could know it, be more
-truly real to us. But we delude ourselves with a verbal fiction.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;What is the meaning of the word <em>real</em>? This
-is the question which underlies every metaphysical inquiry;
-and the neglect of it is the remaining cause of the chronic
-antagonisms of metaphysicians. In the interpretation put on
-the word <em>real</em>, the discussions of philosophy retain one element
-of the vulgar conception of things, while they reject all
-its other elements; and create confusion by the inconsistency.
-The peasant, on contemplating an object, does not regard
-that which he contemplates as something in himself, but believes
-the thing of which he is conscious to be the external
-<span class='pageno' id='Page_226'>226</span>object—imagines that his consciousness extends to the very
-place where the object lies: to him the appearance and the
-reality are one and the same thing. The metaphysician,
-however, is convinced that consciousness cannot embrace the
-reality, but only the appearance of it; and so he transfers the
-appearance into consciousness and leaves the reality outside.
-This reality left outside of consciousness, he continues to
-think of much in the same way as the ignorant man thinks
-of the appearance. Though the reality is asserted to be out
-of consciousness, yet the <em>realness</em> ascribed to it is constantly
-spoken of as though it were a knowledge possessed apart from
-consciousness. It seems to be forgotten that the conception of
-reality can be nothing more than some mode of consciousness;
-and that the question to be considered is—What is the relation
-between this mode and other modes?</p>
-
-<p class='c000'>By reality we mean <em>persistence</em> in consciousness: a persistence
-that is either unconditional, as our consciousness of
-space, or that is conditional, as our consciousness of a body
-while grasping it. The real, as we conceive it, is distinguished
-solely by the test of persistence; for by this test we separate
-it from what we call the unreal. Between a person standing
-before us, and the idea of such a person, we discriminate by
-our ability to expel the idea from consciousness, and our inability,
-while looking at him, to expel the person from consciousness.
-And when in doubt as to the validity or illusiveness
-of some impression made upon us in the dusk, we settle
-the matter by observing whether the impression persists on
-closer observation; and we predicate reality if the persistence
-is complete. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;How truly persistence is what we mean
-by reality, is shown in the fact that when, after criticism has
-proved that the real as we are conscious of it is not the objectively
-real, the indefinite notion which we form of the objectively
-real, is of something which persists absolutely, under
-all changes of mode, form, or appearance. And the fact that
-we cannot form even an indefinite notion of the absolutely
-real, except as the absolutely persistent, clearly implies that
-<span class='pageno' id='Page_227'>227</span>persistence is our ultimate test of the real as present to consciousness.</p>
-
-<p class='c000'>Reality then, as we think it, being nothing more than persistence
-in consciousness, the result must be the same to us
-whether that which we perceive be the Unconditioned itself,
-or an effect invariably wrought on us by the Unconditioned.
-If some mode of the Unconditioned uniformly produces some
-mode of consciousness—if the mode of consciousness so produced,
-is as persistent as would be such mode of the Unconditioned
-were it immediately known; it follows that the
-reality will be to our consciousness as complete in the one case
-as in the other. Were the Unconditioned itself present in
-thought, it could but be persistent; and if instead of it, there
-is present its persistent effect, the resulting consciousness of
-reality must be exactly the same.</p>
-
-<p class='c000'>Hence there may be drawn these conclusions:—First, that
-we have an indefinite consciousness of an absolute reality
-transcending relations, which is produced by the absolute
-persistence in us of something which survives all changes of
-relation. Second, that we have a definite consciousness of
-relative reality, which unceasingly persists in us under one
-or other of its forms, and under each form so long as the conditions
-of presentation are fulfilled; and that the relative
-reality, being thus continuously persistent in us, is as real to
-us as would be the absolute reality could it be immediately
-known. Third, that thought being possible only under relation,
-the relative reality can be conceived as such only in connexion
-with an absolute reality; and the connexion between
-the two being absolutely persistent in our consciousness, is
-real in the same sense as the terms it unites are real.</p>
-
-<p class='c000'>Thus then we may resume, with entire confidence, those
-realistic conceptions which philosophy at first sight seems to
-dissipate. Though reality under the forms of our consciousness,
-is but a conditioned effect of the absolute reality, yet
-this conditioned effect standing in indissoluble relation with
-its unconditioned cause, and being equally persistent with it
-<span class='pageno' id='Page_228'>228</span>so long as the conditions persist, is, to the consciousness supplying
-those conditions, equally real. The persistent impressions
-being the persistent results of a persistent cause, are for
-practical purposes the same to us as the cause itself; and may
-be habitually dealt with as its equivalents. Somewhat in the
-same way that our visual perceptions, though merely symbols
-found to be the equivalents of tactual perceptions, are yet so
-identified with those tactual perceptions that we actually appear
-to see the solidity and hardness which we do but infer,
-and thus conceive as objects what are only the signs of objects;
-so, on a higher stage, do we deal with these relative realities
-as though they were absolutes instead of effects of the absolute.
-And we may legitimately continue so to deal with them
-as long as the conclusions to which they help us are understood
-as relative realities and not absolute ones.</p>
-
-<p class='c000'>This general conclusion it now remains to interpret specifically,
-in its application to each of our ultimate scientific
-ideas.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 62.<a id='r11' /><a href='#f11' class='c011'><sup>[11]</sup></a> We think in relations. This is truly the form of
-all thought; and if there are any other forms, they must be
-derived from this. We have seen (Chap. iii. Part I.) that
-the several ultimate modes of being cannot be known or conceived
-as they exist in themselves; that is, out of <em>relation</em> to
-our consciousness. We have seen, by analyzing the product
-of thought, (§ 23,) that it always consists of <em>relations</em>;
-and cannot include anything beyond the most general of these.
-On analyzing the process of thought, we found that cognition
-of the Absolute was impossible, because it presented
-neither <em>relation</em>, nor its elements—difference and likeness.
-Further, we found that not only Intelligence but Life itself,
-consists in the establishment of internal <em>relations</em> in correspondence
-with external relations. And lastly, it was shown
-<span class='pageno' id='Page_229'>229</span>that though by the relativity of our thought we are eternally
-debarred from knowing or conceiving Absolute Being; yet
-that this very <em>relativity</em> of our thought, necessitates that vague
-consciousness of Absolute Being which no mental effort can
-suppress. That <em>relation</em> is the universal form of thought, is
-thus a truth which all kinds of demonstration unite in
-proving.</p>
-
-<p class='c000'>By the transcendentalists, certain other phenomena of consciousness
-are regarded as forms of thought. Presuming
-that relation would be admitted by them to be a universal
-mental form, they would class with it two others as also universal.
-Were their hypothesis otherwise tenable however, it
-must still be rejected if such alleged further forms are interpretable
-as generated by the primary form. If we think in
-relations, and if relations have certain universal forms, it is
-manifest that such universal forms of relations will become
-universal forms of our consciousness. And if these further
-universal forms are thus explicable, it is superfluous, and
-therefore unphilosophical, to assign them an independent
-origin. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Now relations are of two orders—relations
-of sequence, and relations of co-existence; of which the one
-is original and the other derivative. The relation of sequence
-is given in every change of consciousness. The relation of
-co-existence, which cannot be originally given in a consciousness
-of which the states are serial, becomes distinguished only
-when it is found that certain relations of sequence have their
-terms presented in consciousness in either order with equal
-facility; while the others are presented only in one order.
-Relations of which the terms are not reversible, become recognized
-as sequences proper; while relations of which the
-terms occur indifferently in both directions, become recognized
-as co-existences. Endless experiences, which from
-moment to moment present both orders of these relations,
-render the distinction between them perfectly definite;
-and at the same time generate an abstract conception of
-each. The abstract of all sequences is Time. The abstract
-<span class='pageno' id='Page_230'>230</span>of all co-existences is Space. From the fact that in thought,
-Time is inseparable from sequence, and Space from co-existence,
-we do not here infer that Time and Space are original
-conditions of consciousness under which sequences and co-existences
-are known; but we infer that our conceptions of
-Time and Space are generated, as other abstracts are generated
-from other concretes: the only difference being, that
-the organization of experiences has, in these cases, been going
-on throughout the entire evolution of intelligence.</p>
-
-<p class='c000'>This synthesis is confirmed by analysis. Our consciousness
-of Space is a consciousness of co-existent positions. Any limited
-portion of space can be conceived only by representing its
-limits as co-existing in certain relative positions; and each of
-its imagined boundaries, be it line or plane, can be thought of
-in no other way than as made up of co-existent positions in
-close proximity. And since a position is not an entity—since
-the congeries of positions which constitute any conceived portion
-of space, and mark its bounds, are not sensible existences;
-it follows that the co-existent positions which make up our
-consciousness of Space, are not co-existences in the full sense
-of the word (which implies realities as their terms), but are the
-blank forms of co-existences, left behind when the realities are
-absent; that is, are the abstracts of co-existences. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The
-experiences out of which, during the evolution of intelligence,
-this abstract of all co-existences has been generated,
-are experiences of individual positions as ascertained by touch;
-and each of such experiences involves the resistance of an object
-touched, and the muscular tension which measures this
-resistance. By countless unlike muscular adjustments, involving
-unlike muscular tensions, different resisting positions are disclosed;
-and these, as they can be experienced in one order as
-readily as another, we regard as co-existing. But since, under
-other circumstances, the same muscular adjustments do
-not produce contact with resisting positions, there result the
-same states of consciousness, minus the resistances—blank
-forms of co-existence from which the co-existent objects before
-<span class='pageno' id='Page_231'>231</span>experienced are absent. And from a building up of these, too
-elaborate to be here detailed, results that abstract of all relations
-of co-existence which we call Space. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;It remains
-only to point out, as a thing which we must not forget, that
-the experiences from which the consciousness of Space arises,
-are experiences of <em>force</em>. A certain correlation of the muscular
-forces we ourselves exercise, is the index of each position
-as originally disclosed to us; and the resistance which makes
-us aware of something existing in that position, is an equivalent
-of the pressure we consciously exert. Thus, experiences
-of forces variously correlated, are those from which our consciousness
-of Space is abstracted.</p>
-
-<p class='c000'>That which we know as Space being thus shown, alike by
-its genesis and definition, to be purely relative, what are we
-to say of that which causes it? Is there an absolute Space
-which relative Space in some sort represents? Is Space in itself
-a form or condition of absolute existence, producing in
-our minds a corresponding form or condition of relative existence?
-These are unanswerable questions. Our conception
-of Space is produced by some mode of the Unknowable; and
-the complete unchangeableness of our conception of it simply
-implies a complete uniformity in the effects wrought by this
-mode of the Unknowable upon us. But therefore to call it a
-necessary mode of the Unknowable, is illegitimate. All we
-can assert is, that Space is a relative reality; that our consciousness
-of this unchanging relative reality implies an absolute
-reality equally unchanging in so far as we are concerned;
-and that the relative reality may be unhesitatingly accepted
-in thought as a valid basis for our reasonings; which, when
-rightly carried on, will bring us to truths that have a like
-relative reality—the only truths which concern us or can
-possibly be known to us.</p>
-
-<p class='c000'>Concerning Time, relative and absolute, a parallel argument
-leads to parallel conclusions. These are too obvious to
-need specifying in detail.</p>
-
-<hr class='c013' />
-
-<p class='c000'><span class='pageno' id='Page_232'>232</span>§ 63. Our conception of Matter, reduced to its simplest shape,
-is that of co-existent positions that offer resistance; as contrasted
-with our conception of Space, in which the co-existent
-positions offer no resistance. We think of Body as bounded
-by surfaces that resist; and as made up throughout of parts
-that resist. Mentally abstract the co-existent resistances, and
-the consciousness of Body disappears; leaving behind it the
-consciousness of Space. And since the group of co-existing
-resistent positions constituting a portion of matter, is uniformly
-capable of giving us impressions of resistance in combination
-with various muscular adjustments, according as we
-touch its near, its remote, its right, or its left side; it results
-that as different muscular adjustments habitually indicate different
-co-existences, we are obliged to conceive every portion
-of matter as containing more than one resistent position—that
-is, as occupying Space. Hence the necessity we are under of
-representing to ourselves the ultimate elements of Matter as
-being at once extended and resistent: this being the universal
-form of our sensible experiences of Matter, becomes the
-form which our conception of it cannot transcend, however
-minute the fragments which imaginary subdivisions produce.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Of these two inseparable elements, the resistance
-is primary, and the extension secondary. Occupied extension,
-or Body, being distinguished in consciousness from
-unoccupied extension, or Space, by its resistance, this attribute
-must clearly have precedence in the genesis of the idea. Such a
-conclusion is, indeed, an obvious corollary from that at which
-we arrived in the foregoing section. If, as was there contended,
-our consciousness of Space is a product of accumulated experiences,
-partly our own but chiefly ancestral—if, as was
-pointed out, the experiences from which our consciousness of
-Space is abstracted, can be received only through impressions
-of resistance made upon the organism; the necessary inference
-is, that experiences of resistance being those from which the
-conception of Space is generated, the resistance-attribute of
-Matter must be regarded as primordial and the space-attribute
-<span class='pageno' id='Page_233'>233</span>as derivative. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Whence it becomes manifest that our
-experience of <em>force</em>, is that out of which the idea of Matter is
-built. Matter as opposing our muscular energies, being immediately
-present to consciousness in terms of force; and its
-occupancy of Space being known by an abstract of experiences
-originally given in terms of force; it follows that forces,
-standing in certain correlations, form the whole content of
-our idea of Matter.</p>
-
-<p class='c000'>Such being our cognition of the relative reality, what are
-we to say of the absolute reality? We can only say that it
-is some mode of the Unknowable, related to the Matter we
-know, as cause to effect. The relativity of our cognition of
-Matter is shown alike by the above analysis, and by the contradictions
-which are evolved when we deal with the cognition
-as an absolute one (§ 16). But, as we have lately seen,
-though known to us only under relation, Matter is as real in
-the true sense of that word, as it would be could we know it
-out of relation; and further, the relative reality which we
-know as Matter, is necessarily represented to the mind as
-standing in a persistent or real relation to the absolute reality.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;We may therefore deliver ourselves over without
-hesitation, to those terms of thought which experience has
-organized in us. We need not in our physical, chemical,
-or other researches, refrain from dealing with Matter as made
-up of extended and resistent atoms; for this conception, necessarily
-resulting from our experiences of Matter, is not less
-legitimate, than the conception of aggregate masses as extended
-and resistent. The atomic hypothesis, as well as the kindred
-hypothesis of an all-pervading ether consisting of molecules, is
-simply a necessary development of those universal forms which
-the actions of the Unknowable have wrought in us. The conclusions
-logically worked out by the aid of these hypotheses, are
-sure to be in harmony with all others which these same forms
-involve, and will have a relative truth that is equally complete.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 64. The conception of Motion as presented or represented
-<span class='pageno' id='Page_234'>234</span>in the developed consciousness, involves the conceptions of
-Space, of Time, and of Matter. A something that moves; a
-series of positions occupied in succession; and a group of co-existent
-positions united in thought with the successive ones—these
-are the constituents of the idea. And since, as we
-have seen, these are severally elaborated from experiences of
-<em>force</em> as given in certain correlations, it follows that from a
-further synthesis of such experiences, the idea of Motion is
-also elaborated. A certain other element in the idea, which
-is in truth its fundamental element, (namely, the necessity
-which the moving body is under to go on changing its position),
-results immediately from the earliest experiences of force.
-Movements of different parts of the organism in relation to
-each other, are the first presented in consciousness. These,
-produced by the action of the muscles, necessitate reactions
-upon consciousness in the shape of sensations of muscular tension.
-Consequently, each stretching-out or drawing-in of a
-limb, is originally known as a series of muscular tensions,
-varying in intensity as the position of the limb changes. And
-this rudimentary consciousness of Motion, consisting of serial
-impressions of force, becomes inseparably united with the
-consciousness of Space and Time as fast as these are abstracted
-from further impressions of force. Or rather, out of this
-primitive conception of Motion, the adult conception of it is
-developed simultaneously with the development of the conceptions
-of Space and Time: all three being evolved from the
-more multiplied and varied impressions of muscular tension
-and objective resistance. Motion, as we know it, is thus traceable,
-in common with the other ultimate scientific ideas, to experiences
-of force.</p>
-
-<p class='c000'>That this relative reality answers to some absolute reality,
-it is needful only for form’s sake to assert. What has been
-said above, respecting the Unknown Cause which produces in
-us the effects called Matter, Space, and Time, will apply, on
-simply changing the terms, to Motion.</p>
-
-<hr class='c013' />
-
-<p class='c000'><span class='pageno' id='Page_235'>235</span>§ 65. We come down then finally to Force, as the ultimate
-of ultimates. Though Space, Time, Matter, and Motion, are
-apparently all necessary data of intelligence, yet a psychological
-analysis (here indicated only in rude outline) shows us
-that these are either built up of, or abstracted from, experiences
-of Force. Matter and Motion, as we know them, are
-differently conditioned manifestations of Force. Space and
-Time, as we know them, are disclosed along with these different
-manifestations of Force as the conditions under which
-they are presented. Matter and Motion are concretes built
-up from the <em>contents</em> of various mental relations; while Space
-and Time are abstracts of the <em>forms</em> of these various relations.
-Deeper down than these, however, are the primordial
-experiences of Force, which, as occurring in consciousness
-in different combinations, supply at once the materials
-whence the forms of relations are generalized, and the related
-objects built up. A single impression of force is
-manifestly receivable by a sentient being devoid of mental
-forms: grant but sensibility, with no established power of
-thought, and a force producing some nervous change, will
-still be presentable at the supposed seat of sensation. Though
-no single impression of force so received, could itself produce
-consciousness (which implies relations between different states),
-yet a multiplication of such impressions, differing in kind
-and degree, would give the materials for the establishment
-of relations, that is, of thought. And if such relations
-differed in their forms as well as in their contents,
-the impressions of such forms would be organized simultaneously
-with the impressions they contained. Thus all other
-modes of consciousness are derivable from experiences of
-Force; but experiences of Force are not derivable from anything
-else. Indeed, it needs but to remember that consciousness
-consists of changes, to see that the ultimate datum of consciousness
-must be that of which change is the manifestation;
-and that thus the force by which we ourselves produce changes,
-<span class='pageno' id='Page_236'>236</span>and which serves to symbolize the cause of changes in general,
-is the final disclosure of analysis.</p>
-
-<p class='c000'>It is a truism to say that the nature of this undecomposable
-element of our knowledge is inscrutable. If, to use an algebraic
-illustration, we represent Matter, Motion, and Force, by the
-symbols <em>x</em>, <em>y</em>, and <em>z</em>; then, we may ascertain the values of <em>x</em>
-and <em>y</em> in terms of <em>z</em>; but the value of <em>z</em> can never be found: <em>z</em>
-is the unknown quantity which must for ever remain unknown;
-for the obvious reason that there is nothing in which its value
-can be expressed. It is within the possible reach of our intelligence
-to go on simplifying the equations of all phenomena,
-until the complex symbols which formulate them are reduced
-to certain functions of this ultimate symbol; but when we
-have done this, we have reached that limit which eternally
-divides science from nescience.</p>
-
-<p class='c000'>That this undecomposable mode of consciousness into
-which all other modes may be decomposed, cannot be itself
-the Power manifested to us through phenomena, has been
-already proved (§ 18). We saw that to assume an identity
-of nature between the cause of changes as it absolutely exists,
-and that cause of change of which we are conscious in our own
-muscular efforts, betrays us into alternative impossibilities of
-thought. Force, as we know it, can be regarded only as a
-certain conditioned effect of the Unconditioned Cause—as the
-relative reality indicating to us an Absolute Reality by which
-it is immediately produced. And here, indeed, we see even
-more clearly than before, how inevitable is that transfigured
-realism to which sceptical criticism finally brings us round.
-Getting rid of all complications, and contemplating pure
-Force, we are irresistibly compelled by the relativity of our
-thought, to vaguely conceive some unknown force as the
-correlative of the known force. Conditioned effect and unconditioned
-cause, are here presented in their primordial relation
-as two sides of the same change; of which we are obliged
-to regard the conditioned and the unconditioned sides as
-equally real: the only difference being that the reality of
-<span class='pageno' id='Page_237'>237</span>the one is made relative by the imposition of the forms and
-limits of our consciousness, while the reality of the other,
-in the absence of those forms and limits, remains absolute.</p>
-
-<p class='c000'>Thus much respecting the nature of our ultimate scientific
-ideas. Before proceeding to our general inquiry concerning
-the causes of Evolution, we have still to consider certain
-ultimate scientific truths.</p>
-
-<hr class='c015' />
-
-<div class='footnote' id='f11'>
-<p class='c000'><span class='label'><a href='#r11'>11</a>.&nbsp;&nbsp;</span>For the psychological conclusions briefly set forth in this and the three sections
-following it, the justification will be found in the writer’s <cite>Principles of
-Psychology</cite>.</p>
-</div>
-
-<div>
- <span class='pageno' id='Page_238'>238</span>
- <h3 class='c001'>CHAPTER VI.<br /> <span class='large'>THE INDESTRUCTIBILITY OF MATTER.</span></h3>
-</div>
-
-<p class='c006'>§ 66. Not because the truth is unfamiliar, is it needful here
-to say something concerning the indestructibility of Matter;
-but partly because the symmetry of our argument demands the
-enunciation of this truth, and partly because the evidence on
-which it is accepted requires examination. Could it be shown,
-or could it with any rationality be even supposed, that Matter,
-either in its aggregates or in its units, ever became non-existent,
-there would be an end to the inquiry on which we are
-now setting out. Evolution, considered as a re-arrangement
-of parts, could not be scientifically explained, if, during its
-course, any of the parts might arise out of nothing or might
-lapse into nothing. The question would no longer be one
-comprehending only the forces and motions by which the
-re-arrangement is effected; but would involve an incalculable
-element, and would hence be insoluble. Clearly, therefore,
-the indestructibility of Matter is an indispensable axiom.</p>
-
-<p class='c000'>So far from being admitted as a self-evident truth, this
-would, in primitive times, have been rejected as a self-evident
-error. There was once universally current, a notion that things
-could vanish into absolute nothing, or arise out of absolute
-nothing. If we analyze early superstitions, or that faith in
-magic which was general in later times and even still survives
-among the uncultured, we find one of its postulates to
-be, that by some potent spell Matter can be called out of nonentity,
-and can be made non-existent. If men did not believe
-<span class='pageno' id='Page_239'>239</span>this in the strict sense of the word (which would imply
-that the process of creation or annihilation was clearly represented
-in consciousness), they still believed that they believed
-it; and how nearly, in their confused thoughts, the one was
-equivalent to the other, is shown by their conduct. Nor, indeed,
-have dark ages and inferior minds alone betrayed this
-belief. The current theology, in its teachings respecting the
-beginning and end of the world, is clearly pervaded by it;
-and it may be even questioned whether Shakespeare, in his
-poetical anticipation of a time when all things should disappear
-and “leave not a wrack behind,” was not under its influence.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The gradual accumulation of experiences
-however, and still more the organization of experiences, has
-tended slowly to reverse this conviction; until now, the doctrine
-that Matter is indestructible has become a common-place.
-Whatever may be true of it absolutely, we have learnt that
-relatively to our consciousness, Matter never either comes into
-existence or ceases to exist. Cases which once gave an
-apparent support to the illusion that something could come out
-of nothing, a wider knowledge has one by one cancelled. The
-comet that is all at once discovered in the heavens and nightly
-waxes larger, is proved not to be a newly-created body, but a
-body that was until lately beyond the range of vision. The
-cloud which in the course of a few minutes forms in the sky, consists
-not of substance that has just begun to be, but of substance
-that previously existed in a more diffused and transparent form.
-And similarly with a crystal or precipitate in relation to
-the fluid depositing it. Conversely, the seeming annihilations
-of Matter turn out, on closer observation, to be only changes
-of state. It is found that the evaporated water, though it has
-become invisible, may be brought by condensation to its original
-shape. The discharged fowling-piece gives evidence
-that though the gunpowder has disappeared, there have appeared
-in place of it certain gases, which, in assuming a
-larger volume, have caused the explosion. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Not, however,
-until the rise of quantitative chemistry, could the conclusion
-<span class='pageno' id='Page_240'>240</span>suggested by such experiences be reduced to a certainty.
-When, having ascertained not only the combinations into
-which various substances enter, but also the proportions in
-which they combine, chemists were enabled to account for
-the matter that had made its appearance or become invisible,
-the proof was rendered complete. When, in place of the candle
-that had slowly burnt away, it was shown that certain calculable
-quantities of carbonic acid and water had resulted—when
-it was demonstrated that the joint weight of the carbonic
-acid and water thus produced, was equal to the weight
-of the candle plus that of the oxygen uniting with its constituents
-during combustion; it was put beyond doubt that
-the carbon and hydrogen forming the candle, were still in existence,
-and had simply changed their state. And of the
-general conclusion thus exemplified, the exact analyses daily
-made, in which the same portion of matter is pursued through
-numerous transformations and finally separated, furnish
-never-ceasing confirmations.</p>
-
-<p class='c000'>Such has become the effect of this specific evidence, joined
-to that general evidence which the continued existence of
-familiar objects unceasingly gives us; that the indestructibility
-of Matter is now recognized by many as a truth of which the
-negation is inconceivable. Habitual experiences being no
-longer met by any counter-experiences, as they once seemed
-to be; but these apparent counter-experiences furnishing new
-proof that Matter exists permanently, even where the senses fail
-to detect it; it has grown into an axiom of science, that whatever
-metamorphoses Matter undergoes, its quantity is fixed.
-The chemist, the physicist, and the physiologist, not only
-one and all take this for granted, but would severally profess
-themselves unable to realize any supposition to the
-contrary.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 67. This last fact naturally raises the question, whether
-we have any higher warrant for this fundamental belief, than
-the warrant of conscious induction. The indestructibility of
-<span class='pageno' id='Page_241'>241</span>Matter is proved experimentally to be an absolute uniformity
-within the range of our experience. But absolute uniformities
-of experience, generate absolute uniformities of thought.
-Does it not follow, then, that this ultimate truth must be a
-cognition involved in our mental organization? An affirmative
-answer we shall find unavoidable.</p>
-
-<p class='c000'>What is termed the ultimate incompressibility of Matter,
-is an admitted law of thought. Though it is possible to imagine
-a piece of matter to be compressed without limit, yet however
-small the bulk to which we conceive it reduced, it is impossible
-to conceive it reduced into nothing. While we can
-represent to ourselves the parts of the matter as indefinitely
-approximated, and the space occupied as indefinitely decreased,
-we cannot represent to ourselves the quantity of matter as
-made less. To do this would imply an imagined disappearance
-of some of the constituent parts—would imply that
-some of the constituent parts were in thought compressed
-into nothing; which is no more possible than the compression
-of the whole into nothing. Whence it is an obvious corollary,
-that the total quantity of matter in the Universe, cannot
-really be conceived as diminished, any more than it can be
-conceived as increased. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Our inability to conceive
-Matter becoming non-existent, is immediately consequent on
-the very nature of thought. Thought consists in the establishment
-of relations. There can be no relation established, and
-therefore no thought framed, when one of the related terms
-is absent from consciousness. Hence it is impossible to think
-of something becoming nothing, for the same reason that it is
-impossible to think of nothing becoming something—the
-reason, namely, that nothing cannot become an object of consciousness.
-The annihilation of Matter is unthinkable for
-the same reason that the creation of Matter is unthinkable;
-and its indestructibility thus becomes an <i><span lang="fr" xml:lang="fr">à priori</span></i> cognition of
-the highest order—not one that results from a long continued
-registry of experiences gradually organized into an irreversible
-<span class='pageno' id='Page_242'>242</span>mode of thought; but one that is given in the form of all
-experiences whatever.</p>
-
-<p class='c000'>Doubtless it will be considered strange that a truth only
-in modern times accepted as unquestionable, and then only
-by men of science, should be classed as an <i><span lang="fr" xml:lang="fr">à priori</span></i> truth; not
-only of equal certainty with those commonly so classed, but
-of even higher certainty. To set down as a proposition which
-cannot be thought, one which mankind once universally professed
-to think, and which the great majority profess to think
-even now, seems absurd. The explanation is, that in this, as
-in countless other cases, men have supposed themselves to
-think what they did not think. As was shown at the outset,
-the greater part of our conceptions are symbolic. Many of
-these symbolic conceptions, though rarely developed into real
-ones, admit of being so developed; and, being directly or indirectly
-proved to correspond with actualities, are valid. But
-along with these there pass current others which cannot be
-developed—cannot by any direct or indirect process be realized
-in thought; much less proved to correspond with actualities.
-Not being habitually tested, however, the legitimate and
-illegitimate symbolic conceptions are confounded together;
-and supposing themselves to have literally thought, that
-which they have thought only symbolically, men say they believe
-propositions of which the terms cannot even be put together
-in consciousness. Hence the ready acceptance given
-to sundry hypotheses respecting the origin of the Universe,
-which yet are absolutely unthinkable. And as before we
-found the commonly asserted doctrine that Matter was created
-out of nothing, to have been never really conceived at all,
-but to have been conceived only symbolically; so here we
-find the annihilation of Matter to have been conceived only
-symbolically, and the symbolic conception mistaken for a real
-one. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Possibly it will be objected that the words
-<em>thought</em>, and <em>belief</em>, and <em>conception</em>, are here employed in
-new senses; and that it is a misuse of language to say that
-<span class='pageno' id='Page_243'>243</span>men did not really think that which has nevertheless so profoundly
-influenced their conduct. It must be confessed that
-there is an inconvenience in so restricting the meanings of
-these words. There is no remedy however. Definite conclusions
-can be reached, only by the use of well-defined terms.
-Questions touching the validity of any portion of our knowledge,
-cannot be profitably discussed unless the words <em>knowing</em>,
-and <em>thinking</em>, have specific interpretations. We must
-not include under them whatever confused processes of consciousness
-the popular speech applies them to; but only the
-distinct processes of consciousness. And if this obliges us to
-reject a large part of human thinking as not thinking at all,
-but merely pseudo-thinking, there is no help for it.</p>
-
-<p class='c000'>Returning to the general question, we find the results to
-be:—that we have positive experience of the continued existence
-of Matter; that the form of our thought renders it impossible
-for us to have experience of Matter passing into non-existence,
-since such experience would involve cognition of a
-relation having one of its terms not representable in consciousness;
-that hence the indestructibility of Matter is in strictness
-an <i><span lang="fr" xml:lang="fr">à priori</span></i> truth; that nevertheless, certain illusive experiences,
-suggesting the notion of its annihilation, have produced in
-undisciplined minds not only the supposition that Matter
-could be conceived to become non-existent, but the notion that
-it did so; but that careful observation, showing the supposed
-annihilations to have never taken place, has confirmed, <i><span lang="fr" xml:lang="fr">à
-posteriori</span></i>, the <i><span lang="fr" xml:lang="fr">à priori</span></i> cognition which Psychology shows to
-result from a uniformity of experience that can never be met
-by counter-experience.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 68. The fact, however, which it most concerns us here
-to observe, is, the nature of the perceptions by which the permanence
-of Matter is perpetually illustrated to us, and from
-which Science draws the inference that Matter is indestructible.
-These perceptions, under all their forms, amount simply
-to this—that the <em>force</em> which a given quantity of matter exercises,
-<span class='pageno' id='Page_244'>244</span>remains always the same. This is the proof on which
-common sense and exact science alike rely. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;When,
-for example, somebody known to have existed a few years since
-is said to exist still, by one who yesterday saw him, his assertion
-amounts to this—that an object which in past time
-wrought on his consciousness a certain group of changes, still
-exists because a like group of changes has been again wrought
-on his consciousness: the continuance of the power thus to
-impress him, he holds to prove the continuance of the object.
-Should some auditor allege a mistake in identity, the witness
-is admitted to give conclusive proof when he says that he not
-only saw, but shook hands with this person, and remarked
-while grasping his hand, that absence of the index finger
-which was his known peculiarity: the implication being, that
-an object which through a special combination of forces, produces
-special tactual impressions, is concluded still to exist
-while it continues still to do this. Even more clearly do we
-see that force is our ultimate measure of Matter, in those cases
-where the shape of the matter has been changed. A piece of
-gold given to an artizan to be worked into an ornament, and
-which when brought back appears to be less, is placed in the
-scales; and if it balances a much smaller weight than it did
-in its rough state, we infer that much has been lost
-either in manipulation or by direct abstraction. Here the
-obvious postulate is, that the quantity of Matter is finally
-determinable by the quantity of gravitative force it manifests.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;And this is the kind of evidence on which
-Science bases its experimentally-established induction that
-Matter is indestructible. Whenever a piece of substance lately
-visible and tangible, has been reduced to an invisible, intangible
-shape, but is proved by the weight of the gas into which
-it has been transformed to be still existing; the assumption is,
-that though otherwise insensible to us, the amount of matter
-is the same, if it still tends towards the Earth with the same
-force. Similarly, every case in which the weight of an element
-present in combination, is inferred from the known
-<span class='pageno' id='Page_245'>245</span>weight of another element which it neutralizes, is a case in
-which the quantity of matter is expressed in terms of the
-quantity of chemical force it exerts; and in which this specific
-chemical force is assumed to be the necessary correlative of
-a specific gravitative force.</p>
-
-<p class='c000'>Thus then by the indestructibility of Matter, we really mean
-the indestructibility of the <em>force</em> with which Matter affects us.
-As we become conscious of Matter only through that resistance
-which it opposes to our muscular energy, so do we become
-conscious of the permanence of Matter only through the permanence
-of this resistance; as either immediately or mediately
-proved to us. And this truth is made manifest not only by
-analysis of the <i><span lang="fr" xml:lang="fr">à posteriori</span></i> cognition, but equally so by analysis
-of the <i><span lang="fr" xml:lang="fr">à priori</span></i> one. For that which we cannot conceive to be
-diminished by the continued compression of Matter, is not its
-occupancy of space, but its ability to resist.</p>
-
-<div>
- <span class='pageno' id='Page_246'>246</span>
- <h3 class='c001'>CHAPTER VII.<br /> <span class='large'>THE CONTINUITY OF MOTION.</span></h3>
-</div>
-
-<p class='c006'>§ 69. Another general truth of the same order with the
-foregoing, must here be specified—one which, though not so
-generally recognized, has yet long been familiar among men
-of science. The continuity of Motion, like the indestructibility
-of Matter, is clearly an axiom underlying the very
-possibility of a rational theory of Evolution. That kind of
-change in the arrangement of parts, which we have found to
-constitute Evolution, could not be deductively explained
-were it possible for Motion either to appear or disappear. If
-those motions through which the parts pass into a new
-arrangement, might either proceed from nothing or lapse
-into nothing, there would be an end to scientific interpretation
-of them. Each constituent change might as well as not
-be supposed to begin and end of itself.</p>
-
-<p class='c000'>The axiomatic character of the truth that Motion is continuous,
-is recognized only after the discipline of exact
-science has given precision to the conceptions. Aboriginal
-men, our uneducated population, and even most of the so-called
-educated, think in an extremely indefinite manner.
-From careless observations, they pass by careless reasoning,
-to conclusions of which they do not contemplate the implications—conclusions
-which they never develope for the purpose
-of seeing whether they are consistent. Accepting without
-criticism the dicta of unaided perception, to the effect that
-surrounding bodies when put in motion soon return to rest,
-<span class='pageno' id='Page_247'>247</span>the great majority tacitly assume that the motion is actually
-lost. They do not consider whether the phenomenon can be
-otherwise interpreted; or whether the interpretation they
-put on it can be mentally realized. They are content with a
-colligation of mere appearances. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;But the establishment
-of certain facts having quite an opposite implication,
-led to inquiries which have gradually proved such appearances
-to be illusive. The discovery that the planets revolve
-round the Sun with undiminishing speed, raised the suspicion
-that a moving body, when not interfered with, will go on for
-ever without change of velocity; and suggested the question
-whether bodies which lose their motion, do not at the same
-time communicate as much motion to other bodies. It was a
-familiar fact that a stone would glide further over a smooth
-surface, such as ice, presenting no small objects to which it
-could part with its motion by collision, than over a surface
-strewn with such small objects; and that a projectile would
-travel a far greater distance through a rare medium like air,
-than through a dense medium like water. Thus the primitive
-notion that moving bodies had an inherent tendency gradually
-to lose their motion and finally stop—a notion of which
-the Greeks did not get rid, but which lasted till the time of
-Galileo—began to give way. It was further shaken by such
-experiments as those of Hooke, which proved that the spinning
-of a top continued long in proportion as it was prevented
-from communicating movement to surrounding matter—experiments
-which, when repeated with the aid of modern appliances,
-have shown that <i><span lang="la" xml:lang="la">in vacuo</span></i> such rotation, retarded
-only by the friction of the axis, will continue for nearly an
-hour. Thus have been gradually dispersed, the obstacles to
-the reception of the first law of motion;—the law, namely,
-that when not influenced by external forces, a moving body
-will go on in a straight line with a uniform velocity. And
-this law is in our day being merged in the more general one,
-that Motion, like Matter, is indestructible; and that whatever
-is lost by any one portion of matter is transferred to
-<span class='pageno' id='Page_248'>248</span>other portions—a conclusion which, however much at variance
-it seems with cases of sudden arrest from collision with
-an immovable object, is yet reconciled with such cases by the
-discovery that the motion apparently lost continues under
-new forms, though forms not directly perceptible.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 70. And here it may be remarked of Motion, as it was
-before of Matter, that its indestructibility is not only to be
-inductively inferred, but that it is a necessity of thought: its
-destructibility never having been truly conceived at all, but
-having always been, as it is now, a mere verbal proposition
-that cannot be realized in consciousness—a pseud-idea.
-Whether that absolute reality which produces in us the consciousness
-we call Motion, be or be not an eternal mode of
-the Unknowable, it is impossible for us to say; but that the
-relative reality which we call Motion never can come into
-existence, or cease to exist, is a truth involved in the very
-nature of our consciousness. To think of Motion as either
-being created or annihilated—to think of nothing becoming
-something, or something becoming nothing—is to establish
-in consciousness a relation between two terms of which one
-is absent from consciousness, which is impossible. The very
-nature of intelligence, negatives the supposition that Motion
-can be conceived (much less known) to either commence or
-cease.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 71. It remains to be pointed out that the continuity of
-Motion, as well as the indestructibility of Matter, is really
-known to us in terms of <em>force</em>. That a certain manifestation
-of force remains for ever undiminished, is the ultimate content
-of the thought; whether reached <i><span lang="fr" xml:lang="fr">à posteriori</span></i> or <i><span lang="fr" xml:lang="fr">à priori</span></i>.</p>
-
-<p class='c000'>From terrestrial physics let us take the case of sound propagated
-to a great distance. Whenever we are directly conscious
-of the causation of sound (namely, when we produce it
-ourselves), its invariable antecedent is force. The immediate
-sequence of this force we know to be motion—first, of our
-<span class='pageno' id='Page_249'>249</span>own organs, and then of the body which we set vibrating.
-The vibrations so generated we can discern both through the
-fingers and through the ears; and that the sensations received
-by the ears are the equivalents of mechanical force
-communicated to the air, and by it impressed on surrounding
-objects, we have clear proof when objects are fractured: as
-windows by the report of a cannon; or a glass vessel by a
-powerful voice. On what, then, rests the reasoning when, as
-occasionally happens under favourable circumstances, men
-on board a vessel a hundred miles from shore, hear the ringing
-of church-bells on placing their ears in the focus of the
-main sail; and when it is inferred that atmospheric undulations
-have traversed this immense distance? Manifestly, the
-assertion that the motion of the clapper, transformed into the
-vibrations of the bell, and communicated to the surrounding
-air, has propagated itself thus far on all sides, diminishing in
-intensity as the mass of air moved became greater, is based
-solely upon a certain change produced in consciousness
-through the ears. The listeners are not conscious of motion;
-they are conscious of an impression produced on them—an
-impression which implies a force as its necessary correlative.
-With force they begin, and with force they end: the intermediate
-motion being simply inferred. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Again, where,
-as in celestial physics, the continuity of motion is quantitatively
-proved, the proof is not direct but inferential; and forces
-furnish the data for the inference. A particular planet can
-be identified only by its constant power to affect our visual
-organs in a special way—to impress upon the retina a group
-of forces standing in a particular correlation. Further, such
-planet has not been <em>seen</em> to move by the astronomical observer;
-but its motion is <em>inferred</em> from a comparison of its present
-position with the position it before occupied. If rigorously
-examined, this comparison proves to be a comparison between
-the different impressions produced on him by the different adjustments
-of the observing instruments. Going a step further
-back, it turns out that this difference is meaningless until
-<span class='pageno' id='Page_250'>250</span>shown to correspond with a certain calculated position which
-the planet must occupy, supposing that no motion has been
-lost. And if, finally, we examine the implied calculation,
-we find that it makes allowances for those accelerations and
-retardations which ellipticity of the orbit involves, as well as
-those variations of velocity caused by adjacent planets—we
-find, that is, that the motion is concluded to be indestructible
-not from the uniform velocity of the planet, but from
-the constant quantity of motion exhibited when allowance is
-made for the motion communicated to, or received from, other
-celestial bodies. And when we ask how this communicated
-motion is estimated, we discover that the estimate is based
-upon certain laws of force; which laws, one and all, embody
-the postulate that force cannot be destroyed. Without the
-axiom that action and re-action are equal and opposite, astronomy
-could not make its exact predictions; and we should
-lack the rigorous inductive proof they furnish that motion
-can never be lost, but can only be transferred.</p>
-
-<p class='c000'>Similarly with the <i><span lang="fr" xml:lang="fr">à priori</span></i> conclusion that Motion is continuous.
-That which defies suppression in thought, is really
-the force which the motion indicates. The unceasing change
-of position, considered by itself, may be mentally abolished
-without difficulty. We can readily imagine retardation and
-stoppage to result from the action of external bodies. But
-to imagine this, is not possible without an abstraction of the
-force implied by the motion. We are obliged to conceive
-this force as impressed in the shape of re-action on the bodies
-that cause the arrest. And the motion that is communicated
-to them, we are compelled to regard, not as directly communicated,
-but as a product of the communicated force. We
-can mentally diminish the velocity or space-element of
-motion, by diffusing the momentum or force-element over
-a larger mass of matter; but the quantity of this force-element,
-which we regard as the cause of the motion, is unchangeable
-in thought.</p>
-
-<div>
- <span class='pageno' id='Page_251'>251</span>
- <h3 class='c001'>CHAPTER VIII.<br /> <span class='large'>THE PERSISTENCE OF FORCE.<a id='r12' /><a href='#f12' class='c011'><sup>[12]</sup></a></span></h3>
-</div>
-
-<p class='c006'>§ 72. Before taking a first step in the rational interpretation
-of Evolution, it is needful to recognize, not only the facts that
-Matter is indestructible and Motion continuous, but also the
-fact that Force persists. An attempt to assign the <em>causes</em> of
-Evolution, would manifestly be absurd, if that agency to which
-the metamorphosis in general and in detail is due, could either
-come into existence or cease to exist. The succession of phenomena
-would in such case be altogether arbitrary; and deductive
-science impossible.</p>
-
-<p class='c000'>Here, indeed, the necessity is even more imperative than in
-the two preceding cases. For the validity of the proofs given
-that Matter is indestructible and Motion continuous, really
-depends upon the validity of the proof that Force is persistent.
-An analysis of the reasoning demonstrated that in both cases,
-the <i><span lang="fr" xml:lang="fr">à posteriori</span></i> conclusion involves the assumption that unchanged
-quantities of Matter and Motion are proved by unchanged
-manifestations of Force; and in the <i><span lang="fr" xml:lang="fr">à priori</span></i> cognition
-<span class='pageno' id='Page_252'>252</span>we found this to be the essential constituent. Hence, that the
-quantity of Force remains always the same, is the fundamental
-cognition in the absence of which these derivative cognitions
-must disappear.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 73. But now on what grounds do we assert the persistence
-of Force? Inductively we can allege no evidence except such
-as is presented to us throughout the world of sensible phenomena.
-No force however, save that of which we are conscious
-during our own muscular efforts, is immediately known to us.
-All other force is mediately known through the changes we
-attribute to it. Since, then, we cannot infer the persistence
-of Force from our own sensation of it, which does not persist;
-we must infer it, if it is inferred at all, from the continuity of
-Motion, and the undiminished ability of Matter to produce certain
-effects. But to reason thus is manifestly to reason in a
-circle. It is absurd to allege the indestructibility of Matter,
-because we find experimentally that under whatever changes of
-form a given mass of matter exhibits the same gravitation, and
-then afterwards to argue that gravitation is constant because
-a given mass of matter exhibits always the same quantity of
-it. We cannot prove the continuity of Motion by assuming
-that Force is persistent, and then prove the persistence of Force
-by assuming that Motion is continuous.</p>
-
-<p class='c000'>The data of both objective and subjective science being involved
-in this question touching the nature of our cognition that
-Force is persistent, it will be desirable here to examine it more
-closely. At the risk of trying the reader’s patience, we must
-reconsider the reasoning through which the indestructibility of
-Matter and the continuity of Motion are established; that we
-may see how impossible it is to arrive by parallel reasoning at
-the persistence of Force. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;In all three cases the question
-is one of quantity:—does the Matter, or Motion, or Force,
-ever diminish in quantity? Quantitative science implies measurement;
-and measurement implies a unit of measure. The
-units of measure from which all others of any exactness are derived,
-<span class='pageno' id='Page_253'>253</span>are units of linear extension. From these, through the
-medium of the equal-armed lever or scales, we derive our equal
-units of weight, or gravitative force. And it is by means of these
-equal units of extension and equal units of weight, that we make
-those quantitative comparisons by which the truths of exact
-science are reached. Throughout the investigations leading
-the chemist to the conclusion that of the carbon which has disappeared
-during combustion, no portion has been lost, and that
-in any compound afterwards formed by the resulting carbonic
-acid the whole of the original carbon is present, what is his
-repeatedly assigned proof? That afforded by the scales. In
-what terms is the verdict of the scales given? In grains—in
-units of weight—in units of gravitative force. And what is
-the total content of the verdict? That as many units of gravitative
-force as the carbon exhibited at first, it exhibits still.
-The quantity of matter is asserted to be the same, if the number
-of units of force it counter-balances is the same. The validity
-of the inference, then, depends entirely upon <em>the constancy
-of the units of force</em>. If the force with which the portion
-of metal called a grain-weight, tends towards the Earth, has
-varied, the inference that Matter is indestructible is vicious.
-Everything turns on the truth of the assumption that the gravitation
-of the weights is persistent; and of this no proof is
-assigned, or can be assigned. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;In the reasonings of
-the astronomer there is a like implication; from which we
-may draw the like conclusion. No problem in celestial physics
-can be solved without the assumption of some unit of force.
-This unit need not be, like a pound or a ton, one of which we
-can take direct cognizance. It is requisite only that the mutual
-attraction which some two of the bodies concerned exercise
-at a given distance, should be taken as one; so that the
-other attractions with which the problem deals, may be expressed
-in terms of this one. Such unit being assumed, the
-momenta which the respective masses will generate in each
-other in a given time, are calculated; and compounding
-these with the momenta they already have, their places at the
-<span class='pageno' id='Page_254'>254</span>end of that time are predicted. The prediction is verified by
-observation. From this, either of two inferences may be drawn.
-Assuming the masses to be fixed, the motion may be proved
-to be undiminished; or assuming the motion to be undiminished,
-the masses may be proved to be fixed. But the validity of
-one or other inference, depends wholly on the truth of the assumption
-that the unit of force is unchanged. Let it be supposed
-that the gravitation of the two bodies towards each
-other at the given distance, has varied, and the conclusions
-drawn are no longer true. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Nor is it only in their
-concrete data that the reasonings of terrestrial and celestial
-physics assume the persistence of Force. They equally assume
-it in the abstract principle with which they set out; and which
-they repeat in justification of every step. The equality of action
-and reaction is taken for granted from beginning to end
-of either argument; and to assert that action and reaction
-are equal and opposite, is to assert that Force is persistent.
-The allegation really amounts to this, that there cannot be an
-isolated force beginning and ending in nothing; but that
-any force manifested, implies an equal antecedent force from
-which it is derived, and against which it is a reaction. Further,
-that the force so originating cannot disappear without result;
-but must expend itself in some other manifestation of force,
-which, in being produced, becomes its reaction; and so on
-continually. Clearly then the persistence of Force is an
-ultimate truth of which no inductive proof is possible.</p>
-
-<p class='c000'>We might indeed be certain, even in the absence of any
-such analysis as the foregoing, that there must exist some
-principle which, as being the basis of science, cannot be
-established by science. All reasoned-out conclusions whatever,
-must rest on some postulate. As before shown (§ 23), we
-cannot go on merging derivative truths in those wider and
-wider truths from which they are derived, without reaching
-at last a widest truth which can be merged in no other, or
-derived from no other. And whoever contemplates the relation
-in which it stands to the truths of science in general, will
-<span class='pageno' id='Page_255'>255</span>see that this truth transcending demonstration is the persistence
-of Force.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 74. But now what is the force of which we predicate
-persistence? It is not the force we are immediately conscious
-of in our own muscular efforts; for this does not persist. As
-soon as an outstretched limb is relaxed, the sense of tension
-disappears. True, we assert that in the stone thrown or in the
-weight lifted, is exhibited the effect of this muscular tension;
-and that the force which has ceased to be present in our consciousness,
-exists elsewhere. But it does not exist elsewhere
-under any form cognizable by us. It was proved (§ 18),
-that though, on raising an object from the ground, we are
-obliged to think of its downward pull as equal and opposite
-to our upward pull; and though it is impossible to represent
-these pulls as equal without representing them as like in
-kind; yet, since their likeness in kind would imply in the
-object a sensation of muscular tension, which cannot be
-ascribed to it, we are compelled to admit that force as it
-exists out of our consciousness, is not force as we know it.
-Hence the force of which we assert persistence is that Absolute
-Force of which we are indefinitely conscious as the necessary
-correlate of the force we know. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Thus, by the persistence
-of Force, we really mean the persistence of some Power
-which transcends our knowledge and conception. The manifestations,
-as occurring either in ourselves or outside of us, do
-not persist; but that which persists is the Unknown Cause
-of these manifestations. In other words, asserting the
-persistence of Force, is but another mode of asserting an
-Unconditioned Reality, without beginning or end.</p>
-
-<p class='c000'>Thus, quite unexpectedly, we come down once more to
-that ultimate truth in which, as we saw, Religion and
-Science coalesce. On examining the data underlying a
-rational theory of Evolution, we find them all at last resolvable
-into that datum without which consciousness was
-shown to be impossible—the continued existence of an Unknowable
-<span class='pageno' id='Page_256'>256</span>as the necessary correlative of the Knowable. Once
-commenced, the analysis of the truths taken for granted in
-scientific inquiries, inevitably brings us down to this deepest
-truth, in which Common Sense and Philosophy are reconciled.</p>
-
-<p class='c000'>The arguments and conclusion contained in this and the
-foregoing three chapters, supply, indeed, the complement to
-the arguments and conclusion set forth in the preceding part
-of this work. It was there first shown, by an examination of
-our ultimate religious ideas, that knowledge of Absolute Being
-is impossible; and the impossibility of knowing Absolute
-Being, was also shown by an examination of our ultimate
-scientific ideas. In a succeeding chapter a subjective analysis
-proved, that while, by the very conditions of thought, we are
-prevented from knowing anything beyond relative being; yet
-that by these very same conditions of thought, an indefinite
-consciousness of Absolute Being is necessitated. And here,
-by objective analysis, we similarly find that the axiomatic
-truths of physical science, unavoidably postulate Absolute
-Being as their common basis.</p>
-
-<p class='c000'>Thus there is even a more profound agreement between
-Religion and Science than was before shown. Not only are
-they wholly at one on the negative proposition that the Non-relative
-cannot be known; but they are wholly at one on the
-positive proposition that the Non-relative is an actual existence.
-Both are obliged by the demonstrated untenability of their
-supposed cognitions, to confess that the Ultimate Reality is incognizable;
-and yet both are obliged to assert the existence of
-an Ultimate Reality. Without this, Religion has no subject-matter;
-and without this, Science, subjective and objective,
-lacks its indispensable datum. We cannot construct a theory
-of internal phenomena without postulating Absolute Being;
-and unless we postulate Absolute Being, or being which persists,
-we cannot construct a theory of external phenomena.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 75. A few words must be added respecting the nature
-<span class='pageno' id='Page_257'>257</span>of this fundamental consciousness. Already it has been looked
-at from several points of view; and here it seems needful
-finally to sum up the results.</p>
-
-<p class='c000'>In Chapter IV. we saw that the Unknown Power of
-which neither beginning nor end can be conceived, is present
-to us as that unshaped material of consciousness which
-is shaped afresh in every thought. Our inability to conceive
-its limitation, is thus simply the obverse of our inability to
-put an end to the thinking subject while still continuing to
-think. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;In the two foregoing chapters, we contemplated
-this fundamental truth under another aspect. The indestructibility
-of Matter and the continuity of Motion, we saw to be
-really corollaries from the impossibility of establishing in
-thought a relation between something and nothing. What
-we call the establishment of a relation in thought, is the passage
-of the substance of consciousness, from one form into another.
-To think of something becoming nothing, would involve
-that this substance of consciousness having just existed
-under a given form, should next assume no form; or should
-cease to be consciousness. And thus our inability to conceive
-Matter and Motion destroyed, is our inability to suppress consciousness
-itself. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;What, in these two foregoing chapters,
-was proved true of Matter and Motion, is, <i><span lang="fr" xml:lang="fr">à fortiori</span></i>, true
-of the Force out of which our conceptions of Matter and Motion
-are built. Indeed, as we saw, that which is indestructible in
-matter and motion, is the force they present. And, as we
-here see, the truth that Force is indestructible, is the obverse
-of the truth that the Unknown Cause of the changes going on
-in consciousness is indestructible. So that the persistence of
-consciousness, constitutes at once our immediate experience of
-the persistence of Force, and imposes on us the necessity we
-are under of asserting its persistence.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 76. Thus, in all ways there is forced on us the fact, that
-here is an ultimate truth given in our mental constitution.
-It is not only a datum of science, but it is a datum which even
-<span class='pageno' id='Page_258'>258</span>the assertion of our nescience involves. Whoever alleges that
-the inability to conceive a beginning or end of the Universe,
-is a <em>negative</em> result of our mental structure, cannot deny that
-our consciousness of the Universe as persistent, is a <em>positive</em> result
-of our mental structure. And this persistence of the
-Universe, is the persistence of that Unknown Cause, Power, or
-Force, which is manifested to us through all phenomena.</p>
-
-<p class='c000'>Such then is the foundation of any possible system of positive
-knowledge. Deeper than demonstration—deeper even
-than definite cognition—deep as the very nature of mind, is
-the postulate at which we have arrived. Its authority transcends
-all other whatever; for not only is it given in the constitution
-of our own consciousness, but it is impossible to
-imagine a consciousness so constituted as not to give it.
-Thought, involving simply the establishment of relations, may
-be readily conceived to go on while yet these relations have
-not been organized into the abstracts we call Space and Time;
-and so there is a conceivable kind of consciousness which
-does not contain the truths, commonly called <i><span lang="fr" xml:lang="fr">à priori</span></i>, involved
-in the organization of these forms of relations. But
-thought cannot be conceived to go on without some element
-between which its relations may be established; and
-so there is no conceivable kind of consciousness which does
-not imply continued existence as its datum. Consciousness
-without this or that particular <em>form</em> is possible; but consciousness
-without <em>contents</em> is impossible.</p>
-
-<p class='c000'>The sole truth which transcends experience by underlying
-it, is thus the persistence of Force. This being the basis of experience,
-must be the basis of any scientific organization of experiences.
-To this an ultimate analysis brings us down; and
-on this a rational synthesis must build up.</p>
-
-<hr class='c015' />
-
-<div class='footnote' id='f12'>
-<p class='c000'><span class='label'><a href='#r12'>12</a>.&nbsp;&nbsp;</span>Some two years ago, I expressed to my friend Professor Huxley, my dissatisfaction
-with the current expression—“Conservation of Force;” assigning as
-reasons, first, that the word “conservation” implies a conserver and an act
-of conserving; and, second, that it does not imply the existence of the force before
-that particular manifestation of it with which we commence. In place of “conservation,”
-Professor Huxley suggested <em>persistence</em>. This entirely meets the first
-of the two objections; and though the second may be urged against it, no other
-word less faulty in this respect can be found. In the absence of a word specially
-coined for the purpose, it seems the best; and as such I adopt it.</p>
-</div>
-
-<div>
- <span class='pageno' id='Page_259'>259</span>
- <h3 class='c001'>CHAPTER IX.<br /> <span class='large'>THE CORRELATION AND EQUIVALENCE OF FORCES.</span></h3>
-</div>
-
-<p class='c006'>§ 77. When, to the unaided senses, Science began to add
-supplementary senses in the shape of measuring instruments,
-men began to perceive various phenomena which eyes and
-fingers could not distinguish. Of known forms of force,
-minuter manifestations became appreciable; and forms of
-force before unknown were rendered cognizable and measurable.
-Where forces had apparently ended in nothing, and
-had been carelessly supposed to have actually done so, instrumental
-observation proved that effects had in every instance
-been produced: the forces reappearing in new shapes.
-Hence there has at length arisen the inquiry whether the
-force displayed in each surrounding change, does not in the
-act of expenditure undergo metamorphosis into an equivalent
-amount of some other force or forces. And to this inquiry
-experiment is giving an affirmative answer, which becomes
-day by day more decisive. Grove, Helmholtz, and Meyer,
-are more than any others to be credited with the clear enunciation
-of this doctrine. Let us glance at the evidence on
-which it rests.</p>
-
-<p class='c000'>Motion, wherever we can directly trace its genesis, we find
-to pre-exist as some other mode of force. Our own voluntary
-acts have always certain sensations of muscular
-tension as their antecedents. When, as in letting fall a relaxed
-limb, we are conscious of a bodily movement requiring
-no effort, the explanation is that the effort was exerted in
-<span class='pageno' id='Page_260'>260</span>raising the limb to the position whence it fell. In this case,
-as in the case of an inanimate body descending to the Earth,
-the force accumulated by the downward motion is just equal
-to the force previously expended in the act of elevation.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Conversely, Motion that is arrested produces,
-under different circumstances, heat, electricity, magnetism,
-light. From the warming of the hands by rubbing them
-together, up to the ignition of a railway-brake by intense
-friction—from the lighting of detonating powder by percussion,
-up to the setting on fire a block of wood by a few blows
-from a steam-hammer; we have abundant instances in which
-heat arises as Motion ceases. It is uniformly found, that the
-heat generated is great in proportion as the Motion lost is
-great; and that to diminish the arrest of motion, by diminishing
-the friction, is to diminish the quantity of heat
-evolved. The production of electricity by Motion is illustrated
-equally in the boy’s experiment with rubbed sealing-wax,
-in the common electrical machine, and in the apparatus
-for exciting electricity by the escape of steam. Wherever
-there is friction between heterogeneous bodies, electrical disturbance
-is one of the consequences. Magnetism may result
-from Motion either immediately, as through percussion on
-iron, or mediately as through electric currents previously
-generated by Motion. And similarly, Motion may create
-light; either directly, as in the minute incandescent fragments
-struck off by violent collisions, or indirectly, as
-through the electric spark. “Lastly, Motion may be again
-reproduced by the forces which have emanated from Motion;
-thus, the divergence of the electrometer, the revolution of
-the electrical wheel, the deflection of the magnetic needle,
-are, when resulting from frictional electricity, palpable movements
-reproduced by the intermediate modes of force, which
-have themselves been originated by motion.”</p>
-
-<p class='c000'>That mode of force which we distinguish as Heat, is now
-generally regarded by physicists as molecular motion—not
-motion as displayed in the changed relations of sensible
-<span class='pageno' id='Page_261'>261</span>masses to each other, but as occurring among the units of
-which such sensible masses consist. If we cease to think of
-Heat as that particular sensation given to us by bodies in
-certain conditions, and consider the phenomena otherwise
-presented by these bodies, we find that motion, either in
-them or in surrounding bodies, or in both, is all that
-we have evidence of. With one or two exceptions which are
-obstacles to every theory of Heat, heated bodies expand; and
-expansion can be interpreted only as a movement of the units
-of a mass in relation to each other. That so-called radiation
-through which anything of higher temperature than
-things around it, communicates Heat to them, is clearly a
-species of motion. Moreover, the evidence afforded by the
-thermometer that Heat thus diffuses itself, is simply a movement
-caused in the mercurial column. And that the molecular
-motion which we call Heat, may be transformed into visible
-motion, familiar proof is given by the steam-engine; in
-which “the piston and all its concomitant masses of matter
-are moved by the molecular dilatation of the vapour of
-water.” &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Where Heat is absorbed without apparent
-result, modern inquiries show that decided though unobtrusive
-changes are produced: as on glass, the molecular
-state of which is so far changed by heat, that a polarized ray
-of light passing through it becomes visible, which it does not
-do when the glass is cold; or as on polished metallic surfaces,
-which are so far changed in structure by thermal radiations
-from objects very close to them, as to retain permanent impressions
-of such objects. The transformation of Heat into
-electricity, occurs when dissimilar metals touching each other
-are heated at the point of contact: electric currents being so
-induced. Solid, incombustible matter introduced into heated
-gas, as lime into the oxyhydrogen flame, becomes incandescent;
-and so exhibits the conversion of Heat into light.
-The production of magnetism by Heat, if it cannot be proved
-to take place directly, may be proved to take place indirectly
-through the medium of electricity. And through the same
-<span class='pageno' id='Page_262'>262</span>medium may be established the correlation of Heat and
-chemical affinity—a correlation which is indeed implied by
-the marked influence that Heat exercises on chemical composition
-and decomposition.</p>
-
-<p class='c000'>The transformations of Electricity into other modes of
-force, are still more clearly demonstrable. Produced by the
-motion of heterogeneous bodies in contact, Electricity, through
-attractions and repulsions, will immediately reproduce motion
-in neighbouring bodies. Now a current of Electricity generates
-magnetism in a bar of soft iron; and now the rotation
-of a permanent magnet generates currents of Electricity.
-Here we have a battery in which from the play of chemical
-affinities an electric current results; and there, in the
-adjacent cell, we have an electric current effecting chemical
-decomposition. In the conducting wire we witness the
-transformation of Electricity into heat; while in electric
-sparks and in the voltaic arc we see light produced. Atomic
-arrangement, too, is changed by Electricity: as instance
-the transfer of matter from pole to pole of a battery; the
-fractures caused by the disruptive discharge; the formation
-of crystals under the influence of electric currents. And
-whether, conversely, Electricity be or be not directly generated
-by re-arrangement of the atoms of matter, it is at any
-rate indirectly so generated through the intermediation of
-magnetism.</p>
-
-<p class='c000'>How from Magnetism the other physical forces result,
-must be next briefly noted—briefly, because in each successive
-case the illustrations become in great part the obverse
-forms of those before given. That Magnetism produces
-motion is the ordinary evidence we have of its existence. In
-the magneto-electric machine we see a rotating magnet
-evolving electricity. And the electricity so evolved may
-immediately after exhibit itself as heat, light, or chemical
-affinity. Faraday’s discovery of the effect of Magnetism on
-polarized light, as well as the discovery that change of magnetic
-state is accompanied by heat, point to further like connexions.
-<span class='pageno' id='Page_263'>263</span>Lastly, various experiments show that the magnetization
-of a body alters its internal structure; and that
-conversely, the alteration of its internal structure, as by
-mechanical strain, alters its magnetic condition.</p>
-
-<p class='c000'>Improbable as it seemed, it is now proved that from Light
-also may proceed the like variety of agencies. The solar rays
-change the atomic arrangements of particular crystals.
-Certain mixed gases, which do not otherwise combine, combine
-in the sunshine. In some compounds Light produces
-decomposition. Since the inquiries of photographers
-have drawn attention to the subject, it has been shown that
-“a vast number of substances, both elementary and compound,
-are notably affected by this agent, even those apparently
-the most unalterable in character, such as metals.”
-And when a daguerreotype plate is connected with a proper
-apparatus “we get chemical action on the plate, electricity
-circulating through the wires, magnetism in the coil, heat in
-the helix, and motion in the needles.”</p>
-
-<p class='c000'>The genesis of all other modes of force from Chemical
-Action, scarcely needs pointing out. The ordinary accompaniment
-of chemical combination is heat; and when the
-affinities are intense, light also is, under fit conditions, produced.
-Chemical changes involving alteration of bulk, cause
-motion, both in the combining elements and in adjacent
-masses of matter: witness the propulsion of a bullet by the
-explosion of gunpowder. In the galvanic battery we see
-electricity resulting from chemical composition and decomposition.
-While through the medium of this electricity,
-Chemical Action produces magnetism.</p>
-
-<p class='c000'>These facts, the larger part of which are culled from Mr.
-Grove’s work on “The Correlation of Physical Forces,” show
-us that each force is transformable, directly or indirectly,
-into the others. In every change Force undergoes metamorphosis;
-and from the new form or forms it assumes, may
-subsequently result either the previous one or any of the
-rest, in endless variety of order and combination. It is
-<span class='pageno' id='Page_264'>264</span>further becoming manifest that the physical forces stand not
-simply in qualitative correlations with each other, but also in
-quantitative correlations. Besides proving that one mode of
-force may be transformed into another mode, experiments
-illustrate the truth that from a definite amount of one, definite
-amounts of others always arise. Ordinarily it is indeed
-difficult to show this; since it mostly happens that the
-transformation of any force is not into some one of the rest
-but into several of them: the proportions being determined
-by the ever-varying conditions. But in certain cases, positive
-results have been reached. Mr. Joule has ascertained
-that the fall of 772 lbs. through one foot, will raise the
-temperature of a pound of water one degree of Fahrenheit.
-The investigations of Dulong, Petit and Neumann, have
-proved a relation in amount between the affinities of combining
-bodies and the heat evolved during their combination. Between
-chemical action and voltaic electricity, a quantitative
-connexion has also been established: Faraday’s experiments
-implying that a specific measure of electricity is disengaged
-by a given measure of chemical action. The well-determined
-relations between the quantities of heat generated and water
-turned into steam, or still better the known expansion produced
-in steam by each additional degree of heat, may be
-cited in further evidence. Whence it is no longer doubted
-that among the several forms which force assumes, the
-quantitative relations are fixed. The conclusion tacitly
-agreed on by physicists, is, not only that the physical forces
-undergo metamorphoses, but that a certain amount of each is
-the constant equivalent of certain amounts of the others.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 78. Throughout Evolution under all its phases, this truth
-of course invariably holds. Every successive change or
-group of changes forming part of it, is of necessity limited
-by the conditions thus implied. The forces which any step
-in Evolution exhibits, must be affiliable on the like or unlike
-forces previously existing; while from the forces so generated
-<span class='pageno' id='Page_265'>265</span>must thereafter be derived others more or less transformed.
-And besides recognizing the forces at any time existing, as
-necessarily linked with those preceding and succeeding them,
-we must also recognize the amounts of these forces successively
-manifested as determinate,—as necessarily producing
-such and such quantities of results, and as necessarily
-limited to those quantities.</p>
-
-<p class='c000'>Involved as are the phenomena of Evolution, it is not to be
-expected that a <em>definite</em> quantitative relation can in each case,
-or indeed in any case, be shown between the forces expended
-in successive phases. We have not adequate data for this;
-and probably shall never have them. The antecedents of
-the simpler forms of Evolution, belong to a remote past respecting
-which we can have nothing but inferential knowledge;
-while the antecedents of the only kind of Evolution
-which is traceable from beginning to end (namely, that of
-individual organisms) are too complex to be dealt with by
-exact methods. Hence we cannot hope to establish <em>equivalence</em>
-among the successive manifestations of force which each
-order of Evolution affords. The most we can hope is to
-establish a qualitative correlation that is indefinitely quantitative—quantitative
-in so far as involving something like a due
-proportion between causes and effects. If this can be done,
-however, some progress will be made towards the solution of
-our problem. Though it may be beyond our power to show
-a measurable relation between the force or group of forces
-which any phase of Evolution displays, and the force or group
-of forces immediately succeeding it; yet if we can show that
-there always are antecedent forces, and that the effects they
-produce always become the antecedents of further ones—if
-while unable to calculate how much of each change will be
-produced, we can prove that a change of that kind was necessitated—if
-we can discern even the vaguest correspondence
-between the amount of such change and the amount of the
-pre-existing force; we shall advance a step towards interpreting
-the transformation of the simple into the complex.</p>
-
-<p class='c000'><span class='pageno' id='Page_266'>266</span>With the view of attempting this, let us now reconsider
-the different types of Evolution awhile since delineated:
-taking them in the same order as before.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 79. On contemplating our Solar System the first fact
-which strikes us, is, that all its members are in motion; and
-that their motion is of a two-fold, or rather of a three-fold,
-kind. Each planet and satellite has a movement of rotation
-and a movement of translation; besides the movement
-through space which all have in common with their rotating
-primary. Whence this unceasing change of place?</p>
-
-<p class='c000'>The hypothesis of Evolution supplies us with an answer.
-Impossible as it is to assign a reason for the pre-existence of
-matter in the diffused form supposed; yet assuming its pre-existence
-in that form, we have in the gravitation of its parts
-a cause of motion adequate to the results. So far too as the
-evidence carries us, we can perceive some quantitative relation
-between the motions produced, and the gravitative forces
-expended in producing them. The planets formed from that
-matter which has travelled the shortest distance towards the
-common centre of gravity, have the smallest velocities: the
-uniform law being that in advancing from the outermost to
-the innermost planets, the rate of orbital motion progressively
-increases. It may indeed be remarked that this is explicable
-on the teleological hypothesis; since it is a condition to equilibrium.
-But without dwelling on the fact that this is beside
-the question, it will suffice to point out that the like cannot
-be said of the planetary rotations. No such final cause can
-be assigned for the rapid axial movement of Jupiter and
-Saturn, or the slow axial movement of Mercury. But if in
-pursuance of the doctrine of correlation we look for the antecedents
-of these gyrations which all planets exhibit, the
-theory of Evolution furnishes us with equivalent ones; and
-ones which bear manifest quantitative relations to the motions
-displayed. For the planets that turn on their axes with extreme
-rapidity, are those having great masses and large
-<span class='pageno' id='Page_267'>267</span>orbits—those, that is, of which the once diffused elements
-moved to their centres of gravity through immense spaces,
-and so acquired high velocities. While, conversely, there
-has resulted the smallest axial movement where the orbit
-and the mass are both the smallest.</p>
-
-<p class='c000'>“But what,” it may be asked, “has in such case become
-of all that motion which brought about the aggregation of
-this diffused matter into solid bodies?” The rotation of each
-body can be but a residuary result of concentration—a result
-due to the imperfect balancing of gravitative movements
-from opposite points towards the common centre. Such
-gravitative movements from opposite points must in great
-measure destroy each other. What then has become of
-these mutually-destroyed motions? The answer which the
-doctrine of correlation suggests is—they must have been
-radiated in the form of heat and light. And this answer
-the evidence, so far as it goes, confirms. Apart from any
-speculation respecting the genesis of the solar system, the
-inquiries of geologists lead to the conclusion that the heat of
-the Earth’s still molten nucleus is but a remnant of the heat
-which once made molten the entire Earth. The mountainous
-surfaces of the Moon and of Venus (which alone are near
-enough to be scrutinized), indicating, as they do, crusts that
-have, like our own, been corrugated by contraction, imply
-that these bodies too have undergone refrigeration—imply
-in each of them a primitive heat, such as the hypothesis necessitates.
-Lastly, we have in the Sun a still-continued production
-of this heat and light, which must result from the
-arrest of diffused matter moving towards a common centre of
-gravity. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Here also, as before, a quantitative relation
-is traceable. Among the bodies which make up the Solar
-System, those containing comparatively small amounts of
-matter whose centripetal motion has been destroyed, have already
-lost nearly all the produced heat: a result which their
-relatively larger surfaces have facilitated. But the Sun, a
-thousand times as great in mass as the largest planet, and
-<span class='pageno' id='Page_268'>268</span>having therefore to give off an enormously greater quantity of
-heat and light due to arrest of moving matter, is still radiating
-with great intensity.</p>
-
-<p class='c000'>Thus we see that when, in pursuance of the doctrine of correlation,
-we ask whence come the forces which our Solar System
-displays, the hypothesis of Evolution gives us a proximate
-explanation. If the Solar System once existed in a state of
-indefinite, incoherent homogeneity, and has progressed to its
-present state of definite, coherent heterogeneity; then the
-Motion, Heat, and Light now exhibited by its members, are
-interpretable as the correlatives of pre-existing forces; and
-between them and their antecedents we may discern relations
-that are not only qualitative, but also rudely quantitative.
-How matter came to exist under the form assumed, is a
-mystery which we must regard as ultimate. But grant such
-a previous form of existence, and the hypothesis of Evolution
-interpreted by the laws of correlation, explains for us the
-forces as we now see them.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 80. If we inquire the origin of those forces which have
-wrought the surface of our planet into its present shape, we
-find them traceable to the same primordial source as that
-just assigned. Assuming the solar system to have been
-evolved, then geologic changes are either direct or indirect
-results of the unexpended heat caused by nebular condensation.
-These changes are commonly divided into igneous and
-aqueous:—heads under which we may most conveniently consider
-them.</p>
-
-<p class='c000'>All those periodic disturbances which we call earthquakes,
-all those elevations and subsidences which they severally
-produce, all those accumulated effects of many such elevations
-and subsidences exhibited in ocean-basins, islands, continents,
-table-lands, mountain-chains, and all those formations
-which are distinguished as volcanic, geologists now
-regard as modifications of the Earth’s crust produced by the
-still-molten matter occupying its interior. However untenable
-<span class='pageno' id='Page_269'>269</span>may be the details of M. Elie de Beaumont’s theory,
-there is good reason to accept the general proposition that
-the disruptions and variations of level which take place at
-intervals on the terrestrial surface, are due to the progressive
-collapse of the Earth’s solid envelope upon its cooling and
-contracting nucleus. Even supposing that volcanic eruptions,
-extrusions of igneous rock, and upheaved mountain-chains,
-could be otherwise satisfactorily accounted for, which
-they cannot; it would be impossible otherwise to account for
-those wide-spread elevations and depressions whence continents
-and oceans result. The conclusion to be drawn is,
-then, that the forces displayed in these so-called igneous
-changes, are derived positively or negatively from the unexpended
-heat of the Earth’s interior. Such phenomena as the
-fusion or agglutination of sedimentary deposits, the warming
-of springs, the sublimation of metals into the fissures where
-we find them as ores, may be regarded as positive results of
-this residuary heat; while fractures of strata and alterations
-of level are its negative results, since they ensue on its escape.
-The original cause of all these effects is still, however, as it
-has been from the first, the gravitating movement of the
-Earth’s matter towards the Earth’s centre; seeing that to
-this is due both the internal heat itself and the collapse
-which takes place as it is radiated into space.</p>
-
-<p class='c000'>When we inquire under what forms previously existed the
-force which works out the geological changes classed as
-aqueous, the answer is less obvious. The effects of rain, of
-rivers, of winds, of waves, of marine currents, do not manifestly
-proceed from one general source. Analysis, nevertheless,
-proves to us that they have a common genesis. If we
-ask,—Whence comes the power of the river-current, bearing
-sediment down to the sea? the reply is,—The gravitation of
-water throughout the tract which this river drains. If we
-ask,—How came the water to be dispersed over this tract? the
-reply is,—It fell in the shape of rain. If we ask,—How came
-the rain to be in that position whence it fell? the reply is,—The
-<span class='pageno' id='Page_270'>270</span>vapour from which it was condensed was drifted there
-by the winds. If we ask,—How came this vapour to be at
-that elevation? the reply is,—It was raised by evaporation.
-And if we ask,—What force thus raised it? the reply is,—The
-sun’s heat. Just that amount of gravitative force which
-the sun’s heat overcame in raising the atoms of water, is
-given out again in the fall of those atoms to the same level.
-Hence the denudations effected by rain and rivers, during
-the descent of this condensed vapour to the level of the sea,
-are indirectly due to the sun’s heat. Similarly with the
-winds that transport the vapours hither and thither. Consequent
-as atmospheric currents are on differences of temperature
-(either general, as between the equatorial and polar
-regions, or special as between tracts of the Earth’s surface of
-unlike physical characters) all such currents are due to that
-source from which the varying quantities of heat proceed.
-And if the winds thus originate, so too do the waves raised
-by them on the sea’s surface. Whence it follows that whatever
-changes waves produce—the wearing away of shores,
-the breaking down of rocks into shingle, sand, and mud—are
-also traceable to the solar rays as their primary cause.
-The same may be said of ocean-currents. Generated as the
-larger ones are by the excess of heat which the ocean in
-tropical climates continually acquires from the Sun; and
-generated as the smaller ones are by minor local differences
-in the quantities of solar heat absorbed; it follows that the
-distribution of sediment and other geological processes which
-these marine currents effect, are affiliable upon the force
-which the sun radiates. The only aqueous agency otherwise
-originating is that of the tides—an agency which, equally with
-the others, is traceable to unexpended astronomical motion.
-But making allowance for the changes which this works, we
-reach the conclusion that the slow wearing down of continents
-and gradual filling up of seas, by rain, rivers, winds,
-waves, and ocean-streams, are the indirect effects of solar
-heat.</p>
-
-<p class='c000'><span class='pageno' id='Page_271'>271</span>Thus the implication forced on us by the doctrine of correlation,
-that the forces which have moulded and re-moulded
-the Earth’s crust must have pre-existed under some other
-shape, is quite in conformity with the theory of Evolution;
-since this pre-supposes certain forces that are both adequate
-to the results, and cannot be expended without producing
-the results. We see that while the geological changes classed
-as igneous, result from the still-progressing motion of the
-Earth’s substance to its centre of gravity; the antagonistic
-changes classed as aqueous, result from the still-progressing
-motion of the Sun’s substance towards its centre of gravity—a
-motion which, transformed into heat and radiated to us, is
-here re-transformed, directly into motions of the gaseous and
-liquid matters on the Earth’s surface, and indirectly into
-motions of the solid matters.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 81. That the forces exhibited in vital actions, vegetal
-and animal, are similarly derived, is so obvious a deduction
-from the facts of organic chemistry, that it will meet with
-ready acceptance from readers acquainted with these facts.
-Let us note first the physiological generalizations; and then
-the generalizations which they necessitate.</p>
-
-<p class='c000'>Plant-life is all directly or indirectly dependant on the
-heat and light of the sun—directly dependant in the immense
-majority of plants, and indirectly dependant in plants
-which, as the fungi, flourish in the dark: since these, growing
-as they do at the expense of decaying organic matter, mediately
-draw their forces from the same original source. Each
-plant owes the carbon and hydrogen of which it mainly consists,
-to the carbonic acid and water contained in the surrounding
-air and earth. The carbonic acid and water must, however,
-be decomposed before their carbon and hydrogen can
-be assimilated. To overcome the powerful affinities which
-hold their elements together, requires the expenditure of
-force; and this force is supplied by the Sun. In what
-manner the decomposition is effected we do not know. But
-<span class='pageno' id='Page_272'>272</span>we know that when, under fit conditions, plants are exposed
-to the Sun’s rays, they give off oxygen and accumulate carbon
-and hydrogen. In darkness this process ceases. It ceases
-too when the quantities of light and heat received are greatly
-reduced, as in winter. Conversely, it is active when the light
-and heat are great, as in summer. And the like relation is
-seen in the fact that while plant-life is luxuriant in the
-tropics, it diminishes in temperate regions, and disappears as
-we approach the poles. Thus the irresistible inference is,
-that the forces by which plants abstract the materials of their
-tissues from surrounding inorganic compounds—the forces by
-which they grow and carry on their functions, are forces that
-previously existed as solar radiations.</p>
-
-<p class='c000'>That animal life is immediately or mediately dependant on
-vegetal life is a familiar truth; and that, in the main, the
-processes of animal life are opposite to those of vegetal life is a
-truth long current among men of science. Chemically considered,
-vegetal life is chiefly a process of de-oxidation, and
-animal life chiefly a process of oxidation: chiefly, we must
-say, because in so far as plants are expenders of force for the
-purposes of organization, they are oxidizers (as is shown by
-the exhalation of carbonic acid during the night); and animals,
-in some of their minor processes, are probably de-oxidizers.
-But with this qualification, the general truth is
-that while the plant, decomposing carbonic acid and water
-and liberating oxygen, builds up the detained carbon and
-hydrogen (along with a little nitrogen and small quantities
-of other elements elsewhere obtained) into branches,
-leaves, and seeds; the animal, consuming these branches,
-leaves, and seeds, and absorbing oxygen, recomposes carbonic
-acid and water, together with certain nitrogenous
-compounds in minor amounts. And while the decomposition
-effected by the plant, is at the expense of certain
-forces emanating from the sun, which are employed
-in overcoming the affinities of carbon and hydrogen for the
-oxygen united with them; the recomposition effected by the
-<span class='pageno' id='Page_273'>273</span>animal, is at the profit of these forces, which are liberated
-during the combination of such elements. Thus the movements,
-internal and external, of the animal, are re-appearances
-in new forms of a power absorbed by the plant under
-the shape of light and heat. Just as, in the manner
-above explained, the solar forces expended in raising vapour
-from the sea’s surface, are given out again in the fall of rain
-and rivers to the same level, and in the accompanying transfer
-of solid matters; so, the solar forces that in the plant
-raised certain chemical elements to a condition of unstable
-equilibrium, are given out again in the actions of the animal
-during the fall of these elements to a condition of stable
-equilibrium.</p>
-
-<p class='c000'>Besides thus tracing a qualitative correlation between these
-two great orders of organic activity, as well as between both
-of them and inorganic agencies, we may rudely trace a
-quantitative correlation. Where vegetal life is abundant, we
-usually find abundant animal life; and as we advance from
-torrid to temperate and frigid climates, the two decrease together.
-Speaking generally, the animals of each class reach
-a larger size in regions where vegetation is abundant, than
-in those where it is sparse. And further, there is a tolerably
-apparent connexion between the quantity of energy which
-each species of animal expends, and the quantity of force
-which the nutriment it absorbs gives out during oxidation.</p>
-
-<p class='c000'>Certain phenomena of development in both plants and
-animals, illustrate still more directly the ultimate truth
-enunciated. Pursuing the suggestion made by Mr. Grove,
-in the first edition of his work on the “Correlation of the
-Physical Forces,” that a connexion probably exists between
-the forces classed as vital and those classed as physical,
-Dr. Carpenter has pointed out that such a connexion is
-clearly exhibited during incubation. The transformation of
-the unorganized contents of an egg into the organized chick,
-is altogether a question of heat: withhold heat and the process
-does not commence; supply heat and it goes on while the
-<span class='pageno' id='Page_274'>274</span>temperature is maintained, but ceases when the egg is allowed
-to cool. The developmental changes can be completed only
-by keeping the temperature with tolerable constancy at a
-definite height for a definite time; that is—only by supplying
-a definite quantity of heat. In the metamorphoses of
-insects we may discern parallel facts. Experiments show
-not only that the hatching of their eggs is determined by
-temperature, but also that the evolution of the pupa into the
-imago is similarly determined; and may be immensely accelerated
-or retarded according as heat is artificially supplied
-or withheld. It will suffice just to add that the germination of
-plants presents like relations of cause and effect—relations so
-similar that detail is superfluous.</p>
-
-<p class='c000'>Thus then the various changes exhibited to us by the
-organic creation, whether considered as a whole, or in its two
-great divisions, or in its individual members, conform, so far
-as we can ascertain, to the law of correlation. Where, as in
-the transformation of an egg into a chick, we can investigate
-the phenomena apart from all complications, we find that the
-re-arrangement of parts which constitutes evolution, involves
-expenditure of a pre-existing force. Where it is not, as
-in the egg or the chrysalis, merely the change of a fixed
-quantity of matter into a new shape, but where, as in the
-growing plant or animal, we have an incorporation of matter
-existing outside, there is still a pre-existing external force
-at the cost of which this incorporation is effected. And
-where, as in the higher division of organisms, there remain
-over and above the forces expended in organization,
-certain surplus forces expended in movement, these too are
-indirectly derived from this same pre-existing external force.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 82. Even after all that has been said in the foregoing
-part of this work, many will be alarmed by the assertion,
-that the forces which we distinguish as mental, come within
-the same generalization. Yet there is no alternative but to
-make this assertion: the facts which justify, or rather which
-<span class='pageno' id='Page_275'>275</span>necessitate it, being abundant and conspicuous. They fall
-into the following groups.</p>
-
-<p class='c000'>All impressions from moment to moment made on our
-organs of sense, stand in direct correlation with physical
-forces existing externally. The modes of consciousness called
-pressure, motion, sound, light, heat, are effects produced in
-us by agencies which, as otherwise expended, crush or fracture
-pieces of matter, generate vibrations in surrounding objects,
-cause chemical combinations, and reduce substances from a
-solid to a liquid form. Hence if we regard the changes of
-relative position, of aggregation, or of chemical state, thus
-arising, as being transformed manifestations of the agencies
-from which they arise; so must we regard the sensations
-which such agencies produce in us, as new forms of the forces
-producing them. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Any hesitation to admit that, between
-the physical forces and the sensations there exists a
-correlation like that between the physical forces themselves,
-must disappear on remembering how the one correlation, like
-the other, is not qualitative only but quantitative. Masses
-of matter which, by scales or dynamometer, are shown to
-differ greatly in weight, differ as greatly in the feelings of
-pressure they produce on our bodies. In arresting moving
-objects, the strains we are conscious of are proportionate to
-the momenta of such objects as otherwise measured. Under
-like conditions the impressions of sounds given to us by
-vibrating strings, bells, or columns of air, are found to vary
-in strength with the amount of force applied. Fluids or
-solids proved to be markedly contrasted in temperature by
-the different degrees of expansion they produce in the
-mercurial column, produce in us correspondingly different
-degrees of the sensation of heat. And similarly unlike intensities
-in our impressions of light, answer to unlike effects
-as measured by photometers.</p>
-
-<p class='c000'>Besides the correlation and equivalence between external
-physical forces, and the mental forces generated by them in
-us under the form of sensations, there is a correlation and
-<span class='pageno' id='Page_276'>276</span>equivalence between sensations and those physical forces
-which, in the shape of bodily actions, result from them. The
-feelings we distinguish as light, heat, sound, odour, taste,
-pressure, &amp;.c, do not die away without immediate results;
-but are invariably followed by other manifestations of force.
-In addition to the excitements of secreting organs, that are
-in some cases traceable, there arises a contraction of the involuntary
-muscles, or of the voluntary muscles, or of both.
-Sensations increase the action of the heart—slightly when
-they are slight; markedly when they are marked; and recent
-physiological inquiries imply not only that contraction of the
-heart is excited by every sensation, but also that the muscular
-fibres throughout the whole, vascular system, are at the same
-time more or less contracted. The respiratory muscles, too,
-are stimulated into greater activity by sensations. The rate
-of breathing is visibly and audibly augmented both by pleasurable
-and painful impressions on the nerves, when these
-reach any intensity. It has even of late been shown that
-inspiration becomes more frequent on transition from darkness
-into sunshine,—a result probably due to the increased
-amount of direct and indirect nervous stimulation involved.
-When the quantity of sensation is great, it generates contractions
-of the voluntary muscles, as well as of the involuntary
-ones. Unusual excitement of the nerves of touch, as by
-tickling, is followed by almost incontrollable movements of
-the limbs. Violent pains cause violent struggles. The
-start that succeeds a loud sound, the wry face produced by
-the taste of anything extremely disagreeable, the jerk with
-which the hand or foot is snatched out of water that is very
-hot, are instances of the transformation of feeling: into
-motion; and in these cases, as in all others, it is manifest
-that the quantity of bodily action is proportionate to the
-quantity of sensation. Even where from pride there is a
-suppression of the screams and groans expressive of great
-pain (also indirect results of muscular contraction), we may
-still see in the clenching of the hands, the knitting of the
-<span class='pageno' id='Page_277'>277</span>brows, and the setting of the teeth, that the bodily actions
-developed are as great, though less obtrusive in their results.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;If we take emotions instead of sensations, we
-find the correlation and equivalence equally manifest. Not
-only are the modes of consciousness directly produced in us
-by physical forces, re-transformable into physical forces under
-the form of muscular motions and the changes they initiate;
-but the like is true of those modes of consciousness which are
-not directly produced in us by the physical forces. Emotions
-of moderate intensity, like sensations of moderate intensity,
-generate little beyond excitement of the heart and vascular
-system, joined sometimes with increased action of glandular
-organs. But as the emotions rise in strength, the muscles of
-the face, body, and limbs, begin to move. Of examples may
-be mentioned the frowns, dilated nostrils, and stampings of
-anger; the contracted brows, and wrung hands, of grief; the
-smiles and leaps of joy; and the frantic struggles of terror or
-despair. Passing over certain apparent, but only apparent,
-exceptions, we see that whatever be the kind of emotion,
-there is a manifest relation between its amount, and the
-amount of muscular action induced: alike from the erect
-carriage and elastic step of exhilaration, up to the dancings
-of immense delight, and from the fidgetiness of impatience
-up to the almost convulsive movements accompanying great
-mental agony. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;To these several orders of evidence
-must be joined the further one, that between our feelings and
-those voluntary motions into which they are transformed,
-there comes the sensation of muscular tension, standing in
-manifest correlation with both—a correlation that is distinctly
-quantitative: the sense of strain varying, other
-things equal, directly as the quantity of momentum
-generated.</p>
-
-<p class='c000'>“But how,” it may be asked, “can we interpret by the
-law of correlation the genesis of those thoughts and feelings
-which, instead of following external stimuli, arise spontaneously?
-Between the indignation caused by an insult, and the
-<span class='pageno' id='Page_278'>278</span>loud sounds or violent acts that follow, the alleged connexion
-may hold; but whence come the crowd of ideas and the mass
-of feelings that expend themselves in these demonstrations?
-They are clearly not equivalents of the sensations produced
-by the words on the ears; for the same words otherwise
-arranged, would not have caused them. The thing said
-bears to the mental action it excites, much the same relation
-that the pulling of a trigger bears to the subsequent explosion—does
-not produce the power, but merely liberates it.
-Whence then arises this immense amount of nervous energy
-which a whisper or a glance may call forth?” &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The
-reply is, that the immediate correlates of these and other such
-modes of consciousness, are not to be found in the agencies
-acting on us externally, but in certain internal agencies.
-The forces called vital, which we have seen to be correlates
-of the forces called physical, are the immediate sources of
-these thoughts and feelings; and are expended in producing
-them. The proofs of this are various. Here are some of
-them. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;It is a conspicuous fact that mental action is
-contingent on the presence of a certain nervous apparatus;
-and that, greatly obscured as it is by numerous and involved
-conditions, a general relation may be traced between the size
-of this apparatus and the quantity of mental action as measured
-by its results. Further, this apparatus has a particular
-chemical constitution on which its activity depends; and
-there is one element in it between the amount of which and
-the amount of function performed, there is an ascertained
-connexion: the proportion of phosphorus present in the brain
-being the smallest in infancy, old age and idiotcy, and the
-greatest during the prime of life. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Note next, that
-the evolution of thought and emotion varies, other things
-equal, with the supply of blood to the brain. On the one
-hand, a cessation of the cerebral circulation, from arrest of
-the heart’s action, immediately entails unconsciousness. On
-the other hand, excess of cerebral circulation (unless it is
-such as to cause undue pressure) results in an excitement
-<span class='pageno' id='Page_279'>279</span>rising finally to delirium. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Not the quantity only,
-but also the condition of the blood passing through the
-nervous system, influences the mental manifestations. The
-arterial currents must be duly aerated, to produce the normal
-amount of cerebration. At the one extreme, we find that if
-the blood is not allowed to exchange its carbonic acid for
-oxygen, there results asphyxia, with its accompanying stoppage
-of ideas and feelings. While at the other extreme, we
-find that by the inspiration of nitrous oxide, there is produced
-an excessive, and indeed irrepressible, nervous activity.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Besides the connexion between the development
-of the mental forces and the presence of sufficient
-oxygen in the cerebral arteries, there is a kindred connexion
-between the development of the mental forces and the presence
-in the cerebral arteries of certain other elements.
-There must be supplied special materials for the nutrition of
-the nervous centres, as well as for their oxidation. And how
-what we may call the quantity of consciousness, is, other things
-equal, determined by the constituents of the blood, is unmistakably
-seen in the exaltation that follows when certain
-chemical compounds, as alcohol and the vegeto-alkalies, are
-added to it. The gentle exhilaration which tea and coffee
-create, is familiar to all; and though the gorgeous imaginations
-and intense feelings of happiness produced by opium
-and hashish, have been experienced by few, (in this country
-at least,) the testimony of those who have experienced them
-is sufficiently conclusive. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Yet another proof that the
-genesis of the mental energies is immediately dependent on
-chemical change, is afforded by the fact, that the effete products
-separated from the blood by the kidneys, vary in character
-with the amount of cerebral action. Excessive activity
-of mind is habitually accompanied by the excretion of an unusual
-quantity of the alkaline phosphates. Conditions of
-abnormal nervous excitement bring on analogous effects.
-And the “peculiar odour of the insane,” implying as it does
-morbid products in the perspiration, shows a connexion between
-<span class='pageno' id='Page_280'>280</span>insanity and a special composition of the circulating
-fluids—a composition which, whether regarded as cause or
-consequence, equally implies correlation of the mental and
-the physical forces. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Lastly we have to note that this
-correlation too, is, so far as we can trace it, quantitative.
-Provided the conditions to nervous action are not infringed
-on, and the concomitants are the same, there is a tolerably
-constant ratio between the amounts of the antecedents and
-consequents. Within the implied limits, nervous stimulants
-and anæsthetics produce effects on the thoughts and feelings,
-proportionate to the quantities administered. And
-conversely, where the thoughts and feelings form the initial
-term of the relation, the degree of reaction on the bodily
-energies is great, in proportion as they are great: reaching
-in extreme cases a total prostration of physique.</p>
-
-<p class='c000'>Various classes of facts thus unite to prove that the law of
-metamorphosis, which holds among the physical forces,
-holds equally between them and the mental forces.
-Those modes of the Unknowable which we call motion,
-heat, light, chemical affinity, &amp;c., are alike transformable
-into each other, and into those modes of the
-Unknowable which we distinguish as sensation, emotion,
-thought: these, in their turns, being directly or indirectly
-re-transformable into the original shapes. That no idea or
-feeling arises, save as a result of some physical force expended
-in producing it, is fast becoming a common place of science;
-and whoever duly weighs the evidence will see, that nothing
-but an overwhelming bias in favour of a pre-conceived
-theory, can explain its non-acceptance. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;How this
-metamorphosis takes place—how a force existing as motion,
-heat, or light, can become a mode of consciousness—how it is
-possible for aerial vibrations to generate the sensation we call
-sound, or for the forces liberated by chemical changes in the
-brain to give rise to emotion—these are mysteries which it is
-impossible to fathom. But they are not profounder mysteries
-than the transformations of the physical forces into each other.
-<span class='pageno' id='Page_281'>281</span>They are not more completely beyond our comprehension
-than the natures of Mind and Matter. They have simply the
-same insolubility as all other ultimate questions. We can
-learn nothing more than that here is one of the uniformities
-in the order of phenomena.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 83. Of course if the law of correlation and equivalence
-holds of the forces we class as vital and mental, it must hold
-also of those which we class as social. Whatever takes place
-in a society is due to organic or inorganic agencies, or to
-a combination of the two—results either from the undirected
-physical forces around, from these physical forces as directed
-by men, or from the forces of the men themselves. No
-change can occur in its organization, its modes of activity, or
-the effects it produces on the face of the Earth, but what
-proceeds, mediately or immediately, from these. Let us consider
-first the correlation between the phenomena which
-societies display, and the vital phenomena.</p>
-
-<p class='c000'>Social power and life varies, other things equal, with the
-population. Though different races, differing widely in their
-fitness for combination, show us that the forces manifested in
-a society are not necessarily proportionate to the number of
-people; yet we see that under given conditions, the forces
-manifested are confined within the limits which the number
-of people imposes. A small society, no matter how superior
-the character of its members, cannot exhibit the same
-quantity of social action as a large one. The production and
-distribution of commodities must be on a comparatively small
-scale. A multitudinous press, a prolific literature, or a
-massive political agitation, is not possible. And there can
-be but a small total of results in the shape of art-products
-and scientific discoveries. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The correlation of the
-social with the physical forces through the intermediation of
-the vital ones, is, however, most clearly shown in the different
-amounts of activity displayed by the same society according
-as its members are supplied with different amounts of force
-<span class='pageno' id='Page_282'>282</span>from the external world. In the effects of good and bad
-harvests, we yearly see this relation illustrated. A greatly
-deficient yield of wheat is soon followed by a diminution of
-business. Factories are worked half-time, or close entirely;
-railway traffic falls; retailers find their sales much lessened;
-house-building is almost suspended; and if the scarcity
-rises to famine, a thinning of the population still more
-diminishes the industrial vivacity. Conversely, an unusually
-abundant harvest, occurring under conditions not otherwise
-unfavourable, both excites the old producing and distributing
-agencies and sets up new ones. The surplus social energy
-finds vent in speculative enterprises. Capital seeking investment
-carries out inventions that have been lying unutilized.
-Labour is expended in opening new channels of communication.
-There is increased encouragement to those who
-furnish the luxuries of life and minister to the æsthetic
-faculties. There are more marriages, and a greater rate of
-increase in population. Thus the social organism grows
-larger, more complex, and more active. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;When, as
-happens with most civilized nations, the whole of the materials
-for subsistence are not drawn from the area inhabited,
-but are partly imported, the people are still supported by
-certain harvests elsewhere grown at the expense of certain
-physical forces. Our own cotton-spinners and weavers supply
-the most conspicuous instance of a section in one nation living,
-in great part, on imported commodities, purchased by the
-labour they expend on other imported commodities. But
-though the social activities of Lancashire are due chiefly to
-materials not drawn from our own soil, they are none the less
-evolved from physical forces elsewhere stored up in fit forms
-and then brought here.</p>
-
-<p class='c000'>If we ask whence come these physical forces from which,
-through the intermediation of the vital forces, the social
-forces arise, the reply is of course as heretofore—the solar
-radiations. Based as the life of a society is on animal and
-vegetal products; and dependent as these animal and vegetal
-<span class='pageno' id='Page_283'>283</span>products are on the light and heat of the sun; it follows that
-the changes going on in societies are effects of forces having
-a common origin with those which produce all the other
-orders of changes that have been analyzed. Not only is the
-force expended by the horse harnessed to the plough, and by
-the labourer guiding it, derived from the same reservoir
-as is the force of the falling cataract and the roaring hurricane;
-but to this same reservoir are eventually traceable those
-subtler and more complex manifestations of force which
-humanity, as socially embodied, evolves. The assertion is a
-startling one, and by many will be thought ludicrous; but it
-is an unavoidable deduction which cannot here be passed over.</p>
-
-<p class='c000'>Of the physical forces that are directly transformed into
-social ones, the like is to be said. Currents of air and water,
-which before the use of steam were the only agencies brought
-in aid of muscular effort for the performance of industrial
-processes, are, as we have seen, generated by the heat of the
-sun. And the inanimate power that now, to so vast an
-extent, supplements human labour, is similarly derived. The
-late George Stephenson was one of the first to recognize the
-fact that the force impelling his locomotive, originally emanated
-from the sun. Step by step we go back—from the motion
-of the piston to the evaporation of the water; thence to
-the heat evolved during the oxidation of coal; thence to the
-assimilation of carbon by the plants of whose imbedded remains
-coal consists; thence to the carbonic acid from which
-their carbon was obtained; and thence to the rays of light
-that de-oxidized this carbonic acid. Solar forces millions of
-years ago expended on the Earth’s vegetation, and since
-locked up beneath its surface, now smelt the metals required
-for our machines, turn the lathes by which the machines are
-shaped, work them when put together, and distribute the
-fabrics they produce. And in so far as economy of labour
-makes possible the support of a larger population; gives a
-surplus of human power that would else be absorbed in
-manual occupations; and so facilitates the development of
-<span class='pageno' id='Page_284'>284</span>higher kinds of activity; it is clear that these social forces
-which are directly correlated with physical forces anciently
-derived from the sun, are only less important than those
-whose correlates are the vital forces recently derived from it.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 84. Regarded as an induction, the doctrine set forth in
-this chapter will most likely be met by a demurrer. Many
-who admit that among physical phenomena at least, the
-correlation of forces is now established, will probably say that
-inquiry has not yet gone far enough to enable us to predicate
-equivalence. And in respect of the forces classed as vital,
-mental, and social, the evidence assigned, however little to be
-explained away, they will consider by no means conclusive
-even of correlation, much less of equivalence.</p>
-
-<p class='c000'>To those who think thus, it must now however be pointed
-out, that the universal truth above illustrated under its various
-aspects, is a necessary corollary from the persistence of force.
-Setting out with the proposition that force can neither come
-into existence, nor cease to exist, the several foregoing
-general conclusions inevitably follow. Each manifestation of
-force can be interpreted only as the effect of some antecedent
-force: no matter whether it be an inorganic action, an
-animal movement, a thought, or a feeling. Either this must
-be conceded, or else it must be asserted that our successive
-states of consciousness are self-created. Either mental
-energies, as well as bodily ones, are quantitatively correlated
-to certain energies expended in their production, and to
-certain other energies which they initiate; or else nothing
-must become something and something must become nothing.
-The alternatives are, to deny the persistence of force, or to
-admit that every physical and psychial change is generated
-by certain antecedent forces, and that from given amounts of
-such forces neither more nor less of such physical and psychial
-changes can result. And since the persistence of force, being a
-datum of consciousness, cannot be denied, its unavoidable corollary
-must be accepted. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;This corollary cannot indeed be
-<span class='pageno' id='Page_285'>285</span>made more certain by accumulating illustrations. The truth as
-arrived at deductively, cannot be inductively confirmed. For
-every one of such facts as those above detailed, is established
-only through the indirect assumption of that persistence of
-force, from which it really follows as a direct consequence.
-The most exact proof of correlation and equivalence which it
-is possible to reach by experimental inquiry, is that based on
-measurement of the forces expended and the forces produced.
-But, as was shown in the last chapter, any such process of
-measurement implies the use of some unit of force which is
-assumed to remain constant; and for this assumption there
-can be no warrant but that it is a corollary from the persistence
-of force. How then can any reasoning based on this
-corollary, prove the equally direct corollary that when a given
-quantity of force ceases to exist under one form, an equal
-quantity must come into existence under some other form or
-forms? Clearly the <i><span lang="fr" xml:lang="fr">à priori</span></i> truth expressed in this last
-corollary, cannot be more firmly established by any <i><span lang="fr" xml:lang="fr">à posteriori</span></i>
-proofs which the first corollary helps us to.</p>
-
-<p class='c000'>“What then,” it may be asked, “is the use of these investigations
-by which the correlation and equivalence of forces is
-sought to be established as an inductive truth? Surely it
-will not be alleged that they are useless. Yet if this correlation
-cannot be made more certain by them than it is already,
-does not their uselessness necessarily follow?” No. They are
-of value as disclosing the many particular implications which
-the general truth does not specify. They are of value as
-teaching us how much of one mode of force is the equivalent
-of so much of another mode. They are of value as determining
-under what conditions each metamorphosis occurs. And
-they are of value as leading us to inquire in what shape
-the remnant of force has escaped, when the apparent results
-are not equivalent to the cause.</p>
-
-<div>
- <span class='pageno' id='Page_286'>286</span>
- <h3 class='c001'>CHAPTER X.<br /> <span class='large'>THE DIRECTION OF MOTION.</span></h3>
-</div>
-
-<p class='c006'>§ 85. The Absolute Cause of changes, inclusive of those
-constituting Evolution, is not less incomprehensible in respect
-of the unity or duality of its action, than in all other respects.
-We cannot decide between the alternative suppositions, that
-phenomena are due to the variously-conditioned workings of a
-single force, and that they are due to the conflict of two forces.
-Whether, as some contend, everything is explicable on the
-hypothesis of universal pressure, whence what we call tension
-results differentially from inequalities of pressure in opposite
-directions; or whether, as might be with equal propriety contended,
-things are to be explained on the hypothesis of universal
-tension, from which pressure is a differential result; or
-whether, as most physicists hold, pressure and tension everywhere
-co-exist; are questions which it is impossible to settle.
-Each of these three suppositions makes the facts comprehensible,
-only by postulating an inconceivability. To assume a
-universal pressure, confessedly requires us to assume an
-infinite plenum—an unlimited space full of something which
-is everywhere pressed by something beyond; and this
-assumption cannot be mentally realized. That universal
-tension is the immediate agency to which phenomena are
-due, is an idea open to a parallel and equally fatal objection.
-And however verbally intelligible may be the proposition that
-pressure and tension everywhere co-exist, yet we cannot truly
-<span class='pageno' id='Page_287'>287</span>represent to ourselves one ultimate unit of matter as drawing
-another while resisting it.</p>
-
-<p class='c000'>Nevertheless, this last belief is one which we are compelled
-to entertain. Matter cannot be conceived except as manifesting
-forces of attraction and repulsion. Body is distinguished
-in our consciousness from Space, by its opposition
-to our muscular energies; and this opposition we feel under
-the two-fold form of a cohesion that hinders our efforts to
-rend, and a resistance that hinders our efforts to compress.
-Without resistance there can be merely empty extension.
-Without cohesion there can be no resistance. Probably this
-conception of antagonistic forces, is originally derived from
-the antagonism of our flexor and extensor muscles. But be
-this as it may, we are obliged to think of all objects as made
-up of parts that attract and repel each other; since this is the
-form of our experience of all objects.</p>
-
-<p class='c000'>By a higher abstraction results the conception of attractive
-and repulsive forces pervading space. We cannot dissociate
-force from occupied extension, or occupied extension from
-force; because we have never an immediate consciousness of
-either in the absence of the other. Nevertheless, we have
-abundant proof that force is exercised through what appears
-to our senses a vacuity. Mentally to represent this
-exercise, we are hence obliged to fill the apparent vacuity
-with a species of matter—an etherial medium. The constitution
-we assign to this etherial medium, however, like the
-constitution we assign to solid substance, is necessarily an
-abstract of the impressions received from tangible bodies.
-The opposition to pressure which a tangible body offers to us,
-is not shown in one direction only, but in all directions; and
-so likewise is its tenacity. Suppose countless lines radiating
-from its centre on every side, and it resists along each of these
-lines and coheres along each of these lines. Hence the
-constitution of those ultimate units through the instrumentality
-of which phenomena are interpreted. Be they atoms
-of ponderable matter or molecules of ether, the properties we
-<span class='pageno' id='Page_288'>288</span>conceive them to possess are nothing else than these perceptible
-properties idealized. Centres of force attracting and
-repelling each other in all directions, are simply insensible
-portions of matter having the endowments common to sensible
-portions of matter—endowments of which we cannot by
-any mental effort divest them. In brief, they are the invariable
-elements of the conception of matter, abstracted from
-its variable elements—size, form, quality, &amp;c. And so to
-interpret manifestations of force which cannot be tactually
-experienced, we use the terms of thought supplied by our
-tactual experiences; and this for the sufficient reason that we
-must use these or none.</p>
-
-<p class='c000'>After all that has been before shown, and after the hint
-given above, it needs scarcely be said that these universally
-co-existent forces of attraction and repulsion, must not be
-taken as realities, but as our symbols of the reality. They
-are the forms under which the workings of the Unknowable
-are cognizable by us—modes of the Unconditioned as presented
-under the conditions of our consciousness. But while
-knowing that the ideas thus generated in us are not absolutely
-true, we may unreservedly surrender ourselves to them as relatively
-true; and may proceed to evolve a series of deductions
-having a like relative truth.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 86. From universally co-existent forces of attraction and
-repulsion, there result certain laws of direction of all movement.
-Where attractive forces alone are concerned, or
-rather are alone appreciable, movement takes place in the direction
-of their resultant; which may, in a sense, be called the
-line of greatest traction. Where repulsive forces alone are
-concerned, or rather are alone appreciable, movement takes
-place along their resultant; which is usually known as the line
-of least resistance. And where both attractive and repulsive
-forces are concerned, or are appreciable, movement takes
-place along the resultant of all the tractions and resistances.
-Strictly speaking, this last is the sole law; since, by the
-<span class='pageno' id='Page_289'>289</span>hypothesis, both forces are everywhere in action. But
-very frequently the one kind of force is so immensely in
-excess that the effect of the other kind may be left out of
-consideration. Practically we may say that a body falling
-to the Earth, follows the line of greatest traction; since,
-though the resistance of the air must, if the body be irregular,
-cause some divergence from this line, (quite perceptible with
-feathers and leaves,) yet ordinarily the divergence is so slight
-that we may omit it. In the same manner, though the course
-taken by the steam from an exploding boiler, differs somewhat
-from that which it would take were gravitation out of the question;
-yet, as gravitation affects its course infinitesimally, we are
-justified in asserting that the escaping steam follows the line of
-least resistance. Motion then, we may say, always follows the
-line of greatest traction, or the line of least resistance, or the
-resultant of the two: bearing in mind that though the last is
-alone strictly true, the others are in many cases sufficiently
-near the truth for practical purposes.</p>
-
-<p class='c000'>Movement set up in any direction is itself a cause of further
-movement in that direction, since it is the embodiment of a
-surplus force in that direction. This holds equally with the
-transit of matter through space, the transit of matter through
-matter, and the transit through matter of any kind of vibration.
-In the case of matter moving through space, this principle
-is expressed in the law of inertia—a law on which the
-calculations of physical astronomy are wholly based. In the
-case of matter moving through matter, we trace the same
-truth under the familiar experience that any breach made by
-one solid through another, or any channel formed by a fluid
-through a solid, becomes a route along which, other things
-equal, subsequent movements of like nature take place. And
-in the case of motion passing through matter under the form
-of an impulse communicated from part to part, the facts of
-magnetization go to show that the establishment of undulations
-along certain lines, determines their continuance along
-those lines.</p>
-
-<p class='c000'><span class='pageno' id='Page_290'>290</span>It further follows from the conditions, that the direction of
-movement can rarely if ever be perfectly straight. For
-matter in motion to pursue continuously the exact line in
-which it sets out, the forces of attraction and repulsion
-must be symmetrically disposed around its path; and the
-chances against this are infinitely great. The impossibility
-of making an absolutely true edge to a bar of metal—the
-fact that all which can be done by the best mechanical appliances,
-is to reduce the irregularities of such an edge to
-amounts that cannot be perceived without magnifiers—sufficiently
-exemplifies how, in consequence of the unsymmetrical
-distribution of forces around the line of movement, the movement
-is rendered more or less indirect. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;It may be
-well to add that in proportion as the forces at work are
-numerous and varied, the curve a moving body describes is
-necessarily complex: witness the contrast between the flight
-of an arrow and the gyrations of a stick tossed about by
-breakers.</p>
-
-<p class='c000'>We have now to trace these laws of direction of movement
-throughout the process of Evolution, under its various forms.
-We have to note how every change in the arrangement of
-parts, takes place along the line of greatest traction, of least
-resistance, or of their resultant; how the setting up of motion
-along a certain line, becomes a cause of its continuance along
-that line; how, nevertheless, change of relations to external
-forces, always renders this line indirect; and how the degree
-of its indirectness increases with every addition to the number
-of influences at work.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 87. If we assume the first stage in nebular condensation
-to be the precipitation into flocculi of denser matter previously
-diffused through a rarer medium, (a supposition both physically
-justified, and in harmony with certain astronomical observations,)
-we shall find that nebular motion is interpretable
-in pursuance of the above general laws. Each portion of such
-vapour-like matter must begin to move towards the common
-<span class='pageno' id='Page_291'>291</span>centre of gravity. The tractive forces which would of themselves
-carry it in a straight line to the centre of gravity, are
-opposed by the resistant forces of the medium through
-which it is drawn. The direction of movement must be the
-resultant of these—a resultant which, in consequence of the
-unsymmetrical form of the flocculus, must be a curve directed,
-not to the centre of gravity, but towards one side of it. And
-it may be readily shown that in an aggregation of such flocculi,
-severally thus moving, there must, by composition of
-forces, eventually result a rotation of the whole nebula in one
-direction.</p>
-
-<p class='c000'>Merely noting this hypothetical illustration for the purpose
-of showing how the law applies to the case of nebular evolution,
-supposing it to have taken place, let us pass to the phenomena
-of the Solar System as now exhibited. Here the
-general principles above set forth are every instant exemplified.
-Each planet and satellite has a momentum which
-would, if acting alone, carry it forward in the direction it is
-at any instant pursuing. This momentum hence acts as a
-resistance to motion in any other direction. Each planet and
-satellite, however, is drawn by a force which, if unopposed,
-would take it in a straight line towards its primary. And the
-resultant of these two forces is that curve which it describes—a
-curve manifestly consequent on the unsymmetrical distribution
-of the forces around its path. This path, when more
-closely examined, supplies us with further illustrations. For
-it is not an exact circle or ellipse; which it would be were the
-tangential and centripetal forces the only ones concerned.
-Adjacent members of the Solar System, ever varying in their
-relative positions, cause what we call perturbations; that is,
-slight divergences in various directions from that circle or
-ellipse which the two chief forces would produce. These perturbations
-severally show us in minor degrees, how the line of
-movement is the resultant of all the forces engaged; and how
-this line becomes more complicated in proportion as the
-forces are multiplied. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;If instead of the motions of the
-<span class='pageno' id='Page_292'>292</span>planets and satellites as wholes, we consider the motions of
-their parts, we meet with comparatively complex illustrations.
-Every portion of the Earth’s substance in its daily rotation,
-describes a curve which is in the main a resultant of that
-resistance which checks its nearer approach to the centre of
-gravity, that momentum which would carry it off at a tangent,
-and those forces of gravitation and cohesion which keep it
-from being so carried off. If this axial motion be compounded
-with the orbital motion, the course of each part is seen to be
-a much more involved one. And we find it to have a still
-greater complication on taking into account that lunar attraction
-which mainly produces the tides and the precession of
-the equinoxes.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 88. We come next to terrestrial changes: present ones
-as observed, and past ones as inferred by geologists. Let us
-set out with the hourly-occurring alterations in the Earth’s
-atmosphere; descend to the slower alterations in progress on
-its surface; and then to the still slower ones going on beneath.</p>
-
-<p class='c000'>Masses of air, absorbing heat from surfaces warmed by the
-sun, expand, and so lessen the weight of the atmospheric
-columns of which they are parts. Hence they offer to adjacent
-atmospheric columns, diminished lateral resistance; and these,
-moving in the directions of the diminished resistance, displace
-the expanded air; while this, pursuing an upward course, displays
-a motion along that line in which there is least pressure.
-When again, by the ascent of such heated masses from extended
-areas like the torrid zone, there is produced at the
-upper surface of the atmosphere, a protuberance beyond the
-limits of equilibrium—when the air forming this protuberance
-begins to overflow laterally towards the poles; it does
-so because, while the tractive force of the Earth is nearly the
-same, the lateral resistance is greatly diminished. And
-throughout the course of each current thus generated, as well
-as throughout the course of each counter-current flowing: into
-the vacuum that is left, the direction is always the resultant
-<span class='pageno' id='Page_293'>293</span>of the Earth’s tractive force and the resistance offered by the
-surrounding masses of air: modified only by conflict with
-other currents similarly determined, and by collision with
-prominences on the Earth’s crust. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The movements
-of water, in both its gaseous and liquid states, furnish further
-examples. In conformity with the mechanical theory of heat,
-it may be shown that evaporation is the escape of particles of
-water in the direction of least resistance; and that as the resistance
-(which is due to the pressure of the water diffused in
-a gaseous state) diminishes, the evaporation increases. Conversely,
-that rushing together of particles called condensation,
-which takes place when any portion of atmospheric vapour
-has its temperature much lowered, may be interpreted as a
-diminution of the mutual pressure among the condensing
-particles, while the pressure of surrounding particles remains
-the same; and so is a motion taking place in the direction of
-lessened resistance. In the course followed by the resulting
-rain-drops, we have one of the simplest instances of the joint
-effect of the two antagonist forces. The Earth’s attraction,
-and the resistance of atmospheric currents ever varying in
-direction and intensity, give as their resultants, lines which
-incline to the horizon in countless different degrees and undergo
-perpetual variations. More clearly still is the law exemplified
-by these same rain-drops when they reach the ground.
-In the course they take while trickling over its surface, in
-every rill, in every larger stream, and in every river, we see
-them descending as straight as the antagonism of surrounding
-objects permits. From moment to moment, the motion
-of water towards the Earth’s centre is opposed by the solid
-matter around and under it; and from moment to moment
-its route is the resultant of the lines of greatest traction and
-least resistance. So far from a cascade furnishing, as it seems
-to do, an exception, it furnishes but another illustration. For
-though all solid obstacles to a vertical fall of the water are
-removed, yet the water’s horizontal momentum is an obstacle;
-and the parabola in which the stream leaps from the projecting
-<span class='pageno' id='Page_294'>294</span>ledge, is generated by the combined gravitation and
-momentum. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;It may be well just to draw attention
-to the degree of complexity here produced in the line of
-movement by the variety of forces at work. In atmospheric
-currents, and still more clearly in water-courses (to which
-might be added ocean-streams), the route followed is too complex
-to be defined, save as a curve of three dimensions with
-an ever varying equation.</p>
-
-<p class='c000'>The Earth’s solid crust undergoes changes that supply another
-group of illustrations. The denudation of lands and
-the depositing of the removed sediment in new strata at the
-bottoms of seas and lakes, is a process throughout which motion
-is obviously determined in the same way as is that of the
-water effecting the transport. Again, though we have no
-direct inductive proof that the forces classed as igneous, expend
-themselves along lines of least resistance; yet what little
-we know of them is in harmony with the belief that they do
-so. Earthquakes continually revisit the same localities, and
-special tracts undergo for long periods together successive
-elevations or subsidences,—facts which imply that already-fractured
-portions of the Earth’s crust are those most prone
-to yield under the pressure caused by further contractions.
-The distribution of volcanoes along certain lines, as well as
-the frequent recurrence of eruptions from the same vents,
-are facts of like meaning.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 89. That organic growth takes place in the direction of
-least resistance, is a proposition that has been set forth and
-illustrated by Mr. James Hinton, in the <cite>Medico-Chirurgical
-Review</cite> for October, 1858. After detailing a few of the early
-observations which led him to this generalization, he formulates
-it thus:—</p>
-
-<p class='c000'>“Organic form is the result of motion.”</p>
-
-<p class='c000'>“Motion takes the direction of least resistance.”</p>
-
-<p class='c000'>“Therefore organic form is the result of motion in the
-direction of least resistance.”</p>
-
-<p class='c000'><span class='pageno' id='Page_295'>295</span>After an elucidation and defence of this position, Mr.
-Hinton proceeds to interpret, in conformity with it, sundry
-phenomena of development. Speaking of plants he
-says:—</p>
-
-<p class='c000'>“The formation of the root furnishes a beautiful illustration
-of the law of least resistance, for it grows by insinuating
-itself, cell by cell, through the interstices of the soil; it is by
-such minute additions that it increases, winding and twisting
-whithersoever the obstacles it meets in its path determine, and
-growing there most, where the nutritive materials are added
-to it most abundantly. As we look on the roots of a mighty
-tree, it appears to us as if they had forced themselves with
-giant violence into the solid earth. But it is not so; they
-were led on gently, cell added to cell, softly as the dews descended,
-and the loosened earth made way. Once formed, indeed,
-they expand with an enormous power, but the spongy
-condition of the growing radicles utterly forbids the supposition
-that they are forced into the earth. Is it not probable,
-indeed, that the enlargement of the roots already formed may
-crack the surrounding soil, and help to make the interstices
-into which the new rootlets grow?” *&nbsp;*&nbsp;*</p>
-
-<p class='c000'>“Throughout almost the whole of organic nature the spiral
-form is more or less distinctly marked. Now, motion under
-resistance takes a spiral direction, as may be seen by the motion
-of a body rising or falling through water. A bubble
-rising rapidly in water describes a spiral closely resembling
-a corkscrew, and a body of moderate specific gravity dropped
-into water may be seen to fall in a curved direction, the
-spiral tendency of which may be distinctly observed.
-*&nbsp;*&nbsp;* In this prevailing spiral form of organic
-bodies, therefore, it appears to me, that there is presented a
-strong <i><span lang="la" xml:lang="la">prima facie</span></i> case for the view I have maintained.
-*&nbsp;*&nbsp;* The spiral form of the branches of many
-trees is very apparent, and the universally spiral arrangement
-of the leaves around the stem of plants needs only to be referred
-to. *&nbsp;*&nbsp;* The heart commences as a spiral turn,
-<span class='pageno' id='Page_296'>296</span>and in its perfect form a manifest spiral may be traced through
-the left ventricle, right ventricle, right auricle, left auricle
-and appendix. And what is the spiral turn in which the
-heart commences but a necessary result of the lengthening,
-under a limit, of the cellular mass of which it then consists?”
-*&nbsp;*&nbsp;*</p>
-
-<p class='c000'>“Every one must have noticed the peculiar curling up of
-the young leaves of the common fern. The appearance is as
-if the leaf were rolled up, but in truth this form is merely a
-phenomenon of growth. The curvature results from the increase
-of the leaf, it is only another form of the wrinkling up,
-or turning at right angles by extension under limit.”</p>
-
-<p class='c000'>“The rolling up or imbrication of the petals in many flower-buds
-is a similar thing; at an early period the small petals
-may be seen lying side by side, afterwards growing within the
-capsule, they become folded round one another.” *&nbsp;*&nbsp;*</p>
-
-<p class='c000'>“If a flower-bud be opened at a sufficiently early period,
-the stamens will be found as if moulded in the cavity between
-the pistil and the corolla, which cavity the antlers exactly
-fill; the stalks lengthen at an after period. I have noticed
-also in a few instances, that in those flowers in which the
-petals are imbricated, or twisted together, the pistil is tapering
-as growing up between the petals; in some flowers which
-have the petals so arranged in the bud as to form a dome (as
-the hawthorn; e. g.), the pistil is flattened at the apex, and
-in the bud occupies a space precisely limited by the stamens
-below, and the enclosing petals above and at the sides. I
-have not, however, satisfied myself that this holds good in all
-cases.”</p>
-
-<p class='c000'>Without endorsing all Mr. Hinton’s illustrations, to
-some of which exception might be taken, his conclusion
-may be accepted as a large instalment of the truth. It is,
-however, to be remarked, that in the case of organic growth,
-as in all other cases, the line of movement is in strictness
-the resultant of tractive and resistant forces; and that
-the tractive forces here form so considerable an element
-<span class='pageno' id='Page_297'>297</span>that the formula is scarcely complete without them. The
-shapes of plants are manifestly modified by gravitation:
-the direction of each branch is not what it would have been
-were the tractive force of the Earth absent; and every flower
-and leaf is somewhat altered in the course of development by
-the weight of its parts. Though in animals such effects are
-less conspicuous, yet the instances in which flexible organs
-have their directions in great measure determined by gravity,
-justify the assertion that throughout the whole organism the
-forms of parts must be affected by this force.</p>
-
-<p class='c000'>The organic movements which constitute growth, are not,
-however, the only organic movements to be interpreted.
-There are also those which constitute function. And throughout
-these the same general principles are discernible. That
-the vessels along which blood, lymph, bile, and all the
-secretions, find their ways, are channels of least resistance,
-is a fact almost too conspicuous to be named as an illustration.
-Less conspicuous, however, is the truth, that the currents setting
-along these vessels are affected by the tractive force of
-the Earth: witness varicose veins; witness the relief to an
-inflamed part obtained by raising it; witness the congestion
-of head and face produced by stooping. And in the fact that
-dropsy in the legs gets greater by day and decreases at night,
-while, conversely, that œdematous fullness under the eyes
-common in debility, grows worse during the hours of reclining
-and decreases after getting up, shows us how the transudation
-of fluid through the walls of the capillaries, varies according
-as change of position changes the effect of gravity in
-different parts of the body.</p>
-
-<p class='c000'>It may be well in passing just to note the bearing of the
-principle on the development of species. From a dynamic
-point of view, “natural selection” is the evolution of Life
-along lines of least resistance. The multiplication of any kind
-of plant or animal in localities that are favourable to it, is a
-growth where the antagonistic forces are less than elsewhere.
-And the preservation of varieties that succeed better than their
-<span class='pageno' id='Page_298'>298</span>allies in coping with surrounding conditions, is the continuance
-of vital movement in those directions where the obstacles
-to it are most eluded.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 90. Throughout the phenomena of mind the law enunciated
-is not so readily established. In a large part of them,
-as those of thought and emotion, there is no perceptible movement.
-Even in sensation and volition, which show us in one
-part of the body an effect produced by a force applied to another
-part, the intermediate movement is inferential rather
-than visible. Such indeed are the difficulties that it is not
-possible here to do more than briefly indicate the proofs which
-might be given did space permit.</p>
-
-<p class='c000'>Supposing the various forces throughout an organism to be
-previously in equilibrium, then any part which becomes the
-seat of a further force, added or liberated, must be one from
-which the force, being resisted by smaller forces around, will
-initiate motion towards some other part of the organism. If
-elsewhere in the organism there is a point at which force is
-being expended, and which so is becoming minus a force which
-it before had, instead of plus a force which it before had not,
-and thus is made a point at which the re-action against surrounding
-forces is diminished; then, manifestly, a motion taking
-place between the first and the last of these points is a
-motion along the line of least resistance. Now a sensation
-implies a force added to, or evolved in, that part of the organism
-which is its seat; while a mechanical movement implies
-an expenditure or loss of force in that part of the organism
-which is its seat. Hence if, as we find to be the fact, motion is
-habitually propagated from those parts of an organism to which
-the external world adds forces in the shape of nervous impressions,
-to those parts of an organism which react on the external
-world through muscular contractions, it is simply a fulfilment
-of the law above enunciated. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;From this general
-conclusion we may pass to a more special one. When there
-is anything in the circumstances of an animal’s life, involving
-<span class='pageno' id='Page_299'>299</span>that a sensation in one particular place is habitually followed
-by a contraction in another particular place—when there is
-thus a frequently-repeated motion through the organism between
-these places; what must be the result as respects the
-line along which the motions take place? Restoration of equilibrium
-between the points at which the forces have been
-increased and decreased, must take place through some channel.
-If this channel is affected by the discharge—if the
-obstructive action of the tissues traversed, involves any
-reaction upon them, deducting from their obstructive
-power; then a subsequent motion between these two points
-will meet with less resistance along this channel than the previous
-motion met with; and will consequently take this
-channel still more decidedly. If so, every repetition will still
-further diminish the resistance offered by this route; and
-hence will gradually be formed between the two a permanent
-line of communication, differing greatly from the surrounding
-tissue in respect of the ease with which force traverses it. We
-see, therefore, that if between a particular impression and a
-particular motion associated with it, there is established a
-connexion producing what is called reflex action, the law that
-motion follows the line of least resistance, and that, if the
-conditions remain constant, resistance in any direction is diminished
-by motion occurring in that direction, supplies an explanation.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Without further details it will be manifest that
-a like interpretation may be given to the succession of all
-other nervous changes. If in the surrounding world there
-are objects, attributes, or actions, that usually occur together,
-the effects severally produced by them in the organism will become
-so connected by those repetitions which we call experience,
-that they also will occur together. In proportion to the frequency
-with which any external connexion of phenomena is
-experienced, will be the strength of the answering internal connexion
-of nervous states. Thus there will arise all degrees of
-cohesion among nervous states, as there are all degrees of commonness
-among the surrounding co-existences and sequences
-<span class='pageno' id='Page_300'>300</span>that generate them: whence must result a general correspondence
-between associated ideas and associated actions in the
-environment.<a id='r13' /><a href='#f13' class='c011'><sup>[13]</sup></a></p>
-
-<p class='c000'>The relation between emotions and actions may be similarly
-construed. As a first illustration let us observe what happens
-with emotions that are undirected by volitions. These, like
-feelings in general, expend themselves in generating organic
-changes, and chiefly in muscular contractions. As was
-pointed out in the last chapter, there result movements of
-the involuntary and voluntary muscles, that are great in proportion
-as the emotions are strong. It remains here to be
-pointed out, however, that the order in which these muscles
-are affected is explicable only on the principle above set forth.
-Thus, a pleasurable or painful state of mind of but slight
-intensity, does little more than increase the pulsations of the
-heart. Why? For the reason that the relation between
-nervous excitement and vascular contraction, being common
-to every genus and species of feeling, is the one of most
-frequent repetition; that hence the nervous connexion is, in
-the way above shown, the one which offers the least resistance
-to a discharge; and is therefore the one along which a feeble
-force produces motion. A sentiment or passion that is somewhat
-stronger, affects not only the heart but the muscles of
-the face, and especially those around the mouth. Here the
-like explanation applies; since these muscles, being both comparatively
-small, and, for purposes of speech, perpetually
-used, offer less resistance than other voluntary muscles
-to the nerve-motor force. By a further increase of emotion
-the respiratory and vocal muscles become perceptibly excited.
-Finally, under strong passion, the muscles in general of the
-trunk and limbs are violently contracted. Without saying
-that the facts can be thus interpreted in all their details (a
-<span class='pageno' id='Page_301'>301</span>task requiring data impossible to obtain) it may be safely said
-that the order of excitation is from muscles that are small and
-frequently acted on, to those which are larger and less frequently
-acted on. The single instance of laughter, which is
-an undirected discharge of feeling that affects first the
-muscles round the mouth, then those of the vocal and respiratory
-apparatus, then those of the limbs, and then those of
-the spine;<a id='r14' /><a href='#f14' class='c011'><sup>[14]</sup></a> suffices to show that when no special route is
-opened for it, a force evolved in the nervous centres produces
-motion along channels which offer the least resistance, and if
-it is too great to escape by these, produces motion along
-channels offering successively greater resistance.</p>
-
-<p class='c000'>Probably it will be thought impossible to extend this
-reasoning so as to include volitions. Yet we are not without
-evidence that the transition from special desires to special
-muscular acts, conforms to the same principle. It may be
-shown that the mental antecedents of a voluntary movement,
-are antecedents which temporarily make the line along which
-this movement takes place, the line of least resistance. For
-a volition, suggested as it necessarily is by some previous
-thought connected with it by associations that determine the
-transition, is itself a representation of the movements that are
-willed, and of their sequences. But to represent in consciousness
-certain of our own movements, is partially to arouse the
-sensations accompanying such movements, inclusive of those
-of muscular tension—is partially to excite the appropriate
-motor-nerves and all the other nerves implicated. That is to
-say, the volition is itself an incipient discharge along a line
-which previous experiences have rendered a line of least resistance.
-And the passing of volition into action is simply a
-completion of the discharge.</p>
-
-<p class='c000'>One corollary from this must be noted before proceeding;
-namely, that the particular set of muscular movements by
-which any object of desire is reached, are movements implying
-<span class='pageno' id='Page_302'>302</span>the smallest total of forces to be overcome. As each feeling
-generates motion along the line of least resistance, it is
-tolerably clear that a group of feelings, constituting a more
-or less complex desire, will generate motion along a series of
-lines of least resistance. That is to say, the desired end will
-be achieved with the smallest expenditure of effort. Should
-it be objected that through want of knowledge or want of
-skill, a man often pursues the more laborious of two courses,
-and so overcomes a larger total of opposing forces than was
-necessary; the reply is, that relatively to his mental state the
-course he takes is that which presents the fewest difficulties.
-Though there is another which in the abstract is easier, yet
-his ignorance of it, or inability to adopt it, is, physically considered,
-the existence of an insuperable obstacle to the discharge
-of his energies in that direction. Experience obtained
-by himself, or communicated by others, has not established
-in him such channels of nervous communication as are required
-to make this better course the course of least resistance
-to him.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 91. As in individual animals, inclusive of man, motion
-follows lines of least resistance, it is to be inferred that among
-aggregations of men, the like will hold good. The changes
-in a society, being due to the joint actions of its members, the
-courses of such changes will be determined as are those of all
-other changes wrought by composition of forces.</p>
-
-<p class='c000'>Thus when we contemplate a society as an organism, and
-observe the direction of its growth, we find this direction to
-be that in which the average of opposing forces is the least.
-Its units have energies to be expended in self-maintenance
-and reproduction. These energies are met by various
-environing energies that are antagonistic to them—those of
-geological origin, those of climate, of wild animals, of other
-human races with whom they are at enmity or in competition.
-And the tracts the society spreads over, are those in
-which there is the smallest total antagonism. Or, reducing
-<span class='pageno' id='Page_303'>303</span>the matter to its ultimate terms, we may say that these social
-units have jointly and severally to preserve themselves and
-their offspring from those inorganic and organic forces which
-are ever tending to destroy them (either indirectly by oxidation
-and by undue abstraction of heat, or directly by bodily
-mutilation); that these forces are either counteracted by
-others which are available in the shape of food, clothing,
-habitations, and appliances of defence, or are, as far as may
-be, eluded; and that population spreads in whichever directions
-there is the readiest escape from these forces, or the
-least exertion in obtaining the materials for resisting them,
-or both. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;For these reasons it happens that fertile
-valleys where water and vegetal produce abound, are early
-peopled. Sea-shores, too, supplying a large amount of easily-gathered
-food, are lines along which mankind have commonly
-spread. The general fact that, so far as we can judge from
-the traces left by them, large societies first appeared in those
-tropical regions where the fruits of the earth are obtainable
-with comparatively little exertion, and where the cost of
-maintaining bodily heat is but slight, is a fact of like meaning.
-And to these instances may be added the allied one
-daily furnished by emigration; which we see going on towards
-countries presenting the fewest obstacles to the
-self-preservation of individuals, and therefore to national
-growth. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Similarly with that resistance to the movements
-of a society which neighbouring societies offer. Each
-of the tribes or nations inhabiting any region, increases in
-numbers until it outgrows its means of subsistence. In each
-there is thus a force ever pressing outwards on to adjacent
-areas—a force antagonized by like forces in the tribes or
-nations occupying those areas. And the ever-recurring wars
-that result—the conquests of weaker tribes or nations, and
-the over-running of their territories by the victors, are
-instances of social movements taking place in the directions
-of least resistance. Nor do the conquered peoples, when
-they escape extermination or enslavement, fail to show us
-<span class='pageno' id='Page_304'>304</span>movements that are similarly determined. For migrating as
-they do to less fertile regions—taking refuge in deserts or
-among mountains—moving in a direction where the resistance
-to social growth is comparatively great; they still do
-this only under an excess of pressure in all other directions:
-the physical obstacles to self-preservation they encounter,
-being really less than the obstacles offered by the enemies
-from whom they fly.</p>
-
-<p class='c000'>Internal social movements may also be thus interpreted.
-Localities naturally fitted for producing particular commodities—that
-is, localities in which such commodities are got at
-the least cost of force—that is, localities in which the desires
-for these commodities meet with the least resistance; become
-localities especially devoted to the obtainment of these commodities.
-Where soil and climate render wheat a profitable
-crop, or a crop from which the greatest amount of life-sustaining
-power is gained by a given quantity of effort, the growth
-of wheat becomes the dominant industry. Where wheat cannot
-be economically produced, oats, or rye, or maize, or rice,
-or potatoes, is the agricultural staple. Along sea-shores men
-support themselves with least effort by catching fish; and
-hence choose fishing as an occupation. And in places that
-are rich in coal or metallic ores, the population, finding that
-labour devoted to the raising of these materials brings a
-larger return of food and clothing than when otherwise directed,
-becomes a population of miners. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;This last
-instance introduces us to the phenomena of exchange; which
-equally illustrate the general law. For the practice of
-barter begins as soon as it facilitates the fulfilment of men’s
-desires, by diminishing the exertion needed to reach the objects
-of those desires. When instead of growing his own
-corn, weaving his own cloth, sewing his own shoes, each man
-began to confine himself to farming, or weaving, or shoemaking;
-it was because each found it more laborious to make
-everything he wanted, than to make a great quantity of one
-thing and barter the surplus for the rest: by exchange, each
-<span class='pageno' id='Page_305'>305</span>procured the necessaries of life without encountering so much
-resistance. Moreover, in deciding what commodity to produce,
-each citizen was, as he is at the present day, guided in
-the same manner. For besides those local conditions which
-determine whole sections of a society towards the industries
-easiest for them, there are also individual conditions and individual
-aptitudes which to each citizen render certain occupations
-preferable; and in choosing those forms of activity
-which their special circumstances and faculties dictate,
-these social units are severally moving towards the objects
-of their desires in the directions which present to them the
-fewest obstacles. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The process of transfer which commerce
-pre-supposes, supplies another series of examples. So
-long as the forces to be overcome in procuring any necessary
-of life in the district where it is consumed, are less than the
-forces to be overcome in procuring it from an adjacent district,
-exchange does not take place. But when the adjacent
-district produces it with an economy that is not out-balanced
-by cost of transit—when the distance is so small and the
-route so easy that the labour of conveyance plus the labour
-of production is less than the labour of production in the consuming
-district, transfer commences. Movement in the direction
-of least resistance is also seen in the establishment of
-the channels along which intercourse takes place. At the
-outset, when goods are carried on the backs of men and
-horses, the paths chosen are those which combine shortness
-with levelness and freedom from obstacles—those which are
-achieved with the smallest exertion. And in the subsequent
-formation of each highway, the course taken is that which
-deviates horizontally from a straight line so far only as is
-needful to avoid vertical deviations entailing greater labour
-in draught. The smallest total of obstructive forces determines
-the route, even in seemingly exceptional cases; as
-where a detour is made to avoid the opposition of a landowner.
-All subsequent improvements, ending in macadamized
-roads, canals, and railways, which reduce the antagonism
-<span class='pageno' id='Page_306'>306</span>of friction and gravity to a minimum, exemplify
-the same truth. After there comes to be a choice of roads
-between one point and another, we still see that the road
-chosen is that along which the cost of transit is the least:
-cost being the measure of resistance. Even where, time being
-a consideration, the more expensive route is followed, it is so
-because the loss of time involves loss of force. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;When,
-division of labour having been carried to a considerable extent
-and means of communication made easy, there arises a
-marked localization of industries, the relative growths of the
-populations devoted to them may be interpreted on the same
-principle. The influx of people to each industrial centre, as
-well as the rate of multiplication of those already inhabiting
-it, is determined by the payment for labour; that is—by the
-quantity of commodities which a given amount of effort will
-obtain. To say that artisans flock to places where, in consequence
-of facilities for production, an extra proportion of produce
-can be given in the shape of wages; is to say that they
-flock to places where there are the smallest obstacles to the
-support of themselves and families. Hence, the rapid increase
-of number which occurs in such places, is really a
-social growth at points where the opposing forces are the
-least.</p>
-
-<p class='c000'>Nor is the law less clearly to be traced in those functional
-changes daily going on. The flow of capital into businesses
-yielding the largest returns; the buying in the cheapest
-market and selling in the dearest; the introduction of more
-economical modes of manufacture; the development of better
-agencies for distribution; and all those variations in the
-currents of trade that are noted in our newspapers and telegrams
-from hour to hour; exhibit movement taking place in
-directions where it is met by the smallest total of opposing
-forces. For if we analyze each of these changes—if instead
-of interest on capital we read surplus of products which remains
-after maintenance of labourers; if we so interpret
-large interest or large surplus to imply labour expended with
-<span class='pageno' id='Page_307'>307</span>the greatest results; and if labour expended with the greatest
-results means muscular action so directed as to evade obstacles
-as far as possible; we see that all these commercial
-phenomena are complicated motions set up along lines of
-least resistance.</p>
-
-<p class='c000'>Objections of two opposite kinds will perhaps be made to
-these sociological applications of the law. By some it may
-be said that the term force as here used, is used metaphorically—that
-to speak of men as <em>impelled</em> in certain directions
-by certain desires, is a figure of speech and not the statement
-of a physical fact. The reply is, that the foregoing illustrations
-are to be interpreted literally, and that the processes described
-<em>are</em> physical ones. The pressure of hunger is an
-actual force—a sensation implying some state of nervous tension;
-and the muscular action which the sensation prompts
-is really a discharge of it in the shape of bodily motion—a
-discharge which, on analyzing the mental acts involved, will
-be found to follow lines of least resistance. Hence the
-motions of a society whose members are impelled by this or
-any other desire, are actually, and not metaphorically, to be
-understood in the manner shown. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;An opposite objection
-may possibly be, that the several illustrations given
-are elaborated truisms; and that the law of direction of motion
-being once recognized, the fact that social movements,
-in common with all others, must conform to it, follows inevitably.
-To this it may be rejoined, that a mere abstract assertion
-that social movements must do this, would carry no conviction
-to the majority; and that it is needful to show <em>how</em>
-they do it. For social evolution to be interpreted after the
-method proposed, it is requisite that such generalisations as
-those of political economy shall be reduced to equivalent propositions
-expressed in terms of force and motion.</p>
-
-<p class='c000'>Social movements of these various orders severally conform
-to the two derivative principles named at the outset. In the
-first place we may observe how, once set up in given directions,
-such movements, like all others, tend to continue in
-<span class='pageno' id='Page_308'>308</span>these directions. A commercial mania or panic, a current
-of commodities, a social custom, a political agitation, or a
-popular delusion, maintains its course for a long time after its
-original source has ceased; and requires antagonistic forces
-to arrest it. In the second place it is to be noted that in
-proportion to the complexity of social forces is the tortuousness
-of social movements. The involved series of muscular
-contractions gone through by the artizan, that he may get
-the wherewithal to buy a loaf lying at the baker’s next door,
-show us how extreme becomes the indirectness of motion
-when the agencies at work become very numerous—a truth
-still better illustrated by the more public social actions; as
-those which end in bringing a successful man of business,
-towards the close of his life, into parliament.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 92. And now of the general truth set forth in this
-chapter, as of that dealt with in the last, let us ask—what is
-our ultimate evidence? Must we accept it simply as an empirical
-generalization? or is it to be established as a corollary
-from a still deeper truth? The reader will anticipate the
-answer. We shall find it deducible from that datum of
-consciousness which underlies all science.</p>
-
-<p class='c000'>Suppose several tractive forces, variously directed, to be acting
-on a given body. By what is known among mathematicians
-as the composition of forces, there may be found for
-any two of these, a single force of such amount and direction
-as to produce on the body an exactly equal effect. If in the
-direction of each of them there be drawn a straight line,
-and if the lengths of these two straight lines be made proportionate
-to the amounts of the forces; and if from the end
-of each line there be drawn a line parallel to the other, so
-as to complete a parallelogram; then the diagonal of this
-parallelogram represents the amount and direction of a force
-that is equivalent to the two. Such a resultant force, as it is
-called, may be found for any pair of forces throughout the
-group. Similarly, for any pair of such resultants a single
-<span class='pageno' id='Page_309'>309</span>resultant may be found. And by repeating this course, all of
-them may be reduced to two. If these two are equal and
-opposite—that is, if there is no line of greatest traction,
-motion does not take place. If they are opposite but not
-equal, motion takes place in the direction of the greater.
-And if they are neither equal nor opposite, motion takes
-place in the direction of their resultant. For in either of
-these cases there is an unantagonized force in one direction.
-And this residuary force that is not neutralized by an opposing
-one, must move the body in the direction in which it is
-acting. To assert the contrary is to assert that a force can
-be expended without effect—without generating an equivalent
-force; and by so implying that force can cease to exist,
-this involves a denial of the persistence of force. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;It
-needs scarcely be added that if in place of tractions we take
-resistances, the argument equally holds; and that it holds also
-where both tractions and resistances are concerned. Thus
-the law that motion follows the line of greatest traction, or
-the line of least resistance, or the resultant of the two, is a
-necessary deduction from that primordial truth which transcends
-proof.</p>
-
-<p class='c000'>Reduce the proposition to its simplest form, and it becomes
-still more obviously consequent on the persistence of force.
-Suppose two weights suspended over a pulley or from the ends
-of an equal-armed lever; or better still—suppose two men
-pulling against each other. In such cases we say that the
-heavier weight will descend, and that the stronger man
-will draw the weaker towards him. But now, if we are asked
-how we know which is the heavier weight or the stronger
-man; we can only reply that it is the one producing motion
-in the direction of its pull. Our only evidence of excess of
-force is the movement it produces. But if of two opposing
-tractions we can know one as greater than the other only by
-the motion it generates in its own direction, then the assertion
-that motion occurs in the direction of greatest traction is a
-truism. When, going a step further back, we seek a warrant
-<span class='pageno' id='Page_310'>310</span>for the assumption that of the two conflicting forces, that is
-the greater which produces motion in its own direction, we
-find no other than the consciousness that such part of the
-greater force as is unneutralized by the lesser, must produce
-its effect—the consciousness that this residuary force cannot
-disappear, but must manifest itself in some equivalent change—the
-consciousness that force is persistent. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Here too,
-as before, it may be remarked that no amount of varied illustrations,
-like those of which this chapter mainly consists, can
-give greater certainty to the conclusion thus immediately
-drawn from the ultimate datum of consciousness. For in all
-cases, as in the simple ones just given, we can identify the
-greatest force only by the resulting motion. It is impossible
-for us ever to get evidence of the occurrence of motion in any
-other direction than that of the greatest force; since our
-measure of relative greatness among forces is their relative
-power of generating motion. And clearly, while the comparative
-greatness of forces is thus determined, no multiplication
-of instances can add certainty to a law of direction of movement
-which follows immediately from the persistence of force.</p>
-
-<p class='c000'>From this same primordial truth, too, may be deduced the
-principle that motion once set up along any line, becomes itself
-a cause of subsequent motion along that line. The mechanical
-axiom that, if left to itself, matter moving in any direction
-will continue in that direction with undiminished
-velocity, is but an indirect assertion of the persistence of
-force; since it is an assertion that the force manifested in
-the transfer of a body along a certain length of a certain
-line in a certain time, cannot disappear without producing
-some equal manifestation—a manifestation which, in the absence
-of conflicting forces, must be a further transfer in the
-same direction at the same velocity. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;In the case of
-matter traversing matter the like inference is necessitated.
-Here indeed the actions are much more complicated. A liquid
-that follows a certain channel through or over a solid, as water
-along the Earth’s surface, loses part of its motion in the shape
-<span class='pageno' id='Page_311'>311</span>of heat, through friction and collision with the matters forming
-its bed. A further amount of its motion may be absorbed
-in overcoming forces which it liberates; as when it loosens a
-mass which falls into, and blocks up, its channel. But after
-these deductions by transformation into other modes of force,
-any further deduction from the motion of the water is at the
-expense of a reaction on the channel, which by so much diminishes
-its obstructive power: such reaction being shown in
-the motion acquired by the detached portions which are carried
-away. The cutting out of river-courses is a perpetual
-illustration of this truth. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Still more involved is the
-case of motion passing through matter by impulse from part
-to part; as a nervous discharge through animal tissue. Some
-chemical change may be wrought along the route traversed,
-which may render it less fit than before for conveying a current.
-Or the motion may itself be in part metamorphosed into some
-obstructive form of force; as in metals, the conducting power
-of which is, for the time, decreased by the heat which the
-passage of electricity itself generates. The real question is,
-however, what structural modification, if any, is produced
-throughout the matter traversed, apart from <em>incidental</em> disturbing
-forces—apart from everything but the <em>necessary</em> resistance
-of the matter: that, namely, which results from the
-inertia of its units. If we confine our attention to that
-part of the motion which, escaping transformation, continues
-its course, then it is a corollary from the persistence of
-force that as much of this remaining motion as is taken
-up in changing the positions of the units, must leave these by
-so much less able to obstruct subsequent motion in the same
-direction.</p>
-
-<p class='c000'>Thus in all the changes heretofore and at present displayed
-by the Solar System; in all those that have gone on and are
-still going on in the Earth’s crust; in all processes of organic
-development and function; in all mental actions and the
-effects they work on the body; and in all modifications of
-structure and activity in societies; the implied movements are
-<span class='pageno' id='Page_312'>312</span>of necessity determined in the manner above set forth. Every
-alteration in the arrangement of parts, constituting Evolution
-under each of its phases, must conform to this universal principle.
-Wherever we see motion, its direction must be that of
-the greatest force. And wherever we see the greatest force
-to be acting in a given direction, in that direction motion must
-ensue.</p>
-
-<hr class='c015' />
-
-<div class='footnote' id='f13'>
-<p class='c000'><span class='label'><a href='#r13'>13</a>.&nbsp;&nbsp;</span>This paragraph is a re-statement, somewhat amplified, of an idea set forth in
-the <cite>Medico-Chirurgical Review</cite> for January, 1859 (pp. 189 and 190); and contains
-the germ of the intended fifth part of the <cite>Principles of Psychology</cite>, which
-was withheld for the reasons given in the preface to that work.</p>
-</div>
-
-<div class='footnote' id='f14'>
-<p class='c000'><span class='label'><a href='#r14'>14</a>.&nbsp;&nbsp;</span>For details see a paper on “The Physiology of Laughter,” published in
-<cite>Macmillan’s Magazine</cite> for March 1860.</p>
-</div>
-
-<div>
- <span class='pageno' id='Page_313'>313</span>
- <h3 class='c001'>CHAPTER XI.<br /> <span class='large'>THE RHYTHM OF MOTION.</span></h3>
-</div>
-
-<p class='c006'>§ 93. When the pennant of a vessel lying becalmed first
-shows the coming breeze, it does so by gentle undulations
-that travel from its fixed to its free end. Presently the sails
-begin to flap; and their blows against the mast increase in
-rapidity as the breeze rises. Even when, being fully bellied
-out, they are in great part steadied by the strain of the yards
-and cordage, their free edges tremble with each stronger
-gust. And should there come a gale, the jar that is felt on
-laying hold of the shrouds shows that the rigging vibrates;
-while the rush and whistle of the wind prove that in it, also,
-rapid undulations are generated. Ashore the conflict between
-the current of air and the things it meets results in a like
-rhythmical action. The leaves all shiver in the blast; each
-branch oscillates; and every exposed tree sways to and fro.
-The blades of grass and dried bents in the meadows, and still
-better the stalks in the neighbouring corn-fields, exhibit the
-same rising and falling movement. Nor do the more stable
-objects fail to do the like, though in a less manifest fashion;
-as witness the shudder that may be felt throughout a house
-during the paroxysms of a violent storm. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Streams of
-water produce in opposing objects the same general effects as
-do streams of air. Submerged weeds growing in the middle
-of a brook, undulate from end to end. Branches brought
-down by the last flood, and left entangled at the bottom
-<span class='pageno' id='Page_314'>314</span>where the current is rapid, are thrown into a state of up and
-down movement that is slow or quick in proportion as they
-are large or small; and where, as in great rivers like the
-Mississippi, whole trees are thus held, the name “sawyers,”
-by which they are locally known, sufficiently describes the
-rhythm produced in them. Note again the effect of the
-antagonism between the current and its channel. In shallow
-places, where the action of the bottom on the water flowing
-over it is visible, we see a ripple produced—a series of undulations.
-And if we study the action and re-action going on
-between the moving fluid and its banks, we still find the
-principle illustrated, though in a different way. For in every
-rivulet, as in the mapped-out course of every great river, the
-bends of the stream from side to side throughout its tortuous
-course constitute a lateral undulation—an undulation so inevitable
-that even an artificially straightened channel is
-eventually changed into a serpentine one. Analogous phenomena
-may be observed where the water is stationary and
-the solid matter moving. A stick drawn laterally through
-the water with much force, proves by the throb which it
-communicates to the hand that it is in a state of vibration.
-Even where the moving body is massive, it only requires that
-great force should be applied to get a sensible effect of like
-kind: instance the screw of a screw-steamer, which instead
-of a smooth rotation falls into a rapid rhythm that sends a
-tremor through the whole vessel. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The sound which
-results when a bow is drawn over a violin-string, shows us
-vibrations produced by the movement of a solid over a solid.
-In lathes and planing machines, the attempt to take off a
-thick shaving causes a violent jar of the whole apparatus, and
-the production of a series of waves on the iron or wood that
-is cut. Every boy in scraping his slate-pencil finds it
-scarcely possible to help making a ridged surface. If you
-roll a ball along the ground or over the ice, there is always
-more or less up and down movement—a movement that is
-visible while the velocity is considerable, but becomes too
-<span class='pageno' id='Page_315'>315</span>small and rapid to be seen by the unaided eye as the velocity
-diminishes. However smooth the rails, and however perfectly
-built the carriages, a railway-train inevitably gets into
-oscillations, both lateral and vertical. Even where moving
-matter is suddenly arrested by collision, the law is still illustrated;
-for both the body striking and the body struck are
-made to tremble; and trembling is rhythmical movement.
-Little as we habitually observe it, it is yet certain that the
-impulses our actions impress from moment to moment on
-surrounding objects, are propagated through them in vibrations.
-It needs but to look through a telescope of high
-power, to be convinced that each pulsation of the heart gives
-a jar to the whole room. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;If we pass to motions of
-another order—those namely which take<a id='t315'></a> place in the etherial
-medium—we still find the same thing. Every fresh discovery
-confirms the hypothesis that light consists of undulations.
-The rays of heat, too, are now found to have a like
-fundamental nature; their undulations differing from those
-of light only in their comparative length. Nor do the movements
-of electricity fail to furnish us with an illustration;
-though one of a different order. The northern aurora may
-often be observed to pulsate with waves of greater brightness;
-and the electric discharge through a vacuum shows us by its
-stratified appearance that the current is not uniform, but
-comes in gushes of greater and lesser intensity. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Should
-it be said that at any rate there are some motions, as those of
-projectiles, which are not rhythmical, the reply is, that the
-exception is apparent only; and that these motions would be
-rhythmical if they were not interrupted. It is common to
-assert that the trajectory of a cannon ball is a parabola; and
-it is true that (omitting atmospheric resistance) the curve described
-differs so slightly from a parabola that it may practically
-be regarded as one. But, strictly speaking, it is a portion
-of an extremely eccentric ellipse, having the Earth’s
-centre of gravity for its remoter focus; and but for its arrest
-by the substance of the Earth, the cannon ball would travel
-<span class='pageno' id='Page_316'>316</span>round that focus and return to the point whence it started;
-again to repeat this slow rhythm. Indeed, while seeming at
-first sight to do the reverse, the discharge of a cannon
-furnishes one of the best illustrations of the principle enunciated.
-The explosion produces violent undulations in the
-surrounding air. The whizz of the shot, as it flies towards
-its mark, is due to another series of atmospheric undulations.
-And the movement to and from the Earth’s centre, which the
-cannon ball is beginning to perform, being checked by solid
-matter, is transformed into a rhythm of another order;
-namely, the vibration which the blow sends through neighbouring
-bodies.<a id='r15' /><a href='#f15' class='c011'><sup>[15]</sup></a></p>
-
-<p class='c000'>Rhythm is very generally not simple but compound.
-There are usually at work various forces, causing undulations
-differing in rapidity; and hence it continually happens that
-besides the primary rhythms there are secondary rhythms,
-produced by the periodic coincidence and antagonism of the
-primary ones. Double, triple, and even quadruple rhythms,
-are thus generated. One of the simplest instances is afforded
-by what in acoustics are known as “beats:” recurring intervals
-of sound and silence which are perceived when two notes
-of nearly the same pitch are struck together; and which are
-due to the alternate correspondence and antagonism of the
-atmospheric waves. In like manner the various phenomena
-due to what is called interference of light, severally result
-from the periodic agreement and disagreement of etherial
-undulations—undulations which, by alternately intensifying
-and neutralizing each other, produce intervals of
-increased and diminished light. On the sea-shore may be
-noted sundry instances of compound rhythm. We have
-that of the tides, in which the daily rise and fall undergoes
-a fortnightly increase and decrease, due to the alternate
-coincidence and antagonism of the solar and lunar
-<span class='pageno' id='Page_317'>317</span>attractions. We have again that which is perpetually
-furnished by the surface of the sea: every large wave bearing
-smaller ones on its sides, and these still smaller ones;
-with the result that each flake of foam, along with the portion
-of water bearing it, undergoes minor ascents and descents
-of several orders while it is being raised and lowered by the
-greater billows. A quite different and very interesting
-example of compound rhythm, occurs in the little rills which,
-at low tide, run over the sand out of the shingle banks above.
-Where the channel of one of these is narrow, and the stream
-runs strongly, the sand at the bottom is raised into a series
-of ridges corresponding to the ripple of the water. On
-watching for a short time, it will be seen that these ridges
-are being raised higher and the ripple growing stronger;
-until at length, the action becoming violent, the whole series
-of ridges is suddenly swept away, the stream runs smoothly,
-and the process commences afresh. Instances of still more
-complex rhythms might be added; but they will come more
-appropriately in connexion with the several forms of Evolution,
-hereafter to be dealt with.</p>
-
-<p class='c000'>From the ensemble of the facts as above set forth, it will be
-seen that rhythm results wherever there is a conflict of forces
-not in equilibrium. If the antagonist forces at any point are
-balanced, there is rest; and in the absence of motion there
-can of course be no rhythm. But if instead of a balance
-there is an excess of force in one direction—if, as necessarily
-follows, motion is set up in that direction; then for that
-motion to continue uniformly in that direction, it is requisite
-that the moving matter should, notwithstanding its unceasing
-change of place, present unchanging relations to the sources
-of force by which its motion is produced and opposed. This
-however is impossible. Every further transfer through space
-must alter the ratio between the forces concerned—must increase
-or decrease the predominance of one force over the
-other—must prevent uniformity of movement. And if the
-movement cannot be uniform, then, in the absence of acceleration
-<span class='pageno' id='Page_318'>318</span>or retardation continued through infinite time and space,
-(results which cannot be conceived) the only alternative is
-rhythm.</p>
-
-<p class='c000'>A secondary conclusion must not be omitted. In the last
-chapter we saw that motion is never absolutely rectilinear;
-and here it remains to be added that, as a consequence, rhythm
-is necessarily incomplete. A truly rectilinear rhythm can
-arise only when the opposing forces are in exactly the same
-line; and the probabilities against this are infinitely great.
-To generate a perfectly circular rhythm, the two forces concerned
-must be exactly at right angles to each other, and
-must have exactly a certain ratio; and against this the probabilities
-are likewise infinitely great. All other proportions
-and directions of the two forces will produce an ellipse of
-greater or less eccentricity. And when, as indeed always
-happens, above two forces are engaged, the curve described
-must be more complex; and cannot exactly repeat itself. So
-that in fact throughout nature, this action and re-action of
-forces never brings about a complete return to a previous
-state. Where the movement is very involved, and especially
-where it is that of some aggregate whose units are partially
-independent, anything like a regular curve is no longer
-traceable; we see nothing more than a general oscillation.
-And on the completion of any periodic movement, the degree
-in which the state arrived at differs from the state departed
-from, is usually marked in proportion as the influences
-at work are numerous.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 94. That spiral arrangement so general among the more
-diffused nebulæ—an arrangement which must be assumed by
-matter moving towards a centre of gravity through a resisting
-medium—shows us the progressive establishment of
-revolution, and therefore of rhythm; in those remote spaces
-which the nebulæ occupy. Double stars, moving round common
-centres of gravity in periods some of which are now
-ascertained, exhibit settled rhythmical actions in distant parts
-<span class='pageno' id='Page_319'>319</span>of our sidereal system. And another fact which, though of a
-different order, has a like general significance, is furnished by
-variable stars—stars which alternately brighten and fade.</p>
-
-<p class='c000'>The periodicities of the planets, satellites, and comets, are
-so familiar that it would be inexcusable to name them, were
-it not needful here to point out that they are so many grand
-illustrations of this general law of movement. But besides
-the revolutions of these bodies in their orbits (all more or less
-excentric) and their rotations on their axes, the Solar System
-presents us with various rhythms of a less manifest and more
-complex kind. In each planet and satellite there is the revolution
-of the nodes—a slow change in the position of the
-orbit-plane, which after completing itself commences afresh.
-There is the gradual alteration in the length of the axis
-major of the orbit; and also of its excentricity: both of
-which are rhythmical alike in the sense that they alternate
-between maxima and minima, and in the sense that the progress
-from one extreme to the other is not uniform, but is
-made with fluctuating velocity. Then, too, there is the revolution
-of the line of apsides, which in course of time moves
-round the heavens—not regularly, but through complex
-oscillations. And further we have variations in the directions
-of the planetary axes—that known as nutation, and that
-larger gyration which, in the case of the Earth, causes the
-precession of the equinoxes. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;These rhythms, already
-more or less compound, are compounded with each other.
-Such an instance as the secular acceleration and retardation
-of the moon, consequent on the varying excentricity of the
-Earth’s orbit, is one of the simplest. Another, having more
-important consequences, results from the changing direction
-of the axes of rotation in planets whose orbits are decidedly
-excentric. Every planet, during a certain long period, presents
-more of its northern than of its southern hemisphere to
-the sun at the time of its nearest approach to him; and then
-again, during a like period, presents more of its southern
-hemisphere than of its northern—a recurring coincidence
-<span class='pageno' id='Page_320'>320</span>which, though causing in some planets no sensible alterations
-of climate, involves in the case of the Earth an epoch of
-21,000 years, during which each hemisphere goes through a
-cycle of temperate seasons, and seasons that are extreme in
-their heat and cold. Nor is this all. There is even a variation
-of this variation. For the summers and winters of the
-whole Earth become more or less strongly contrasted, as the
-excentricity of its orbit increases and decreases. Hence
-during increase of the excentricity, the epochs of moderately
-contrasted seasons and epochs of strongly contrasted seasons,
-through which alternately each hemisphere passes, must grow
-more and more different in the degrees of their contrasts;
-and contrariwise during decrease of the excentricity. So
-that in the quantity of light and heat which any portion of
-the Earth receives from the sun, there goes on a quadruple
-rhythm: that of day and night; that of summer and winter;
-that due to the changing position of the axis at perihelion
-and aphelion, taking 21,000 years to complete; and that
-involved by the variation of the orbit’s excentricity, gone
-through in millions of years.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 95. Those terrestrial processes whose dependence on the
-solar heat is direct, of course exhibit a rhythm that corresponds
-to the periodically changing amount of heat which
-each part of the Earth receives. The simplest, though the
-least obtrusive, instance is supplied by the magnetic variations.
-In these there is a diurnal increase and decrease, an annual
-increase and decrease, and a decennial increase and decrease;
-the latter answering to a period during which the solar spots
-become alternately abundant and scarce: besides which known
-variations there are probably others corresponding with the
-astronomical cycles just described. More obvious examples
-are furnished by the movements of the ocean and the atmosphere.
-Marine currents from the equator to the poles above,
-and from the poles to the equator beneath, show us an unceasing
-backward and forward motion throughout this vast
-<span class='pageno' id='Page_321'>321</span>mass of water—a motion varying in amount according to the
-seasons, and compounded with smaller like motions of local
-origin. The similarly-caused general currents in the air, have
-similar annual variations similarly modified. Irregular as
-they are in detail, we still see in the monsoons and other tropical
-atmospheric disturbances, or even in our own equinoctial
-gales and spring east winds, a periodicity sufficiently decided.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Again, we have an alternation of times during
-which evaporation predominates with times during which condensation
-predominates: shown in the tropics by strongly
-marked rainy seasons and seasons of drought, and in the
-temperate zones by corresponding changes of which the periodicity,
-though less definite, is still traceable. The diffusion
-and precipitation of water, besides the slow alternations
-answering to different parts of the year, furnish us with examples
-of rhythm of a more rapid kind. During wet
-weather, lasting, let us say, over some weeks, the tendency
-to condense, though greater than the tendency to evaporate,
-does not show itself in continuous rain; but the period is
-made up of rainy days and days that are wholly or partially
-fair. Nor is it in this rude alternation only that the law is
-manifested. During any day throughout this wet weather a
-minor rhythm is traceable; and especially so when the tendencies
-to evaporate and to condense are nearly balanced.
-Among mountains this minor rhythm and its causes may be
-studied to great advantage. Moist winds, which do not precipitate
-their contained water in passing over the comparatively
-warm lowlands, lose so much heat when they reach
-the cold mountain peaks, that condensation rapidly takes
-place. Water, however, in passing from the gaseous to the
-fluid state, gives out a considerable amount of heat; and
-hence the resulting clouds are warmer than the air that precipitates
-them, and much warmer than the high rocky surfaces
-round which they fold themselves. Hence in the
-course of the storm, these high rocky surfaces are raised in
-temperature, partly by radiation from the enwrapping cloud,
-<span class='pageno' id='Page_322'>322</span>partly by contact of the falling rain-drops. Giving off more
-heat than before, they no longer lower so greatly the temperature
-of the air passing over them; and so cease to precipitate
-its contained water. The clouds break; the sky begins
-to clear; and a gleam of sunshine promises that the day is
-going to be fine. But the small supply of heat which the
-cold mountain’s sides have received, is soon lost: especially
-when the dispersion of the clouds permits free radiation into
-space. Very soon, therefore, these elevated surfaces, becoming
-as cold as at first, (or perhaps even colder in virtue of the
-evaporation set up,) begin again to condense the vapour in
-the air above; and there comes another storm, followed by
-the same effects as before. In lowland regions this action
-and reaction is usually less conspicuous, because the contrast
-of temperatures is less marked. Even here, however, it may
-be traced; and that not only on showery days, but on days
-of continuous rain; for in these we do not see uniformity:
-always there are fits of harder and gentler rain that are probably
-caused as above explained.</p>
-
-<p class='c000'>Of course these meteorologic rhythms involve something
-corresponding to them in the changes wrought by wind and
-water on the Earth’s surface. Variations in the quantities of
-sediment brought down by rivers that rise and fall with the
-seasons, must cause variations in the resulting strata—alternations
-of colour or quality in the successive laminæ. Beds
-formed from the detritus of shores worn down and carried
-away by the waves, must similarly show periodic differences
-answering to the periodic winds of the locality. In so far as
-frost influences the rate of denudation, its recurrence is a
-factor in the rhythm of sedimentary deposits. And the
-geological changes produced by glaciers and icebergs must
-similarly have their alternating periods of greater and less
-intensity.</p>
-
-<p class='c000'>There is evidence also that modifications in the Earth’s
-crust due to igneous action have a certain periodicity. Volcanic
-eruptions are not continuous but intermittent, and as
-<span class='pageno' id='Page_323'>323</span>far as the data enable us to judge, have a certain average
-rate of recurrence; which rate of recurrence is complicated
-by rising into epochs of greater activity and falling into
-epochs of comparative quiescence. So too is it with earthquakes
-and the elevations or depressions caused by them. At
-the mouth of the Mississippi, the alternation of strata gives
-decisive proof of successive sinkings of the surface, that
-have taken place at tolerably equal intervals. Everywhere,
-in the extensive groups of conformable strata that imply
-small subsidences recurring with a certain average frequency,
-we see a rhythm in the action and reaction between the
-Earth’s crust and its molten contents—a rhythm compounded
-with those slower ones shown in the termination of groups of
-strata, and the commencement of other groups not conformable
-to them. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;There is even reason for suspecting
-a geological periodicity that is immensely slower and far
-wider in its effects; namely, an alternation of those vast upheavals
-and submergencies by which continents are produced
-where there were oceans, and oceans where there were continents.
-For supposing, as we may fairly do, that the Earth’s
-crust is throughout of tolerably equal thickness, it is manifest
-that such portions of it as become most depressed below the
-average level, must have their inner surfaces most exposed
-to the currents of molten matter circulating within, and will
-therefore undergo a larger amount of what may be called
-igneous denudation; while, conversely, the withdrawal of the
-inner surfaces from these currents where the Earth’s crust is
-most elevated, will cause a thickening more or less compensating
-the aqueous denudation going on externally. Hence
-those depressed areas over which the deepest oceans lie, being
-gradually thinned beneath and not covered by much sedimentary
-deposit above, will become areas of least resistance,
-and will then begin to yield to the upward pressure of the
-Earth’s contents; whence will result, throughout such areas,
-long-continued elevations, ceasing only when the reverse state
-of things has been brought about. Whether this speculation
-<span class='pageno' id='Page_324'>324</span>be well or ill founded, does not however affect the general
-conclusion. Apart from it we have sufficient evidence that
-geologic processes are rhythmical.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 96. Perhaps nowhere are the illustrations of rhythm
-so numerous and so manifest as among the phenomena of life.
-Plants do not, indeed, usually show us any decided periodicities,
-save those determined by day and night and by the
-seasons. But in animals we have a great variety of movements
-in which the alternation of opposite extremes goes on
-with all degrees of rapidity. The swallowing of food is
-effected by a wave of constriction passing along the œsophagus;
-its digestion is accompanied by a muscular action of the
-stomach that is also undulatory; and the peristaltic motion of
-the intestines is of like nature. The blood obtained from this
-food is propelled not in a uniform current but in pulses; and
-it is aerated by lungs that alternately contract and expand. All
-locomotion results from oscillating movements: even where it
-is apparently continuous, as in many minute forms, the microscope
-proves the vibration of cilia to be the agency by
-which the creature is moved smoothly forwards.</p>
-
-<p class='c000'>Primary rhythms of the organic actions are compounded
-with secondary ones of longer duration. These various
-modes of activity have their recurring periods of increase and
-decrease. We see this in the periodic need for food, and in the
-periodic need for repose. Each meal induces a more rapid
-rhythmic action of the digestive organs; the pulsation of
-the heart is accelerated; and the inspirations become more
-frequent. During sleep, on the contrary, these several
-movements slacken. So that in the course of the twenty-four
-hours, those small undulations of which the different
-kinds of organic action are constituted, undergo one long
-wave of increase and decrease, complicated with several
-minor waves. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Experiments have shown that there
-are still slower rises and falls of functional activity.
-Waste and assimilation are not balanced by every meal, but
-<span class='pageno' id='Page_325'>325</span>one or other maintains for some time a slight excess; so that
-a person in ordinary health is found to undergo an increase
-and decrease of weight during recurring intervals of tolerable
-equality. Besides these regular periods there are still longer
-and comparatively irregular ones; namely, those alternations
-of greater and less vigour, which even healthy people experience.
-So inevitable are these oscillations that even men in
-training cannot be kept stationary at their highest power, but
-when they have reached it begin to retrograde. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Further
-evidence of rhythm in the vital movements is furnished
-by invalids. Sundry disorders are named from the
-intermittent character of their symptoms. Even where the
-periodicity is not very marked, it is mostly traceable. Patients
-rarely if ever get uniformly worse; and convalescents have
-usually their days of partial relapse or of less decided advance.</p>
-
-<p class='c000'>Aggregates of living creatures illustrate the general truth
-in other ways. If each species of organism be regarded as a
-whole, it displays two kinds of rhythm. Life as it exists in
-all the members of such species, is an extremely complex kind
-of movement, more or less distinct from the kinds of movement
-which constitutes life in other species. In each individual
-of the species, this extremely complex kind of movement
-begins, rises to its climax, declines, and ceases in
-death. And every successive generation thus exhibits a wave
-of that peculiar activity characterizing the species as a
-whole. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The other form of rhythm is to be traced in
-that variation of number which each tribe of animals and
-plants is ever undergoing. Throughout the unceasing conflict
-between the tendency of a species to increase and the
-antagonistic tendencies, there is never an equilibrium: one
-always predominates. In the case even of a cultivated plant
-or domesticated animal, where artificial means are used to
-maintain the supply at a uniform level, we still see that oscillations
-of abundance and scarcity cannot be avoided. And
-among the creatures uncared for by man, such oscillations
-<span class='pageno' id='Page_326'>326</span>are usually more marked. After a race of organisms has
-been greatly thinned by enemies or lack of food, its surviving
-members become more favourably circumstanced than usual.
-During the decline in their numbers their food has grown
-relatively more abundant; while their enemies have diminished
-from want of prey. The conditions thus remain for
-some time favourable to their increase; and they multiply
-rapidly. By and by their food is rendered relatively scarce,
-at the same time that their enemies have become more
-numerous; and the destroying influences being thus in excess,
-their number begins to diminish again. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Yet one
-more rhythm, extremely slow in its action, may be traced in
-the phenomena of Life, contemplated under their most general
-aspect. The researches of palæontologists show, that there
-have been going on, during the vast period of which our sedimentary
-rocks bear record, successive changes of organic
-forms. Species have appeared, become abundant, and then
-disappeared. Genera, at first constituted of but few species,
-have for a time gone on growing more multiform; and then
-have begun to decline in the number of their subdivisions;
-leaving at last but one or two representatives, or none at all.
-During longer epochs whole orders have thus arisen, culminated,
-and dwindled away. And even those wider divisions containing
-many orders have similarly undergone a gradual rise,
-a high tide, and a long-continued ebb. The stalked <em>Crinoidea</em>,
-for example, which, during the carboniferous epoch, became
-abundant, have almost disappeared: only a single species
-being extant. Once a large family of molluscs, the <em>Brachiopoda</em>
-have now become rare. The shelled Cephalopods, at
-one time dominant among the inhabitants of the ocean, both in
-number of forms and of individuals, are in our day nearly
-extinct. And after an “age of reptiles,” there has come an
-age in which reptiles have been in great measure supplanted
-by mammals. Whether these vast rises and falls of different
-kinds of life ever undergo anything approaching to repetitions,
-(which they may possibly do in correspondence with those
-<span class='pageno' id='Page_327'>327</span>vast cycles of elevation and subsidence that produce continents
-and oceans,) it is sufficiently clear that Life on the Earth has
-not progressed uniformly, but in immense undulations.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 97. It is not manifest that the changes of consciousness
-are in any sense rhythmical. Yet here, too, analysis proves
-both that the mental state existing at any moment is not
-uniform, but is decomposable into rapid oscillations; and also
-that mental states pass through longer intervals of increasing
-and decreasing intensity.</p>
-
-<p class='c000'>Though while attending to any single sensation, or any
-group of related sensations constituting the consciousness of
-an object, we seem to remain for the time in a persistent and
-homogeneous condition of mind, a careful self-examination
-shows that this apparently unbroken mental state is in truth
-traversed by a number of minor states, in which various other
-sensations and perceptions are rapidly presented and disappear.
-From the admitted fact that thinking consists in the establishment
-of relations, it is a necessary corollary that the maintenance
-of consciousness in any one state to the entire exclusion
-of other states, would be a cessation of thought, that is, of
-consciousness. So that any seemingly continuous feeling, say
-of pressure, really consists of portions of that feeling perpetually
-recurring after the momentary intrusion of other feelings
-and ideas—quick thoughts concerning the place where it is
-felt, the external object producing it, its consequences, and
-other things suggested by association. Thus there is going
-on an extremely rapid departure from, and return to, that particular
-mental state which we regard as persistent. Besides
-the evidence of rhythm in consciousness which direct analysis
-thus affords, we may gather further evidence from the correlation
-between feeling and movement. Sensations and emotions
-expend themselves in producing muscular contractions. If a
-sensation or emotion were strictly continuous, there would be a
-continuous discharge along those motor nerves acted upon. But
-so far as experiments with artificial stimuli enable us to judge,
-a continuous discharge along the nerve leading to a muscle,
-<span class='pageno' id='Page_328'>328</span>does not contract it: a broken discharge is required—a rapid
-succession of shocks. Hence muscular contraction pre-supposes
-that rhythmic state of consciousness which direct observation
-discloses. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;A much more conspicuous rhythm, having
-longer waves, is seen during the outflow of emotion into
-dancing, poetry, and music. The current of mental energy
-that shows itself in these modes of bodily action, is not continuous,
-but falls into a succession of pulses. The measure of
-a dance is produced by the alternation of strong muscular
-contractions with weaker ones; and, save in measures of the
-simplest order such as are found among barbarians and
-children, this alternation is compounded with longer rises and
-falls in the degree of muscular excitement. Poetry is a form of
-speech which results when the emphasis is regularly recurrent;
-that is, when the muscular effort of pronunciation has definite
-periods of greater and less intensity—periods that are
-complicated with others of like nature answering to the successive
-verses. Music, in still more various ways, exemplifies
-the law. There are the recurring bars, in each of which there
-is a primary and a secondary beat. There is the alternate
-increase and decrease of muscular strain, implied by the
-ascents and descents to the higher and lower notes—ascents
-and descents composed of smaller waves, breaking the
-rises and falls of the larger ones, in a mode peculiar to each
-melody. And then we have, further, the alternation of <em>piano</em>
-and <em>forte</em> passages. That these several kinds of rhythm,
-characterizing æsthetic expression, are not, in the common
-sense of the word, artificial, but are intenser forms of an undulatory
-movement habitually generated by feeling in its
-bodily discharge, is shown by the fact that they are all traceable
-in ordinary speech; which in every sentence has its
-primary and secondary emphases, and its cadence containing
-a chief rise and fall complicated with subordinate rises
-and falls; and which is accompanied by a more or less
-oscillatory action of the limbs when the emotion is
-great. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Still longer undulations may be observed by
-every one, in himself and in others, on occasions of extreme
-<span class='pageno' id='Page_329'>329</span>pleasure or extreme pain. Note, in the first place, that pain
-having its origin in bodily disorder, is nearly always perceptibly
-rhythmical. During hours in which it never actually
-ceases, it has its variations of intensity—fits or paroxysms; and
-then after these hours of suffering there usually come hours
-of comparative ease. Moral pain has the like smaller and
-larger waves. One possessed by intense grief does not utter
-continuous moans, or shed tears with an equable rapidity;
-but these signs of passion come in recurring bursts. Then
-after a time during which such stronger and weaker waves
-of emotion alternate, there comes a calm—a time of comparative
-deadness; to which again succeeds another interval,
-when dull sorrow rises afresh into acute anguish, with its
-series of paroxysms. Similarly in great delight, especially as
-manifested by children who have its display less under control,
-there are visible variations in the intensity of feeling shown—fits
-of laughter and dancing about, separated by pauses in
-which smiles, and other slight manifestations of pleasure,
-suffice to discharge the lessened excitement. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Nor are
-there wanting evidences of mental undulations greater in
-length than any of these—undulations which take weeks, or
-months, or years, to complete themselves. We continually
-hear of moods which recur at intervals. Very many persons
-have their epochs of vivacity and depression. There are periods
-of industry following periods of idleness; and times at which
-particular subjects or tastes are cultivated with zeal, alternating
-with times at which they are neglected. Respecting
-which slow oscillations, the only qualification to be made is,
-that being affected by numerous influences, they are comparatively
-irregular.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 98. In nomadic societies the changes of place, determined
-as they usually are by exhaustion or failure of the
-supply of food, are periodic; and in many cases show a
-recurrence answering to the seasons. Each tribe that has
-become in some degree fixed in its locality, goes on increasing,
-<span class='pageno' id='Page_330'>330</span>till under the pressures of unsatisfied desires, there results
-migration of some part of it to a new region—a process repeated
-at intervals. From such excesses of population, and such
-successive waves of migration, come conflicts with other
-tribes; which are also increasing and tending to diffuse
-themselves. This antagonism, like all others, results not in an
-uniform motion, but in an intermittent one. War, exhaustion,
-recoil—peace, prosperity, and renewed aggression:—see
-here the alternation more or less discernible in the military
-activities of both savage and civilized nations. And irregular
-as is this rhythm, it is not more so than the different sizes
-of the societies, and the extremely involved causes of variation
-in their strengths, would lead us to anticipate.</p>
-
-<p class='c000'>Passing from external to internal changes, we meet with
-this backward and forward movement under many forms. In
-the currents of commerce it is especially conspicuous.
-Exchange during early times is almost wholly carried on at
-fairs, held at long intervals in the chief centres of population.
-The flux and reflux of people and commodities which each of
-these exhibits, becomes more frequent as national development
-leads to greater social activity. The more rapid rhythm
-of weekly markets begins to supersede the slow rhythm of
-fairs. And eventually the process of exchange becomes at
-certain places so active, as to bring about daily meetings of
-buyers and sellers—a daily wave of accumulation and distribution
-of cotton, or corn, or capital. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;If from
-exchange we turn to production and consumption, we see
-undulations, much longer indeed in their periods, but almost
-equally obvious. Supply and demand are never completely
-adapted to each other; but each of them from time to time
-in excess, leads presently to an excess of the other. Farmers
-who have one season produced wheat very abundantly, are
-disgusted with the consequent low price; and next season,
-sowing a much smaller quantity, bring to market a deficient
-crop; whence follows a converse effect. Consumption
-undergoes parallel undulations that need not be specified.
-<span class='pageno' id='Page_331'>331</span>The balancing of supplies between different districts, too,
-entails analogous oscillations. A place at which some necessary
-of life is scarce, becomes a place to which currents of it
-are set up from other places where it is relatively abundant;
-and these currents from all sides lead to a wave of accumulation
-where they meet—a glut: whence follows a recoil—a
-partial return of the currents. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;But the undulatory
-character of these actions is perhaps best seen in the rises and
-falls of prices. These, given in numerical measures which
-may be tabulated and reduced to diagrams, show us in the
-clearest manner how commercial movements are compounded
-of oscillations of various magnitudes. The price of consols or
-the price of wheat, as thus represented, is seen to undergo
-vast ascents and descents whose highest and lowest points are
-reached only in the course of years. These largest waves of
-variation are broken by others extending over periods of
-perhaps many months. On these again come others having
-a week or two’s duration. And were the changes marked in
-greater detail, we should have the smaller undulations that
-take place each day, and the still smaller ones which brokers
-telegraph from hour to hour. The whole outline would show
-a complication like that of a vast ocean-swell, on whose surface
-there rise large billows, which themselves bear waves of
-moderate size, covered by wavelets, that are roughened by a
-minute ripple. Similar diagrammatic representations of births,
-marriages, and deaths, of disease, of crime, of pauperism,
-exhibit involved conflicts of rhythmical motions throughout
-society under these several aspects.</p>
-
-<p class='c000'>There are like characteristics in social changes of a more
-complex kind. Both in England and among continental
-nations, the action and reaction of political progress have
-come to be generally recognized. Religion, besides its occasional
-revivals of smaller magnitude, has its long periods of
-exaltation and depression—generations of belief and self-mortification,
-following generations of indifference and laxity.
-There are poetical epochs, and epochs in which the sense of the
-<span class='pageno' id='Page_332'>332</span>beautiful seems almost dormant. Philosophy, after having
-been awhile predominant, lapses for a long season into neglect;
-and then again slowly revives. Each science has its eras of
-deductive reasoning, and its eras when attention is chiefly
-directed to collecting and colligating facts. And how in such
-minor but more obtrusive phenomena as those of fashion,
-there are ever going on oscillations from one extreme to the
-other, is a trite observation.</p>
-
-<p class='c000'>As may be foreseen, social rhythms well illustrate the
-irregularity that results from combination of many causes.
-Where the variations are those of one simple element in national
-life, as the supply of a particular commodity, we do indeed
-witness a return, after many involved movements, to a
-previous condition—the price may become what it was before:
-implying a like relative abundance. But where the action is
-one into which many factors enter, there is never a recurrence
-of exactly the same state. A political reaction never
-brings round just the old form of things. The rationalism
-of the present day differs widely from the rationalism of the
-last century. And though fashion from time to time revives
-extinct types of dress, these always re-appear with decided
-modifications.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 99. The universality of this principle suggests a question
-like that raised in foregoing cases. Rhythm being manifested
-in all forms of movement, we have reason to suspect that it
-is determined by some primordial condition to action in
-general. The tacit implication is that it is deducible from
-the persistence of force. This we shall find to be the fact.</p>
-
-<p class='c000'>When the prong of a tuning-fork is pulled on one side by
-the finger, a certain extra tension is produced among its cohering
-particles; which resist any force that draws them out
-of their state of equilibrium. As much force as the finger
-exerts in pulling the prong aside, so much opposing force is
-brought into play among the cohering particles. Hence,
-when the prong is liberated, it is urged back by a force equal
-<span class='pageno' id='Page_333'>333</span>to that used in deflecting it. When, therefore, the prong
-reaches its original position, the force impressed on it during
-its recoil, has generated in it a corresponding amount of momentum—an
-amount of momentum nearly equivalent, that
-is, to the force originally impressed (nearly, we must say,
-because a certain portion has gone in communicating motion
-to the air, and a certain other portion has been transformed
-into heat). This momentum carries the prong beyond the
-position of rest, nearly as far as it was originally drawn in
-the reverse direction; until at length, being gradually used
-up in producing an opposing tension among the particles, it
-is all lost. The opposing tension into which the expended
-momentum has been transformed, then generates a second recoil;
-and so on continually—the vibration eventually ceasing
-only because at each movement a certain amount of force
-goes in creating atmospheric and etherial undulations.
-Now it needs but to contemplate this repeated action and reaction,
-to see that it is, like every action and reaction, a
-consequence of the persistence of force. The force exerted
-by the finger in bending the prong cannot disappear.
-Under what form then does it exist? It exists under the
-form of that cohesive tension which it has generated among
-the particles. This cohesive tension cannot cease without an
-equivalent result. What is its equivalent result? The
-momentum generated in the prong while being carried back
-to its position of rest. This momentum too—what becomes
-of it? It must either continue as momentum, or produce
-some correlative force of equal amount. It cannot continue
-as momentum, since change of place is resisted by the cohesion
-of the parts; and thus it gradually disappears by being
-transformed into tension among these parts. This is re-transformed
-into the equivalent momentum; and so on continuously.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;If instead of motion that is directly antagonized
-by the cohesion of matter, we consider motion through
-space, the same truth presents itself under another form.
-Though here no opposing force seems at work, and therefore
-<span class='pageno' id='Page_334'>334</span>no cause of rhythm is apparent, yet its own accumulated
-momentum must eventually carry the moving body beyond
-the body attracting it; and so must become a force at variance
-with that which generated it. From this conflict,
-rhythm necessarily results as in the foregoing case. The
-force embodied as momentum in a given direction, cannot be
-destroyed; and if it eventually disappears, it re-appears in
-the reaction on the retarding body; which begins afresh to
-draw the now arrested mass back from its aphelion. The
-only conditions under which there could be absence of rhythm—the
-only conditions, that is, under which there could be a
-continuous motion through space in the same straight line
-for ever, would be the existence of an infinity void of everything
-but the moving body. And neither of these conditions
-can be represented in thought. Infinity is inconceivable;
-and so also is a motion which never had a commencement in
-some pre-existing source of power. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Thus, then, rhythm
-is a necessary characteristic of all motion. Given the coexistence
-everywhere of antagonist forces—a postulate which,
-as we have seen, is necessitated by the form of our experience—and
-rhythm is an inevitable corollary from the persistence
-of force.</p>
-
-<p class='c000'>Hence, throughout that re-arrangement of parts which
-constitutes Evolution, we must nowhere expect to see the
-change from one position of things to another, effected by
-continuous movement in the same direction. Be it in that
-kind of Evolution which the inorganic creation presents, or
-in that presented by the organic creation, we shall everywhere
-find a periodicity of action and reaction—a backward
-and forward motion, of which progress is a differential result.</p>
-
-<hr class='c015' />
-
-<div class='footnote' id='f15'>
-<p class='c000'><span class='label'><a href='#r15'>15</a>.&nbsp;&nbsp;</span>After having for some years supposed myself alone in the belief that all motion
-is rhythmical, I discovered that my friend Professor Tyndall also held this
-doctrine.</p>
-</div>
-
-<div>
- <span class='pageno' id='Page_335'>335</span>
- <h3 class='c001'>CHAPTER XII.<br /> <span class='large'>THE CONDITIONS ESSENTIAL TO EVOLUTION.</span></h3>
-</div>
-
-<p class='c006'>§ 100. One more preliminary is needful before proceeding.
-We have still to study the conditions under which alone,
-Evolution can take place.</p>
-
-<p class='c000'>The process to be interpreted is, as already said, a certain
-change in the arrangement of parts. That increase of heterogeneity
-commonly displayed throughout Evolution, is not an
-increase in the number of kinds of ultimate or undecomposable
-units which an aggregate contains; but it is a change
-in the distribution of such units. If it be assumed that
-what we call chemical elements, are absolutely simple (which
-is, however, an hypothesis having no better warrant than the
-opposite one); then it must be admitted that in respect to the
-number of kinds of matter contained in it, the Earth is not
-more heterogeneous at present than it was at first—that in this
-respect, it would be as heterogeneous were all its undecomposable
-parts uniformly mixed, as it is now, when they are
-arranged and combined in countless different ways. But the
-increase of heterogeneity with which we have to deal, and of
-which alone our senses can take cognizance, is that produced
-by the passage from unity of distribution to variety of distribution.
-Given an aggregate consisting of several orders of
-primitive units that are unchangeable; then, these units may
-be so uniformly dispersed among each other, that any portion
-of the mass shall be like any other portion in its sensible properties;
-<span class='pageno' id='Page_336'>336</span>or they may be so segregated, simply and in endless
-combinations, that the various portions of the mass shall not
-be like each other in their sensible properties. A transformation
-of one of these arrangements into the other, is that
-which constitutes Evolution. We have to analyze the process
-through which structural uniformity becomes structural
-multiformity—to ascertain how the originally equal relations
-of position among the mixed units, pass into relations of position
-that are more and more unequal, and more and more
-numerous in their kinds of inequality; and how this
-takes place throughout all the ascending grades of compound
-units, until we come even to those of which societies
-are made up.</p>
-
-<p class='c000'>Change in the relations of position among the component
-units, simple or complex, being the phenomenon we have to
-interpret; we must first inquire what are the circumstances
-which prevent its occurrence, and what are the circumstances
-which facilitate it.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 101. The constituents of an aggregate cannot be re-arranged,
-unless they are moveable: manifestly, they must
-not be so firmly bound together that the incident force fails
-to alter their positions. No bodies are, indeed, possessed of
-this absolute rigidity; since an incident force in being propagated
-through a body, always produces temporary alterations
-in the relative positions of its units, if not permanent alterations.
-It is true also, that even permanent re-arrangements of
-the units may be thus wrought throughout the interiors of
-comparatively dense masses, without any outward sign: as
-happens with certain crystals, which, on exposure to sunlight,
-undergo molecular changes so great as to alter their
-planes of cleavage. Nevertheless, since total immobility of the
-parts must totally negative their re-arrangement; and since
-that comparative immobility which we see in very coherent
-matter, is a great obstacle to re-arrangement; it is self-evident
-that Evolution can be exhibited in any considerable
-<span class='pageno' id='Page_337'>337</span>degree, only where there is comparative mobility of
-parts. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;On the other hand, those definite distributive
-changes which constitute Evolution, cannot be extensively
-or variously displayed, where the mobility of the parts is
-extreme. In liquids, the cohesion of the units is so slight
-that there is no permanency in their relations of position to
-each other. Such re-arrangement as any incident force
-generates, is immediately destroyed again by the momentum
-of the constituents moved; and so, nothing but that
-temporary heterogeneity seen in circulating currents, can
-be produced. The like still more obviously holds of
-gases. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Thus, while the theoretical limits between
-which Evolution is possible, are absolute immobility of parts
-and absolute mobility of parts; we may say that practically,
-Evolution cannot go on to any considerable extent where the
-mobility is very great or very little. A few examples will
-facilitate the realization of this truth.</p>
-
-<p class='c000'>The highest degrees of Evolution are found in semi-solid
-bodies, or bodies that come midway between the two extremes
-specified. Even semi-solid bodies of the inorganic class, exhibit
-the segregation of mixed units with comparative readiness:
-witness the fact to which attention was first drawn by
-Mr. Babbage, that when the pasty mixture of ground flints
-and kaolin, prepared for the manufacture of porcelain, is kept
-some time, it becomes gritty and unfit for use, in consequence
-of the particles of silica separating themselves from the rest,
-and uniting together in grains; or witness the fact known to
-every housewife, that in long-kept currant-jelly the sugar
-takes the shape of imbedded crystals. While throughout the
-immense majority of the semi-solid bodies, namely, the
-organic bodies, the proclivity to a re-arrangement of parts is
-so comparatively great, as to be usually taken for a distinctive
-characteristic of them. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Among organic bodies
-themselves, we may trace contrasts having a like significance.
-It is an accepted generalization that, other things equal, the
-rate of Evolution is greatest where the plasticity is most
-<span class='pageno' id='Page_338'>338</span>marked. In that portion of an egg which displays the
-formative processes during the early stages of incubation, the
-changes of arrangement are more rapid than those which an
-equal portion of the body of a hatched chick undergoes. As
-may be inferred from their respective powers to acquire habits
-and aptitudes, the structural modifiability of a child is greater
-than that of an adult man; and the structural modifiability of
-an adult man is greater than that of an old man: contrasts
-which are accompanied by corresponding contrasts in the
-densities of the tissues; since the ratio of water to solid matter
-diminishes with advancing age. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The most decisive
-proof, however, is furnished by those marked retardations or
-arrests of organic change, that take place when the tissues
-suffer a great loss of water. Certain of the lower animals, as
-the <em>Rotifera</em>, may be rendered apparently lifeless by desiccation,
-and will yet revive when wetted: as their substance
-passes from the fluid-solid to the solid state, it ceases to be
-the seat of those changes which constitute functional activity
-and cause structural advance; and such changes recommence
-as their substance passes from the solid to the fluid-solid
-state. Analogous instances occur among much higher animals.
-When the African rivers which it inhabits are
-dried up, the <em>Lepidosiren</em> remains torpid in the hardened
-mud, until the return of the rainy season brings water.
-Humboldt states that during the summer drought, the alligators
-of the Pampas lie buried in a state of suspended animation
-beneath the parched surface, and struggle up out of
-the earth as soon as it becomes humid. Now though we
-have no proof that these partial arrests of vital activity, are
-consequent on the reduction of the fluid-solid tissues to a more
-solid form; yet their occurrence along with a cessation in the
-supply of water, is reason for suspecting that this is the case.
-And similarly, though in the more numerous instances where
-loss of water leads to complete arrest of vital activity, we are
-unable to say that the immediate cause is a stoppage of molecular
-changes that results from a diminution of molecular
-<span class='pageno' id='Page_339'>339</span>mobility; yet it seems not improbable that this is the
-rationale of death by thirst.</p>
-
-<p class='c000'>Probably few will expect to find this same condition to
-Evolution, illustrated in aggregates so widely different in
-kind as societies. Yet even here it may be shown that no
-considerable degree of Evolution is exhibited, where there is
-either great mobility of the parts, or great immobility of
-them. In such tribes as those inhabiting Australia, we see
-extremely little cohesion among the units: there is neither
-that partial fixity of relative positions which results from the
-commencement of agriculture, nor that partial fixity of relative
-positions implied by the establishment of social grades.
-And along with this want of cohesion, we find an absence of
-permanent differentiations. Conversely, in societies of the
-oriental type, where accumulated traditions, laws, and
-usages, and long-fixed class-arrangements, exercise great
-restraining power over individual actions, we find Evolution
-almost stopped. Through the medium of institutions and
-opinions, the forces brought to bear on each unit by the rest,
-are so great as to prevent the units from sensibly yielding to
-forces tending to re-arrange them. The condition most
-favourable to increase of social heterogeneity, is a medium
-coherence among the parts—a moderate facility of change in
-the relations of citizens, joined with a moderate resistance to
-such change—a considerable freedom of individual actions,
-qualified by a considerable restraint over individual actions—a
-certain attachment to pre-established arrangements, and a
-certain readiness to be impelled by new influences into new
-arrangements—a compromise between fixity and unfixity such
-as that which we, perhaps as much as any nation, exhibit.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 102. Another condition to Evolution, of the same order
-as the last though of a different genus, must be noted. We
-have found that permanent re-arrangement among the units
-of an aggregate, can take place only when they have neither
-<span class='pageno' id='Page_340'>340</span>extreme immobility nor extreme mobility. The mobility and
-immobility thus far considered (at least in all aggregates
-except social ones) are those due to mechanical cohesion.
-There is, however, what we must call chemical cohesion,
-which also influences the mobility of the units, and consequently
-the re-arrangement of them. Manifestly, if two or
-more kinds of units contained in any aggregate, are united
-by powerful affinities, an incident force, failing to destroy
-their cohesions, will not cause such various re-arrangements
-as it would, could it produce new chemical combinations as
-well as new mechanical adjustments. On the other hand,
-chemical affinities that are easily overcome, must be favourable
-to multiplied re-arrangements of the units.</p>
-
-<p class='c000'>This condition, as well as the preceding one, is fulfilled in
-the highest degree, by those aggregates which most variously
-display the transformation of the uniform into the multiform.
-Organic bodies are on the average distinguished from inorganic
-bodies, by the readiness with which the compounds
-they consist of undergo decomposition, and recomposition:
-the chemical cohesions of their components are so comparatively
-small, that small incident forces suffice to overcome
-them and cause transpositions of the components. Further,
-between the two great divisions of organisms, we find a
-contrast in the degree of Evolution co-existing with a contrast
-in the degree of chemical modifiability. As a class, the
-nitrogenous compounds are peculiarly unstable; and, speaking
-generally, these are present in much larger quantities in
-animal tissues than they are in vegetal tissues; while, speaking
-generally, animals are much more heterogeneous than
-plants.</p>
-
-<p class='c000'>Under this head it may be well also to point out that, other
-things equal, the structural variety which is possible in any
-aggregate, must bear a relation to the number of kinds of
-units contained in the aggregate. A body made up of units
-of one order, cannot admit of so many different re-arrangements,
-<span class='pageno' id='Page_341'>341</span>as one made up of units of two orders. And each
-additional order of units must increase, in a geometrical proportion,
-the number of re-arrangements that may be made.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 103. Yet one more condition to be specified, is the state
-of agitation in which the constituents of an aggregate are
-kept. A familiar expedience will introduce us to this condition.
-When a vessel has been filled to the brim with loose
-fragments, shaking the vessel causes them to settle down
-into less space, so that more may be put in. And when
-among these fragments, there are some of much greater
-specific gravity than the rest, these will, in the course of a
-prolonged shaking, find their way to the bottom. What
-now is the meaning of these two results, when expressed in
-general terms? We have a group of units acted on by an
-incident force—the attraction of the Earth. So long as
-these units are not agitated, this incident force produces no
-changes in their relative positions; agitate them, and immediately
-their loose arrangement passes into a more compact
-arrangement. Again, so long as they are not agitated,
-the incident force cannot separate the heavier units from the
-lighter; agitate them, and immediately the heavier units
-begin to segregate. By these illustrations, a rude idea will
-be conveyed of the effect which vibration has in facilitating
-those re-arrangements which constitute Evolution. What
-here happens with visible units subject to visible oscillations,
-happens also with invisible units subject to invisible oscillations.</p>
-
-<p class='c000'>One or two cases in which these oscillations are of mechanical
-origin, may first be noted. When a bar of steel is
-suspended in the magnetic meridian, and repeatedly so struck
-as to send vibrations through it, it becomes magnetized: the
-magnetic force of the Earth, which does not permanently
-affect it while undisturbed, alters its internal state when a
-mechanical agitation is propagated among its particles; and
-the alteration is believed by physicists, to be a molecular re-arrangement.
-<span class='pageno' id='Page_342'>342</span>It may be fairly objected that this re-arrangement
-is hypothetical; and did the fact stand alone, it would
-be of little worth. It gains significance, however, when
-joined with the fact that in the same substance, long-continued
-mechanical vibrations are followed by molecular
-re-arrangements that are abundantly visible. A piece of iron
-which, when it leaves the workshop, is fibrous in structure,
-will become crystalline if exposed to a perpetual jar.
-Though the polar forces mutually exercised by the atoms,
-fail to change their disorderly arrangement into an orderly
-arrangement while the atoms are relatively quiescent, these
-forces produce this change when the atoms are kept in a
-state of intestine disturbance.</p>
-
-<p class='c000'>But the effects which visible oscillations and oscillations
-sensible to touch, have in facilitating the re-arrangement of
-parts by an incident force, are insignificant compared with
-the effects which insensible oscillations have in aiding such
-change of structure. It is a doctrine now generally accepted
-among men of science, that the particles of tangible matter,
-as well as the particles of ether, undulate. As interpreted in
-conformity with this doctrine, the heat of a body is simply
-its state of molecular motion. A mass which feels cold,
-is one having but slight molecular motion, and conveying
-but slight molecular motion to the surrounding medium or to
-the hand touching it. A mass hot enough to radiate a sensible
-warmth, is one of which the more violently agitated molecules,
-communicate increased undulations to the surrounding
-ethereal medium; while the burn inflicted by it on the skin,
-is the expression of increased undulations of the organic
-molecules. Such further heat as produces softening and a
-consequent distortion of the mass, is an agitation so much
-augmented that the units can no longer completely maintain
-their relative positions. Fusion is an agitation so extreme,
-that the relative positions of the units are changeable
-with ease. When, finally, at a still higher temperature,
-the liquid is transformed into a gas, the explanation
-<span class='pageno' id='Page_343'>343</span>is, that the oscillations are so violent as to overbalance
-that force which held the units in close contiguity—so violent
-as to keep the units at those relatively great distances
-apart to which they are now thrown. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Since
-the establishment of the correlation between heat and motion
-first gave probability to this hypothesis, it has been receiving
-various confirmations—especially by recent remarkable discoveries
-respecting the absorption of heat by gases. Prof.
-Tyndall has proved that the quantity of heat which any gas
-takes up from rays of heat passing through it, has a distinct
-relation to the complexity of the atoms composing the gas.
-The simple gases abstract but little; the gases composed of
-binary atoms abstract, say in round numbers, a hundred times
-as much; while the gases composed of atoms severally containing
-three, four, or more simple ones, abstract something
-like a thousand times as much. These differences Prof. Tyndall
-regards as due to the different abilities of the different
-atoms to take up, in the increase of their own undulations,
-those undulations of the ethereal medium which constitute
-heat—an interpretation in perfect accordance with the late
-results of spectrum-analysis; which go to show that the
-various elementary atoms, when in an aeriform state, intercept
-those luminiferous vibrations of the ether which are in
-unison or harmony with their own. And since it holds of
-solid as of gaseous matters, that those consisting of simple
-units transmit heat far more readily than those consisting of
-complex units; we get confirmation of the inference otherwise
-reached, that the units of matter in whatever state of aggregation
-they exist, oscillate, and that variations of temperature
-are variations in the amounts of their oscillations.</p>
-
-<p class='c000'>Proceeding on this hypothesis, which it would be out of
-place here to defend at greater length, we have now to note
-how the re-arrangement of parts is facilitated by these insensible
-vibrations, as we have seen it to be by sensible vibrations.
-One or two cases of physical re-arrangement may first
-be noted. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;When some molten glass is dropped into
-<span class='pageno' id='Page_344'>344</span>water, and when its outside is thus, by sudden solidification,
-prevented from partaking in that contraction which the subsequent
-cooling of the inside tends to produce; the units are
-left in such a state of tension, that the mass flies into fragments
-if a small portion of it be broken off. But now, if this
-mass be kept for a day or two at a considerable heat, though
-a heat not sufficient to alter its form or produce any sensible
-diminution of hardness, this extreme brittleness disappears:
-the component particles being thrown into greater agitation,
-the tensile forces are enabled to re-arrange them into a state
-of equilibrium. An illustration of another order is furnished
-by the subsidence of fine precipitates. These sink down very
-slowly from solutions that are cold; while warm solutions
-deposit them with comparative rapidity. That is to say, an
-increase of molecular vibration throughout the mass, allows
-the suspended particles to separate more readily from the
-particles of fluid. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The effect of heat on chemical re-arrangement
-is so familiar, that examples are scarcely needed.
-Be the substances concerned gaseous, liquid, or solid, it
-equally holds that their chemical unions and disunions are
-aided by a rise of temperature. Affinities which do not
-suffice to effect the re-arrangement of mixed units that are in
-a state of feeble agitation, suffice to effect it when the agitation
-is raised to a certain point. And so long as this molecular
-motion is not great enough to prevent those chemical
-cohesions which the affinities tend to produce, increase of it
-gives increased facility of chemical re-arrangement.</p>
-
-<p class='c000'>This condition, in common with the preceding ones, is
-fulfilled most completely in those aggregates which exhibit
-the phenomena of Evolution in the highest degree; namely,
-the organic aggregates. And throughout the various orders
-and states of these, we find minor contrasts showing the relation
-between amount of molecular vibration and activity of
-the metamorphic changes. Such contrasts may be arranged
-in the several following groups. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Speaking generally,
-the phenomena of Evolution are manifested in a much lower
-<span class='pageno' id='Page_345'>345</span>degree throughout the vegetal kingdom than throughout the
-animal kingdom; and speaking generally, the heat of plants
-is less than that of animals. Among plants themselves, the
-organic changes vary in rate as the temperature varies.
-Though light is the agent which effects those molecular
-changes causing vegetal growth, yet we see that in the absence
-of heat, such changes are not effected: in winter there
-is enough light, but the heat being insufficient, plant-life is
-suspended. That this is the sole cause of the suspension, is
-proved by the fact that at the same season, plants contained
-in hot-houses, where they receive even a smaller amount of
-light, go on producing leaves and flowers. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;A comparison
-of the several divisions of the animal kingdom with
-each other, shows among them parallel relations. Regarded
-as a whole, vertebrate animals are higher in temperature than
-invertebrate ones; and they are as a whole higher in organic
-activity and development. Between subdivisions of the vertebrata
-themselves, like differences in the state of molecular
-vibration, accompany like differences in the degree of evolution.
-The least heterogeneous of the vertebrata are the
-fishes; and in most cases, the heat of fishes is nearly the
-same as that of the water in which they swim: only some
-of them being decidedly warmer. Though we habitually speak
-of reptiles as cold-blooded; and though they have not much
-more power than fishes of maintaining a temperature above
-that of their medium; yet since their medium (which is, in
-the majority of cases, the air of warm climates) is on the
-average warmer than the medium inhabited by fishes, the
-temperature of the class of reptiles is higher than that of the
-class of fishes; and we see in them a correspondingly higher
-complexity. The much more active molecular agitation in
-mammals and birds, is associated with a considerably greater
-multiformity of structure and a very much greater vivacity.
-And though birds, which are hotter blooded than mammals,
-do not show us a greater multiformity; yet, judging
-from their apparently greater locomotive powers, we may
-<span class='pageno' id='Page_346'>346</span>infer more rapid functional changes, which, equally with structural
-changes, imply molecular re-arrangement. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The
-most instructive contrasts, however, are those presented by
-the same organic aggregates at different temperatures.
-Thus we see that ova undergoing development, must be kept
-more or less warm—that in the absence of a certain molecular
-vibration, the re-arrangement of parts does not go on.
-We see, again, that in hybernating animals, loss of heat carried
-to a particular point, results in extreme retardation of
-the organic changes. Yet further, we see that in animals
-which do not hybernate, as in man, prolonged exposure to
-extreme cold, produces an irresistible tendency to sleep
-(which implies a lowering of the functional activity); and
-then, if the abstraction of heat continues, this sleep ends in
-death, or arrest of functional activity. Lastly, we see that
-when the temperature is lowered till the contained water
-solidifies, there is a stoppage not only of those molecular re-arrangements
-which constitute life and development, but also
-of those molecular re-arrangements which constitute decomposition.</p>
-
-<p class='c000'>Evidently then, both sensible and insensible agitations
-among the components of an aggregate, facilitate any re-distributions
-to which there may be a tendency. When that
-rhythmic change in the relative positions of the units which
-constitutes vibration, is considerable, the relative positions of
-the units more readily undergo permanent changes through
-the action of incident forces.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 104. These special conditions to Evolution, are clearly
-but different forms of one general condition. The abstract
-proposition, that a permanent re-arrangement of units is possible
-only when they have neither absolute immobility nor
-absolute mobility with respect to each other, we saw to be
-practically equivalent to the proposition, that extreme cohesion
-and extreme want of cohesion among the units are unfavourable
-to Evolution. Be this cohesion or want of cohesion
-<span class='pageno' id='Page_347'>347</span>that which physically characterizes the matter as we
-ordinarily know it; be it that cohesion or want of cohesion
-distinguished as chemical; or be it that cohesion or want of
-cohesion consequent on the degree of molecular vibration;
-matters not, in so far as the general conclusion is concerned.
-Inductively as well as deductively, we find that the genesis
-of such permanent changes in the relative positions of parts,
-as can be effected without destroying the continuity of the
-aggregate, implies a medium stability in the relative positions
-of the parts: be this stability physical, chemical, or
-that which varies with the state of agitation. And as might
-be anticipated <i><span lang="fr" xml:lang="fr">à priori</span></i>, it is proved <i><span lang="fr" xml:lang="fr">à posteriori</span></i>, that this re-arrangement
-of parts goes on most actively in those aggregates
-whose units are moderately influenced by all these
-forces which affect their mobility.</p>
-
-<p class='c000'>Here also may properly be added the remark, that to effect
-these changes in the relative positions of parts, the incident
-forces must range within certain limits. It is wholly a
-question of the ratio between those agencies which hold the
-units in their positions, and those agencies which tend to
-change their positions. Having given intensities in the
-powers that oppose re-arrangement, there need proportionate
-intensities in the powers that work re-arrangement. As
-there must be neither too great nor too little cohesion; so
-there must be neither too little nor too great amounts of the
-influences antagonistic to cohesion. While a slight mechanical
-strain produces no lasting alterations in the relative positions
-of parts, an excessive mechanical strain causes disruption—causes
-so great an alteration in the relative positions of
-parts as to destroy their union in one aggregate. While a
-very feeble chemical affinity brought to bear on the associated
-units, fails to work any re-arrangement of them; a chemical
-affinity that is extremely intense, destroys their structural
-continuity, and reduces such complex re-arrangements as
-have been made, to comparatively simple ones. And while
-in the absence of adequate thermal undulations, the units
-<span class='pageno' id='Page_348'>348</span>have not freedom enough to obey the re-arranging influences
-impressed on them, the incidence of violent thermal undulations
-gives them such extreme freedom that they break their
-connexions, and the aggregate lapses into a liquid or gaseous
-form.</p>
-
-<p class='c000'>On the one hand, therefore, the statical forces which uphold
-the state of aggregation must not be so great as wholly
-to prevent those changes of relative position among the
-units which the dynamical forces tend to produce; and, on
-the other hand, the dynamical forces must not be so great as
-wholly to overcome the statical forces, and destroy the state
-of aggregation. The excess of the dynamical forces must
-be sufficient to produce Evolution, but not sufficient to produce
-Dissolution.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 105. And now we are naturally introduced to a consideration
-which, though it does not come quite within the limits
-of this chapter as expressed in its title, may yet be more
-conveniently dealt with here than elsewhere. Hitherto we
-have studied the metamorphosis of things, only as exhibited
-in the changed distribution of matter. It remains to look at
-it as exhibited in the changed distribution of motion. The
-definition of Evolution in its material aspect, has to be
-supplemented by a definition of Evolution in its dynamical
-aspect.</p>
-
-<p class='c000'>On inquiring the source of the sensible motions seen in
-every kind of Evolution, we find them all traceable to insensible
-motions; either of that tangible matter which we perceive as
-constituting the objects around us, or of that intangible matter
-which we infer as occupying space. A brief reconsideration
-of the facts will make this obvious. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The formation of
-celestial bodies, supposing it caused by the union of dispersed
-units, must, from the beginning, have involved a diminished
-motion of these units with respect to each other; and such
-motion as each resulting body acquired, must previously
-have existed in the motions of its units. If concrete matter
-<span class='pageno' id='Page_349'>349</span>has arisen by the aggregation of diffused matter, then
-concrete motion has arisen by the aggregation of diffused
-motion. That which now exists as the movement of masses,
-implies the cessation of an equivalent molecular movement.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Those transpositions of matter which constitute
-geological changes, are clearly referable to the same
-source. As before shown, the denudation of lands and deposit
-of new strata, are effected by water in the course of its descent
-from the clouds to the sea, or during the arrest of those undulations
-produced on it by winds; and, as before shown, the
-elevation of water to the height whence it fell, is due to solar
-heat, as is also the genesis of those aerial currents which drift
-it about when evaporated and agitate its surface when condensed.
-That is to say, the molecular motion of the etherial
-medium, is transformed into the motion of gases, thence into
-the motion of liquids, and thence into the motion of solids—stages
-in each of which, successively, a certain amount of
-molecular motion is lost and an equivalent motion of masses
-produced. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;If we seek the origin of vital movements,
-we soon reach a like conclusion. The actinic rays issuing
-from the Sun, enable the plant to reduce special elements existing
-in gaseous combination around it, to a solid form,—enable
-the plant, that is, to grow and carry on its functional changes.
-And since growth, equally with circulation of sap, is a mode of
-sensible motion, while those rays which have been expended in
-generating it consist of insensible motions, we have here, too, a
-transformation of the kind alleged. Animals, derived as their
-forces are, directly or indirectly, from plants, carry this transformation
-a step further. The automatic movements of the
-viscera, together with the voluntary movements of the limbs
-and body at large, arise at the expense of certain molecular
-movements throughout the nervous and muscular tissues; and
-these originally arose at the expense of certain other molecular
-movements propagated by the Sun to the Earth; so that
-both the structural and functional motions which organic
-Evolution displays, are motions of aggregates generated by
-<span class='pageno' id='Page_350'>350</span>the arrested motions of units. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Even with the aggregates
-of these aggregates the same rule holds. For among
-associated men, the progress is ever towards a merging of individual
-actions in the actions of corporate bodies. An undeveloped
-society is composed of members between whom
-there is little concert: they fulfil their several wants without
-mutual aid; and only on occasions of aggression or defence,
-act together—occasions on which their combination, small as
-it is in extent, frequently fails because it is so imperfect.
-In the course of civilization, however, co-operation becomes
-step by step more decided. As tribes grow into nations, there
-result larger aggregates, each of which has a joint political
-life—a common policy and movement with respect to other
-aggregates. Legislative and administrative progress, involves
-an increase in the number of restraining agents
-brought into united and simultaneous action. In military
-organization, we see an advance from small undisciplined hordes
-of armed men, to vast bodies of regular troops, so drilled
-that the movements of the units are entirely subordinated to
-the movements of the masses. Nor does industrial development
-fail to show parallel changes. Beginning with independent
-workers, and passing step by step to the employment
-of several assistants by one master, there has ever been, and
-still is, a progress towards the co-operation of greater masses
-of labourers in the same establishment, and towards the union
-of capitalists into more numerous and larger companies: in
-both which kinds of combined action, equivalent amounts of
-individual action disappear. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Under all its forms,
-then, Evolution, considered dynamically, is a decrease in the
-relative movements of parts, and an increase in the relative
-movements of wholes—using the words parts and wholes in
-their widest senses. From the infinitesimal motions of those
-infinitesimal units composing the etherial medium, to the
-larger though still insensible motions of the larger though
-still insensible units composing gaseous, fluid, and solid
-matter, and thence to the visible motions of visible aggregates,
-<span class='pageno' id='Page_351'>351</span>the advance is from molecular motion to the motion of
-masses.</p>
-
-<p class='c000'>But now what of the converse process? If the foregoing
-proposition is true, then a change from the motion of masses
-to molecular motion, is the opposite to Evolution—is Dissolution.
-Is this so? &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Of inorganic dissolution we
-have but little experience; or at least, our experience of it is
-on too small a scale to exhibit it as the antithesis of Evolution.
-We know, indeed, that when solids are dissolved in
-liquids, their dissolution implies increased movements of
-their units, at the expense of diminished movements among
-the units of their solvents; and we know that when a liquid
-evaporates, its dissipation or dissolution similarly implies greater
-relative movements of the units, and decrease of such combined
-movement as they before had. But since these small
-aggregates of inorganic matter, do not exhibit the phenomena
-of Evolution, save in the form of simple integration; so they
-do not exhibit the phenomena of dissolution, save in the
-form of simple disintegration. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Of organic dissolution,
-however, our experience suffices to show that it is a decrease
-of combined motion, and an increase in the motion of
-uncombined parts. The gradual cessation of functions,
-vegetal or animal, is a cessation of the sensible movements of
-fluids and solids. In animals, the impulsions of the body
-from place to place, first cease; presently the limbs cannot
-be stirred; later still the respiratory actions stop; finally the
-heart becomes stationary, and, with it, the circulating fluids.
-That is, the transformation of molecular motion into the
-motion of masses, comes to an end. What next takes place?
-We cannot say that sensible movements are transformed into
-insensible movements; for sensible movements no longer exist.
-Nevertheless, the process of decay involves an increase of insensible
-movements; since this is far greater in the gases
-generated by decomposition, than it is in the fluid-solid
-matters generating them. Indeed, it might be contended
-that as, during Dissolution, there is a change from the vibration
-<span class='pageno' id='Page_352'>352</span>of large compound atoms to the vibration of small and
-comparatively simple ones, the process is strictly antithetical
-to that of Evolution. In conformity with the now current
-conception lately explained, each of the highly complex
-chemical units composing an organic body, possesses a
-rhythmic movement—a movement in which its many component
-units jointly partake. When decomposition breaks
-up these highly complex atoms, and their constituents
-assume a gaseous form, there is both an increase of
-molecular motion implied by the diffusion, and a further
-increase implied by the resolving of such motions as the
-aggregate atoms possessed, into motions of their constituent
-atoms. So that in organic dissolution we have, first, an end
-put to that transformation of the motion of units into the
-motion of aggregates, which constitutes Evolution, dynamically
-considered; and we have also, though in a subtler
-sense, a transformation of the motion of aggregates into the
-motion of units. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The formula equally applies to the
-dissolution of a society. When social ties, be they governmental
-or industrial, are destroyed, the combined actions of
-citizens lapse into uncombined actions. Those general forces
-which restrained individual doings, having disappeared, the
-only remaining restraints are those separately exercised by
-individuals on each other. There are no longer any of the
-joint operations by which men satisfy their wants; and, in so
-far as they can, they satisfy their wants by separate operations.
-That is to say, the movement of parts replaces the
-movement of wholes.</p>
-
-<p class='c000'>Under its dynamical aspect then, Evolution, so far as we
-can trace it, is a change from molecular motion to the motion
-of masses; while Dissolution, so far as we can trace it, is a
-change from the motion of masses to molecular motion.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 106. To these abstract definitions may be added concrete
-ones. Besides an integration of motions corresponding to
-the integration of masses, Evolution involves an increase in
-<span class='pageno' id='Page_353'>353</span>the multiformity of the motions, corresponding to the increase
-in the multiformity of the masses. If, contemplating it as
-materially displayed, we find Evolution to consist in the
-change from an indefinite, homogeneous distribution of parts
-to a definite, heterogeneous distribution of parts; then, contemplating
-Evolution as dynamically displayed, it consists in
-a change from indefinite, homogeneous motions to definite,
-heterogeneous motions.</p>
-
-<p class='c000'>This change takes place under the form of an increased
-variety of rhythms. We have already seen that all motion
-is rhythmical, from the infinitesimal vibrations of infinitesimal
-molecules, up to those vast oscillations between perihelion
-and aphelion performed by vast celestial bodies. And
-as the contrast between these extreme cases suggests, a multiplication
-of rhythms must accompany a multiplication in
-the degrees and modes of aggregation, and in the relations
-of the aggregated masses to incident forces. The degree or
-mode of aggregation will not, indeed, affect the rate or
-extent of rhythm where the incident force increases as the
-aggregate increases, which is the case with gravitation: here
-the only cause of variation in rhythm, is difference of relation
-to the incident forces; as we see in a pendulum, which,
-though unaffected in its movements by a change in the
-weight of the bob, alters its rate of oscillation when taken
-to the equator. But in all cases where the incident forces do
-not vary as the masses, every new order of aggregation
-initiates a new order of rhythm: witness the conclusion
-drawn from the recent researches into radiant heat and light,
-that the atoms of different gases have different rates of undulation.
-So that increased multiformity in the arrangement
-of matter, has necessarily generated increased multiformity
-of rhythm; both through increased variety in the
-sizes and forms of aggregates, and through increased variety
-in their relations to the forces which move them. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The
-advancing heterogeneity of motion, thus entailed by advancing
-heterogeneity in the distribution of matter, does not, however,
-<span class='pageno' id='Page_354'>354</span>end here. Besides multiplication in the kinds of rhythm,
-there is a progressing complexity in their combinations. As
-there arise wholes composed of heterogeneous parts, each of
-which has its own rhythm, there must arise compound
-rhythms proportionately heterogeneous. We before saw
-that this is visible even in the cyclical perturbations of the
-Solar System—simple as are its structure and movements.
-And when we contemplate highly-developed organic bodies,
-we find the complication of rhythms so great, that it defies
-definite analysis, and from moment to moment works out in
-resultants that are incalculable.</p>
-
-<p class='c000'>This conception of Evolution forms a needful complement
-to that on which we have hitherto chiefly dwelt. To comprehend
-the phenomena in their entirety, we have to contemplate
-both the increasing multiformity of parts, and the
-increasing multiformity of the actions simultaneously assumed
-by these parts. At the same time that there are differentiations
-and integrations of the matter, there are differentiations
-and integrations of its motion. And this increasingly heterogeneous
-distribution of motion, constitutes Evolution <em>functionally</em>
-considered; as distinguished from that increasingly
-heterogeneous distribution of matter, which constitutes Evolution
-<em>structurally</em> considered. While of course, Dissolution
-exhibits the transition to a reverse distribution, both structurally
-and functionally.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 107. One other preliminary must be set down. When
-specifically interpreting Evolution, we shall have to consider
-under their concrete forms, the various resolutions of force that
-follow its conflict with matter. Here it will be well to contemplate
-such resolutions under their most general or abstract
-forms.</p>
-
-<p class='c000'>Any incident force is primarily resolvable or divisible into
-its <em>effective</em> and <em>non-effective</em> portions. In mechanical impact,
-the entire momentum of a striking body is never communicated
-to the body struck: even under those most favourable
-<span class='pageno' id='Page_355'>355</span>conditions in which the striking body loses all its sensible
-motion, there still remains with it a portion of the original
-momentum, under the shape of that insensible motion produced
-among its particles by the collision. Of the light or
-heat falling on any mass, a part, more or less considerable, is
-reflected; and only the remaining part works molecular
-changes in the mass. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Next it is to be noted that the
-effective force, is itself divisible into the <em>temporarily effective</em>
-and the <em>permanently effective</em>. The units of an aggregate
-acted on, may undergo those rhythmical changes of relative
-position which constitute increased vibration, as well as
-other changes of relative position which are not from instant
-to instant neutralized by opposite ones. Of these, the first,
-disappearing in the shape of radiating undulations, leave the
-molecular arrangement as it originally was; while the
-second conduce to that re-arrangement constituting Evolution.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Yet a further distinction has to be made.
-The permanently effective force works out changes of relative
-position of two kinds—the <em>insensible</em> and the <em>sensible</em>. The
-insensible transpositions among the units are those constituting
-what we call chemical composition and decomposition;
-and it is these which we recognize as the qualitative differences
-that arise in an aggregate. The sensible transpositions
-are such as result when certain of the units, instead of
-being put into different relations with their immediate neighbours,
-are carried away from them and united together elsewhere.</p>
-
-<p class='c000'>Concerning these divisions and sub-divisions of any force
-affecting an aggregate, the fact which it chiefly concerns us
-to observe, is, that they are complementary to each other.
-Of the whole incident force, the effective must be that which
-remains after deducting the non-effective. The two parts of
-the effective force must vary inversely as each other: where
-much of it is temporarily effective, little of it can be permanently
-effective; and <i><span lang="la" xml:lang="la">vice versâ</span></i>. Lastly, the permanently
-effective force, being expended in working both the insensible
-<span class='pageno' id='Page_356'>356</span>re-arrangements which constitute chemical modification, and
-the sensible re-arrangements which result in structure, must
-generate of either kind an amount that is great or small in
-proportion as it has generated a small or great amount of the
-other.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 108. And now of the propositions grouped together in
-this chapter, it may be well to remark that, in common with
-foregoing propositions, they have for their warrant the fundamental
-truth with which our synthesis set out.</p>
-
-<p class='c000'>That when a given force falls on any aggregate, the permanently
-effective part of it will produce an amount of re-arrangement
-that is inversely proportional to the cohesion
-existing among the parts of the aggregate, is demonstrable
-<i><span lang="fr" xml:lang="fr">à priori</span></i>. Whether the cohesion be mechanical or chemical,
-or whether it be temporarily modified by a changed degree
-of molecular vibration, matters not to the general conclusion.
-In all these cases it follows from the persistence of force, that
-in proportion as the units offer great resistance to alteration
-in their relative positions, must the amount of motion which
-a given force impresses on them be small. The proposition
-is in fact an identical one; since the cohesion of units is
-known to be great or small, only by the smallness or greatness
-of the re-arrangement which a given incident force
-produces.</p>
-
-<p class='c000'>The continuity of motion we found to be a corollary from
-the persistence of force; and from the continuity of motion,
-it follows that molecular motion and the motion of masses
-can be respectively increased only at each other’s expense.
-Hence, if in the course of Evolution there arises a motion of
-masses that did not before exist, there must have ceased an
-equivalent molecular motion; and if in the course of Dissolution
-there arises a molecular motion that did not before
-exist, an equivalent motion of masses must have disappeared.</p>
-
-<p class='c000'>Equally necessary is the conclusion that the several results
-of the force expended on any aggregate, must be complementary
-<span class='pageno' id='Page_357'>357</span>to each other. It is not less obviously a corollary
-from the persistence of force, that of the whole incident force
-the effective is the part which remains after deducting the
-non-effective; than it is, that of the effective force, whatever
-does not work permanent results, works temporary results,
-and that such amount of the permanently effective force as is
-not absorbed in producing insensible re-arrangements, will
-produce sensible re-arrangements.</p>
-
-<div>
- <span class='pageno' id='Page_358'>358</span>
- <h3 class='c001'>CHAPTER XIII.<br /> <span class='large'>THE INSTABILITY OF THE HOMOGENEOUS.<a id='r16' /><a href='#f16' class='c011'><sup>[16]</sup></a></span></h3>
-</div>
-
-<p class='c006'>§ 109. Thus far our steps towards the interpretation of
-Evolution have been preparatory. We have dealt with the
-factors of the process, rather than the process itself. After
-the ultimate truth that, Matter, Motion, and Force, as
-cognizable by human intelligence, can neither come into
-existence nor cease to exist, we have considered certain other
-ultimate truths concerning the modes in which Force and
-Motion are manifested during the changes they produce in
-Matter. Now we have to study the changes themselves.
-We have here to analyze that re-arrangement in the parts of
-Matter, which occurs under the influence of Force, that is unchangeable
-in quantity though changeable in form, through
-the medium of Motion taking place rhythmically along lines
-of least resistance. The proposition which comes first in
-logical order, is, that some re-arrangement must result; and
-this proposition may be best dealt with under the more
-specific shape, that the condition of homogeneity is a condition
-of unstable equilibrium.</p>
-
-<p class='c000'>First, as to the meaning of the terms; respecting which
-some readers may need explanation. The phrase <em>unstable
-equilibrium</em> is one used in mechanics to express a balance of
-forces of such kind, that the interference of any further force,
-however minute, will destroy the arrangement previously
-<span class='pageno' id='Page_359'>359</span>subsisting; and bring about a totally different arrangement.
-Thus, a stick poised on its lower end is in unstable equilibrium:
-however exactly it may be placed in a perpendicular
-position, as soon as it is left to itself it begins, at first imperceptibly,
-to lean on one side, and with increasing rapidity
-falls into another attitude. Conversely, a stick suspended
-from its upper end is in stable equilibrium: however much
-disturbed, it will return to the same position. The proposition
-is, then, that the state of homogeneity, like the state of
-the stick poised on its lower end, is one that cannot be maintained.
-Let us take a few illustrations.</p>
-
-<p class='c000'>Of mechanical ones the most familiar is that of the scales.
-If they be accurately made, and not clogged by dirt or rust,
-it is impossible to keep a pair of scales perfectly balanced:
-eventually one scale will descend and the other ascend—they
-will assume a heterogeneous relation. Again, if we sprinkle
-over the surface of a fluid a number of equal-sized particles,
-having an attraction for each other, they will, no matter how
-uniformly distributed, by and by concentrate irregularly into
-one or more groups. Were it possible to bring a mass of
-water into a state of perfect homogeneity—a state of complete
-quiescence, and exactly equal density throughout—yet the
-radiation of heat from neighbouring bodies, by affecting
-differently its different parts, would inevitably produce inequalities
-of density and consequent currents; and would so
-render it to that extent heterogeneous. Take a piece of red-hot
-matter, and however evenly heated it may at first be, it
-will quickly cease to be so: the exterior, cooling faster than
-the interior, will become different in temperature from it.
-And the lapse into heterogeneity of temperature, so obvious
-in this extreme case, takes place more or less in all
-cases. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The action of chemical forces supplies other
-illustrations. Expose a fragment of metal to air or water,
-and in course of time it will be coated with a film of oxide,
-carbonate, or other compound: that is—its outer parts will
-become unlike its inner parts. Usually the heterogeneity
-<span class='pageno' id='Page_360'>360</span>produced by the action of chemical forces on the surfaces of
-masses, is not striking; because the changed portions are
-soon washed away, or otherwise removed. But if this is prevented,
-comparatively complex structures result. Quarries
-of trap-rock contain some striking examples. Not unfrequently
-a piece of trap may be found reduced, by the
-action of the weather, to a number of loosely-adherent coats,
-like those of an onion. Where the block has been quite undisturbed,
-we may trace the whole series of these, from the
-angular, irregular outer one, through successively included
-ones in which the shape becomes gradually rounded, ending
-finally in a spherical nucleus. On comparing the original
-mass of stone with this group of concentric coats, each of
-which differs from the rest in form, and probably in the state
-of decomposition at which it has arrived, we get a marked
-illustration of the multiformity to which, in lapse of time,
-a uniform body may be brought by external chemical
-action. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The instability of the homogeneous is equally
-seen in the changes set up throughout the interior of a mass,
-when it consists of units that are not rigidly bound together.
-The atoms of a precipitate never remain separate, and equably
-distributed through the fluid in which they make their appearance.
-They aggregate either into crystalline grains,
-each containing an immense number of atoms, or they aggregate
-into flocculi, each containing a yet larger number; and
-where the mass of fluid is great, and the process prolonged,
-these flocculi do not continue equidistant, but break up into
-groups. That is to say, there is a destruction of the balance
-at first subsisting among the diffused particles, and also of
-the balance at first subsisting among the groups into which
-these particles unite. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Certain solutions of non-crystalline
-substances in highly volatile liquids, exhibit in
-the course of half an hour a whole series of changes that are
-set up in the alleged way. If for example a little shell-lac-varnish
-(made by dissolving shell-lac in coal-naphtha until it
-is of the consistence of cream) be poured on a piece of paper,
-<span class='pageno' id='Page_361'>361</span>the surface of the varnish will shortly become marked by
-polygonal divisions, which, first appearing round the edge of
-the mass, spread towards its centre. Under a lense these
-irregular polygons of five or more sides, are seen to be severally
-bounded by dark lines, on each side of which there are
-light-coloured borders. By the addition of matter to their
-inner edges, the borders slowly broaden, and thus encroach
-on the areas of the polygons; until at length there remains
-nothing but a dark spot in the centre of each. At
-the same time the boundaries of the polygons become curved;
-and they end by appearing like spherical sacs pressed together;
-strangely simulating (but only simulating) a group of
-nucleated cells. Here a rapid loss of homogeneity is exhibited
-in three ways:—First, in the formation of the film,
-which is the seat of these changes; second, in the formation
-of the polygonal sections into which this film divides; and
-third, in the contrast that arises between the polygonal sections
-round the edge, where they are small and early formed,
-and those in the centre which are larger and formed later.</p>
-
-<p class='c000'>The instability thus variously illustrated is obviously consequent
-on the fact, that the several parts of any homogeneous
-aggregation are necessarily exposed to different forces—forces
-that differ either in kind or amount; and being exposed
-to different forces they are of necessity differently
-modified. The relations of outside and inside, and of comparative
-nearness to neighbouring sources of influence, imply
-the reception of influences that are unlike in quantity or
-quality, or both; and it follows that unlike changes will be
-produced in the parts thus dissimilarly acted upon.</p>
-
-<p class='c000'>For like reasons it is manifest that the process must repeat
-itself in each of the subordinate groups of units that are
-differentiated by the modifying forces. Each of these subordinate
-groups, like the original group, must gradually, in
-obedience to the influences acting upon it, lose its balance of
-parts—must pass from a uniform into a multiform state.
-And so on continuously. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Whence indeed it is clear
-<span class='pageno' id='Page_362'>362</span>that not only must the homogeneous lapse into the non-homogeneous,
-but that the more homogeneous must tend
-ever to become less homogeneous. If any given whole, instead
-of being absolutely uniform throughout, consist of parts
-distinguishable from each other—if each of these parts, while
-somewhat unlike other parts, is uniform within itself; then,
-each of them being in unstable equilibrium, it follows that
-while the changes set up within it must render it multiform,
-they must at the same time render the whole more multiform
-than before. The general principle, now to be followed
-out in its applications, is thus somewhat more comprehensive
-than the title of the chapter implies. No demurrer to
-the conclusions drawn, can be based on the ground that perfect
-homogeneity nowhere exists; since, whether that state with
-which we commence be or be not one of perfect homogeneity,
-the process must equally be towards a relative heterogeneity.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 110. The stars are distributed with a three-fold irregularity.
-There is first the marked contrast between the
-plane of the milky way and other parts of the heavens, in
-respect of the quantities of stars within given visual areas.
-There are secondary contrasts of like kind in the milky way
-itself, which has its thick and thin places; as well as
-throughout the celestial spaces in general, which are much
-more closely strewn in some regions than in others. And
-there is a third order of contrasts produced by the aggregation
-of stars into small clusters. Besides this heterogeneity
-of distribution of the stars in general, considered without
-distinction of kinds, a further such heterogeneity is disclosed
-when they are classified by their differences of colour, which
-doubtless answer to differences of physical constitution.
-While the yellow stars are found in all parts of the heavens,
-the red and blue stars are not so: there are wide regions in
-which both red and blue stars are rare; there are regions in
-which the blue occur in considerable numbers, and there
-are other regions in which the red are comparatively abundant.
-<span class='pageno' id='Page_363'>363</span>Yet one more irregularity of like significance is presented
-by the nebulæ,—aggregations of matter which, whatever
-be their nature, most certainly belong to our sidereal
-system. For the nebulæ are not dispersed with anything
-like uniformity; but are abundant around the poles of the
-galactic circle and rare in the neighbourhood of its
-plane. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;No one will expect that anything like a definite
-interpretation of this structure can be given on the
-hypothesis of Evolution, or any other hypothesis. The most
-that can be looked for is some reason for thinking that irregularities,
-not improbably of these kinds, would occur in the
-course of Evolution, supposing it to have taken place. Any
-one called on to assign such reason might argue, that if the
-matter of which stars and all other celestial bodies consist, be
-assumed to have originally existed in a diffused form throughout
-a space far more vast even than that which our sidereal
-system now occupies, the instability of the homogeneous
-would negative its continuance in that state. In default of
-an absolute balance among the forces with which the dispersed
-particles acted on each other (which could not exist in
-any aggregation having limits) he might show that motion
-and consequent changes of distribution would necessarily
-result. The next step in the argument would be that in
-matter of such extreme tenuity and feeble cohesion there
-would be motion towards local centres of gravity, as well as
-towards the general centre of gravity; just as, to use a
-humble illustration, the particles of a precipitate aggregate
-into flocculi at the same time that they sink towards the
-earth. He might urge that in the one case as in the other,
-these smallest and earliest local aggregations must gradually
-divide into groups, each concentrating to its own centre of
-gravity,—a process which must repeat itself on a larger and
-larger scale. In conformity with the law that motion once
-set up in any direction becomes itself a cause of subsequent
-motion in that direction, he might further infer that the
-heterogeneities thus set up would tend ever to become more
-<span class='pageno' id='Page_364'>364</span>pronounced. Established mechanical principles would
-justify him in the conclusion that the motions of these irregular
-masses of slightly aggregated nebular matter towards
-their common centre of gravity must be severally rendered
-curvelinear, by the resistance of the medium from which they
-were precipitated; and that in consequence of the irregularities
-of distribution already set up, such conflicting curvelinear
-motions must, by composition of forces, end in a rotation
-of the incipient sidereal system. He might without difficulty
-show that the resulting centrifugal force must so far modify the
-process of general aggregation, as to prevent anything like
-uniform distribution of the stars eventually formed—that
-there must arise a contrast such as we see between the galactic
-circle and the rest of the heavens. He might draw the
-further not unwarrantable inference, that differences in the
-process of local concentration would probably result from the
-unlikeness between the physical conditions existing around
-the general axis of rotation and those existing elsewhere.
-To which he might add, that after the formation of distinct
-stars, the ever-increasing irregularities of distribution due to
-continuance of the same causes would produce that patchiness
-which distinguishes the heavens in both its larger and
-smaller areas. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;We need not here however commit
-ourselves to such far-reaching speculations. For the purposes
-of the general argument it is needful only to show, that
-any finite mass of diffused matter, even though vast enough
-to form our whole sidereal system, could not be in stable
-equilibrium; that in default of absolute sphericity, absolute
-uniformity of composition, and absolute symmetry of relation
-to all forces external to it; its concentration must go on with
-an ever-increasing irregularity; and that thus the present
-aspect of the heavens is not, so far as we can judge, incongruous
-with the hypothesis of a general evolution consequent
-on the instability of the homogeneous.</p>
-
-<p class='c000'>Descending to that more limited form of the nebular hypothesis
-which regards the solar system as having resulted
-<span class='pageno' id='Page_365'>365</span>by gradual concentration; and assuming this concentration
-to have advanced so far as to produce a rotating spheroid of
-nebulous matter; let us consider what further consequence
-the instability of the homogeneous necessitates. Having
-become oblate in figure, unlike in the densities of its centre
-and surface, unlike in their temperatures, and unlike in the
-velocities with which its parts move round their common axis,
-such a mass can no longer be called homogeneous; and
-therefore any further changes exhibited by it as a whole, can
-illustrate the general law, only as being changes from a
-more homogeneous to a less homogeneous state. Changes of
-this kind are to be found in the transformations of such of its
-parts as are still homogeneous within themselves. If we
-accept the conclusion of Laplace, that the equatorial portion
-of this rotating and contracting spheroid will at successive
-stages acquire a centrifugal force great enough to prevent
-any nearer approach to the centre round which it rotates,
-and will so be left behind by the inner parts of the spheroid
-in its still-continued contraction; we shall find, in the fate of
-the detached ring, a fresh exemplification of the principle we
-are following out. Consisting of gaseous matter, such a
-ring, even if absolutely uniform at the time of its detachment,
-cannot continue so. To maintain its equilibrium there
-must be an almost perfect uniformity in the action of all
-external forces upon it (almost, we must say, because the
-cohesion, even of extremely attenuated matter, might suffice
-to neutralize very minute disturbances); and against this the
-probabilities are immense. In the absence of equality among
-the forces, internal and external, acting on such a ring,
-there must be a point or points at which the cohesion of
-its parts is less than elsewhere—a point or points at which
-rupture will therefore take place. Laplace assumed that
-the ring would rupture at one place only; and would then
-collapse on itself. But this is a more than questionable
-assumption—such at least I know to be the opinion of an
-authority second to none among those now living. So
-<span class='pageno' id='Page_366'>366</span>vast a ring, consisting of matter having such feeble cohesion,
-must break up into many parts. Nevertheless, it is
-still inferrable from the instability of the homogeneous,
-that the ultimate result which Laplace predicted would
-take place. For even supposing the masses of nebulous
-matter into which such a ring separated, were so equal in
-their sizes and distances as to attract each other with
-exactly equal forces (which is infinitely improbable); yet
-the unequal action of external disturbing forces would
-inevitably destroy their equilibrium—there would be one or
-more points at which adjacent masses would begin to part
-company. Separation once commenced, would with ever-accelerating
-speed lead to a grouping of the masses. And
-obviously a like result would eventually take place with the
-groups thus formed; until they at length aggregated into a
-single mass.</p>
-
-<p class='c000'>Leaving the region of speculative astronomy, let us consider
-the Solar System as it at present exists. And here it
-will be well, in the first place, to note a fact which may be
-thought at variance with the foregoing argument—namely,
-the still-continued existence of Saturn’s rings; and especially
-of the internal nebulous ring lately discovered. To the
-objection that the outer rings maintain their equilibrium, the
-reply is that the comparatively great cohesion of liquid
-or solid substance would suffice to prevent any slight tendency
-to rupture from taking effect. And that a nebulous
-ring here still preserves its continuity, does not really negative
-the foregoing conclusion; since it happens under the quite
-exceptional influence of those symmetrically disposed forces
-which the external rings exercise on it. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Here indeed
-it deserves to be noted, that though at first sight the Saturnian
-system appears at variance with the doctrine that a
-state of homogeneity is one of unstable equilibrium, it does
-in reality furnish a curious confirmation of this doctrine. For
-Saturn is not quite concentric with his rings; and it has
-been proved mathematically that were he and his rings concentrically
-<span class='pageno' id='Page_367'>367</span>situated, they could not remain so: the homogeneous
-relation being unstable, would gravitate into a
-heterogeneous one. And this fact serves to remind us of the
-allied one presented throughout the whole Solar System. All
-orbits, whether of planets or satellites, are more or less excentric—none
-of them are perfect circles; and were they
-perfect circles they would soon become ellipses. Mutual perturbations
-would inevitably generate excentricities. That is
-to say, the homogeneous relations would lapse into heterogeneous
-ones.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 111. Already so many references have been made to the
-gradual formation of a crust over the originally incandescent
-Earth, that it may be thought superfluous again to name it.
-It has not, however, been before considered in connexion with
-the general principle under discussion. Here then it must
-be noted as a necessary consequence of the instability of the
-homogeneous. In this cooling down and solidification of
-the Earth’s surface, we have one of the simplest, as well as
-one of the most important, instances, of that change from
-a uniform to a multiform state which occurs in any mass
-through exposure of its different parts to different conditions.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;To the differentiation of the Earth’s exterior
-from its interior thus brought about, we must add one of the
-most conspicuous differentiations which the exterior itself
-afterwards undergoes, as being similarly brought about. Were
-the conditions to which the surface of the Earth is exposed,
-alike in all directions, there would be no obvious reason why
-certain of its parts should become permanently unlike the rest.
-But being unequally exposed to the chief external centre of
-force—the Sun—its main divisions become unequally modified:
-as the crust thickens and cools, there arises that contrast,
-now so decided, between the polar and equatorial regions.</p>
-
-<p class='c000'>Along with these most marked physical differentiations of
-the Earth, which are manifestly consequent on the instability
-of the homogeneous, there have been going on numerous
-<span class='pageno' id='Page_368'>368</span>chemical differentiations, admitting of similar interpretation.
-Without raising the question whether, as some think,
-the so-called simple substances are themselves compounded of
-unknown elements (elements which we cannot separate by
-artificial heat, but which existed separately when the heat of
-the Earth was greater than any which we can produce),—without
-raising this question, it will suffice the present purpose
-to show how, in place of that comparative homogeneity
-of the Earth’s crust, chemically considered, which must have
-existed when its temperature was high, there has arisen,
-during its cooling, an increasing chemical heterogeneity:
-each element or compound, being unable to maintain its
-homogeneity in presence of various surrounding affinities,
-having fallen into heterogeneous combinations. Let us contemplate
-this change somewhat in detail. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;There is
-every reason to believe that at an extreme heat, the bodies
-we call elements cannot combine. Even under such heat as
-can be generated artificially, some very strong affinities yield;
-and the great majority of chemical compounds are decomposed
-at much lower temperatures. Whence it seems not
-improbable that, when the Earth was in its first state of incandescence,
-there were no chemical combinations at all.
-But without drawing this inference, let us set out with the
-unquestionable fact that the compounds which can exist at
-the highest temperatures, and which must therefore have
-been the first formed as the Earth cooled, are those of the
-simplest constitutions. The protoxides—including under
-that head the alkalies, earths, &amp;c.—are, as a class, the most
-fixed compounds known: the majority of them resisting decomposition
-by any heat we can generate. These, consisting
-severally of one atom of each component element, are combinations
-of the simplest order—are but one degree less
-homogeneous than the elements themselves. More heterogeneous
-than these, more decomposable by heat, and therefore
-later in the Earth’s history, are the deutoxides, tritoxides,
-peroxides, &amp;c.; in which two, three, four, or more atoms of
-<span class='pageno' id='Page_369'>369</span>oxygen are united with one atom of metal or other base.
-Still less able to resist heat, are the salts; which present us
-with compound atoms each made up of five, six, seven, eight,
-ten, twelve, or more atoms, of three, if not more, kinds.
-Then there are the hydrated salts, of a yet greater heterogeneity,
-which undergo partial decomposition at much lower
-temperatures. After them come the further-complicated
-supersalts and double salts, having a stability again decreased;
-and so throughout. After making a few unimportant qualifications
-demanded by peculiar affinities, I believe no chemist
-will deny it to be a general law of these inorganic combinations
-that, other things equal, the stability decreases as the
-complexity increases. And then when we pass to the compounds
-that make up organic bodies, we find this general law
-still further exemplified: we find much greater complexity
-and much less stability. An atom of albumen, for instance,
-consists of 482 ultimate atoms of five different kinds. Fibrine,
-still more intricate in constitution, contains in each atom, 298
-atoms of carbon, 49 of nitrogen, 2 of sulphur, 228 of hydrogen,
-and 92 of oxygen—in all, 660 atoms; or, more strictly
-speaking—equivalents. And these two substances are so unstable
-as to decompose at quite moderate temperatures; as
-that to which the outside of a joint of roast meat is
-exposed. Possibly it will be objected that some inorganic
-compounds, as phosphuretted hydrogen and chloride of nitrogen,
-are more decomposable than most organic compounds.
-This is true. But the admission may be made without damage
-to the argument. The proposition is not that <em>all</em> simple combinations
-are more fixed than <em>all</em> complex ones. To establish
-our inference it is necessary only to show that, as an <em>average
-fact</em>, the simple combinations can exist at a higher temperature
-than the complex ones. And this is wholly beyond
-question. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Thus it is manifest that the present chemical
-heterogeneity of the Earth’s surface has arisen by degrees
-as the decrease of heat has permitted; and that it has shown
-itself in three forms—first, in the multiplication of chemical
-<span class='pageno' id='Page_370'>370</span>compounds; second, in the greater number of different elements
-contained in the more modern of these compounds; and
-third, in the higher and more varied multiples in which these
-more numerous elements combine.</p>
-
-<p class='c000'>Without specifying them, it will suffice just to name the
-meteorologic processes eventually set up in the Earth’s atmosphere,
-as further illustrating the alleged law. They
-equally display that destruction of a homogeneous state which
-results from unequal exposure to incident forces.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 112. Take a mass of unorganized but organizable matter—either
-the body of one of the lowest living forms, or the
-germ of one of the higher. Consider its circumstances.
-Either it is immersed in water or air, or it is contained within
-a parent organism. Wherever placed, however, its outer
-and inner parts stand differently related to surrounding
-agencies—nutriment, oxygen, and the various stimuli. But
-this is not all. Whether it lies quiescent at the bottom of
-the water or on the leaf of a plant; whether it moves through
-the water preserving some definite attitude; or whether it is
-in the inside of an adult; it equally results that certain parts
-of its surface are more exposed to surrounding agencies than
-other parts—in some cases more exposed to light, heat, or
-oxygen, and in others to the maternal tissues and their contents.
-Hence must follow the destruction of its original
-equilibrium. This may take place in one of two ways. Either
-the disturbing forces may be such as to overbalance the
-affinities of the organic elements, in which case there result
-those changes which are known as decomposition; or, as is
-ordinarily the case, such changes are induced as do not destroy
-the organic compounds, but only modify them: the
-parts most exposed to the modifying forces being most modified.
-To elucidate this, suppose we take a few cases.</p>
-
-<p class='c000'>Note first what appear to be exceptions. Certain minute
-animal forms present us either with no appreciable differentiations
-or with differentiations so obscure as to be made out
-<span class='pageno' id='Page_371'>371</span>with great difficulty. In the Rhizopods, the substance of the
-jelly-like body remains throughout life unorganized, even to
-the extent of having no limiting membrane; as is proved by
-the fact that the thread-like processes protruded by the mass,
-coalesce on touching each other. Whether or not the nearly
-allied <em>Amœba</em>, of which the less numerous and more bulky
-processes do not coalesce, has, as lately alleged, something
-like a cell-wall and a nucleus, it is clear that the distinction
-of parts is very slight; since particles of food pass bodily into
-the inside through any part of the periphery, and since when
-the creature is crushed to pieces, each piece behaves as the
-whole did. Now these cases, in which there is either no contrast
-of structure between exterior and interior or very little, though
-seemingly opposed to the above inference, are really very
-significant evidences of its truth. For what is the peculiarity
-of this division of the <em>Protozoa</em>? Its members undergo perpetual
-and irregular changes of form—they show no persistent
-relation of parts. What lately formed a portion of
-the interior is now protruded, and, as a temporary limb, is
-attached to some object it happens to touch. What is now a
-part of the surface will presently be drawn, along with the
-atom of nutriment sticking to it, into the centre of the mass.
-Either the relations of inner and outer have no permanent
-existence, or they are very slightly marked. But by the
-hypothesis, it is only because of their unlike positions with
-respect to modifying forces, that the originally like units of a
-living mass become unlike. We must therefore expect no
-established differentiation of parts in creatures which exhibit
-no established differences of position in their parts; and we
-must expect extremely little differentiation of parts where the
-differences of position are but little determined—which is
-just what we find. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;This negative evidence is borne
-out by positive evidence. When we turn from these proteiform
-specks of living jelly to organisms having an unchanging
-distribution of substance, we find differences of tissue
-corresponding to differences of relative position. In all
-<span class='pageno' id='Page_372'>372</span>the higher <em>Protozoa</em>, as also in the <em>Protophyta</em>, we meet with
-a fundamental differentiation into cell-membrane and cell-contents;
-answering to that fundamental contrast of conditions
-implied by the terms outside and inside. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;On
-passing from what are roughly classed as unicellular organisms,
-to the lowest of those which consist of aggregated cells,
-we equally observe the connection between structural differences
-and differences of circumstance. Negatively, we see
-that in the sponge, permeated throughout by currents of sea-water,
-the indefiniteness of organization corresponds with the
-absence of definite unlikeness of conditions: the peripheral
-and central portions are as little contrasted in structure as in
-exposure to surrounding agencies. While positively, we see
-that in a form like the <em>Thalassicolla</em>, which, though equally
-humble, maintains its outer and inner parts in permanently
-unlike circumstances, there is displayed a rude structure
-obviously subordinated to the primary relations of centre and
-surface: in all its many and important varieties, the parts
-exhibit a more or less concentric arrangement.</p>
-
-<p class='c000'>After this primary modification, by which the outer tissues
-are differentiated from the inner, the next in order of constancy
-and importance is that by which some part of the
-outer tissues is differentiated from the rest; and this corresponds
-with the almost universal fact that some part of the
-outer tissues is more exposed to certain environing influences
-than the rest. Here, as before, the apparent exceptions are
-extremely significant. Some of the lowest vegetal organisms,
-as the <em>Hematococci</em> and <em>Protococci</em>, evenly imbedded in a
-mass of mucus, or dispersed through the Arctic snow, display
-no differentiations of surface; the several parts of their surfaces
-being subjected to no definite contrasts of conditions.
-Ciliated spheres such as the <em>Volvox</em> have no parts of their
-periphery unlike other parts; and it is not to be expected
-that they should have; since, as they revolve in all directions,
-they do not, in traversing the water, permanently expose any
-part to special conditions. But when we come to organisms
-<span class='pageno' id='Page_373'>373</span>that are either fixed, or while moving preserve definite attitudes,
-we no longer find uniformity of surface. The most
-general fact which can be asserted with respect to the structures
-of plants and animals, is, that however much alike in
-shape and texture the various parts of the exterior may at
-first be, they acquire unlikenesses corresponding to the unlikenesses
-of their relations to surrounding agencies. The ciliated
-germ of a Zoophyte, which, during its locomotive stage,
-is distinguishable only into outer and inner tissues, no sooner
-becomes fixed, than its upper end begins to assume a different
-structure from its lower. The disc-shaped <em>gemmæ</em> of the
-<em>Marchantia</em>, originally alike on both surfaces, and falling at
-random with either side uppermost, immediately begin to
-develop rootlets on the under side, and <em>stomata</em> on the upper
-side: a fact proving beyond question, that this primary differentiation
-is determined by this fundamental contrast of conditions.</p>
-
-<p class='c000'>Of course in the germs of higher organisms, the metamorphoses
-immediately due to the instability of the homogeneous,
-are soon masked by those due to the assumption of the hereditary
-type. Such early changes, however, as are common to
-all classes of organisms, and so cannot be ascribed to heredity,
-entirely conform to the hypothesis. A germ which has undergone
-no developmental modifications, consists of a spheroidal
-group of homogeneous cells. Universally, the first step
-in its evolution is the establishment of a difference between
-some of the peripheral cells and the cells which form the interior—some
-of the peripheral cells, after repeated spontaneous
-fissions, coalesce into a membrane; and by continuance
-of the process this membrane spreads until it speedily invests
-the entire mass, as in mammals, or, as in birds, stops short of
-that for some time. Here we have two significant facts.
-The first is, that the primary unlikeness arises between the
-exterior and the interior. The second is, that the change
-which thus initiates development, does not take place simultaneously
-over the whole exterior; but commences at one
-<span class='pageno' id='Page_374'>374</span>place, and gradually involves the rest. Now these facts
-are just those which might be inferred from the instability of
-the homogeneous. The surface must, more than any other
-part, become unlike the centre, because it is most dissimilarly
-conditioned; and all parts of the surface cannot
-simultaneously exhibit this differentiation, because they cannot
-be exposed to the incident forces with absolute uniformity.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;One other general fact of like implication remains.
-Whatever be the extent of this peripheral layer of
-cells, or blastoderm as it is called, it presently divides into
-two layers—the serous and mucous; or, as they have been
-otherwise called, the ectoderm and the endoderm. The first
-of these is formed from that portion of the layer which lies
-in contact with surrounding agents; and the second of them
-is formed from that portion of the layer which lies in contact
-with the contained mass of yelk. That is to say, after the
-primary differentiation, more or less extensive, of surface
-from centre, the resulting superficial portion undergoes a
-secondary differentiation into inner and outer parts—a
-differentiation which is clearly of the same order with the
-preceding, and answers to the next most marked contrast of
-conditions.</p>
-
-<p class='c000'>But, as already hinted, this principle, understood in the
-simple form here presented, supplies no key to the detailed
-phenomena of organic development. It fails entirely to explain
-generic and specific peculiarities; and indeed leaves us
-equally in the dark respecting those more important distinctions
-by which families and orders are marked out.
-Why two ova, similarly exposed in the same pool, should
-become the one a fish, and the other a reptile, it cannot tell
-us. That from two different eggs placed under the same
-hen, should respectively come forth a duckling and a chicken,
-is a fact not to be accounted for on the hypothesis above
-developed. We have here no alternative but to fall back
-upon the unexplained principle of hereditary transmission.
-The capacity possessed by an unorganized germ of unfolding
-<span class='pageno' id='Page_375'>375</span>into a complex adult, which repeats ancestral traits in the
-minutest details, and that even when it has been placed in
-conditions unlike those of its ancestors, is a capacity we cannot
-at present understand. That a microscopic portion of seemingly
-structureless matter should embody an influence of such
-kind, that the resulting man will in fifty years after become
-gouty or insane, is a truth which would be incredible were it
-not daily illustrated. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Should it however turn out, as
-we shall hereafter find reason for suspecting, that these complex
-differentiations which adults exhibit, are themselves the
-slowly accumulated and transmitted results of a process like
-that seen in the first changes of the germ; it will follow that
-even those embryonic changes due to hereditary influence,
-are remote consequences of the alleged law. Should it be
-shown that the slight modifications wrought during life on
-each adult, and bequeathed to offspring along with all like
-preceding modifications, are themselves unlikenesses of parts
-that are produced by unlikenesses of conditions; then it will
-follow that the modifications displayed in the course of embryonic
-development, are partly direct consequences of the
-instability of the homogeneous, and partly indirect consequences
-of it. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;To give reasons for entertaining this
-hypothesis, however, is not needful for the justification of the
-position here taken. It is enough that the most conspicuous
-differentiations which incipient organisms universally display,
-correspond to the most marked differences of conditions to
-which their parts are subject. It is enough that the habitual
-contrast between outside and inside, which we <em>know</em> is produced
-in inorganic masses by unlikeness of exposure to incident
-forces, is strictly paralleled by the first contrast that
-makes its appearance in all organic masses.</p>
-
-<p class='c000'>It remains to point out that in the assemblage of organisms
-constituting a species, the principle enunciated is equally
-traceable. We have abundant materials for the induction
-that each species will not remain uniform, but is ever becoming
-to some extent multiform; and there is ground for the
-<span class='pageno' id='Page_376'>376</span>deduction that this lapse from homogeneity to heterogeneity is
-caused by the subjection of its members to unlike sets of
-circumstances. The fact that in every species, animal and
-vegetal, the individuals are never quite alike; joined with
-the fact that there is in every species a tendency to the production
-of differences marked enough to constitute varieties;
-form a sufficiently wide basis for the induction. While the
-deduction is confirmed by the familiar experience that varieties
-are most numerous and decided where, as among cultivated
-plants and domestic animals, the conditions of life depart
-from the original ones, most widely and in the most numerous
-ways. Whether we regard “natural selection” as wholly,
-or only in part, the agency through which varieties are
-established, matters not to the general conclusion. For as
-the survival of any variety proves its constitution to be in
-harmony with a certain aggregate of surrounding forces—as
-the multiplication of a variety and the usurpation by it of an
-area previously occupied by some other part of the species,
-implies different effects produced by such aggregate of forces
-on the two, it is clear that this aggregate of forces is the
-real cause of the differentiation—it is clear that if the variety
-supplants the original species in some localities but not in
-others, it does so because the aggregate of forces in the one
-locality is unlike that in the other—it is clear that the lapse
-of the species from a state of homogeneity to a state of heterogeneity
-arises from the exposure of its different parts to
-different aggregates of forces.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 113. Among mental phenomena it is difficult to establish
-the alleged law without an analysis too extensive for the
-occasion. To show satisfactorily how states of consciousness,
-originally homogeneous, become heterogeneous through differences
-in the changes wrought by different forces, would
-require us carefully to trace out the organization of early
-experiences. Were this done it would become manifest that
-the development of intelligence, is, under one of its chief
-<span class='pageno' id='Page_377'>377</span>aspects, a dividing into separate classes, the unlike things
-previously confounded together in one class—a formation of
-sub-classes and sub-sub-classes, until the once confused aggregate
-of objects known, is resolved into an aggregate which
-unites extreme heterogeneity among its multiplied groups,
-with complete homogeneity among the members of each
-group. If, for example, we followed, through ascending grades
-of creatures, the genesis of that vast structure of knowledge
-acquired by sight, we should find that in the first stage,
-where eyes suffice for nothing beyond the discrimination of
-light from darkness, the only possible classifications of objects
-seen, must be those based on the manner in which light is
-obstructed, and the degree in which it is obstructed. We
-should find that by such undeveloped visual organs, the
-shadows traversing the rudimentary retina would be merely
-distinguished into those of the stationary objects which
-the creature passed during its own movements, and those
-of the moving objects which came near the creature while
-it was at rest; and that so the extremely general classification
-of visible things into stationary and moving, would
-be the earliest formed. We should find that whereas the
-simplest eyes are not fitted to distinguish between an obstruction
-of light caused by a small object close to, and an obstruction
-caused by a large object at some distance, eyes a little
-more developed must be competent to such a distinction;
-whence must result a vague differentiation of the class of
-moving objects, into the nearer and the more remote. We
-should find that such further improvements in vision as those
-which make possible a better estimation of distances by
-adjustment of the optic axes, and those which, through enlargement
-and subdivision of the retina, make possible the discrimination
-of shapes, must have the effects of giving greater
-definiteness to the classes already formed, and of sub-dividing
-these into smaller classes, consisting of objects less unlike. And
-we should find that each additional refinement of the perceptive
-organs, must similarly lead to a multiplication of divisions
-<span class='pageno' id='Page_378'>378</span>and a sharpening of the limits of each division. In every infant
-might be traced the analogous transformation of a confused
-aggregate of impressions of surrounding objects, not recognized
-as differing in their distances, sizes, and shapes, into separate
-classes of objects unlike each other in these and various other
-respects. And in the one case as in the other, it might be
-shown that the change from this first indefinite, incoherent
-and comparatively homogeneous consciousness, to a definite,
-coherent, and heterogeneous one, is due to differences in the
-actions of incident forces on the organism. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;These
-brief indications of what might be shown, did space permit,
-must here suffice. Probably they will give adequate clue to
-an argument by which each reader may satisfy himself that
-the course of mental evolution offers no exception to the
-general law. In further aid of such an argument, I will here
-add an illustration that is comprehensible apart from the
-process of mental evolution as a whole.</p>
-
-<p class='c000'>It has been remarked (I am told by Coleridge, though I
-have been unable to find the passage) that with the advance
-of language, words which were originally alike in their
-meanings acquire unlike meanings—a change which he
-expresses by the formidable word “desynonymization.”
-Among indigenous words this loss of equivalence cannot
-be clearly shown; because in them the divergencies of
-meaning began before the dawn of literature. But among
-words that have been coined, or adopted from other
-languages, since the writing of books commenced, it is
-demonstrable. In the old divines, <em>miscreant</em> is used in
-its etymological sense of <em>unbeliever</em>; but in modern speech it
-has entirely lost this sense. Similarly with <em>evil-doer</em> and
-<em>malefactor</em>: exactly synonymous as these are by derivation,
-they are no longer synonymous by usage: by a <em>malefactor</em>
-we now understand a convicted criminal, which is far from
-being the acceptation of <em>evil-doer</em>. The verb <em>produce</em>, bears in
-Euclid its primary meaning—to <em>prolong</em>, or <em>draw out</em>; but
-the now largely developed meanings of <em>produce</em> have little in
-<span class='pageno' id='Page_379'>379</span>common with the meanings of <em>prolong</em>, or <em>draw out</em>. In the
-Church of England liturgy, an odd effect results from the
-occurrence of <em>prevent</em> in its original sense—<em>to come before</em>,
-instead of its modern specialized sense—<em>to come before with the
-effect of arresting</em>. But the most conclusive cases are those
-in which the contrasted words consist of the same parts differently
-combined; as in <em>go under</em> and <em>undergo</em>. We <em>go under</em>
-a tree, and we <em>undergo</em> a pain. But though, if analytically
-considered, the meanings of these expressions would be the
-same were the words transposed, habit has so far modified
-their meanings that we could not without absurdity speak of
-<em>undergoing</em> a tree and <em>going under</em> a pain. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Countless
-such instances might be brought to show that between two
-words which are originally of like force, an equilibrium cannot
-be maintained. Unless they are daily used in exactly
-equal degrees, in exactly similar relations (against which
-there are infinite probabilities), there necessarily arises a habit
-of associating one rather than the other with particular acts,
-or objects. Such a habit, once commenced, becomes confirmed;
-and gradually their homogeneity of meaning disappears.
-In each individual we may see the tendency which inevitably
-leads to this result. A certain vocabulary and a certain set
-of phrases, distinguish the speech of each person: each person
-habitually uses certain words in places where other words
-are habitually used by other persons; and there is a continual
-recurrence of favourite expressions. This inability to
-maintain a balance in the use of verbal symbols, which characterizes
-every man, characterizes, by consequence, aggregates
-of men; and the desynonymization of words is the ultimate
-effect.</p>
-
-<p class='c000'>Should any difficulty be felt in understanding how these
-mental changes exemplify a law of physical transformations
-that are wrought by physical forces, it will disappear on contemplating
-acts of mind as nervous functions. It will be
-seen that each loss of equilibrium above instanced, is a loss of
-functional equality between some two elements of the nervous
-<span class='pageno' id='Page_380'>380</span>system. And it will be seen that, as in other cases, this loss
-of functional equality is due to differences in the incidence of
-forces.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 114. Masses of men, in common with all other masses,
-show a like proclivity similarly caused. Small combinations
-and large societies equally manifest it; and in the one, as in
-the other, both governmental and industrial differentiations
-are initiated by it. Let us glance at the facts under these
-two heads.</p>
-
-<p class='c000'>A business partnership, balanced as the authorities of its
-members may theoretically be, practically becomes a union in
-which the authority of one partner is tacitly recognized as
-greater than that of the other or others. Though the shareholders
-have given equal powers to the directors of their
-company, inequalities of power soon arise among them; and
-usually the supremacy of some one director grows so marked,
-that his decisions determine the course which the board takes.
-Nor in associations for political, charitable, literary, or other
-purposes, do we fail to find a like process of division into
-dominant and subordinate parties; each having its leader, its
-members of less influence, and its mass of uninfluential members.
-These minor instances in which unorganized groups of
-men, standing in homogeneous relations, may be watched
-gradually passing into organized groups of men standing in
-heterogeneous relations, give us the key to social inequalities.
-Barbarous and civilized communities are alike characterized
-by separation into classes, as well as by separation of each
-class into more important and less important units; and this
-structure is manifestly the gradually-consolidated result of a
-process like that daily exemplified in trading and other combinations.
-So long as men are constituted to act on one another,
-either by physical force or by force of character, the
-struggles for supremacy must finally be decided in favour of
-some one; and the difference once commenced must tend to
-become ever more marked. Its unstable equilibrium being destroyed,
-<span class='pageno' id='Page_381'>381</span>the uniform must gravitate with increasing rapidity
-into the multiform. And so supremacy and subordination
-must establish themselves, as we see they do, throughout the
-whole structure of a society, from the great class-divisions
-pervading its entire body, down to village cliques, and even
-down to every posse of school-boys. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Probably it will
-be objected that such changes result, not from the homogeneity
-of the original aggregations, but from their non-homogeneity—from
-certain slight differences existing among their
-units at the outset. This is doubtless the proximate cause.
-In strictness, such changes must be regarded as transformations
-of the relatively homogeneous into the relatively heterogeneous.
-But it is abundantly clear that an aggregation of
-men, absolutely alike in their endowments, would eventually
-undergo a similar transformation. For in the absence of
-perfect uniformity in the lives severally led by them—in
-their occupations, physical conditions, domestic relations, and
-trains of thought and feeling—there must arise differences
-among them; and these must finally initiate social differentiations.
-Even inequalities of health caused by accidents,
-must, by entailing inequalities of physical and mental power,
-disturb the exact balance of mutual influences among the
-units; and the balance once disturbed, must inevitably be
-lost. Whence, indeed, besides seeing that a body of men
-absolutely homogeneous in their governmental relations, must,
-like all other homogeneous bodies, become heterogeneous,
-we also see that it must do this from the same ultimate cause—unequal
-exposure of its parts to incident forces.</p>
-
-<p class='c000'>The first industrial divisions of societies are much more
-obviously due to unlikenesses of external circumstances.
-Such divisions are absent until such unlikenesses are established.
-Nomadic tribes do not permanently expose any
-groups of their members to special local conditions; nor does
-a stationary tribe, when occupying only a small area, maintain
-from generation to generation marked contrasts in the
-local conditions of its members; and in such tribes there are
-<span class='pageno' id='Page_382'>382</span>no decided economical differentiations. But a community
-which, growing populous, has overspread a large tract, and
-has become so far settled that its members live and die in their
-respective districts, keeps its several sections in different
-physical circumstances; and then they no longer remain alike
-in their occupations. Those who live dispersed continue to
-hunt or cultivate the earth; those who spread to the sea-shore
-fall into maritime occupations; while the inhabitants of some
-spot chosen, perhaps for its centrality, as one of periodical
-assemblage, become traders, and a town springs up. Each
-of these classes undergoes a modification of character consequent
-on its function, and better fitting it to its function.
-Later in the process of social evolution these local adaptations
-are greatly multiplied. A result of differences in
-soil and climate, is that the rural inhabitants in different
-parts of the kingdom have their occupations partially specialized;
-and become respectively distinguished as chiefly producing
-cattle, or sheep, or wheat, or oats, or hops, or cyder.
-People living where coal-fields are discovered are transformed
-into colliers; Cornishmen take to mining because Cornwall
-is metalliferous; and the iron-manufacture is the dominant
-industry where ironstone is plentiful. Liverpool
-has assumed the office of importing cotton, in consequence of
-its proximity to the district where cotton goods are made;
-and for analogous reasons, Hull has become the chief port at
-which foreign wools are brought in. Even in the establishment
-of breweries, of dye-works, of slate-quarries, of brickyards,
-we may see the same truth. So that both in general
-and in detail, the specializations of the social organism which
-characterize separate districts, primarily depend on local
-circumstances. Those divisions of labour which under another
-aspect were interpreted as due to the setting up of motion
-in the directions of least resistance (§ 91), are here interpreted
-as due to differences in the incident forces; and
-the two interpretations are quite consistent with each
-other. For that which in each case <em>determines</em> the direction
-<span class='pageno' id='Page_383'>383</span>of least resistance, is the distribution of the forces to be overcome;
-and hence unlikenesses of distribution in separate
-localities, entails unlikenesses in the course of human action
-in those localities—entails industrial differentiations.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 115. In common with the general truths set forth in
-preceding chapters, the instability of the homogeneous is demonstrable
-<i><span lang="fr" xml:lang="fr">à priori</span></i>. It, like each of them, is a corollary from
-the persistence of force. Already this has been tacitly implied
-by assigning unlikeness in the exposure of its part to
-surrounding agencies, as the reason why a uniform mass loses
-its uniformity. But here it will be proper to expand this
-tacit implication into definite proof.</p>
-
-<p class='c000'>On striking a mass of matter with such force as either to
-indent it or make it fly to pieces, we see both that the blow
-affects differently its different parts, and that the differences
-are consequent on the unlike relations of its parts to the
-force impressed. The part with which the striking body
-comes in contact, receiving the whole of the communicated
-momentum, is driven in towards the centre of the mass.
-It thus compresses and tends to displace the more centrally
-situated portions of the mass. These, however, cannot be
-compressed or thrust out of their places without pressing on
-all surrounding portions. And when the blow is violent
-enough to fracture the mass, we see, in the radial dispersion
-of its fragments, that the original momentum, in being distributed
-throughout it, has been divided into numerous minor
-momenta, unlike in their directions. We see that these directions
-are determined by the positions of the parts with respect
-to each other, and with respect to the point of impact.
-We see that the parts are differently affected by the disruptive
-force, because they are differently related to it in their
-directions and attachments—that the effects being the joint
-products of the cause and the conditions, cannot be alike in
-parts which are differently conditioned. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;A body on
-which radiant heat is falling, exemplifies this truth still more
-<span class='pageno' id='Page_384'>384</span>clearly. Taking the simplest case (that of a sphere) we see
-that while the part nearest to the radiating centre receives
-the rays at right angles, the rays strike the other parts of the
-exposed side at all angles from 90° down to 0°. Again, the
-molecular vibrations propagated through the mass from the
-surface which receives the heat, must proceed inwards at angles
-differing for each point. Further, the interior parts of
-the sphere affected by the vibrations proceeding from all
-points of the heated side, must be dissimilarly affected in proportion
-as their positions are dissimilar. So that whether
-they be on the recipient area, in the middle, or at the remote
-side, the constituent atoms are all thrown into states of vibration
-more or less unlike each other.</p>
-
-<p class='c000'>But now, what is the ultimate meaning of the conclusion
-that a uniform force produces different changes throughout a
-uniform mass, because the parts of the mass stand in different
-relations to the force? Fully to understand this, we must
-contemplate each part as simultaneously subject to other
-forces—those of gravitation, of cohesion, of molecular motion,
-&amp;c. The effect wrought by an additional force, must be a
-resultant of it and the forces already in action. If the forces
-already in action on two parts of any aggregate, are different in
-their directions, the effects produced on these two parts by like
-forces must be different in their directions. Why must they be
-different? They must be different because such unlikeness as
-exists between the two sets of factors, is made by the presence
-in the one of some specially-directed force that is not present
-in the other; and that this force will produce an
-effect, rendering the total result in the one case unlike that
-in the other, is a necessary corollary from the persistence of
-force. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Still more manifest does it become that the dissimilarly-placed
-parts of any aggregate must be dissimilarly
-modified by an incident force, when we remember that the
-<em>quantities</em> of the incident force to which they are severally
-subject, are not equal, as above supposed; but are nearly always
-very unequal. The outer parts of masses are usually
-<span class='pageno' id='Page_385'>385</span>alone exposed to chemical actions; and not only are their
-inner parts shielded from the affinities of external elements,
-but such affinities are brought to bear unequally on their
-surfaces; since chemical action sets up currents through the
-medium in which it takes place, and so brings to the various
-parts of the surface unequal quantities of the active agent.
-Again, the amounts of any external radiant force which the
-different parts of an aggregate receive, are widely contrasted:
-we have the contrast between the quantity falling on the
-side next the radiating centre, and the quantity, or rather no
-quantity, falling on the opposite side; we have contrasts in
-the quantities received by differently-placed areas on the
-exposed side; and we have endless contrasts between the
-quantities received by the various parts of the interior. Similarly
-when mechanical force is expended on any aggregate,
-either by collision, continued pressure, or tension, the amounts
-of strain distributed throughout the mass are manifestly
-unlike for unlike positions. But to say the different parts of
-an aggregate receive different quantities of any incident force,
-is to say that their states are modified by it in different
-degrees—is to say that if they were before homogeneous in
-their relations they must be rendered to a proportionate
-extent heterogeneous; since, force being persistent, the
-different quantities of it falling on the different parts,
-must work in them different quantities of effect—different
-changes. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Yet one more kindred deduction is required
-to complete the argument. We may, by parallel reasoning,
-reach the conclusion that, even apart from the action of any external
-force, the equilibrium of a homogeneous aggregate must
-be destroyed by the unequal actions of its parts on each other.
-That mutual influence which produces aggregation (not to
-mention other mutual influences) must work different effects
-on the different parts; since they are severally exposed to it
-in unlike amounts and directions. This will be clearly seen
-on remembering that the portions of which the whole is made
-up, may be severally regarded as minor wholes; that on each of
-<span class='pageno' id='Page_386'>386</span>these minor wholes, the action of the entire aggregate then
-becomes an external incident force; that such external incident
-force must, as above shown, work unlike changes in the
-parts of any such minor whole; and that if the minor wholes
-are severally thus rendered heterogeneous, the entire aggregate
-is rendered heterogeneous.</p>
-
-<p class='c000'>The instability of the homogeneous is thus deducible from
-that primordial truth which underlies our intelligence. One
-stable homogeneity only, is hypothetically possible. If centres
-of force, absolutely uniform in their powers, were diffused
-with absolute uniformity through unlimited space, they would
-remain in equilibrium. This however, though a verbally
-intelligible supposition, is one that cannot be represented in
-thought; since unlimited space is inconceivable. But all
-finite forms of the homogeneous—all forms of it which we
-can know or conceive, must inevitably lapse into heterogeneity.
-In three several ways does the persistence of force
-necessitate this. Setting external agencies aside, each unit
-of a homogeneous whole must be differently affected from
-any of the rest by the aggregate action of the rest upon it.
-The resultant force exercised by the aggregate on each unit,
-being in no two cases alike in both amount and direction, and
-usually not in either, any incident force, even if uniform in
-amount and direction, cannot produce like effects on the units.
-And the various positions of the parts in relation to any incident
-force, preventing them from receiving it in uniform
-amounts and directions, a further difference in the effects
-wrought on them is inevitably produced.</p>
-
-<p class='c000'>One further remark is needed. To the conclusion that
-the changes with which Evolution <em>commences</em>, are thus necessitated,
-remains to be added the conclusion that these
-changes must <em>continue</em>. The absolutely homogeneous must
-lose its equilibrium; and the relatively homogeneous must
-lapse into the relatively less homogeneous. That which
-is true of any total mass, is true of the parts into which
-it segregates. The uniformity of each such part must
-<span class='pageno' id='Page_387'>387</span>as inevitably be lost in multiformity, as was that of the
-original whole; and for like reasons. And thus the continued
-changes which characterize Evolution, in so far as they are
-constituted by the lapse of the homogeneous into the heterogeneous,
-and of the less heterogeneous into the more heterogeneous,
-are necessary consequences of the persistence of
-force.</p>
-
-<hr class='c015' />
-
-<div class='footnote' id='f16'>
-<p class='c000'><span class='label'><a href='#r16'>16</a>.&nbsp;&nbsp;</span>The idea developed in this chapter originally formed part of an article on
-“Transcendental Physiology,” published in 1857. See <em>Essays</em>, pp. 279–290.</p>
-</div>
-
-<div>
- <span class='pageno' id='Page_388'>388</span>
- <h3 class='c001'>CHAPTER XIV.<br /> <span class='large'>THE MULTIPLICATION OF EFFECTS.</span></h3>
-</div>
-
-<p class='c006'>§ 116. To the cause of increasing complexity set forth in
-the last chapter, we have in this chapter to add another.
-Though secondary in order of time, it is scarcely secondary in
-order of importance. Even in the absence of the cause
-already assigned, it would necessitate a change from the
-homogeneous to the heterogeneous; and joined with it, it
-makes this change both more rapid and more involved. To
-come in sight of it, we have but to pursue a step further,
-that conflict between force and matter already delineated.
-Let us do this.</p>
-
-<p class='c000'>When a uniform aggregate is subject to a uniform force,
-we have seen that its constituents, being differently conditioned,
-are differently modified. But while we have contemplated
-the various parts of the aggregate as thus undergoing
-unlike changes, we have not yet contemplated the unlike
-changes simultaneously produced on the various parts of the
-incident force. These must be as numerous and important as
-the others. Action and re-action being equal and opposite, it
-follows that in differentiating the parts on which it falls in
-unlike ways, the incident force must itself be correspondingly
-differentiated. Instead of being as before, a uniform
-force, it must thereafter be a multiform force—a group of
-dissimilar forces. A few illustrations will make this truth
-manifest.</p>
-
-<p class='c000'><span class='pageno' id='Page_389'>389</span>A single force is divided by conflict with matter into
-forces that widely diverge. In the case lately cited, of a
-body shattered by violent collision, besides the change of the
-homogeneous mass into a heterogeneous group of scattered
-fragments, there is a change of the homogeneous momentum
-into a group of momenta, heterogeneous in both amounts
-and directions. Similarly with the forces we know as light
-and heat. After the dispersion of these by a radiating body
-towards all points, they are re-dispersed towards all points
-by the bodies on which they fall. Of the Sun’s rays, issuing
-from him on every side, some few strike the Moon.
-These being reflected at all angles from the Moon’s surface,
-some few of them strike the Earth. By a like
-process the few which reach the Earth are again diffused
-through surrounding space. And on each occasion,
-such portions of the rays as are absorbed instead of reflected,
-undergo refractions that equally destroy their
-parallelism. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;More than this is true. By conflict
-with matter, a uniform force is in part changed into forces
-differing in their directions; and in part it is changed into
-forces differing in their kinds. When one body is struck
-against another, that which we usually regard as the effect,
-is a change of position or motion in one or both bodies. But
-a moment’s thought shows that this is a very incomplete
-view of the matter. Besides the visible mechanical result,
-sound is produced; or, to speak accurately, a vibration in
-one or both bodies, and in the surrounding air: and under
-some circumstances we call this the effect. Moreover, the
-air has not simply been made to vibrate, but has had currents
-raised in it by the transit of the bodies. Further, if there is
-not that great structural change which we call fracture, there
-is a disarrangement of the particles of the two bodies around
-their point of collision; amounting in some cases to a visible
-condensation. Yet more, this condensation is accompanied
-by disengagement of heat. In some cases a spark—that is,
-light—results, from the incandescence of a portion struck
-<span class='pageno' id='Page_390'>390</span>off; and occasionally this incandescence is associated with
-chemical combination. Thus, by the original mechanical
-force expended in the collision, at least five, and often more,
-different kinds of forces have been produced. Take, again,
-the lighting of a candle. Primarily, this is a chemical
-change consequent on a rise of temperature. The process of
-combination having once been set going by extraneous heat,
-there is a continued formation of carbonic acid, water, &amp;c.—in
-itself a result more complex than the extraneous heat that
-first caused it. But along with this process of combination
-there is a production of heat; there is a production of light;
-there is an ascending column of hot gases generated; there
-are currents established in the surrounding air. Nor does
-the decomposition of one force into many forces end here.
-Each of the several changes worked becomes the parent of
-further changes. The carbonic acid formed, will by and by
-combine with some base; or under the influence of sunshine
-give up its carbon to the leaf of a plant. The water will
-modify the hygrometric state of the air around; or, if the
-current of hot gases containing it come against a cold body,
-will be condensed: altering the temperature, and perhaps
-the chemical state, of the surface it covers. The heat given
-out melts the subjacent tallow, and expands whatever it
-warms. The light, falling on various substances, calls forth
-from them reactions by which it is modified; and so divers
-colours are produced. Similarly even with these secondary
-actions, which may be traced out into ever-multiplying
-ramifications, until they become too minute to be appreciated.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Universally, then, the effect is more complex
-than the cause. Whether the aggregate on which it falls be
-homogeneous or otherwise, an incident force is transformed
-by the conflict into a number of forces that differ in their
-amounts, or directions, or kinds; or in all these respects.
-And of this group of variously-modified forces, each ultimately
-undergoes a like transformation.</p>
-
-<p class='c000'>Let us now mark how the process of evolution is furthered
-<span class='pageno' id='Page_391'>391</span>by this multiplication of effects. An incident force decomposed
-by the reactions of a body into a group of unlike forces—a
-uniform force thus reduced to a multiform force—becomes
-the cause of a secondary increase of multiformity in
-the body which decomposes it. In the last chapter we saw
-that the several parts of an aggregate are differently modified
-by any incident force. It has just been shown that by the
-reactions of the differently modified parts, the incident force
-itself must be divided into differently modified parts. Here
-it remains to point out that each differentiated division of
-the aggregate, thus becomes a centre from which a differentiated
-division of the original force is again diffused. And
-since unlike forces must produce unlike results, each of these
-differentiated forces must produce, throughout the aggregate,
-a further series of differentiations. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;This secondary
-cause of the change from homogeneity to heterogeneity,
-obviously becomes more potent in proportion as the heterogeneity
-increases. When the parts into which any evolving
-whole has segregated itself, have diverged widely in nature,
-they will necessarily react very diversely on any incident
-force—they will divide an incident force into so many
-strongly contrasted groups of forces. And each of them becoming
-the centre of a quite distinct set of influences, must
-add to the number of distinct secondary changes wrought
-throughout the aggregate. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Yet another corollary
-must be added. The number of unlike parts of which an
-aggregate consists, as well as the degree of their unlikeness,
-is an important factor in the process. Every additional
-specialized division is an additional centre of specialized
-forces. If a uniform whole, in being itself made multiform
-by an incident force, makes the incident force multiform; if
-a whole consisting of two unlike sections, divides an incident
-force into two unlike groups of multiform forces; it is clear
-that each new unlike section must be a further source of complication
-among the forces at work throughout the mass—a
-further source of heterogeneity. The multiplication of
-<span class='pageno' id='Page_392'>392</span>effects must proceed in geometrical progression. Each stage
-of evolution must initiate a higher stage.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 117. The force of aggregation acting on irregular masses
-of rare matter, diffused through a resisting medium, will not
-cause such masses to move in straight lines to their common
-centre of gravity; but, as before said, each will take a curvilinear
-path, directed to one or other side of the centre of
-gravity. All of them being differently conditioned, gravitation
-will impress on each a motion differing in direction, in
-velocity, and in the degree of its curvature—uniform aggregative
-force will be differentiated into multiform momenta.
-The process thus commenced, must go on till it produces a
-single mass of nebulous matter; and these independent curvilinear
-motions must result in a movement of this mass round
-its axis: a simultaneous condensation and rotation in which
-we see how two effects of the aggregative force, at first but
-slightly divergent, become at last widely differentiated. A
-gradual increase of oblateness in this revolving spheroid, must
-take place through the joint action of these two forces, as the
-bulk diminishes and the rotation grows more rapid; and this
-we may set down as a third effect. The genesis of heat, which
-must accompany augmentation of density, is a consequence
-of yet another order—a consequence by no means simple;
-since the various parts of the mass, being variously condensed,
-must be variously heated. Acting throughout a gaseous
-spheroid, of which the parts are unlike in their temperatures,
-the forces of aggregation and rotation must work a further
-series of changes: they must set up circulating currents,
-both general and local. At a later stage light as well as heat
-will be generated. Thus without dwelling on the likelihood
-of chemical combinations and electric disturbances, it is sufficiently
-manifest that, supposing matter to have originally
-existed in a diffused state, the once uniform force which
-caused its aggregation, must have become gradually divided
-into different forces; and that each further stage of complication
-<span class='pageno' id='Page_393'>393</span>in the resulting aggregate, must have initiated further
-subdivisions of this force—a further multiplication of effects,
-increasing the previous heterogeneity.</p>
-
-<p class='c000'>This section of the argument may however be adequately
-sustained, without having recourse to any such hypothetical
-illustrations as the foregoing. The astronomical attributes
-of the Earth, will even alone suffice our purpose. Consider
-first the effects of its momentum round its axis. There is the
-oblateness of its form; there is the alternation of day and
-night; there are certain constant marine currents; and
-there are certain constant aërial currents. Consider next
-the secondary series of consequences due to the divergence
-of the Earth’s plane of rotation from the plane of its orbit.
-The many differences of the seasons, both simultaneous
-and successive, which pervade its surface, are thus caused.
-External attraction acting on this rotating oblate spheroid
-with inclined axis, produces the motion called nutation, and
-that slower and larger one from which follows the precession of
-the equinoxes, with its several sequences. And then by this
-same force are generated the tides, aqueous and atmospheric.</p>
-
-<p class='c000'>Perhaps, however, the simplest way of showing the multiplication
-of effects among phenomena of this order, will be to
-set down the influences of any member of the Solar System on
-the rest. A planet directly produces in neighbouring planets
-certain appreciable perturbations, complicating those otherwise
-produced in them; and in the remoter planets it directly
-produces certain less visible perturbations. Here is a first
-series of effects. But each of the perturbed planets is itself a
-source of perturbations—each directly affects all the others.
-Hence, planet A having drawn planet B out of the position
-it would have occupied in A’s absence, the perturbations
-which B causes are different from what they would else
-have been; and similarly with C, D, E, &amp;c. Here then is a
-secondary series of effects: far more numerous though far
-smaller in their amounts. As these indirect perturbations
-must to some extent modify the movements of each planet,
-<span class='pageno' id='Page_394'>394</span>there results from them a tertiary series; and so on continually.
-Thus the force exercised by any planet works a different
-effect on each of the rest; this different effect is from
-each as a centre partially broken up into minor different
-effects on the rest; and so on in ever multiplying and diminishing
-waves throughout the entire system.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 118. If the Earth was formed by the concentration of
-diffused matter, it must at first have been incandescent; and
-whether the nebular hypothesis be accepted or not, this original
-incandescence of the Earth must now be regarded as inductively
-established—or, if not established, at least rendered
-so probable that it is a generally admitted geological doctrine.
-Several results of the gradual cooling of the Earth—as the
-formation of a crust, the solidification of sublimed elements,
-the precipitation of water, &amp;c., have been already noticed—and
-I here again refer to them merely to point out that they
-are simultaneous effects of the one cause, diminishing heat.
-Let us now, however, observe the multiplied changes afterwards
-arising from the continuance of this one cause. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The
-Earth, falling in temperature, must contract. Hence the solid
-crust at any time existing, is presently too large for the
-shrinking nucleus; and being unable to support itself, inevitably
-follows the nucleus. But a spheroidal envelope cannot
-sink down into contact with a smaller internal spheroid, without
-disruption: it will run into wrinkles, as the rind of an
-apple does when the bulk of its interior decreases from evaporation.
-As the cooling progresses and the envelope thickens,
-the ridges consequent on these contractions must become
-greater; rising ultimately into hills and mountains; and the
-later systems of mountains thus produced must not only be
-higher, as we find them to be, but they must be longer, as we
-also find them to be. Thus, leaving out of view other modifying
-forces, we see what immense heterogeneity of surface
-arises from the one cause, loss of heat—a heterogeneity which
-the telescope shows us to be paralleled on the Moon, where aqueous
-<span class='pageno' id='Page_395'>395</span>and atmospheric agencies have been absent. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;But
-we have yet to notice another kind of heterogeneity of
-surface, similarly and simultaneously caused. While the
-Earth’s crust was still thin, the ridges produced by its contraction
-must not only have been small, but the tracts between
-them must have rested with comparative smoothness on the
-subjacent liquid spheroid; and the water in those arctic and
-antarctic regions where it first condensed, must have been
-evenly distributed. But as fast as the crust grew thicker
-and gained corresponding strength, the lines of fracture from
-time to time caused in it, necessarily occurred at greater distances
-apart; the intermediate surfaces followed the contracting
-nucleus with less uniformity; and there consequently
-resulted larger areas of land and water. If any one, after
-wrapping an orange in wet tissue paper, and observing both
-how small are the wrinkles and how evenly the intervening
-spaces lie on the surface of the orange, will then wrap it in
-thick cartridge-paper, and note both the greater height of the
-ridges and the larger spaces throughout which the paper does
-not touch the orange, he will realize the fact, that as the
-Earth’s solid envelope thickened, the areas of elevation and
-depression became greater. In place of islands more or less
-homogeneously scattered over an all-embracing sea, there must
-have gradually arisen heterogeneous arrangements of continent
-and ocean, such as we now know. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;This double
-change in the extent and in the elevation of the lands, involved
-yet another species of heterogeneity—that of coast-line.
-A tolerably even surface raised out of the ocean will have a
-simple, regular sea-margin; but a surface varied by table-lands
-and intersected by mountain-chains, will, when raised
-out of the ocean, have an outline extremely irregular, alike
-in its leading features and in its details. Thus endless is the
-accumulation of geological and geographical results slowly
-brought about by this one cause—the escape of the Earth’s
-primitive heat.</p>
-
-<p class='c000'>When we pass from the agency which geologists term igneous,
-<span class='pageno' id='Page_396'>396</span>to aqueous and atmospheric agencies, we see a like
-ever-growing complication of effects. The denuding actions
-of air and water have, from the beginning, been modifying
-every exposed surface: everywhere working many different
-changes. As already shown (§ 80) the original source of those
-gaseous and fluid motions which effect denudation, is the solar
-heat. The transformation of this into various modes of force,
-according to the nature and condition of the matter on which
-it falls, is the first stage of complication. The sun’s rays,
-striking at all angles a sphere, that from moment to moment
-presents and withdraws different parts of its surface, and each
-of them for a different time daily throughout the year, would
-produce a considerable variety of changes even were the
-sphere uniform. But falling as they do on a sphere surrounded
-by an atmosphere in some parts of which wide areas
-of cloud are suspended, and which here unveils vast tracts of
-sea, there of level land, there of mountains, there of snow and
-ice, they initiate in its several parts countless different movements.
-Currents of air of all sizes, directions, velocities, and
-temperatures, are set up; as are also marine currents similarly
-contrasted in their characters. In this region the surface
-is giving off water in the state of vapour; in that, dew
-is being precipitated; and in the other rain is descending—differences
-that arise from the ever-changing ratio between
-the absorption and radiation of heat in each place. At one
-hour, a rapid fall in temperature leads to the formation of ice,
-with an accompanying expansion throughout the moist
-bodies frozen; while at another, a thaw unlocks the dislocated
-fragments of these bodies. And then, passing to a second
-stage of complication, we see that the many kinds of motion
-directly or indirectly caused by the sun’s rays, severally produce
-results that vary with the conditions. Oxidation,
-drought, wind, frost, rain, glaciers, rivers, waves, and other
-denuding agents effect disintegrations that are determined in
-their amounts and qualities by local circumstances. Acting
-upon a tract of granite, such agents here work scarcely an
-<span class='pageno' id='Page_397'>397</span>appreciable effect; there cause exfoliations of the surface, and
-a resulting heap of <i><span lang="fr" xml:lang="fr">débris</span></i> and boulders; and elsewhere, after
-decomposing the feldspar into a white clay, carry away this
-with the accompanying quartz and mica, and deposit them
-in separate beds, fluviatile and marine. When the exposed
-land consists of several unlike formations, sedimentary and
-igneous, changes proportionably more heterogeneous are
-wrought. The formations being disintegrable in different degrees,
-there follows an increased irregularity of surface. The
-areas drained by different rivers being differently constituted,
-these rivers carry down to the sea unlike combinations of
-ingredients; and so sundry new strata of distinct composition
-arise. And here indeed we may see very simply illustrated,
-the truth, that the heterogeneity of the effects increases in a
-geometrical progression, with the heterogeneity of the object
-acted upon. A continent of complex structure, presenting
-many strata irregularly distributed, raised to various levels,
-tilted up at all angles, must, under the same denuding agencies,
-give origin to immensely multiplied results: each district
-must be peculiarly modified; each river must carry
-down a distinct kind of detritus; each deposit must be differently
-distributed by the entangled currents, tidal and other,
-which wash the contorted shores; and every additional complication
-of surface must be the cause of more than one additional
-consequence. But not to dwell on these, let us,
-for the fuller elucidation of this truth in relation to the inorganic
-world, consider what would presently follow from some
-extensive cosmical revolution—say the subsidence of Central
-America. The immediate results of the disturbance would
-themselves be sufficiently complex. Besides the numberless
-dislocations of strata, the ejections of igneous matter, the
-propagation of earthquake vibrations thousands of miles
-around, the loud explosions, and the escape of gases, there
-would be the rush of the Atlantic and Pacific Oceans to supply
-the vacant space, the subsequent recoil of enormous
-waves, which would traverse both these oceans and produce
-<span class='pageno' id='Page_398'>398</span>myriads of changes along their shores, the corresponding atmospheric
-waves complicated by the currents surrounding each
-volcanic vent, and the electrical discharges with which such
-disturbances are accompanied. But these temporary effects
-would be insignificant compared with the permanent ones.
-The complex currents of the Atlantic and Pacific would be
-altered in directions and amounts. The distribution of heat
-achieved by these currents would be different from what it is.
-The arrangement of the isothermal lines, not only on the
-neighbouring continents, but even throughout Europe, would
-be changed. The tides would flow differently from what
-they do now. There would be more or less modification of
-the winds in their periods, strengths, directions, qualities.
-Rain would fall scarcely anywhere at the same times and in
-the same quantities as at present. In short, the meteorological
-conditions thousands of miles off, on all sides, would be
-more or less revolutionized. In these many changes, each of
-which comprehends countless minor ones, the reader will see
-the immense heterogeneity of the results wrought out by one
-force, when that force expends itself on a previously complicated
-area; and he will readily draw the corollary that from
-the beginning the complication has advanced at an increasing
-rate.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 119. We have next to trace throughout organic evolution,
-this same all-pervading principle. And here, where
-the transformation of the homogeneous into the heterogeneous
-was first observed, the production of many changes by one
-cause is least easy to demonstrate. The development of a seed
-into a plant, or an ovum into an animal, is so gradual; while
-the forces which determine it are so involved, and at the same
-time so unobtrusive; that it is difficult to detect the multiplication
-of effects which is elsewhere so obvious. Nevertheless,
-by indirect evidence we may establish our proposition; spite
-of the lack of direct evidence.</p>
-
-<p class='c000'>Observe, first, how numerous are the changes which any
-<span class='pageno' id='Page_399'>399</span>marked stimulus works on an adult organism—a human being,
-for instance. An alarming sound or sight, besides impressions
-on the organs of sense and the nerves, may produce a start, a
-scream, a distortion of the face, a trembling consequent on
-general muscular relaxation, a burst of perspiration, an excited
-action of the heart, a rush of blood to the brain, followed
-possibly by arrest of the heart’s action and by syncope; and
-if the system be feeble, an illness with its long train of
-complicated symptoms may set in. Similarly in cases of
-disease. A minute portion of the small-pox virus introduced
-into the system, will, in a severe case, cause, during the first
-stage, rigors, heat of skin, accelerated pulse, furred tongue,
-loss of appetite, thirst, epigastric uneasiness, vomiting, headache,
-pains in the back and limbs, muscular weakness, convulsions,
-delirium, &amp;c.; in the second stage, cutaneous eruption,
-itching, tingling, sore throat, swelled fauces, salivation,
-cough, hoarseness, dyspnœa, &amp;c.; and in the third stage,
-œdematous inflammations, pneumonia, pleurisy, diarrhœa,
-inflammation of the brain, ophthalmia, erysipelas, &amp;c.: each
-of which enumerated symptoms is itself more or less complex.
-Medicines, special foods, better air, might in like manner be
-instanced as producing multiplied results. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Now it
-needs only to consider that the many changes thus wrought
-by one force on an adult organism, must be partially paralleled
-in an embryo-organism, to understand how here also
-the production of many effects by one cause is a source of
-increasing heterogeneity. The external heat and other
-agencies which determine the first complications of the germ,
-will, by acting on these, superinduce further complications;
-on these still higher and more numerous ones; and so on
-continually: each organ as it is developed, serving, by its
-actions and reactions on the rest, to initiate new complexities.
-The first pulsations of the fœtal heart must simultaneously
-aid the unfolding of every part. The growth of each tissue,
-by taking from the blood special proportions of elements,
-must modify the constitution of the blood; and so must
-<span class='pageno' id='Page_400'>400</span>modify the nutrition of all the other tissues. The distributive
-actions, implying as they do a certain waste, necessitate an
-addition to the blood of effete matters, which must influence
-the rest of the system, and perhaps, as some think, initiate
-the formation of excretory organs. The nervous connections
-established among the viscera must further multiply their
-mutual influences. And so with every modification of
-structure—every additional part and every alteration in the
-ratios of parts. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Still stronger becomes the proof when
-we call to mind the fact, that the same germ may be evolved
-into different forms according to circumstances. Thus, during
-its earlier stages, every embryo is sexless—becomes either
-male or female as the balance of forces acting on it determines.
-Again, it is well-known that the larva of a working-bee
-will develop into a queen-bee, if, before a certain period,
-its food be changed to that on which the larvæ of queen-bees
-are fed. Even more remarkable is the case of certain
-entozoa. The ovum of a tape-worm, getting into the intestine
-of one animal, unfolds into the form of its parent; but
-if carried into other parts of the system, or into the intestine
-of some unlike animal, it becomes one of the sac-like creatures,
-called by naturalists <em>Cysticerci</em>, or <em>Cœnuri</em>, or <em>Echinococci</em>—creatures
-so extremely different from the tape-worm
-in aspect and structure, that only after careful investigations
-have they been proved to have the same origin.
-All which instances imply that each advance in embryonic
-complication results from the action of incident forces on the
-complication previously existing. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Indeed, the now
-accepted doctrine of epigenesis necessitates the conclusion that
-organic evolution proceeds after this manner. For since it is
-proved that no germ, animal or vegetal, contains the slightest
-rudiment, trace, or indication of the future organism—since
-the microscope has shown us that the first process set up in
-every fertilized germ is a process of repeated spontaneous
-fissions, ending in the production of a mass of cells, not one
-of which exhibits any special character; there seems no
-<span class='pageno' id='Page_401'>401</span>alternative but to conclude that the partial organization at
-any moment subsisting in a growing embryo, is transformed
-by the agencies acting on it into the succeeding phase of
-organization, and this into the next, until, through ever-increasing
-complexities, the ultimate form is reached.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Thus, though the subtlety of the forces and the
-slowness of the metamorphosis, prevent us from <em>directly</em>
-tracing the genesis of many changes by one cause, throughout
-the successive stages which every embryo passes through;
-yet, <em>indirectly</em>, we have strong evidence that this is a source
-of increasing heterogeneity. We have marked how multitudinous
-are the effects which a single agency may generate
-in an adult organism; that a like multiplication of effects
-must happen in the unfolding organism, we have inferred
-from sundry illustrative cases; further, it has been pointed
-out that the ability which like germs have to originate unlike
-forms, implies that the successive transformations result
-from the new changes superinduced on previous changes;
-and we have seen that structureless as every germ originally
-is, the development of an organism out of it is otherwise incomprehensible.
-Doubtless we are still in the dark respecting
-those mysterious properties which make the germ, when
-subject to fit influences, undergo the special changes beginning
-this series of transformations. All here contended is,
-that given a germ possessing these mysterious properties, the
-evolution of an organism from it depends, in part, on that
-multiplication of effects which we have seen to be a cause of
-evolution in general, so far as we have yet traced it.</p>
-
-<p class='c000'>When, leaving the development of single plants and animals,
-we pass to that of the Earth’s flora and fauna, the
-course of the argument again becomes clear and simple.
-Though, as before admitted, the fragmentary facts Palæontology
-has accumulated, do not clearly warrant us in saying
-that, in the lapse of geologic time, there have been evolved
-more heterogeneous organisms, and more heterogeneous
-assemblages of organisms; yet we shall now see that there
-<span class='pageno' id='Page_402'>402</span><em>must</em> ever have been a tendency towards these results. We
-shall find that the production of many effects by one cause,
-which, as already shown, has been all along increasing
-the physical heterogeneity of the Earth, has further necessitated
-an increasing heterogeneity in its flora and fauna,
-individually and collectively. An illustration will make this
-clear. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Suppose that by a series of upheavals, occurring,
-as they are now known to do, at long intervals, the East
-Indian Archipelago were to be raised into a continent, and a
-chain of mountains formed along the axis of elevation. By
-the first of these upheavals, the plants and animals inhabiting
-Borneo, Sumatra, New Guinea, and the rest, would be
-subjected to slightly-modified sets of conditions. The climate
-in general would be altered in temperature, in humidity, and
-in its periodical variations; while the local differences would
-be multiplied. These modifications would affect, perhaps
-inappreciably, the entire flora and fauna of the region. The
-change of level would produce additional modifications;
-varying in different species, and also in different members of
-the same species, according to their distance from the axis of
-elevation. Plants, growing only on the sea-shore in special
-localities, might become extinct. Others, living only in
-swamps of a certain humidity, would, if they survived at all,
-probably undergo visible changes of appearance. While
-more marked alterations would occur in some of the
-plants that spread over the lands newly raised above the
-sea. The animals and insects living on these modified plants,
-would themselves be in some degree modified by change of
-food, as well as by change of climate; and the modification
-would be more marked where, from the dwindling or disappearance
-of one kind of plant, an allied kind was eaten. In
-the lapse of the many generations arising before the next upheaval,
-the sensible or insensible alterations thus produced in
-each species, would become organized—in all the races that
-survived there would be a more or less complete adaptation
-to the new conditions. The next upheaval would superinduce
-<span class='pageno' id='Page_403'>403</span>further organic changes, implying wider divergences
-from the primary forms; and so repeatedly. Now however
-let it be observed that this revolution would not be a substitution
-of a thousand modified species for the thousand
-original species; but in place of the thousand original species
-there would arise several thousand species, or varieties, or
-changed forms. Each species being distributed over an area
-of some extent, and tending continually to colonize the new
-area exposed, its different members would be subject to different
-sets of changes. Plants and animals migrating towards
-the equator would not be affected in the same way
-with others migrating from it. Those which spread towards
-the new shores, would undergo changes unlike the changes
-undergone by those which spread into the mountains. Thus,
-each original race of organisms would become the root from
-which diverged several races, differing more or less from it and
-from each other; and while some of these might subsequently
-disappear, probably more than one would survive in the next
-geologic period: the very dispersion itself increasing the
-chances of survival. Not only would there be certain modifications
-thus caused by changes of physical conditions and
-food; but also in some cases other modifications caused by
-changes of habit. The fauna of each island, peopling, step
-by step, the newly-raised tracts, would eventually come in
-contact with the faunas of other islands; and some members
-of these other faunas would be unlike any creatures before
-seen. Herbivores meeting with new beasts of prey, would,
-in some cases, be led into modes of defence or escape differing
-from those previously used; and simultaneously the
-beasts of prey would modify their modes of pursuit and
-attack. We know that when circumstances demand it, such
-changes of habit <em>do</em> take place in animals; and we know
-that if the new habits become the dominant ones, they
-must eventually in some degree alter the organization.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Observe now, however, a further consequence.
-There must arise not simply a tendency towards the differentiation
-<span class='pageno' id='Page_404'>404</span>of each race of organisms into several races; but also
-a tendency to the occasional production of a somewhat higher
-organism. Taken in the mass, these divergent varieties,
-which have been caused by fresh physical conditions and
-habits of life, will exhibit alterations quite indefinite in kind
-and degree; and alterations that do not necessarily constitute
-an advance. Probably in most cases the modified type
-will be not appreciably more heterogeneous than the original
-one. But it <em>must</em> now and then occur, that some division of
-a species, falling into circumstances which give it rather
-more complex experiences, and demand actions somewhat
-more involved, will have certain of its organs further differentiated
-in proportionately small degrees—will become
-slightly more heterogeneous. Hence, there will from time
-to time arise an increased heterogeneity both of the Earth’s
-flora and fauna, and of individual races included in them.
-Omitting detailed explanations, and allowing for the qualifications
-which cannot here be specified, it is sufficiently clear
-that geological mutations have all along tended to complicate
-the forms of life, whether regarded separately or collectively.
-That multiplication of effects which has been a part-cause of
-the transformation of the Earth’s crust from the simple into
-the complex, has simultaneously led to a parallel transformation
-of the Life upon its surface.<a id='r17' /><a href='#f17' class='c011'><sup>[17]</sup></a></p>
-
-<p class='c000'>The deduction here drawn from the established truths of
-<span class='pageno' id='Page_405'>405</span>geology and the general laws of life, gains immensely in weight
-on finding it to be in harmony with an induction drawn from
-direct experience. Just that divergence of many races from
-one race, which we inferred must have been continually occurring
-during geologic time, we know to have occurred during
-the pre-historic and historic periods, in man and domestic
-animals. And just that multiplication of effects which we
-concluded must have been instrumental to the first, we see
-has in a great measure wrought the last. Single causes, as
-famine, pressure of population, war, have periodically led to
-further dispersions of mankind and of dependent creatures:
-each such dispersion initiating new modifications, new varieties
-of type. Whether all the human races be or be not derived
-from one stock, philology makes it clear that whole groups of
-races, now easily distinguishable from each other, were originally
-one race—that the diffusion of one race into different
-climates and conditions of existence has produced many
-altered forms of it. Similarly with domestic animals. Though
-in some cases (as that of dogs) community of origin will perhaps
-be disputed, yet in other cases (as that of the sheep or
-the cattle of our own country) it will not be questioned that
-local differences of climate, food, and treatment, have transformed
-one original breed into numerous breeds, now become
-so far distinct as to produce unstable hybrids. Moreover,
-through the complication of effects flowing from single causes,
-we here find, what we before inferred, not only an increase of
-general heterogeneity, but also of special heterogeneity.
-While of the divergent divisions and subdivisions of the human
-race, many have undergone changes not constituting an
-advance; others have become decidedly more heterogeneous.
-The civilized European departs more widely from the vertebrate
-archetype than does the savage.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 120. A sensation does not expend itself in arousing some
-single state of consciousness; but the state of consciousness
-aroused is made up of various represented sensations connected
-<span class='pageno' id='Page_406'>406</span>by co-existence, or sequence with the presented sensation.
-And that, in proportion as the grade of intelligence is high,
-the number of ideas suggested is great, may be readily inferred.
-Let us, however, look at the proof that here too, each change
-is the parent of many changes; and that the multiplication
-increases in proportion as the area affected is complex.</p>
-
-<p class='c000'>Were some hitherto unknown bird, driven say by stress of
-weather from the remote north, to make its appearance on
-our shores, it would excite no speculation in the sheep or cattle
-amid which it alighted: a perception of it as a creature
-like those constantly flying about, would be the sole interruption
-of that dull current of consciousness which accompanies
-grazing and rumination. The cow-herd, by whom we
-may suppose the exhausted bird to be presently caught, would
-probably gaze at it with some slight curiosity, as being unlike
-any he had before seen—would note its most conspicuous
-markings, and vaguely ponder on the questions, where it
-came from, and how it came. The village bird-stuffer would
-have suggested to him by the sight of it, sundry forms to
-which it bore a little resemblance; would receive from it more
-numerous and more specific impressions respecting structure
-and plumage; would be reminded of various instances of
-birds brought by storms from foreign parts—would tell who
-found them, who stuffed them, who bought them. Supposing
-the unknown bird taken to a naturalist of the old school,
-interested only in externals, (one of those described by the
-late Edward Forbes, as examining animals as though they were
-merely skins filled with straw,) it would excite in him a more
-involved series of mental changes: there would be an elaborate
-examination of the feathers, a noting of all their technical
-distinctions, with a reduction of these perceptions to certain
-equivalent written symbols; reasons for referring the new
-form to a particular family, order, and genus would be sought
-out and written down; communications with the secretary of
-some society, or editor of some journal, would follow; and
-probably there would be not a few thoughts about the addition
-<span class='pageno' id='Page_407'>407</span>of the <em>ii</em> to the describer’s name, to form the name of the
-species. Lastly, in the mind of a comparative anatomist, such
-a new species, should it happen to have any marked internal
-peculiarity, might produce additional sets of changes—might
-very possibly suggest modified views respecting the relationships
-of the division to which it belonged; or, perhaps, alter
-his conceptions of the homologies and developments of certain
-organs; and the conclusions drawn might not improbably
-enter as elements into still wider inquiries concerning the
-origin of organic forms.</p>
-
-<p class='c000'>From ideas let us turn to emotions. In a young child, a
-father’s anger produces little else than vague fear—a disagreeable
-sense of impending evil, taking various shapes of physical
-suffering or deprivation of pleasures. In elder children,
-the same harsh words will arouse additional feelings: sometimes
-a sense of shame, of penitence, or of sorrow for having
-offended; at other times, a sense of injustice, and a
-consequent anger. In the wife, yet a further range of feelings
-may come into existence—perhaps wounded affection,
-perhaps self-pity for ill-usage, perhaps contempt for groundless
-irritability, perhaps sympathy for some suffering which
-the irritability indicates, perhaps anxiety about an unknown
-misfortune which she thinks has produced it. Nor are we
-without evidence that among adults, the like differences of development
-are accompanied by like differences in the number
-of emotions that are aroused, in combination or rapid succession—the
-lower natures being characterized by that impulsiveness
-which results from the uncontrolled action of a few
-feelings; and the higher natures being characterized by the
-simultaneous action of many secondary feelings, modifying
-those first awakened.</p>
-
-<p class='c000'>Possibly it will be objected that the illustrations here given,
-are drawn from the functional changes of the nervous system,
-not from its structural changes; and that what is proved
-among the first, does not necessarily hold among the last.
-This must be admitted. Those, however, who recognize the
-<span class='pageno' id='Page_408'>408</span>truth that the structural changes are the slowly accumulated
-results of the functional changes, will readily draw the corollary,
-that a part-cause of the evolution of the nervous system,
-as of other evolution, is this multiplication of effects which
-becomes ever greater as the development becomes higher.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 121. If the advance of Man towards greater heterogeneity
-in both body and mind, is in part traceable to the production
-of many effects by one cause, still more clearly may the
-advance of Society towards greater heterogeneity be so explained.
-Consider the growth of an industrial organization.
-When, as must occasionally happen, some individual of a
-tribe displays unusual aptitude for making an article of general
-use (a weapon, for instance) which was before made by
-each man for himself, there arises a tendency towards the
-differentiation of that individual into a maker of weapons.
-His companions (warriors and hunters all of them) severally
-wish to have the best weapons that can be made; and are
-therefore certain to offer strong inducements to this skilled
-individual to make weapons for them. He, on the other hand,
-having both an unusual faculty, and an unusual liking, for
-making weapons (the capacity and the desire for any occupation
-being commonly associated), is predisposed to fulfil
-these commissions on the offer of adequate rewards: especially
-as his love of distinction is also gratified. This first
-specialization of function, once commenced, tends ever to become
-more decided. On the side of the weapon-maker, continued
-practice gives increased skill—increased superiority to
-his products. On the side of his clients, cessation of practice
-entails decreased skill. Thus the influences that determine
-this division of labour grow stronger in both ways: this
-social movement tends ever to become more decided in the
-direction in which it was first set up; and the incipient
-heterogeneity is, on the average of cases, likely to become
-permanent for that generation, if no longer. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Such a
-process, besides differentiating the social mass into two parts,
-<span class='pageno' id='Page_409'>409</span>the one monopolizing, or almost monopolizing, the performance
-of a certain function, and the other having lost the
-habit, and in some measure the power, of performing that
-function, has a tendency to initiate other differentiations. The
-advance described implies the introduction of barter: the
-maker of weapons has, on each occasion, to be paid in such
-other articles as he agrees to take in exchange. Now he will
-not habitually take in exchange one kind of article, but many
-kinds. He does not want mats only, or skins, or fishing-gear;
-but he wants all these; and on each occasion will bargain
-for the particular things he most needs. What follows? If
-among the members of the tribe there exist any slight differences
-of skill in the manufacture of these various things, as
-there are almost sure to do, the weapon-maker will take from
-each one the thing which that one excels in making: he will
-exchange for mats with him whose mats are superior, and
-will bargain for the fishing-gear of whoever has the best.
-But he who has bartered away his mats or his fishing-gear,
-must make other mats or fishing-gear for himself; and in so
-doing must, in some degree, further develop his aptitude.
-Thus it results that the small specialities of faculty possessed
-by various members of the tribe will tend to grow more decided.
-If such transactions are from time to time repeated,
-these specializations may become appreciable. And whether
-or not there ensue distinct differentiations of other individuals
-into makers of particular articles, it is clear that incipient
-differentiations take place throughout the tribe: the one
-original cause produces not only the first dual effect, but a
-number of secondary dual effects, like in kind but minor in
-degree. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;This process, of which traces may be seen
-among groups of school-boys, cannot well produce a lasting
-distribution of functions in an unsettled tribe; but where
-there grows up a fixed and multiplying community, such
-differentiations become permanent, and increase with each
-generation. An addition to the number of citizens, involving
-a greater demand for every commodity, intensifies the
-<span class='pageno' id='Page_410'>410</span>functional activity of each specialized person or class; and
-this renders the specialization more definite where it already
-exists, and establishes it where it is but nascent. By
-increasing the pressure on the means of subsistence, a larger
-population again augments these results; since every individual
-is forced more and more to confine himself to that which
-he can do best, and by which he can gain most. And this
-industrial progress, by aiding future production, opens the
-way for further growth of population, which reacts as before.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Presently, under the same stimuli, new occupations
-arise. Competing workers, severally aiming to produce
-improved articles, occasionally discover better processes
-or better materials. In weapons and cutting-tools, the substitution
-of bronze for stone entails on him who first makes it, a
-great increase of demand—so great an increase that he presently
-finds all his time occupied in making the bronze for the
-articles he sells, and is obliged to depute the fashioning of
-these articles to others; and eventually the making of bronze,
-thus gradually differentiated from a pre-existing occupation,
-becomes an occupation by itself. But now mark the ramified
-changes which follow this change. Bronze soon replaces stone,
-not only in the articles it was first used for, but in many others;
-and so affects the manufacture of them. Further, it affects the
-processes which such improved utensils subserve, and the resulting
-products—modifies buildings, carvings, dress, personal
-decorations. Yet again, it sets going sundry manufactures
-which were before impossible, from lack of a material fit for
-the requisite tools. And all these changes react on the people—increase
-their manipulative skill, their intelligence, their
-comfort—refine their habits and tastes.</p>
-
-<p class='c000'>It is out of the question here to follow through its successive
-complications, this increasing social heterogeneity that
-results from the production of many effects by one cause.
-But leaving the intermediate phases of social development,
-let us take an illustration from its passing phase. To trace
-the effects of steam-power, in its manifold applications to
-<span class='pageno' id='Page_411'>411</span>mining, navigation, and manufactures, would carry us into
-unmanageable detail. Let us confine ourselves to the latest
-embodiment of steam-power—the locomotive engine. This,
-as the proximate cause of our railway-system, has changed
-the face of the country, the course of trade, and the habits of
-the people. Consider, first, the complicated sets of changes
-that precede the making of every railway—the provisional
-arrangements, the meetings, the registration, the trial-section,
-the parliamentary survey, the lithographed plans, the books
-of reference, the local deposits and notices, the application to
-Parliament, the passing Standing-Orders Committee, the first,
-second, and third readings: each of which brief heads indicates
-a multiplicity of transactions, and the further development
-of sundry occupations, (as those of engineers, surveyors,
-lithographers, parliamentary agents, share-brokers,) and the
-creation of sundry others (as those of traffic-takers, reference-takers).
-Consider, next, the yet more marked changes
-implied in railway construction—the cuttings, em-bankings,
-tunnellings, diversions of roads; the building of bridges and
-stations; the laying down of ballast, sleepers, and rails; the
-making of engines, tenders, carriages, and wagons: which
-processes, acting upon numerous trades, increase the importation
-of timber, the quarrying of stone, the manufacture of
-iron, the mining of coal, the burning of bricks; institute a
-variety of special manufactures weekly advertised in the
-<cite>Railway Times</cite>; and call into being some new classes of
-workers—drivers, stokers, cleaners, plate-layers, &amp;c. &amp;c.
-Then come the changes, more numerous and involved still,
-which railways in action produce on the community at large.
-The organization of every business is more or less modified:
-ease of communication makes it better to do directly what
-was before done by proxy; agencies are established where
-previously they would not have paid; goods are obtained
-from remote wholesale houses instead of near retail ones; and
-commodities are used which distance once rendered inaccessible.
-The rapidity and small cost of carriage, tend to specialize
-<span class='pageno' id='Page_412'>412</span>more than ever the industries of different districts—to
-confine each manufacture to the parts in which, from local
-advantages, it can be best carried on. Economical distribution
-equalizes prices, and also, on the average, lowers prices:
-thus bringing divers articles within the means of those before
-unable to buy them, and so increasing their comforts and
-improving their habits. At the same time the practice of
-travelling is immensely extended. Classes who before could
-not afford it, take annual trips to the sea; visit their distant
-relations; make tours; and so we are benefited in body,
-feelings, and intellect. The more prompt transmission of
-letters and of news produces further changes—makes the
-pulse of the nation faster. Yet more, there arises a wide
-dissemination of cheap literature through railway book-stalls,
-and of advertisements in railway carriages: both of them
-aiding ulterior progress. And the innumerable changes here
-briefly indicated are consequent on the invention of the locomotive
-engine. The social organism has been rendered more
-heterogeneous, in virtue of the many new occupations introduced,
-and the many old ones further specialized; prices in
-all places have been altered; each trader has, more or less,
-modified his way of doing business; and every person has
-been affected in his actions, thoughts, emotions.</p>
-
-<p class='c000'>The only further fact demanding notice, is, that we here
-see more clearly than ever, that in proportion as the area over
-which any influence extends, becomes heterogeneous, the
-results are in a yet higher degree multiplied in number and
-kind. While among the primitive tribes to whom it was
-first known, caoutchouc caused but few changes, among ourselves
-the changes have been so many and varied that the
-history of them occupies a volume. Upon the small, homogeneous
-community inhabiting one of the Hebrides, the
-electric telegraph would produce, were it used, scarcely any
-results; but in England the results it produces are multitudinous.</p>
-
-<p class='c000'>Space permitting, the synthesis might here be pursued
-<span class='pageno' id='Page_413'>413</span>in relation to all the subtler products of social life. It might
-be shown how, in Science, an advance of one division presently
-advances other divisions—how Astronomy has been
-immensely forwarded by discoveries in Optics, while other
-optical discoveries have initiated Microscopic Anatomy, and
-greatly aided the growth of Physiology—how Chemistry has
-indirectly increased our knowledge of Electricity, Magnetism,
-Biology, Geology—how Electricity has reacted on Chemistry
-and Magnetism, developed our views of Light and Heat, and
-disclosed sundry laws of nervous action. In Literature the
-same truth might be exhibited in the still-multiplying forms
-of periodical publications that have descended from the first
-newspaper, and which have severally acted and reacted on
-other forms of literature and on each other; or in the bias
-given by each book of power to various subsequent books.
-The influence which a new school of Painting (as that of the
-pre-Raphaelites) exercises on other schools; the hints which
-all kinds of pictorial art are deriving from Photography; the
-complex results of new critical doctrines; might severally be
-dwelt on as displaying the like multiplication of effects. But
-it would needlessly tax the reader’s patience to detail, in
-their many ramifications, these various changes: here become
-so involved and subtle as to be followed with some
-difficulty.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 122. After the argument which closed the last chapter, a
-parallel one seems here scarcely required. For symmetry’s
-sake, however, it will be proper briefly to point out how the
-multiplication of effects, like the instability of the homogeneous,
-is a corollary from the persistence of force.</p>
-
-<p class='c000'>Things which we call different are things which react in
-different ways; and we can know them as different only by
-the differences in their reactions. When we distinguish
-bodies as hard and soft, rough and smooth, we simply mean
-that certain like muscular forces expended on them are
-followed by unlike sets of sensations—unlike re-active forces.
-<span class='pageno' id='Page_414'>414</span>Objects that are classed as red, blue, yellow, &amp;c., are objects
-that decompose light in strongly-contrasted ways; that is, we
-know contrasts of colour as contrasts in the changes produced
-in a uniform incident force. Manifestly, any two things
-which do not work unequal effects on consciousness, either by
-unequally opposing our own energies, or by impressing our
-senses with unequally modified forms of certain external
-energies, cannot be distinguished by us. Hence the proposition
-that the different parts of any whole must react differently
-on a uniform incident force, and must so reduce it to
-a group of multiform forces, is in essence a truism. A
-further step will reduce this truism to its lowest terms.</p>
-
-<p class='c000'>When, from unlikeness between the effects they produce
-on consciousness, we predicate unlikeness between two objects,
-what is our warrant? and what do we mean by the
-unlikeness, objectively considered? Our warrant is the persistence
-of force. Some kind or amount of change has been
-wrought in us by the one, which has not been wrought by
-the other. This change we ascribe to some force exercised by
-the one which the other has not exercised. And we have no
-alternative but to do this, or to assert that the change had
-no antecedent; which is to deny the persistence of force.
-Whence it is further manifest that what we regard as the
-objective unlikeness is the presence in the one of some force,
-or set of forces, not present in the other—something in the
-kinds or amounts or directions of the constituent forces of the
-one, which those of the other do not parallel. But now if
-things or parts of things which we call different, are those of
-which the constituent forces differ in one or more respects;
-what must happen to any like forces, or any uniform force,
-falling on them? Such like forces, or parts of a uniform
-force, must be differently modified. The force which is present
-in the one and not in the other, must be an element in
-the conflict—must produce its equivalent reaction; and must
-so affect the total reaction. To say otherwise is to say that
-<span class='pageno' id='Page_415'>415</span>this differential force will produce no effect; which is to say
-that force is not persistent.</p>
-
-<p class='c000'>I need not develop this corollary further. It manifestly
-follows that a uniform force, falling on a uniform aggregate,
-must undergo dispersion; that falling on an aggregate
-made up of unlike parts, it must undergo dispersion from
-each part, as well as qualitative differentiations; that in proportion
-as the parts are unlike, these qualitative differentiations
-must be marked; that in proportion to the number of
-the parts, they must be numerous; that the secondary forces
-so produced, must undergo further transformations while
-working equivalent transformations in the parts that change
-them; and similarly with the forces they generate. Thus the
-conclusions that a part-cause of Evolution is the multiplication
-of effects; and that this increases in geometrical progression
-as the heterogeneity becomes greater; are not only to be
-established inductively, but are deducible from the deepest
-of all truths.</p>
-
-<hr class='c015' />
-
-<div class='footnote' id='f17'>
-<p class='c000'><span class='label'><a href='#r17'>17</a>.&nbsp;&nbsp;</span>Had this paragraph, first published in the <cite>Westminster Review</cite> in 1857, been
-written after the appearance of Mr. Darwin’s work on <cite>The Origin of Species</cite>, it
-would doubtless have been otherwise expressed. Reference would have been
-made to the process of “natural selection,” as greatly facilitating the differentiations
-described. As it is, however, I prefer to let the passage stand in its original
-shape: partly because it seems to me that these successive changes of conditions
-would produce divergent varieties or species, apart from the influence of
-“natural selection” (though in less numerous ways as well as less rapidly); and
-partly because I conceive that in the absence of these successive changes of conditions,
-“natural selection” would effect comparatively little. Let me add that
-though these positions are not enunciated in <cite>The Origin of Species</cite>, yet a mutual
-friend gives me reason to think that Mr. Darwin would coincide in them; if he
-did not indeed consider them as tacitly implied in his work.</p>
-</div>
-
-<div>
- <span class='pageno' id='Page_416'>416</span>
- <h3 class='c001'>CHAPTER XV.<br /> <span class='large'>DIFFERENTIATION AND INTEGRATION.</span></h3>
-</div>
-
-<p class='c006'>§ 123. The general interpretation of Evolution is far from
-being completed in the preceding chapters. We must contemplate
-its changes under yet another aspect, before we can
-form a definite conception of the process constituted by them.
-Though the laws already set forth, furnish a key to the re-arrangement
-of parts which Evolution exhibits, in so far as
-it is an advance from the uniform to the multiform; they
-furnish no key to this re-arrangement in so far as it is an
-advance from the indefinite to the definite. On studying the
-actions and re-actions everywhere going on, we have found
-it to follow inevitably from a certain primordial truth, that
-the homogeneous must lapse into the heterogeneous, and that
-the heterogeneous must become more heterogeneous; but we
-have not discovered why the differently-affected parts of any
-simple whole, become clearly marked off from each other, at
-the same time that they become unlike. Thus far no reason
-has been assigned why there should not ordinarily arise a
-vague chaotic heterogeneity, in place of that orderly heterogeneity
-displayed in Evolution. It still remains to find out
-the cause of that integration of parts which accompanies
-their differentiation—that gradually-completed segregation
-of like units into a group, distinctly separated from neighbouring
-groups which are severally made up of other kinds
-of units. The rationale will be conveniently introduced by a
-<span class='pageno' id='Page_417'>417</span>few instances in which we may watch this segregative process
-taking place.</p>
-
-<p class='c000'>When towards the end of September, the trees are gaining
-their autumn colours, and we are hoping shortly to see a
-further change increasing still more the beauty of the landscape,
-we are not uncommonly disappointed by the occurrence
-of an equinoxial gale. Out of the mixed mass of
-foliage on each branch, the strong current of air carries
-away the decaying and brightly-tinted leaves, but fails to
-detach those which are still green. And while these last,
-frayed and seared by long-continued beatings against each
-other, and the twigs around them, give a sombre colour to
-the woods, the red and yellow and orange leaves are collected
-together in ditches and behind walls and in corners where
-eddies allow them to settle. That is to say, by the action of
-that uniform force which the wind exerts on both kinds, the
-dying leaves are picked out from among their still living companions
-and gathered in places by themselves. Again, the
-separation of particles of different sizes, as dust and sand
-from pebbles, may be similarly effected; as we see on every
-road in March. And from the days of Homer downwards,
-the power of currents of air, natural and artificial, to part
-from one another units of unlike specific gravities, has
-been habitually utilized in the winnowing of chaff from
-wheat. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;In every river we see how the mixed materials
-carried down, are separately deposited—how in rapids
-the bottom gives rest to nothing but boulders and pebbles;
-how where the current is not so strong, sand is let fall; and
-how, in still places, there is a sediment of mud. This selective
-action of moving water, is commonly applied in the arts
-to obtain masses of particles of different degrees of fineness.
-Emery, for example, after being ground, is carried by a slow
-current through successive compartments; in the first of
-which the largest grains subside; in the second of which
-the grains that reach the bottom before the water has
-escaped, are somewhat smaller; in the third smaller still;
-<span class='pageno' id='Page_418'>418</span>until in the last there are deposited only those finest
-particles which fall so slowly through the water, that they
-have not previously been able to reach the bottom. And in
-a way that is different though equally significant, this segregative
-effect of water in motion, is exemplified in the carrying
-away of soluble from insoluble matters—an application
-of it hourly made in every laboratory. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The effects of
-the uniform forces which aerial and aqueous currents exercise,
-are paralleled by those of uniform forces of other orders. Electric
-attraction will separate small bodies from large, or light
-bodies from heavy. By magnetism, grains of iron may be
-selected from among other grains; as by the Sheffield
-grinder, whose magnetized gauze mask filters out the steel-dust
-which his wheel gives off, from the stone-dust that
-accompanies it. And how the affinity of any agent acting
-differently on the components of a given body, enables us to
-take away some component and leave the rest behind, is
-shown in almost every chemical experiment.</p>
-
-<p class='c000'>What now is the general truth here variously presented?
-How are these several facts and countless similar ones, to be
-expressed in terms that embrace them all? In each case we
-see in action a force which may be regarded as simple or uniform—fluid
-motion in a certain direction at a certain velocity;
-electric or magnetic attraction of a given amount; chemical
-affinity of a particular kind: or rather, in strictness, the acting
-force is compounded of one of these and certain other
-uniform forces, as gravitation, etc. In each case we have an
-aggregate made up of unlike units—either atoms of different
-substances combined or intimately mingled, or fragments of
-the same substance of different sizes, or other constituent
-parts that are unlike in their specific gravities, shapes, or
-other attributes. And in each case these unlike units, or
-groups of units, of which the aggregate consists, are, under
-the influence of some resultant force acting indiscriminately
-on them all, separated from each other—segregated
-into minor aggregates, each consisting of units that are
-<span class='pageno' id='Page_419'>419</span>severally like each other and unlike those of the other minor
-aggregates. Such being the common aspect of these changes,
-let us look for the common interpretation of them.</p>
-
-<p class='c000'>In the chapter on “The Instability of the Homogeneous,”
-it was shown that a uniform force falling on any aggregate,
-produces unlike modifications in its different parts—turns the
-uniform into the multiform and the multiform into the more
-multiform. The transformation thus wrought, consists of
-either insensible or sensible changes of relative position
-among the units, or of both—either of those molecular re-arrangements
-which we call chemical, or of those larger
-transpositions which are distinguished as mechanical, or of
-the two united. Such portion of the permanently effective
-force as reaches each different part, or differently-conditioned
-part, may be expended in modifying the mutual relations of
-its constituents; or it may be expended in moving the part
-to another place; or it may be expended partially in the first
-and partially in the second. Hence, so much of the permanently
-effective force as does not work the one kind of effect,
-must work the other kind. It is manifest that if of the
-permanently effective force which falls on some compound
-unit of an aggregate, little, if any, is absorbed in re-arranging
-the ultimate components of such compound unit, much
-or the whole, must show itself in motion of such compound
-unit to some other place in the aggregate; and conversely,
-if little or none of this force is absorbed in generating mechanical
-transposition, much or the whole must go to produce
-molecular alterations. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;What now must follow
-from this? In cases where none or only part of the force
-generates chemical re-distributions, what physical re-distributions
-must be generated? Parts that are similar to each
-other will be similarly acted on by the force; and will similarly
-react on it. Parts that are dissimilar will be dissimilarly
-acted on by the force; and will dissimilarly react on
-it. Hence the permanently effective incident force, when
-wholly or partially transformed into mechanical motion
-<span class='pageno' id='Page_420'>420</span>of the units, will produce like motions in units that are
-alike, and unlike motions in units that are unlike. If
-then, in an aggregate containing two or more orders of mixed
-units, those of the same order will be moved in the same way,
-and in a way that differs from that in which units of other
-orders are moved, the respective orders must segregate. A
-group of like things on which are impressed motions that are
-alike in amount and direction, must be transferred as a group
-to another place, and if they are mingled with some group of
-other things, on which the motions impressed are like each
-other, but unlike those of the first group in amount or direction
-or both, these other things must be transferred as a
-group to some other place—the mixed aggregate must undergo
-a simultaneous differentiation and integration.</p>
-
-<p class='c000'>In further elucidation of this process, it will be well here
-to set down a few instances in which we may see that, other
-things equal, the definiteness of the separation is in proportion
-to the definiteness of the difference between the units.
-Take a handful of any pounded substance, containing fragments
-of all sizes; and let it fall to the ground while a
-gentle breeze is blowing. The large fragments will be
-collected together on the ground almost immediately under
-the hand; somewhat smaller fragments will be carried a
-little to the leeward; still smaller ones a little further; and
-those minute particles which we call dust, will be drifted a
-long way before they reach the earth: that is, the integration
-is indefinite where the difference among the fragments is
-indefinite, though the divergence is greatest where the
-difference is greatest. If, again, the handful be made up of
-quite distinct orders of units—as pebbles, coarse sand, and
-dust—these will, under like conditions, be segregated with
-comparative definiteness: the pebbles will drop almost vertically;
-the sand will fall in an inclined direction, and deposit
-itself within a tolerably circumscribed space beyond the
-pebbles; while the dust will be blown almost horizontally to
-a great distance. A case in which another kind of force
-<span class='pageno' id='Page_421'>421</span>comes into play, will still better illustrate this truth.
-Through a mixed aggregate of soluble and insoluble substances,
-let water slowly percolate. There will in the first
-place be a distinct parting of the substances that are the most
-widely contrasted in their relations to the acting forces: the
-soluble will be carried away; the insoluble will remain behind.
-Further, some separation, though a less definite one,
-will be effected among the soluble substances; since the first
-part of the current will remove the most soluble substances in
-the largest amounts, and after these have been all dissolved,
-the current will still continue to bring out the remaining less
-soluble substances. Even the undissolved matters will have
-simultaneously undergone a certain segregation; for the
-percolating fluid will carry down the minute fragments from
-among the large ones, and will deposit those of small specific
-gravity in one place, and those of great specific gravity in
-another. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;To complete the elucidation we must glance
-at the obverse fact; namely, that mixed units which differ but
-slightly, are moved in but slightly-different ways by incident
-forces, and can therefore be separated only by such adjustments
-of the incident forces as allow slight differences to become
-appreciable factors in the result. This truth is made
-manifest by antithesis in the instances just given; but it may
-be made much more manifest by a few such instances as
-those which chemical analysis supplies in abundance. The
-parting of alcohol from water by distillation is a good one.
-Here we have atoms consisting of oxygen and hydrogen,
-mingled with atoms consisting of oxygen, hydrogen, and
-carbon. The two orders of atoms have a considerable
-similarity of nature: they similarly maintain a fluid form at
-ordinary temperatures; they similarly become gaseous more
-and more rapidly as the temperature is raised; and they boil
-at points not very far apart. Now this comparative likeness
-of the atoms is accompanied by difficulty in segregating
-them. If the mixed fluid is unduly heated, much water distils
-over with the alcohol: it is only within a narrow range
-<span class='pageno' id='Page_422'>422</span>of temperature, that the one set of atoms are driven off rather
-than the others; and even then not a few of the others accompany
-them. The most interesting and instructive
-example, however, is furnished by certain phenomena of
-crystallization. When several salts that have little analogy
-of constitution, are dissolved in the same body of water, they
-are separated without much trouble, by crystallization: their
-respective units moved towards each other, as physicists suppose,
-by polar forces, segregate into crystals of their respective
-kinds. The crystals of each salt do, indeed, usually contain
-certain small amounts of the other salts present in the
-solution—especially when the crystallization has been rapid;
-but from these other salts they are severally freed by repeated
-resolutions and crystallizations. Mark now, however, that the
-reverse is the case when the salts contained in the same body
-of water are chemically homologous. The nitrates of baryta
-and lead, or the sulphates of zinc, soda, and magnesia, unite
-in the same crystals; nor will they crystallize separately if
-these crystals be dissolved afresh, and afresh crystallized,
-even with great care. On seeking the cause of this anomaly,
-chemists found that such salts were isomorphous—that their
-atoms, though not chemically identical, were identical in the
-proportions of acid, base, and water, composing them, and in
-their crystalline forms: whence it was inferred that their
-atoms are nearly alike in structure. Thus is clearly illustrated
-the truth, that units of unlike kinds are differentiated and
-integrated with a readiness proportionate to the degree of
-their unlikeness. In the first case we see that being dissimilar
-in their forms, but similar in so far as they are
-soluble in water of a certain temperature, the atoms segregate,
-though imperfectly. In the second case we see that the
-atoms, having not only the likeness implied by solubility in
-the same menstruum, but also a great likeness of structure,
-do not segregate—are differentiated and integrated only
-under quite special conditions, and then very incompletely.
-That is, the incident force of mutual polarity impresses unlike
-<span class='pageno' id='Page_423'>423</span>motions on the mixed units in proportion as they are unlike;
-and therefore, in proportion as they are unlike, tends to deposit
-them in separate places.</p>
-
-<p class='c000'>There is a converse cause of segregation, which it is needless
-here to treat of with equal fulness. If different units
-acted on by the same force, must be differently moved; so,
-too, must units of the same kind be differently moved by
-different forces. Supposing some group of units forming part
-of a homogeneous aggregate, are unitedly exposed to a force
-that is unlike in amount or direction to the force acting on
-the rest of the aggregate; then this group of units will
-separate from the rest, provided that, of the force so acting
-on it, there remains any portion not dissipated in molecular
-vibrations, nor absorbed in producing molecular re-arrangements.
-After all that has been said above, this proposition
-needs no defence.</p>
-
-<p class='c000'>Before ending our preliminary exposition, a complementary
-truth must be specified; namely, that mixed forces
-are segregated by the reaction of uniform matters, just as
-mixed matters are segregated by the action of uniform
-forces. Of this truth a complete and sufficient illustration
-is furnished by the dispersion of refracted light. A beam
-of light, made up of ethereal undulations of different orders,
-is not uniformly deflected by a homogeneous refracting
-body; but the different orders of undulations it contains, are
-deflected at different angles: the result being that these
-different orders of undulations are separated and integrated,
-and so produce what we know as the colours of the spectrum.
-A segregation of another kind occurs when rays of light
-traverse an obstructing medium. Those rays which consist
-of comparatively short undulations, are absorbed before those
-which consist of comparatively long ones; and the red rays,
-which consist of the longest undulations, alone penetrate
-when the obstruction is very great. How, conversely, there
-is produced a separation of like forces by the reaction of unlike
-matters, is also made manifest by the phenomena of
-<span class='pageno' id='Page_424'>424</span>refraction: since adjacent and parallel beams of light, falling
-on, and passing through, unlike substances, are made to
-diverge.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 124. On the assumption of their nebular origin, stars and
-planets exemplify that cause of material integration last
-assigned—the action of unlike forces on like units.</p>
-
-<p class='c000'>In a preceding chapter (§ 110) we saw that if matter
-ever existed in a diffused form, it could not continue uniformly
-distributed, but must break up into masses. It was
-shown that in the absence of a perfect balance of mutual attractions
-among atoms dispersed through unlimited space,
-there must arise breeches of continuity throughout the aggregate
-formed by them, and a concentration of it towards
-centres of dominant attraction. Where any such breech of
-continuity occurs, and the atoms that were before adjacent
-separate from each other; they do so in consequence of a
-difference in the forces to which they are respectively subject.
-The atoms on the one side of the breech are exposed
-to a certain surplus attraction in the direction in which they
-begin to move; and those on the other to a surplus attraction
-in the opposite direction. That is, the adjacent groups
-of like units are exposed to unlike resultant forces; and accordingly
-separate and integrate.</p>
-
-<p class='c000'>The formation and detachment of a nebulous ring, illustrates
-the same general principle. To conclude, as Laplace
-did, that the equatorial portion of a rotating nebulous
-spheroid, will, during concentration, acquire a centrifugal
-force sufficient to prevent it from following the rest of the
-contracting mass, is to conclude that such portions will
-remain behind as are in common subject to a certain differential
-force. The line of division between the ring and
-the spheroid, must be a line inside of which the aggregative
-force is greater than the force resisting aggregation; and
-outside of which the force resisting aggregation is greater
-than the aggregative force. Hence the alleged process
-<span class='pageno' id='Page_425'>425</span>conforms to the law that among like units, separation and
-integration is produced by the action of unlike forces.</p>
-
-<p class='c000'>Astronomical phenomena do not furnish any other than
-these hypothetical examples. In its present comparatively
-settled condition, the Solar System exhibits no direct evidence
-of progressing integration: unless indeed under the
-insignificant form of the union of meteoric masses with the
-Earth, and, occasionally perhaps, of cometary matter with
-the Sun.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 125. Those geologic changes usually classed as aqueous,
-display under numerous forms the segregation of unlike
-units by a uniform incident force. On sea-shores, the waves
-are ever sorting-out and separating the mixed materials
-against which they break. From each mass of fallen cliff,
-the rising and ebbing tide carries away all those particles
-which are so small as to remain long suspended in the
-water; and, at some distance from shore, deposits them in
-the shape of fine sediment. Large particles, sinking with
-comparative rapidity, are accumulated into beds of sand
-near low water-mark. The coarse grit and small pebbles
-collect together on the incline up which the breakers rush.
-And on the top lie the larger stones and boulders. Still
-more specific segregations may occasionally be observed.
-Flat pebbles, produced by the breaking down of laminated
-rock, are sometimes separately collected in one part of a
-shingle bank. On this shore the deposit is wholly of mud;
-on that it is wholly of sand. Here we find a sheltered cove
-filled with small pebbles almost of one size; and there, in a
-curved bay one end of which is more exposed than the other,
-we see a progressive increase in the massiveness of the stones
-as we walk from the less exposed to the more exposed end.
-Indeed, our sedimentary strata form one vast series of illustrations
-of the alleged law. Trace the history of each deposit,
-and we are quickly led down to the fact, that mixed
-fragments of matter, differing in their sizes or weights, are,
-<span class='pageno' id='Page_426'>426</span>when exposed to the momentum and friction of water, joined
-with the attraction of the Earth, selected from each other,
-and united into groups of comparatively like fragments.
-We see that, other things equal, the separation is definite in
-proportion as the differences of the units are marked; and
-that, under the action of the same aggregate of forces, the
-most widely unlike units are most widely removed from each
-other.</p>
-
-<p class='c000'>Among igneous changes we do not find so many examples
-of the process described. When specifying the conditions
-to Evolution, it was pointed out (§ 104) that molecular
-vibration exceeding a certain intensity, does not permit those
-integrations which result from the action of minor differential
-forces. Nevertheless, geological phenomena of this
-order are not barren of illustrations. Where the mixed
-matters composing the Earth’s crust have been raised to a
-very high temperature, segregation habitually takes place
-as the temperature diminishes. Sundry of the substances
-that escape in a gaseous form from volcanoes, sublime into
-crystals on coming against cool surfaces; and solidifying, as
-these substances do, at different temperatures, they are deposited
-at different parts of the crevices through which they
-are emitted together. The best illustration, however, is
-furnished by the changes that occur during the slow cooling
-of igneous rock. When, through one of the fractures from
-time to time made in the solid shell which forms the Earth’s
-crust, a portion of the molten nucleus is extruded; and when
-this is cooled with comparative rapidity, through free radiation
-and contact with cold masses; it forms a substance
-known as trap or basalt—a substance that is uniform in
-texture, though made up of various ingredients. But when,
-not escaping through the superficial strata, such a portion of
-the molten nucleus is slowly cooled, it becomes what we
-know as granite: the mingled particles of quartz, feldspar,
-and mica, being kept for a long time in a fluid and semi-fluid
-state—a state of comparative mobility—undergo those
-<span class='pageno' id='Page_427'>427</span>changes of position which the forces impressed on them by
-their fellow units necessitate. Having time in which to
-generate the requisite motions of the atoms, the differential
-forces arising from mutual polarity, segregate the quartz,
-feldspar, and mica, into crystals. How completely this is dependent
-on the long-continued agitation of the mixed particles,
-and consequent long-continued mobility by small differential
-forces, is proved by the fact that in granite dykes,
-the crystals in the centre of the mass, where the fluidity or
-semi-fluidity continued for a longer time, are much larger
-than those at the sides, where contact with the neighbouring
-rock caused more rapid cooling and solidification.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 126. The actions going on throughout an organism are so
-involved and subtle, that we cannot expect to identify the particular
-forces by which particular integrations are effected.
-Among the few instances admitting of tolerably definite interpretation,
-the best are those in which mechanical pressures
-and tensions are the agencies at work. We shall discover
-several on studying the bony frame of the higher animals.</p>
-
-<p class='c000'>The vertebral column of a man, is subject, as a whole, to
-certain general strains—the weight of the body, together
-with the reactions involved by all considerable muscular
-efforts; and in conformity with this, it has a certain general
-integration. At the same time, being exposed to different
-forces in the course of those lateral bendings which the
-movements necessitate, its parts retain a certain separateness.
-And if we trace up the development of the vertebral column
-from its primitive form of a cartilaginous cord in the lowest
-fishes, we see that, throughout, it maintains an integration
-corresponding to the unity of the incident forces, joined with
-a division into segments corresponding to the variety of
-the incident forces. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Each segment, considered apart,
-exemplifies the truth more simply. A vertebra is not a single
-bone, but consists of a central mass with sundry appendages
-or processes; and in rudimentary types of vertebræ,
-<span class='pageno' id='Page_428'>428</span>those appendages are quite separate from the central mass,
-and, indeed, exist before it makes its appearance. But these
-several independent bones, constituting a primitive spinal
-segment, are subject to a certain aggregate of forces
-which agree more than they differ: as the fulcrum to
-a group of muscles habitually acting together, they perpetually
-undergo certain reactions in common. And accordingly,
-we see that in the course of development they
-gradually coalesce. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Still clearer is the illustration
-furnished by spinal segments that become fused together
-where they are together exposed to some predominant strain.
-The sacrum consists of a group of vertebræ firmly united.
-In the ostrich and its congeners there are from seventeen to
-twenty sacral vertebræ; and besides being confluent with each
-other, these are confluent with the iliac bones, which run on
-each side of them. If now we assume these vertebræ to have
-been originally separate, as they still are in the embryo bird;
-and if we consider the mechanical conditions to which they
-must in such case have been exposed; we shall see that their
-union results in the alleged way. For through these vertebræ
-the entire weight of the body is transferred to the legs: the
-legs support the pelvic arch; the pelvic arch supports the
-sacrum; and to the sacrum is articulated the rest of the
-spine, with all the limbs and organs attached to it. Hence,
-if separate, the sacral vertebræ must be held firmly together
-by strongly-contracted muscles; and must, by implication, be
-prevented from partaking in those lateral movements which
-the other vertebræ undergo—they must be subject to a common
-strain, while they are preserved from strains which
-would affect them differently; and so they fulfil the conditions
-under which integration occurs. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;But the cases
-in which cause and effect are brought into the most obvious
-relation, are supplied by the limbs. The metacarpal bones
-(those which in man support the palm of the hand) are separate
-from each other in the majority of mammalia: the separate
-actions of the toes entailing on them slight amounts of
-<span class='pageno' id='Page_429'>429</span>separate movements. This is not so however in the ox-tribe
-and the horse-tribe. In the ox-tribe, only the middle metacarpals
-(third and fourth) are developed; and these, attaining
-massive proportions, coalesce to form the cannon bone.
-In the horse-tribe, the integration is what we may distinguish
-as indirect: the second and fourth metacarpals are
-present only as rudiments united to the sides of the third,
-while the third is immensely developed; thus forming a
-cannon bone which differs from that of the ox in being a
-single cylinder, instead of two cylinders fused together.
-The metatarsus in these quadrupeds exhibits parallel
-changes. Now each of these metamorphoses occurs where
-the different bones grouped together have no longer any
-different functions, but retain only a common function. The
-feet of oxen and horses are used solely for locomotion—are
-not put like those of unguiculate mammals to purposes
-which involve some relative movements of the metacarpals.
-Thus there directly or indirectly results a single mass of bone
-where the incident force is single. And for the inference
-that these facts have a causal connexion, we find confirmation
-throughout the entire class of birds; in the wings
-and legs of which, like integrations are found under like
-conditions. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;While this sheet is passing through the
-press, a fact illustrating this general truth in a yet more
-remarkable manner, has been mentioned to me by Prof.
-Huxley; who kindly allows me to make use of it while still
-unpublished by him. The <em>Glyptodon</em>, an extinct mammal
-found fossilized in South America, has long been known as a
-large uncouth creature allied to the Armadillo, but having a
-massive dermal armour consisting of polygonal plates closely
-fitted together so as to make a vast box, inclosing the body
-in such way as effectually to prevent it from being bent,
-laterally or vertically, in the slightest degree. This bony
-box, which must have weighed several hundred-weight, was
-supported on the spinous processes of the vertebræ, and on
-the adjacent bones of the pelvic and thoracic arches. And
-<span class='pageno' id='Page_430'>430</span>the significant fact now to be noted, is, that here, where the
-trunk vertebræ were together exposed to the pressure of this
-heavy dermal armour, at the same time that, by its rigidity,
-they were preserved from all relative movements, the entire
-series of them were united into one solid, continuous bone.</p>
-
-<p class='c000'>The formation and maintenance of a species, considered
-as an assemblage of similar organisms, is interpretable in
-an analogous way. We have already seen that in so far as
-the members of a species are subject to different sets of incident
-forces, they are differentiated, or divided into varieties.
-And here it remains to add that in so far as they are subject
-to like sets of incident forces, they are integrated, or reduced
-to, and kept in, the state of a uniform aggregate. For by the
-process of “natural selection,” there is a continual purification
-of each species from those individuals which depart
-from the common type in ways that unfit them for the conditions
-of their existence. Consequently, there is a continual
-leaving behind of those individuals which are in all respects
-fit for the conditions of their existence; and are therefore
-very nearly alike. The circumstances to which any species
-is exposed, being, as we before saw, an involved combination
-of incident forces; and the members of the species having
-mixed with them some that differ more than usual from the
-average structure required for meeting these forces; it results
-that these forces are constantly separating such divergent
-individuals from the rest, and so preserving the uniformity
-of the rest—keeping up its integrity as a species.
-Just as the changing autumn leaves are picked out by the
-wind from among the green ones around them, or just as,
-to use Prof. Huxley’s simile, the smaller fragments pass
-through the sieve while the larger are kept back; so, the
-uniform incidence of external forces affects the members of a
-group of organisms similarly in proportion as they are similar,
-and differently in proportion as they are different; and thus is
-ever segregating the like by parting the unlike from them.
-Whether these separated members are killed off, as mostly
-<span class='pageno' id='Page_431'>431</span>happens, or whether, as otherwise happens, they survive and
-multiply into a distinct variety, in consequence of their
-fitness to certain partially unlike conditions, matters not to
-the argument. The one case conforms to the law, that the
-unlike units of an aggregate are differentiated and integrated
-when uniformly subject to the same incident forces;
-and the other to the converse law, that the like units of an
-aggregate are differentiated and integrated when subject to
-different incident forces. And on consulting Mr. Darwin’s
-remarks on divergence of character, it will be seen that the
-segregations thus caused tend ever to become more definite.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 127. Mental evolution under one of its leading aspects,
-we found to consist in the formation of groups of like objects
-and like relations—a differentiation of the various
-things originally confounded together in one assemblage,
-and an integration of each separate order of things into a
-separate group (§ 113). Here it remains to point out that
-while unlikeness in the incident forces is the cause of such
-differentiations, likeness in the incident forces is the cause of
-such integrations. For what is the process through which
-classifications are established? At first, in common with
-the uninitiated, the botanist recognizes only such conventional
-divisions as those which agriculture has established—distinguishes
-a few vegetables and cereals, and groups the
-rest together into the one miscellaneous aggregate of wild
-plants. How do these wild plants become grouped in his mind
-into orders, genera, and species? Each plant he examines
-yields him a certain complex impression. Every now and
-then he picks up a plant like one before seen; and the recognition
-of it is the production in him of a like connected
-group of sensations, by a like connected group of attributes.
-That is to say, there is produced throughout the nerves concerned,
-a combined set of changes, similar to a combined set
-of changes before produced. Considered analytically, each
-such combined set of changes is a combined set of molecular
-<span class='pageno' id='Page_432'>432</span>modifications wrought in the affected part of the organism.
-On every repetition of the impression, a like combined set of
-molecular modifications is superposed on the previous ones,
-and makes them greater: thus generating an internal idea
-corresponding to these similar external objects. Meanwhile,
-another kind of plant produces in the brain of the botanist
-another set of combined changes or molecular modifications—a
-set which does not agree with and deepen the one we
-have been considering, but disagrees with it; and by repetition
-of such there is generated a different idea answering to
-a different species. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;What now is the nature of this
-process expressed in general terms? On the one hand there
-are the like and unlike things from which severally emanate
-the groups of forces by which we perceive them. On the
-other hand, there are the organs of sense and percipient
-centres, through which, in the course of observation, these
-groups of forces pass. In passing through these organs of
-sense and percipient centres, the like groups of forces are segregated,
-or separated from the unlike groups of forces; and
-each such differentiated and integrated series of groups of
-forces, answering to an external genus or species, constitutes
-a state of consciousness which we call our idea of the genus
-or species. We before saw that as well as a separation of
-mixed matters by the same force, there is a separation of
-mixed forces by the same matter; and here we may further
-see that the unlike forces so separated, work unlike structural
-changes in the aggregate that separates them—structural
-changes each of which thus represents, and is equivalent
-to, the integrated series of motions that has produced it.</p>
-
-<p class='c000'>By a parallel process, the connexions of co-existence and
-sequence among impressions, become differentiated and integrated
-simultaneously with the impressions themselves.
-When two phenomena that have been experienced in a
-given order, are repeated in the same order, those nerves
-which before were affected by the transition are again affected;
-and such molecular modification as they received
-<span class='pageno' id='Page_433'>433</span>from the first motion propagated through them, is increased
-by this second motion along the same route. Each such motion
-works a structural alteration, which, in conformity with
-the general law set forth in Chapter X., involves a diminution
-of the resistance to all such motions that afterwards
-occur. The integration of these successive motions (or more
-strictly, the permanently effective portions of them expended
-in overcoming resistance) thus becomes the cause of, and the
-measure of, the mental connexion between the impressions
-which the phenomena produce. Meanwhile, phenomena that
-are recognized as different from these, being phenomena that
-therefore affect different nervous elements, will have their
-connexions severally represented by motions along other
-routes; and along each of these other routes, the nervous discharges
-will severally take place with a readiness proportionate
-to the frequency with which experience repeats the connexion
-of phenomena. The classification of relations must
-hence go on <i><span lang="la" xml:lang="la">pari passu</span></i> with the classification of the related
-things. In common with the mixed sensations received
-from the external world, the mixed relations it presents,
-cannot be impressed on the organism without more or less
-segregation of them resulting. And through this continuous
-differentiation and integration of changes or motions,
-which constitutes nervous function, there is gradually
-wrought that differentiation and integration of matter,
-which constitutes nervous structure.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 128. In social evolution, the collecting together of the
-like and the separation of the unlike, by incident forces, is
-primarily displayed in the same manner as we saw it to be
-among groups of inferior creatures. The human races tend
-to differentiate and integrate, as do races of other living
-forms. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Of the forces which effect and maintain the
-segregations of mankind, may first be named those external
-ones which we class as physical conditions. The climate and
-food that are favourable to an indigenous people, are more or
-<span class='pageno' id='Page_434'>434</span>less detrimental to a people of different bodily constitution,
-coming from a remote part of the Earth. In tropical regions
-the northern races cannot permanently exist: if not
-killed off in the first generation, they are so in the second;
-and, as in India, can maintain their footing only by the
-artificial process of continuous immigration and emigration.
-That is to say, the external forces acting equally on the inhabitants
-of a given locality, tend to expel all who are not
-of a certain type; and so to keep up the integration of those
-who are of that type. Though elsewhere, as among European
-nations, we see a certain amount of permanent intermixture,
-otherwise brought about, we still see that this takes
-place between races of not very different types, that are
-naturalized to not very different conditions. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The
-other forces conspiring to produce these national integrations,
-are those mental ones which show themselves in the
-affinities of men for others like themselves. Emigrants
-usually desire to get back among their own people; and
-where their desire does not take effect, it is only because the
-restraining ties are too great. Units of one society who
-are obliged to reside in another, very generally form
-colonies in the midst of that other—small societies of their
-own. Races which have been artificially severed, show
-strong tendencies to re-unite. Now though these integrations
-that result from the mutual affinities of kindred men,
-do not seem interpretable as illustrations of the general
-principle above enunciated, they really are thus interpretable.
-When treating of the direction of motion (§ 91),
-it was shown that the actions performed by men for the
-satisfaction of their wants, were always motions along lines
-of least resistance. The feelings characterizing a member
-of a given race, are feelings which get complete satisfaction
-only among other members of that race—a satisfaction
-partly derived from sympathy with those having like feelings,
-but mainly derived from the adapted social conditions
-which grow up where such feelings prevail. When, therefore,
-<span class='pageno' id='Page_435'>435</span>a citizen of any nation is, as we see, attracted towards
-others of his nation, the rationale is, that certain agencies
-which we call desires, move him in the direction of least
-resistance. Human motions, like all other motions, being
-determined by the distribution of forces, it follows that
-such integrations of races as are not produced by incident
-external forces, are produced by forces which the units of
-the races exercise on each other.</p>
-
-<p class='c000'>During the development of each society, we see analogous
-segregations caused in analogous ways. A few of them result
-from minor natural affinities; but those most important
-ones which constitute political and industrial organization,
-result from the union of men in whom similarities have been
-produced by education—using education in its widest sense,
-as comprehending all processes by which citizens are moulded
-to special functions. Men brought up to bodily labour,
-are men who have had wrought in them a certain likeness—a
-likeness which, in respect of their powers of action, obscures
-and subordinates their natural differences. Those trained to
-brain-work, have acquired a certain other community of
-character which makes them, as social units, more like each
-other than like those trained to manual occupations. And
-there arise class-integrations answering to these superinduced
-likenesses. Much more definite integrations take
-place among the much more definitely assimilated members
-of any class who are brought up to the same calling. Even
-where the necessities of their work forbid concentration in one
-locality, as among artizans happens with masons and brick-layers,
-and among traders happens with the retail distributors,
-and among professionals happens with the medical
-men; there are not wanting Operative Builders Unions, and
-Grocers Societies, and Medical Associations, to show that
-these artificially-assimilated citizens become integrated as
-much as the conditions permit. And where, as among the
-manufacturing classes, the functions discharged do not require
-the dispersion of the citizens thus artificially assimilated,
-<span class='pageno' id='Page_436'>436</span>there is a progressive aggregation of them in special
-localities; and a consequent increase in the definiteness of
-the industrial divisions. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;If now we seek the causes
-of these integrations, considered as results of force and motion,
-we find ourselves brought to the same general principle
-as before. This likeness generated in any class or subclass
-by training, is an aptitude acquired by its members
-for satisfying their wants in like ways. That is, the
-occupation to which each man has been brought up, has become
-to him, in common with those similarly brought up, a
-line of least resistance. Hence under that pressure which
-determines all men to activity, these similarly-modified
-social units are similarly affected, and tend to take similar
-courses. If then there be any locality which, either by its
-physical peculiarities or by peculiarities wrought on it
-during social evolution, is rendered a place where a certain
-kind of industrial action meets with less resistance than elsewhere;
-it follows from the law of direction of motion that
-those social units who have been moulded to this kind of
-industrial action, will move towards this place, or become
-integrated there. If, for instance, the proximity of coal and
-iron mines to a navigable river, gives to Glasgow a certain
-advantage in the building of iron ships—if the total labour
-required to produce the same vessel, and get its equivalent
-in food and clothing, is less there than elsewhere; a concentration
-of iron-ship builders is produced at Glasgow:
-either by keeping there the population born to iron-ship
-building; or by immigration of those elsewhere engaged in
-it; or by both—a concentration that would be still more
-marked did not other districts offer counter-balancing facilities.
-The principle equally holds where the occupation is
-mercantile instead of manufacturing. Stock-brokers cluster
-together in the city, because the amount of effort to be
-severally gone through by them in discharging their functions,
-and obtaining their profits, is less there than in other
-localities. A place of exchange having once been established,
-becomes a place where the resistance to be overcome
-<span class='pageno' id='Page_437'>437</span>by each is less than elsewhere; and the pursuit of the course
-of least resistance by each, involves their aggregation around
-this place.</p>
-
-<p class='c000'>Of course, with units so complicated as those which constitute
-a society, and with forces so involved as those which
-move them, the resulting differentiations and integrations
-must be far more entangled, or far less definite, than those we
-have hitherto considered. But though there may be pointed
-out many anomalies which at first sight seem inconsistent
-with the alleged law, a closer study shows that they are but
-subtler illustrations of it. For men’s likenesses being of
-various kinds, lead to various order of integration. There
-are likenesses of disposition, likenesses of taste, likenesses
-produced by intellectual culture, likenesses that result from
-class-training, likenesses of political feeling; and it needs
-but to glance round at the caste-divisions, the associations
-for philanthropic, scientific, and artistic purposes, the religious
-parties and social cliques; to see that some species of
-likeness among the component members of each body
-determines their union. Now these different integrations,
-by traversing each other, and often by their indirect antagonism,
-more or less obscure each other; and prevent any one
-kind of integration from becoming complete. Hence the
-anomalies referred to. But if this cause of incompleteness
-be duly borne in mind, social segregations will be seen to
-conform entirely to the same principle as all other segregations.
-Analysis will show that either by external incident
-forces, or by what we may in a sense regard as mutual
-polarity, there are ever being produced in society integrations
-of those units which have either a natural likeness or a
-likeness generated by training.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 129. Can the general truth thus variously illustrated be
-deduced from the persistence of force, in common with foregoing
-ones? Probably the exposition at the beginning of
-the chapter will have led most readers to conclude that it
-can be so deduced.</p>
-
-<p class='c000'><span class='pageno' id='Page_438'>438</span>The abstract propositions involved are these:—First, that
-like units, subject to a uniform force capable of producing
-motion in them, will be moved to like degrees in the same
-direction. Second, that like units if exposed to unlike forces
-capable of producing motion in them, will be differently
-moved—moved either in different directions or to different
-degrees in the same direction. Third, that unlike units if
-acted on by a uniform force capable of producing motion in
-them, will be differently moved—moved either in different
-directions or to different degrees in the same direction.
-Fourth, that the incident forces themselves must be affected
-in analogous ways: like forces falling on like units must be
-similarly modified by the conflict; unlike forces falling on
-like units must be dissimilarly modified; and like forces falling
-on unlike units must be dissimilarly modified. These
-propositions admit of reduction to a still more abstract form.
-They all of them amount to this:—that in the actions and
-reactions of force and matter, an unlikeness in either of
-the factors necessitates an unlikeness in the effects; and that
-in the absence of unlikeness in either of the factors the
-effects must be alike.</p>
-
-<p class='c000'>When thus generalized, the immediate dependence of these
-propositions on the persistence of force, becomes obvious.
-Any two forces that are not alike, are forces which differ
-either in their amounts or directions or both; and by what
-mathematicians call the resolution of forces, it may be proved
-that this difference is constituted by the presence in the one
-of some force not present in the other. Similarly, any two
-units or portions of matter which are unlike in size, weight,
-form, or other attribute, can be known by us as unlike only
-through some unlikeness in the forces they impress on our
-consciousness; and hence this unlikeness also, is constituted by
-the presence in the one of some force or forces not present in
-the other. Such being the common nature of these unlikenesses,
-what is the inevitable corollary? Any unlikeness in
-the incident forces, where the things acted on are alike, must
-generate a difference between the effects; since otherwise,
-<span class='pageno' id='Page_439'>439</span>the differential force produces no effect, and force is not persistent.
-Any unlikeness in the things acted on, where the
-incident forces are alike, must generate a difference between
-the effects; since otherwise, the differential force whereby
-these things are made unlike, produces no effect, and force is
-not persistent. While, conversely, if the forces acting and
-the things acted on, are alike, the effects must be alike;
-since otherwise, a differential effect can be produced without
-a differential cause, and force is not persistent.</p>
-
-<p class='c000'>Thus these general truths being necessary implications of
-the persistence of force, all the re-distributions above traced
-out as characterizing Evolution in its various phases, are also
-implications of the persistence of force. Such portions of
-the permanently effective forces acting on any aggregate, as
-produce sensible motions in its parts, cannot but work the
-segregations which we see take place. If of the mixed units
-making up such aggregate, those of the same kind have like
-motions impressed on them by a uniform force, while units of
-another kind are moved by this uniform force in ways more
-or less unlike the ways in which those of the first kind are
-moved, the two kinds must separate and integrate. If the
-units are alike and the forces unlike, a division of the differently
-affected units is equally necessitated. Thus there inevitably
-arises the demarcated grouping which we everywhere
-see. By virtue of this segregation that grows ever more
-decided while there remains any possibility of increasing it,
-the change from uniformity to multiformity is accompanied
-by a change from indistinctness in the relations of parts to
-distinctness in the relations of parts. As we before saw that
-the transformation of the homogeneous into the heterogeneous
-is inferrable from that ultimate truth which transcends
-proof; so we here see, that from this same truth is inferrable
-the transformation of an indefinite homogeneity into a definite
-heterogeneity.</p>
-
-<div>
- <span class='pageno' id='Page_440'>440</span>
- <h3 class='c001'>CHAPTER XVI.<br /> <span class='large'>EQUILIBRATION.</span></h3>
-</div>
-
-<p class='c006'>§ 130. And now towards what do these changes tend?
-Will they go on for ever? or will there be an end to them?
-Can things increase in heterogeneity through all future time?
-or must there be a degree which the differentiation and integration
-of Matter and Motion cannot pass? Is it possible
-for this universal metamorphosis to proceed in the same general
-course indefinitely? or does it work towards some ultimate
-state, admitting no further modification of like kind?
-The last of these alternative conclusions is that to which we
-are inevitably driven. Whether we watch concrete processes,
-or whether we consider the question in the abstract, we are
-alike taught that Evolution has an impassable limit.</p>
-
-<p class='c000'>The re-distributions of matter that go on around us, are
-ever being brought to conclusions by the dissipation of the
-motions which effect them. The rolling stone parts with
-portions of its momentum to the things it strikes, and finally
-comes to rest; as do also, in like manner, the various things
-it has struck. Descending from the clouds and trickling
-over the Earth’s surface till it gathers into brooks and rivers,
-water, still running towards a lower level, is at last arrested
-by the resistance of other water that has reached the lowest
-level. In the lake or sea thus formed, every agitation raised
-by a wind or the immersion of a solid body, propagates itself
-around in waves that diminish as they widen, and gradually
-<span class='pageno' id='Page_441'>441</span>become lost to observation in motions communicated to the
-atmosphere and the matter on the shores. The impulse
-given by a player to the harp-string, is transformed through
-its vibrations into aerial pulses; and these, spreading on all
-sides, and weakening as they spread, soon cease to be perceptible;
-and finally die away in generating thermal undulations
-that radiate into space. Equally in the cinder that falls
-out of the fire, and in the vast masses of molten lava ejected
-by a volcano, we see that the molecular agitation known to
-us as heat, disperses itself by radiation; so that however
-great its amount, it inevitably sinks at last to the same degree
-as that existing in surrounding bodies. And if the actions
-observed be electrical or chemical, we still find that they work
-themselves out in producing sensible or insensible movements,
-that are dissipated as before; until quiescence is eventually
-reached. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The proximate rationale of the process
-exhibited under these several forms, lies in the fact
-dwelt on when treating of the Multiplication of Effects, that
-motions are ever being decomposed into divergent motions,
-and these into re-divergent motions. The rolling stone
-sends off the stones it hits in directions differing more or less
-from its own; and they do the like with the things they hit.
-Move water or air, and the movement is quickly resolved into
-radiating movements. The heat produced by pressure in a
-given direction, diffuses itself by undulations in all directions;
-and so do the light and electricity similarly generated.
-That is to say, these motions undergo division and subdivision;
-and by continuance of this process without limit, they
-are, though never lost, gradually reduced to insensible motions.</p>
-
-<p class='c000'>In all cases then, there is a progress toward equilibration.
-That universal co-existence of antagonist forces which, as we
-before saw, necessitates the universality of rhythm, and
-which, as we before saw, necessitates the decomposition of
-every force into divergent forces, at the same time necessitates
-the ultimate establishment of a balance. Every motion
-<span class='pageno' id='Page_442'>442</span>being motion under resistance, is continually suffering deductions;
-and these unceasing deductions finally result in the
-cessation of the motion.</p>
-
-<p class='c000'>The general truth thus illustrated under its simplest
-aspect, we must now look at under those more complex
-aspects it usually presents throughout Nature. In nearly all
-cases, the motion of an aggregate is compound; and the equilibration
-of each of its components, being carried on independently,
-does not affect the rest. The ship’s bell that has
-ceased to vibrate, still continues those vertical and lateral
-oscillations caused by the ocean-swell. The water of the
-smooth stream on whose surface have died away the undulations
-caused by the rising fish, moves as fast as before
-onward to the sea. The arrested bullet travels with
-undiminished speed round the Earth’s axis. And were the
-rotation of the Earth destroyed, there would not be implied
-any diminution of the Earth’s movement with respect to the
-Sun and other external bodies. So that in every case, what
-we regard as equilibration is a disappearance of some one or
-more of the many movements which a body possesses, while
-its other movements continue as before. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;That this
-process may be duly realized and the state of things towards
-which it tends fully understood, it will be well here to cite a
-case in which we may watch this successive equilibration of
-combined movements more completely than we can do in
-those above instanced. Our end will best be served, not by
-the most imposing, but by the most familiar example. Let
-us take that of the spinning top. When the string which
-has been wrapped round a top’s axis is violently drawn off,
-and the top falls on to the table, it usually happens that besides
-the rapid rotation, two other movements are given to it.
-A slight horizontal momentum, unavoidably impressed on it
-when leaving the handle, carries it away bodily from the
-place on which it drops; and in consequence of its axis being
-more or less inclined, it falls into a certain oscillation,
-described by the expressive though inelegant word—“wabbling.”
-<span class='pageno' id='Page_443'>443</span>These two subordinate motions, variable in
-their proportions to each other and to the chief motion, are
-commonly soon brought to a close by separate processes of
-equilibration. The momentum which carries the top bodily
-along the table, resisted somewhat by the air, but mainly by
-the irregularities of the surface, shortly disappears; and the
-top thereafter continues to spin on one spot. Meanwhile, in
-consequence of that opposition which the axial momentum of
-a rotating body makes to any change in the plane of rotation,
-(so beautifully exhibited by the gyroscope,) the “wabbling”
-diminishes; and like the other is quickly ended. These
-minor motions having been dissipated, the rotatory motion,
-interfered with only by atmospheric resistance and the friction
-of the pivot, continues some time with such uniformity
-that the top appears stationary: there being thus temporarily
-established a condition which the French mathematicians
-have termed <i><span lang="fr" xml:lang="fr">equilibrium mobile</span></i>. It is true that when the
-axial velocity sinks below a certain point, new motions commence,
-and increase till the top falls; but these are merely
-incidental to a case in which the centre of gravity is above
-the point of support. Were the top, having an axis of
-steel, to be suspended from a surface adequately magnetized,
-all the phenomena described would be displayed, and the
-moving equilibrium having been once arrived at, would continue
-until the top became motionless, without any further
-change of position. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Now the facts which it behoves
-us here to observe, are these. First, that the various motions
-which an aggregate possesses are separately equilibrated:
-those which are smallest, or which meet with the greatest
-resistance, or both, disappearing first; and leaving at last,
-that which is greatest, or meets with least resistance, or both.
-Second, that when the aggregate has a movement of its parts
-with respect to each other, which encounters but little external
-resistance, there is apt to be established an <i><span lang="fr" xml:lang="fr">equilibrium
-mobile</span></i>. Third, that this moving equilibrium eventually
-lapses into complete equilibrium.</p>
-
-<p class='c000'><span class='pageno' id='Page_444'>444</span>Fully to comprehend the process of equilibration, is not
-easy; since we have simultaneously to contemplate various
-phases of it. The best course will be to glance separately at
-what we may conveniently regard as its four different
-orders. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The first order includes the comparatively
-simple motions, as those of projectiles, which are not prolonged
-enough to exhibit their rhythmical character; but
-which, being quickly divided and subdivided into motions
-communicated to other portions of matter, are presently dissipated
-in the rhythm of ethereal undulations. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;In
-the second order, comprehending the various kinds of vibration
-or oscillation as usually witnessed, the motion is used
-up in generating a tension which, having become equal to it or
-momentarily equilibrated with it, thereupon produces a motion
-in the opposite direction, that is subsequently equilibrated
-in like manner: thus causing a visible rhythm, that
-is, however, soon lost in invisible rhythms. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The third
-order of equilibration, not hitherto noticed, obtains in those
-aggregates which continually receive as much motion as they
-expend. The steam engine (and especially that kind which
-feeds its own furnace and boiler) supplies an example. Here
-the force from moment to moment dissipated in overcoming
-the resistance of the machinery driven, is from moment to
-moment replaced from the fuel; and the balance of the
-two is maintained by a raising or lowering of the expenditure
-according to the variation of the supply: each increase or
-decrease in the quantity of steam, resulting in a rise or fall
-of the engine’s movement, such as brings it to a balance with
-the increased or decreased resistance. This, which we may
-fitly call the <em>dependent</em> moving equilibrium, should be
-specially noted; since it is one that we shall commonly meet
-with throughout various phases of Evolution. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The
-equilibration to be distinguished as of the fourth order, is the
-<em>independent</em> or perfect moving equilibrium. This we see
-illustrated in the rhythmical motions of the Solar System;
-which, being resisted only by a medium of inappreciable
-<span class='pageno' id='Page_445'>445</span>density, undergo no sensible diminution in such periods of
-time as we can measure.</p>
-
-<p class='c000'>All these kinds of equilibration may, however, from the
-highest point of view, be regarded as different modes of one
-kind. For in every case the balance arrived at is relative,
-and not absolute—is a cessation of the motion of some particular
-body in relation to a certain point or points, involving
-neither the disappearance of the relative motion lost,
-which is simply transformed into other motions, nor a diminution
-of the body’s motions with respect to other points.
-Thus understanding equilibration, it manifestly includes that
-<i><span lang="fr" xml:lang="fr">equilibrium mobile</span></i>, which at first sight seems of another
-nature. For any system of bodies exhibiting, like those of
-the Solar System, a combination of balanced rhythms, has
-this peculiarity;—that though the constituents of the system
-have relative movements, the system as a whole has no
-movement. The centre of gravity of the entire group remains
-fixed. Whatever quantity of motion any member
-of it has in any direction, is from moment to moment
-counter-balanced by an equivalent motion in some other
-part of the group in an opposite direction; and so the
-aggregate matter of the group is in a state of rest. Whence
-it follows that the arrival at a state of moving equilibrium,
-is the disappearance of some movement which the aggregate
-had in relation to external things, and a continuance
-of those movements only which the different parts
-of the aggregate have in relation to each other. Thus
-generalizing the process, it becomes clear that all forms of
-equilibration are intrinsically the same; since in every
-aggregate, it is the centre of gravity only that loses its
-motion: the constituents always retaining some motion with
-respect to each other—the motion of molecules if none else.</p>
-
-<p class='c000'>Those readers who happen to bear in mind a proposition
-concerning the functional characteristics of Evolution, which
-was set forth in Chapter XII, will probably regard it as
-wholly at variance with that set forth in this Chapter. It
-<span class='pageno' id='Page_446'>446</span>was there alleged that throughout Evolution, integration of
-matter is accompanied by integration of such motion as
-the matter previously had; and that thus there is a transformation
-of diffused motion into aggregated motion, parallel
-to the transformation of diffused matter into aggregated
-matter. Here however, it is asserted that every aggregate
-motion is constantly undergoing diffusion—every integrated
-motion undergoing perpetual disintegration. And so the
-motion of masses, which before was said gradually to arise
-out of molecular motion, is here said to be gradually lost in
-molecular motion. Doubtless these statements, if severally
-accepted without qualification, are contradictory. Neither
-of them, however, expresses the whole truth. Each needs the
-other as its indispensable complement. It is quite true, as
-before alleged, that there goes on an integration of motion
-corresponding to the integration of matter; and that this
-essential characteristic of Evolution, functionally considered,
-is clearly displayed in proportion as the Evolution is
-active. But the disintegration of motion, which, as we
-before saw, constitutes Dissolution, functionally considered,
-is all along going on; and though at first it forms but
-a small deduction from the change constituting Evolution,
-it gradually becomes equal to it, and eventually exceeding
-it, entails reverse changes. The aggregation of matter
-never being complete, but leaving behind less aggregated
-or unaggregated matter, in the shape of liquid, aeriform,
-or ethereal media; it results that from the beginning, the
-integrated motion of integrated masses, is ever being obstructed
-by these less integrated or unintegrated media. So
-that though while the integration of matter is rapidly going
-on, there is an increase of integrated motion, spite of the
-deductions thus continually made from it, there comes a time
-when the integration of matter and consequently of motion,
-ceases to increase, or increases so slowly that the deductions
-counterbalance it; and thenceforth these begin to decrease
-it, and, by its perpetual diffusion, to bring about a relative
-<span class='pageno' id='Page_447'>447</span>equilibration. From the beginning, the process of Evolution
-is antagonized by a process of Dissolution; and while the
-first for a long time predominates, the last finally arrests
-and reverses it.</p>
-
-<p class='c000'>Returning from this parenthetical explanation, we must
-now especially note two leading truths brought out by the
-foregoing exposition: the one concerning the ultimate, or
-rather the penultimate, state of motion which the processes described
-tend to bring about; the other concerning the concomitant
-distribution of matter. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;This penultimate state
-of motion is the moving equilibrium; which, as we have seen,
-tends to arise in an aggregate having compound motions, as a
-transitional state on the way towards complete equilibrium.
-Throughout Evolution of all kinds, there is a continual approximation
-to, and more or less complete maintenance of, this
-moving equilibrium. As in the Solar System there has been
-established an independent moving equilibrium—an equilibrium
-such that the relative motions of the constituent parts
-are continually so counter-balanced by opposite motions,
-that the mean state of the whole aggregate never varies; so
-is it, though in a less distinct manner, with each form of dependent
-moving equilibrium. The state of things exhibited
-in the cycles of terrestrial changes, in the balanced functions
-of organic bodies that have reached their adult forms, and in
-the acting and re-acting processes of fully-developed societies,
-is similarly one characterized by compensating oscillations.
-The involved combination of rhythms seen in each
-of these cases, has an average condition which remains practically
-constant during the deviations ever taking place on
-opposite sides of it. And the fact which we have here particularly
-to observe, is, that as a corollary from the general
-law of equilibration above set forth, the evolution of every
-aggregate must go on until this <i><span lang="fr" xml:lang="fr">equilibrium mobile</span></i> is established;
-since, as we have seen, an excess of force which
-the aggregate possesses in any direction, must eventually
-be expended in overcoming resistances to change in that
-<span class='pageno' id='Page_448'>448</span>direction: leaving behind only those movements which
-compensate each other, and so form a moving equilibrium.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Respecting the structural state simultaneously
-reached, it must obviously be one presenting an arrangement
-of forces that counterbalance all the forces to
-which the aggregate is subject. So long as there remains a
-residual force in any direction—be it excess of a force exercised
-by the aggregate on its environment, or of a force
-exercised by its environment on the aggregate, equilibrium
-does not exist; and therefore the re-distribution of matter
-must continue. Whence it follows that the limit of heterogeneity
-towards which every aggregate progresses, is the
-formation of as many specializations and combinations of
-parts, as there are specialized and combined forces to be met.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 131. Those successively changed forms which, if the
-nebular hypothesis be granted, must have arisen during
-the evolution of the Solar System, were so many transitional
-kinds of moving equilibrium; severally giving place to more
-permanent kinds on the way towards complete equilibration.
-Thus the assumption of an oblate spheroidal figure by condensing
-nebulous matter, was the assumption of a temporary
-and partial moving equilibrium among the component parts—a
-moving equilibrium that must have slowly grown
-more settled, as local conflicting movements were dissipated.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;In the formation and detachment of the
-nebulous rings, which, according to this hypothesis, from time
-to time took place, we have instances of progressive equilibration
-ending in the establishment of a complete moving
-equilibrium. For the genesis of each such ring, implies a
-perfect balancing of that aggregative force which the
-whole spheroid exercises on its equatorial portion, by that
-centrifugal force which the equatorial portion has acquired
-during previous concentration: so long as these two forces
-are not equal, the equatorial portion follows the contracting
-mass; but as soon as the second force has increased up to an
-<span class='pageno' id='Page_449'>449</span>equality with the first, the equatorial portion can follow no
-further, and remains behind. While, however, the resulting
-ring, regarded as a whole connected by forces with external
-wholes, has reached a state of moving equilibrium; its parts
-are not balanced with respect to each other. As we
-before saw (§ 110) the probabilities against the maintenance
-of an annular form by nebulous matter, are immense:
-from the instability of the homogeneous, it is inferrable that
-nebulous matter so distributed must break up into portions;
-and eventually concentrate into a single mass. That is to
-say, the ring must progress towards a moving equilibrium
-of a more complete kind, during the dissipation of that
-motion which maintained its particles in a diffused form:
-leaving at length a planetary body, attended perhaps by a
-group of minor bodies, severally having residuary relative
-motions that are no longer resisted by sensible media; and
-there is thus constituted an <i><span lang="fr" xml:lang="fr">equilibrium mobile</span></i> that is all but
-absolutely perfect.<a id='r18' /><a href='#f18' class='c011'><sup>[18]</sup></a></p>
-
-<p class='c000'>Hypothesis aside, the principle of equilibration is still
-perpetually illustrated in those minor changes of state which
-the Solar System is undergoing. Each planet, satellite,
-and comet, exhibits to us at its aphelion a momentary equilibrium
-<span class='pageno' id='Page_450'>450</span>between that force which urges it further away from
-its primary, and that force which retards its retreat; since
-the retreat goes on until the last of these forces exactly
-counterpoises the first. In like manner at perihelion a converse
-equilibrium is momentarily established. The variation
-of each orbit in size, in eccentricity, and in the position
-of its plane, has similarly a limit at which the forces producing
-change in the one direction, are equalled by those
-antagonizing it; and an opposite limit at which an opposite
-arrest takes place. Meanwhile, each of these simple perturbations,
-as well as each of the complex ones resulting from
-their combination, exhibits, besides the temporary equilibration
-at each of its extremes, a certain general equilibration
-of compensating deviations on either side of a mean
-state. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;That the moving equilibrium thus constituted,
-tends, in the course of indefinite time, to lapse into a complete
-equilibrium, by the gradual decrease of planetary motions
-and eventually integration of all the separate masses composing
-the Solar System, is a belief suggested by certain
-observed cometary retardations, and entertained by some of
-high authority. The received opinion that the appreciable
-diminution in the period of Encke’s comet, implies a loss of momentum
-caused by resistance of the ethereal medium, commits
-astronomers who hold it, to the conclusion that this same resistance
-must cause a loss of planetary motions—a loss which,
-infinitesimal though it may be in such periods as we can
-measure, will, if indefinitely continued, bring these motions
-to a close. Even should there be, as Sir John Herschel suggests,
-a rotation of the ethereal medium in the same direction
-with the planets, this arrest, though immensely postponed,
-would not be absolutely prevented. Such an eventuality,
-however, must in any case be so inconceivably remote as
-to have no other than a speculative interest for us. It is
-referred to here, simply as illustrating the still-continued
-tendency towards complete equilibrium, through the still-continued
-<span class='pageno' id='Page_451'>451</span>dissipation of sensible motion, or transformation of
-it into insensible motion.</p>
-
-<p class='c000'>But there is another species of equilibration going on in
-the Solar System, with which we are more nearly concerned—the
-equilibration of that molecular motion known as heat.
-The tacit assumption hitherto current, that the Sun can continue
-to give off an undiminished amount of light and heat
-through all future time, is fast being abandoned. Involving
-as it does, under a disguise, the conception of power produced
-out of nothing, it is of the same order as the belief that
-misleads perpetual-motion schemers. The spreading recognition
-of the truth that force is persistent, and that consequently
-whatever force is manifested under one shape must
-previously have existed under another shape, is carrying with
-it a recognition of the truth that the force known to us in
-solar radiations, is the changed form of some other force of
-which the Sun is the seat; and that by the gradual dissipation
-of these radiations into space, this other force is being
-slowly exhausted. The aggregative force by which the Sun’s
-substance is drawn to his centre of gravity, is the only one
-which established physical laws warrant us in suspecting to be
-the correlate of the forces thus emanating from him: the only
-source of a known kind that can be assigned for the insensible
-motions constituting solar light and heat, is the sensible motion
-which disappears during the progressing concentration of the
-Sun’s substance. We before saw it to be a corollary from the
-nebular hypothesis, that there is such a progressing concentration
-of the Sun’s substance. And here remains to be added the
-further corollary, that just as in the case of the smaller members
-of the Solar System, the heat generated by concentration,
-long ago in great part radiated into space, has left only a central
-residue that now escapes but slowly; so in the case of that immensely
-larger mass forming the Sun, the immensely greater
-quantity of heat generated and still in process of rapid diffusion,
-must, as the concentration approaches its limit, diminish in
-<span class='pageno' id='Page_452'>452</span>amount, and eventually leave only an inappreciable internal
-remnant. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;With or without the accompaniment of
-that hypothesis of nebular condensation, whence, as we see,
-it naturally follows, the doctrine that the Sun is gradually
-losing his heat, has now gained considerable currency; and
-calculations have been made, both respecting the amount of
-heat and light already radiated, as compared with the amount
-that remains, and respecting the period during which active
-radiation is likely to continue. Prof. Helmholtz estimates,
-that since the time when, according to the nebular hypothesis,
-the matter composing the Solar System extended to the orbit
-of Neptune, there has been evolved by the arrest of sensible
-motion, an amount of heat 454 times as great as that which
-the Sun still has to give out. He also makes an approximate
-estimate of the rate at which this remaining <span class='overunder'>1<br /><span class='ov'>454</span></span>th is being
-diffused: showing that a diminution of the Sun’s diameter to
-the extent of <span class='overunder'>1<br /><span class='ov'>10,000</span></span>, would produce heat, at the present rate,
-for more than 2000 years; or in other words, that a contraction
-of <span class='overunder'>1<br /><span class='ov'>20,000,000</span></span> of his diameter, suffices to generate the
-amount of light and heat annually emitted; and that thus, at
-the present rate of expenditure, the Sun’s diameter will diminish
-by something like <span class='overunder'>1<br /><span class='ov'>20</span></span> in the lapse of the next million
-years.<a id='r19' /><a href='#f19' class='c011'><sup>[19]</sup></a> Of course these conclusions are not to be considered
-as more than rude approximations to the truth. Until quite
-recently, we have been totally ignorant of the Sun’s chemical
-composition; and even now have obtained but a superficial
-knowledge of it. We know nothing of his internal structure;
-and it is quite possible (probable, I believe,) that the
-assumptions respecting central density, made in the foregoing
-estimates, are wrong. But no uncertainty in the data on
-which these calculations proceed, and no consequent error in
-the inferred rate at which the Sun is expending his reserve
-of force, militates against the general proposition that this
-<span class='pageno' id='Page_453'>453</span>reserve of force <em>is</em> being expended; and must in time be exhausted.
-Though the residue of undiffused motion in the Sun,
-may be much greater than is above concluded; though the
-rate of radiation cannot, as assumed, continue at a uniform
-rate, but must eventually go on with slowly-decreasing
-rapidity; and though the period at which the Sun will cease
-to afford us adequate light and heat, is very possibly far more
-distant than above implied; yet such a period must some
-time be reached, and this is all which it here concerns us
-to observe.</p>
-
-<p class='c000'>Thus while the Solar System, if evolved from diffused matter,
-has illustrated the law of equilibration in the establishment
-of a complete moving equilibrium; and while, as at present constituted,
-it illustrates the law of equilibration in the balancing
-of all its movements; it also illustrates this law in the processes
-which astronomers and physicists infer are still going
-on. That motion of masses produced during Evolution, is
-being slowly re-diffused in molecular motion of the ethereal
-medium; both through the progressive integration of each
-mass, and the resistance to its motion through space. Infinitely
-remote as may be the state when all the motions of masses shall
-be transformed into molecular motion, and all the molecular
-motion equilibrated; yet such a state of complete integration
-and complete equilibration, is that towards which the changes
-now going on throughout the Solar System inevitably tend.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 132. A spherical figure is the one which can alone equilibrate
-the forces of mutually-gravitating atoms. If the aggregate
-of such atoms has a rotatory motion, the form of
-equilibrium becomes a spheroid of greater or less oblateness,
-according to the rate of rotation; and it has been ascertained
-that the Earth is an oblate spheroid, diverging just as much
-from sphericity as is requisite to counterbalance the centrifugal
-force consequent on its velocity round its axis. That is to
-say, during the evolution of the Earth, there has been reached
-a complete equilibrium of those forces which affect its general
-<span class='pageno' id='Page_454'>454</span>outline. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The only other process of equilibration
-which the Earth as a whole can exhibit, is the loss of its axial
-motion; and that any such loss is going on, we have no
-direct evidence. It has been contended, however, by Prof.
-Helmholtz, that inappreciable as may be its effect within
-known periods of time, the friction of the tidal wave must
-be slowly diminishing the Earth’s rotatory motion, and must
-eventually destroy it. Now though it seems an oversight
-to say that the Earth’s rotation can thus be destroyed, since
-the extreme effect, to be reached only in infinite time by such
-a process, would be an extension of the Earth’s day to the
-length of a lunation; yet it seems clear that this friction
-of the tidal wave is a real cause of decreasing rotation. Slow
-as its action is, we must recognize it as exemplifying, under
-another form, the universal progress towards equilibrium.</p>
-
-<p class='c000'>It is needless to point out, in detail, how those movements
-which the Sun’s rays generate in the air and water on the
-Earth’s surface, and through them in the Earth’s solid substance,<a id='r20' /><a href='#f20' class='c011'><sup>[20]</sup></a>
-one and all teach the same general truth. Evidently
-the winds and waves and streams, as well as the denudations and
-depositions they effect, perpetually illustrate on a grand scale,
-and in endless modes, that gradual dissipation of motions
-described in the first section; and the consequent tendency
-towards a balanced distribution of forces. Each of these
-sensible motions, produced directly or indirectly by integration
-of those insensible motions communicated from the Sun,
-becomes, as we have seen, divided and subdivided into
-motions less and less sensible; until it is finally reduced to
-insensible motions, and radiated from the Earth in the shape
-of thermal undulations. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;In their totality, these complex
-<span class='pageno' id='Page_455'>455</span>movements of aerial, liquid, and solid matter on the
-Earth’s crust, constitute a dependent moving equilibrium. As
-we before saw, there is traceable throughout them an involved
-combination of rhythms. The unceasing circulation
-of water from the ocean to the land, and from the land
-back to the ocean, is a type of these various compensating
-actions; which, in the midst of all the irregularities produced
-by their mutual interferences, maintain an average. And in
-this, as in other equilibrations of the third order, we see that
-the power from moment to moment in course of dissipation,
-is from moment to moment renewed from without: the rises
-and falls in the supply, being balanced by rises and falls in the
-expenditure; as witness the correspondence between the magnetic
-variations and the cycle of the solar spots. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;But
-the fact it chiefly concerns us to observe, is, that this process
-must go on bringing things ever nearer to complete rest.
-These mechanical movements, meteorologic and geologic,
-which are continually being equilibrated, both temporarily
-by counter-movements and permanently by the dissipation of
-such movements and counter-movements, will slowly diminish
-as the quantity of force received from the Sun diminishes.
-As the insensible motions propagated to us from the centre
-of our system become feebler, the sensible motions here produced
-by them must decrease; and at that remote period
-when the solar heat has ceased to be appreciable, there will
-no longer be any appreciable re-distributions of matter on the
-surface of our planet.</p>
-
-<p class='c000'>Thus from the highest point of view, all terrestrial changes
-are incidents in the course of cosmical equilibration. It was
-before pointed out, (§ 80) that of the incessant alterations
-which the Earth’s crust and atmosphere undergo, those which
-are not due to the still-progressing motion of the Earth’s substance
-towards its centre of gravity, are due to the still-progressing
-motion of the Sun’s substance towards its centre of
-gravity. Here it is to be remarked, that this continuance of
-integration in the Earth and in the Sun, is a continuance of
-<span class='pageno' id='Page_456'>456</span>that transformation of sensible motion into insensible motion
-which we have seen ends in equilibration; and that the arrival
-in each case at the extreme of integration, is the arrival
-at a state in which no more sensible motion remains to be
-transformed into insensible motion—a state in which the
-forces producing integration and the forces opposing integration,
-have become equal.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 133. Every living body exhibits, in a four-fold form,
-the process we are tracing out—exhibits it from moment to
-moment in the balancing of mechanical forces; from hour to
-hour in the balancing of functions; from year to year in the
-changes of state that compensate changes of condition; and
-finally in the complete arrest of vital movements at death.
-Let us consider the facts under these heads.</p>
-
-<p class='c000'>The sensible motion constituting each visible action of an
-organism, is soon brought to a close by some adverse force
-within or without the organism. When the arm is raised, the
-motion given to it is antagonized partly by gravity and partly
-by the internal resistances consequent on structure; and its
-motion, thus suffering continual deduction, ends when the arm
-has reached a position at which the forces are equilibrated. The
-limits of each systole and diastole of the heart, severally show
-us a momentary equilibrium between muscular strains that produce
-opposite movements; and each gush of blood requires
-to be immediately followed by another, because the rapid
-dissipation of its momentum would otherwise soon bring
-the mass of circulating fluid to a stand. As much in the
-actions and re-actions going on among the internal organs,
-as in the mechanical balancing of the whole body, there is at
-every instant a progressive equilibration of the motions at
-every instant produced. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Viewed in their aggregate,
-and as forming a series, the organic functions constitute
-a dependent moving equilibrium—a moving equilibrium,
-of which the motive power is ever being dissipated through
-the special equilibrations just exemplified, and is ever
-<span class='pageno' id='Page_457'>457</span>being renewed by the taking in of additional motive power.
-Food is a store of force which continually adds to the momentum
-of the vital actions, as much as is continually deducted
-from them by the forces overcome. All the functional movements
-thus maintained, are, as we have seen, rhythmical (§ 96);
-by their union compound rhythms of various lengths and
-complexities are produced; and in these simple and compound
-rhythms, the process of equilibration, besides being
-exemplified at each extreme of every rhythm, is seen in the
-habitual preservation of a constant mean, and in the re-establishment
-of that mean when accidental causes have produced
-divergence from it. When, for instance, there is a great expenditure
-of motion through muscular activity, there arises a
-re-active demand on those stores of latent motion which are laid
-up in the form of consumable matter throughout the tissues:
-increased respiration and increased rapidity of circulation,
-are instrumental to an extra genesis of force, that counter-balances
-the extra dissipation of force. This unusual transformation
-of molecular motion into sensible motion, is presently
-followed by an unusual absorption of food—the source of molecular
-motion; and in proportion as there has been a prolonged
-draft upon the spare capital of the system, is there a tendency
-to a prolonged rest, during which that spare capital is replaced.
-If the deviation from the ordinary course of the functions has
-been so great as to derange them, as when violent exertion
-produces loss of appetite and loss of sleep, an equilibration is
-still eventually effected. Providing the disturbance is not
-such as to overturn the balance of the functions, and destroy
-life (in which case a complete equilibration is suddenly effected),
-the ordinary balance is by and by re-established: the returning
-appetite is keen in proportion as the waste has been large;
-while sleep, sound and prolonged, makes up for previous wakefulness.
-Not even in those extreme cases where some excess
-has wrought a derangement that is never wholly rectified, is
-there an exception to the general law; for in such cases the
-cycle of the functions is, after a time, equilibrated about a new
-<span class='pageno' id='Page_458'>458</span>mean state, which thenceforth becomes the normal state of
-the individual. Thus, among the involved rhythmical changes
-constituting organic life, any disturbing force that works an
-excess of change in some direction, is gradually diminished
-and finally neutralized by antagonistic forces; which thereupon
-work a compensating change in the opposite direction,
-and so, after more or less of oscillation, restore the medium
-condition. And this process it is, which constitutes what
-physicians call the <i><span lang="la" xml:lang="la">vis medicatrix naturæ</span></i>. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The third
-form of equilibration displayed by organic bodies, is a necessary
-sequence of that just illustrated. When through a
-change of habit or circumstance, an organism is permanently
-subject to some new influence, or different amount of an old
-influence, there arises, after more or less disturbance of the
-organic rhythms, a balancing of them around the new average
-condition produced by this additional influence. As temporary
-divergences of the organic rhythms are counteracted by temporary
-divergences of a reverse kind; so there is an equilibration
-of their permanent divergences by the genesis of opposing
-divergences that are equally permanent. If the quantity
-of motion to be habitually generated by a muscle, becomes
-greater than before, its nutrition becomes greater than before.
-If the expenditure of the muscle bears to its nutrition, a
-greater ratio than expenditure bears to nutrition in other parts
-of the system; the excess of nutrition becomes such that the
-muscle grows. And the cessation of its growth is the establishment
-of a balance between the daily waste and the daily
-repair—the daily expenditure of force, and the amount of
-latent force daily added. The like must manifestly be the
-case with all organic modifications consequent on change of
-climate or food. This is a conclusion which we may safely
-draw without knowing the special re-arrangements that effect
-the equilibration. If we see that a different mode of
-life is followed, after a period of functional derangement,
-by some altered condition of the system—if we see that this
-altered condition, becoming by and by established, continues
-<span class='pageno' id='Page_459'>459</span>without further change; we have no alternative but to say,
-that the new forces brought to bear on the system, have
-been compensated by the opposing forces they have evoked.
-And this is the interpretation of the process which we call
-<em>adaptation</em>. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Finally, each organism illustrates the
-law in the <em>ensemble</em> of its life. At the outset it daily absorbs
-under the form of food, an amount of force greater than it
-daily expends; and the surplus is daily equilibrated by
-growth. As maturity is approached, this surplus diminishes;
-and in the perfect organism, the day’s absorption of potential
-motion balances the day’s expenditure of actual motion. That
-is to say, during adult life, there is continuously exhibited an
-equilibration of the third order. Eventually, the daily loss,
-beginning to out-balance the daily gain, there results a diminishing
-amount of functional action; the organic rhythms
-extend less and less widely on each side of the medium
-state; and there finally results that complete equilibration
-which we call death.</p>
-
-<p class='c000'>The ultimate structural state accompanying that ultimate
-functional state towards which an organism tends, both individually
-and as a species, may be deduced from one of the propositions
-set down in the opening section of this chapter.
-We saw that the limit of heterogeneity is arrived at whenever
-the equilibration of any aggregate becomes complete—that
-the re-distribution of matter can continue so long only as
-there continues any motion unbalanced. Whence we found it
-to follow that the final structural arrangements, must be such
-as will meet all the forces acting on the aggregate, by equivalent
-antagonist forces. What is the implication in the case
-of organic aggregates; the equilibrium of which is a moving
-one? We have seen that the maintenance of such a moving
-equilibrium, requires the habitual genesis of internal forces
-corresponding in number, directions, and amounts to the external
-incident forces—as many inner functions, single or
-combined, as there are single or combined outer actions to be
-met. But functions are the correlatives of organs; amounts
-<span class='pageno' id='Page_460'>460</span>of functions are, other things equal, the correlatives of sizes
-of organs; and combinations of functions the correlatives of
-connections of organs. Hence the structural complexity
-accompanying functional equilibration, is definable as one in
-which there are as many specialized parts as are capable,
-separately and jointly, of counteracting the separate and
-joint forces amid which the organism exists. And this is the
-limit of organic heterogeneity; to which man has approached
-more nearly than any other creature.</p>
-
-<p class='c000'>Groups of organisms display this universal tendency towards
-a balance very obviously. In § 96, every species of
-plant and animal was shown to be perpetually undergoing a
-rhythmical variation in number—now from abundance of
-food and absence of enemies rising above its average; and
-then by a consequent scarcity of food and abundance of enemies
-being depressed below its average. And here we have
-to observe that there is thus maintained an equilibrium between
-the sum of those forces which result in the increase of
-each race, and the sum of those forces which result in its decrease.
-Either limit of variation is a point at which the one
-set of forces, before in excess of the other, is counterbalanced
-by it. And amid these oscillations produced by their conflict,
-lies that average number of the species at which its
-expansive tendency is in equilibrium with surrounding
-repressive tendencies. Nor can it be questioned that this
-balancing of the preservative and destructive forces which
-we see going on in every race, must necessarily go on. Since
-increase of number cannot but continue until increase of
-mortality stops it; and decrease of number cannot but continue
-until it is either arrested by fertility or extinguishes the
-race entirely.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 134. The equilibrations of those nervous actions which
-constitute what we know as mental life, may be classified in
-like manner with those which constitute what we distinguish
-<span class='pageno' id='Page_461'>461</span>as bodily life. We may deal with them in the
-same order.</p>
-
-<p class='c000'>Each pulse of nervous force from moment to moment generated,
-(and it was shown in § 97 that nervous currents are not
-continuous but rhythmical) is met by counteracting forces; in
-overcoming which it is dispersed and equilibrated. When
-tracing out the correlation and equivalence of forces, we saw
-that each sensation and emotion, or rather such part of it as
-remains after the excitation of associated ideas and feelings,
-is expended in working bodily changes—contractions of the
-involuntary muscles, the voluntary muscles, or both; as also
-in a certain stimulation of secreting organs. That the movements
-thus initiated are ever being brought to a close by the
-opposing forces they evoke, was pointed out above; and here it
-is to be observed that the like holds with the nervous changes
-thus initiated. Various facts prove that the arousing of a
-thought or feeling, always involves the overcoming of a certain
-resistance: instance the fact that where the association
-of mental states has not been frequent, a sensible effort is
-needed to call up the one after the other; instance the fact
-that during nervous prostration there is a comparative inability
-to think—the ideas will not follow one another with the
-habitual rapidity; instance the converse fact that at times of
-unusual energy, natural or artificial, the friction of thought
-becomes relatively small, and more numerous, more remote,
-or more difficult connections of ideas are formed. That is to
-say, the wave of nervous energy each instant generated, propagates
-itself throughout body and brain, along those channels
-which the conditions at the instant render lines of least
-resistance; and spreading widely in proportion to its amount,
-ends only when it is equilibrated by the resistances it everywhere
-meets. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;If we contemplate mental actions us
-extending over hours and days, we discover equilibrations
-analogous to those hourly and daily established among the
-bodily functions. In the one case as in the other, there are
-<span class='pageno' id='Page_462'>462</span>rhythms which exhibit a balancing of opposing forces at each
-extreme, and the maintenance of a certain general balance.
-This is seen in the daily alternation of mental activity and
-mental rest—the forces expended during the one being compensated
-by the forces acquired during the other. It is also seen in
-the recurring rise and fall of each desire: each desire reaching a
-certain intensity, is equilibrated either by expenditure of the
-force it embodies, in the desired actions, or, less completely, in
-the imagination of such actions: the process ending in that satiety,
-or that comparative quiescence, forming the opposite limit
-of the rhythm. And it is further manifest under a two-fold
-form, on occasions of intense joy or grief: each paroxysm of
-passion, expressing itself in vehement bodily actions, presently
-reaches an extreme whence the counteracting forces produce
-a return to a condition of moderate excitement; and the successive
-paroxysms finally diminishing in intensity, end in a
-mental equilibrium either like that before existing, or partially
-differing from it in its medium state. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;But
-the species of mental equilibration to be more especially noted,
-is that shown in the establishment of a correspondence between
-relations among our states of consciousness and relations
-in the external world. Each outer connection of phenomena
-which we are capable of perceiving, generates, through accumulated
-experiences, an inner connection of mental states;
-and the result towards which this process tends, is the formation
-of a mental connection having a relative strength that
-answers to the relative constancy of the physical connection
-represented. In conformity with the general law that
-motion pursues the line of least resistance, and that, other
-things equal, a line once taken by motion is made a line that
-will be more readily pursued by future motion; we have seen
-that the ease with which nervous impressions follow one another,
-is, other things equal, great in proportion to the number
-of times they have been repeated together in experience.
-Hence, corresponding to such an invariable relation as that between
-the resistance of an object and some extension possessed
-<span class='pageno' id='Page_463'>463</span>by it, there arises an indissoluble connection in consciousness;
-and this connection, being as absolute internally as the answering
-one is externally, undergoes no further change—the inner
-relation is in perfect equilibrium with the outer relation.
-Conversely, it hence happens that to such uncertain relations
-of phenomena as that between clouds and rain, there arise
-relations of ideas of a like uncertainty; and if, under given
-aspects of the sky, the tendencies to infer fair or foul weather,
-correspond to the frequencies with which fair or foul
-weather follow such aspects, the accumulation of experiences
-has balanced the mental sequences and the physical sequences.
-When it is remembered that between these extremes there
-are countless orders of external connections having different
-degrees of constancy, and that during the evolution of intelligence
-there arise answering internal associations having
-different degrees of cohesion; it will be seen that there is a
-progress towards equilibrium between the relations of thought
-and the relations of things. This equilibration can end
-only when each relation of things has generated in us a relation
-of thought, such that on the occurrence of the conditions,
-the relation in thought arises as certainly as the relation in
-things. Supposing this state to be reached (which however it
-can be only in infinite time) experience will cease to produce
-any further mental evolution—there will have been reached a
-perfect correspondence between ideas and facts; and the intellectual
-adaptation of man to his circumstances will be
-complete. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The like general truths are exhibited in
-the process moral of adaptation; which is a continual approach
-to equilibrium between the emotions and the kinds of conduct
-necessitated by surrounding conditions. The connections
-of feelings and actions, are determined in the same way
-as the connections of ideas: just as repeating the association
-of two ideas, facilitates the excitement of the one by the
-other; so does each discharge of feeling into action, render
-the subsequent discharge of such feeling into such action
-more easy. Hence it happens that if an individual is placed
-<span class='pageno' id='Page_464'>464</span>permanently in conditions which demand more action of a
-special kind than has before been requisite, or than is natural
-to him—if the pressure of the painful feelings which these
-conditions entail when disregarded, impels him to perform
-this action to a greater extent—if by every more frequent or
-more lengthened performance of it under such pressure, the
-resistance is somewhat diminished; then, clearly, there
-is an advance towards a balance between the demand for
-this kind of action and the supply of it. Either in himself,
-or in his descendants continuing to live under these
-conditions, enforced repetition must eventually bring about
-a state in which this mode of directing the energies will be
-no more repugnant than the various other modes previously
-natural to the race. Hence the limit towards which emotional
-modification perpetually tends, and to which it must approach
-indefinitely near (though it can absolutely reach it only in
-infinite time) is a combination of desires that correspond to
-all the different orders of activity which the circumstances of
-life call for—desires severally proportionate in strength to
-the needs for these orders of activity; and severally satisfied
-by these orders of activity. In what we distinguish as
-acquired habits, and in the moral differences of races and
-nations produced by habits that are maintained through successive
-generations, we have countless illustrations of this
-progressive adaptation; which can cease only with the establishment
-of a complete equilibrium between constitution and
-conditions.</p>
-
-<p class='c000'>Possibly some will fail to see how the equilibrations described
-in this section, can be classed with those preceding
-them; and will be inclined to say that what are here set
-down as facts, are but analogies. Nevertheless such equilibrations
-are as truly physical as the rest. To show this
-fully, would require a more detailed analysis than can now be
-entered on. For the present it must suffice to point out, as
-before (§ 82), that what we know subjectively as states of
-<span class='pageno' id='Page_465'>465</span>consciousness, are, objectively, modes of force; that so much
-feeling is the correlate of so much motion; that the performance
-of any bodily action is the transformation of a certain amount
-of feeling into its equivalent amount of motion; that this
-bodily action is met by forces which it is expended in overcoming;
-and that the necessity for the frequent repetition of
-this action, implies the frequent recurrence of forces to be so
-overcome. Hence the existence in any individual of an
-emotional stimulus that is in equilibrium with certain external
-requirements, is literally the habitual production of a
-certain specialized portion of nervous energy, equivalent in
-amount to a certain order of external resistances that are
-habitually met. And thus the ultimate state, forming the
-limit towards which Evolution carries us, is one in which the
-kinds and quantities of mental energy daily generated and
-transformed into motions, are equivalent to, or in equilibrium
-with, the various orders and degrees of surrounding forces
-which antagonize such motions.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 135. Each society taken as a whole, displays the process
-of equilibration in the continuous adjustment of its population
-to its means of subsistence. A tribe of men living on wild
-animals and fruits, is manifestly, like every tribe of inferior
-creatures, always oscillating about that average number which
-the locality can support. Though by artificial production, and
-by successive improvements in artificial production, a superior
-race continually alters the limit which external conditions
-put to population; yet there is ever a checking of population
-at the temporary limit reached. It is true that where the
-limit is being so rapidly changed as among ourselves, there
-is no actual stoppage: there is only a rhythmical variation
-in the rate of increase. But in noting the causes of this
-rhythmical variation—in watching how, during periods of
-abundance, the proportion of marriages increases, and how
-it decreases during periods of scarcity; it will be seen that the
-<span class='pageno' id='Page_466'>466</span>expansive force produces unusual advance whenever the repressive
-force diminishes, and <i><span lang="la" xml:lang="la">vice versâ</span></i>; and thus there is as
-near a balancing of the two as the changing conditions permit.</p>
-
-<p class='c000'>The internal actions constituting social functions, exemplify
-the general principle no less clearly. Supply and demand
-are continually being adjusted throughout all industrial processes;
-and this equilibration is interpretable in the same way
-as preceding ones. The production and distribution of a
-commodity, is the expression of a certain aggregate of forces
-causing special kinds and amounts of motion. The price of
-this commodity, is the measure of a certain other aggregate
-of forces expended by the labourer who purchases it, in other
-kinds and amounts of motion. And the variations of price
-represent a rhythmical balancing of these forces. Every rise
-or fall in the rate of interest, or change in the value of a
-particular security, implies a conflict of forces in which some,
-becoming temporarily predominant, cause a movement that
-is presently arrested or equilibrated by the increase of opposing
-forces; and amid these daily and hourly oscillations, lies a
-more slowly-varying medium, into which the value ever tends
-to settle; and would settle but for the constant addition of new
-influences. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;As in the individual organism so in the
-social organism, functional equilibrations generate structural
-equilibrations. When on the workers in any trade there
-comes an increased demand, and when in return for the increased
-supply, there is given to them an amount of other commodities
-larger than was before habitual—when, consequently,
-the resistances overcome by them in sustaining life are less
-than the resistances overcome by other workers; there
-results a flow of other workers into this trade. This
-flow continues until the extra demand is met, and the
-wages so far fall again, that the total resistance overcome
-in obtaining a given amount of produce, is as great in
-this newly-adopted occupation as in the occupations whence
-it drew recruits. The occurrence of motion along lines of
-least resistance, was before shown to necessitate the growth
-<span class='pageno' id='Page_467'>467</span>of population in those places where the labour required for
-self-maintenance is the smallest; and here we further see
-that those engaged in any such advantageous locality, or
-advantageous business, must multiply till there arises an
-approximate balance between this locality or business and
-others accessible to the same citizens. In determining
-the career of every youth, we see an estimation by parents of
-the respective advantages offered by all that are available,
-and a choice of the one which promises best; and through
-the consequent influx into trades that are at the time most
-profitable, and the withholding of recruits from over-stocked
-trades, there is insured a general equipoise between the
-power of each social organ and the function it has to perform.</p>
-
-<p class='c000'>The various industrial actions and re-actions thus continually
-alternating, constitute a dependent moving equilibrium
-like that which is maintained among the functions
-of an individual organism. And this dependent moving
-equilibrium parallels those already contemplated, in its tendency
-to become more complete. During early stages of
-social evolution, while yet the resources of the locality inhabited
-are unexplored, and the arts of production undeveloped,
-there is never anything more than a temporary and partial
-balancing of such actions, under the form of acceleration or
-retardation of growth. But when a society approaches the
-maturity of that type on which it is organized, the various
-industrial activities settle down into a comparatively
-constant state. Moreover, it is observable that advance in
-organization, as well as advance in growth, is conducive to a
-better equilibrium of industrial functions. While the diffusion
-of mercantile information is slow, and the means of
-transport deficient, the adjustment of supply to demand is
-extremely imperfect: great over-production of each commodity
-followed by great under-production, constitute a
-rhythm having extremes that depart very widely from the
-mean state in which demand and supply are equilibrated.
-But when good roads are made, and there is a rapid diffusion of
-<span class='pageno' id='Page_468'>468</span>printed or written intelligence, and still more when railways
-and telegraphs come into existence—when the periodical
-fairs of early days lapse into weekly markets, and these into
-daily markets; there is gradually produced a better balance
-of production and consumption. Extra demand is much
-more quickly followed by augmented supply; and the rapid
-oscillations of price within narrow limits on either side of a
-comparatively uniform mean, indicate a near approach to
-equilibrium. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Evidently this industrial progress has
-for its limit, that which Mr. Mill has called “the stationary
-state.” When population shall have become dense
-over all habitable parts of the globe; when the resources of
-every region have been fully explored; and when the productive
-arts admit of no further improvements; there must result
-an almost complete balance, both between the fertility and
-mortality of each society, and between its producing and
-consuming activities. Each society will exhibit only minor
-deviations from its average number, and the rhythm of its
-industrial functions will go on from day to day and year
-to year with comparatively insignificant perturbations. This
-limit, however, though we are inevitably advancing towards
-it, is indefinitely remote; and can never indeed be absolutely
-reached. The peopling of the Earth up to the point supposed,
-cannot take place by simple spreading. In the future,
-as in the past, the process will be carried on rhythmically,
-by waves of emigration from new and higher centres of
-civilization successively arising; and by the supplanting of
-inferior races by the superior races they beget; and the
-process so carried on must be extremely slow. Nor does
-it seem to me that such an equilibration will, as Mr. Mill
-suggests, leave scope for further mental culture and moral
-progress; but rather that the approximation to it must
-be simultaneous with the approximation to complete equilibrium
-between man’s nature and the conditions of his
-existence.</p>
-
-<p class='c000'>One other kind of social equilibration has still to be considered:—that
-<span class='pageno' id='Page_469'>469</span>which results in the establishment of governmental
-institutions, and which becomes complete as these
-institutions fall into harmony with the desires of the people.
-There is a demand and supply in political affairs as in industrial
-affairs; and in the one case as in the other, the antagonist
-forces produce a rhythm which, at first extreme in its
-oscillations, slowly settles down into a moving equilibrium of
-comparative regularity. Those aggressive impulses inherited
-from the pre-social state—those tendencies to seek self-satisfaction
-regardless of injury to other beings, which are essential
-to a predatory life, constitute an anti-social force, tending
-ever to cause conflict and eventual separation of citizens.
-Contrariwise, those desires whose ends can be achieved
-only by union, as well as those sentiments which find satisfaction
-through intercourse with fellow-men, and those resulting
-in what we call loyalty, are forces tending to keep the
-units of a society together. On the one hand, there is in
-each citizen, more or less of resistance against all restraints
-imposed on his actions by other citizens: a resistance which,
-tending continually to widen each individual’s sphere of
-action, and reciprocally to limit the spheres of action
-of other individuals, constitutes a repulsive force mutually
-exercised by the members of a social aggregate. On the
-other hand, the general sympathy of man for man, and
-the more special sympathy of each variety of man for others
-of the same variety, together with sundry allied feelings
-which the social state gratifies, act as an attractive force,
-tending ever to keep united those who have a common ancestry.
-And since the resistances to be overcome in satisfying
-the totality of their desires when living separately, are greater
-than the resistances to be overcome in satisfying the totality
-of their desires when living together, there is a residuary
-force that prevents their separation. Like all other opposing
-forces, those exerted by citizens on each other, are ever
-producing alternating movements, which, at first extreme,
-undergo a gradual diminution on the way to ultimate equilibrium.
-<span class='pageno' id='Page_470'>470</span>In small, undeveloped societies, marked rhythms
-result from these conflicting tendencies. A tribe whose
-members have held together for a generation or two, reaches
-a size at which it will not hold together; and on the occurrence
-of some event causing unusual antagonism among its
-members, divides. Each primitive nation, depending largely
-for its continued union on the character of its chief, exhibits
-wide oscillations between an extreme in which the subjects
-are under rigid restraint, and an extreme in which the
-restraint is not enough to prevent disorder. In more
-advanced nations of like type, we always find violent actions
-and reactions of the same essential nature—“despotism
-tempered by assassination,” characterizing a political state
-in which unbearable repression from time to time brings
-about a bursting of all bonds. In this familiar fact, that a
-period of tyranny is followed by a period of license and
-<i><span lang="la" xml:lang="la">vice versâ</span></i>, we see how these opposing forces are ever equilibrating
-each other; and we also see, in the tendency of such
-movements and counter-movements to become more moderate,
-how the equilibration progresses towards completeness.
-The conflicts between Conservatism (which stands for the
-restraints of society over the individual) and Reform (which
-stands for the liberty of the individual against society), fall
-within slowly approximating limits; so that the temporary
-predominance of either, produces a less marked deviation
-from the medium state. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;This process, now so far
-advanced among ourselves that the oscillations are comparatively
-unobtrusive, must go on till the balance between the
-antagonist forces approaches indefinitely near perfection.
-For, as we have already seen, the adaptation of man’s nature
-to the conditions of his existence, cannot cease until the internal
-forces which we know as feelings are in equilibrium
-with the external forces they encounter. And the establishment
-of this equilibrium, is the arrival at a state of human
-nature and social organization, such that the individual has
-no desires but those which may be satisfied without exceeding
-<span class='pageno' id='Page_471'>471</span>his proper sphere of action, while society maintains no
-restraints but those which the individual voluntarily respects.
-The progressive extension of the liberty of citizens,
-and the reciprocal removal of political restrictions, are the
-steps by which we advance towards this state. And the ultimate
-abolition of all limits to the freedom of each, save those
-imposed by the like freedom of all, must result from the
-complete equilibration between man’s desires and the conduct
-necessitated by surrounding conditions.</p>
-
-<p class='c000'>Of course in this case, as in the preceding ones, there is
-thus involved a limit to the increase of heterogeneity. A
-few pages back, we reached the conclusion that each advance
-in mental evolution, is the establishment of some further
-internal action, corresponding to some further external
-action—some additional connection of ideas or feelings,
-answering to some before unknown or unantagonized connection
-of phenomena. We inferred that each such new
-function, involving some new modification of structure,
-implies an increase of heterogeneity; and that thus, increase
-of heterogeneity must go on, while there remain any
-outer relations affecting the organism which are unbalanced
-by inner relations. Whence we saw it to follow that increase
-of heterogeneity can come to an end only as equilibration
-is completed. Evidently the like must simultaneously
-take place with society. Each increment of heterogeneity
-in the individual, must directly or indirectly involve, as
-cause or consequence, some increment of heterogeneity in
-the arrangements of the aggregate of individuals. And the
-limit to social complexity can be arrived at, only with the
-establishment of the equilibrium, just described, between
-social and individual forces.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 136. Here presents itself a final question, which has probably
-been taking a more or less distinct shape in the minds
-of many, while reading this chapter. “If Evolution of every
-kind, is an increase in complexity of structure and function
-<span class='pageno' id='Page_472'>472</span>that is incidental to the universal process of equilibration—if
-equilibration, passing through the gradually-perfected forms
-of moving equilibrium, must end in complete rest; what is
-the fate towards which all things tend? If the bodies
-constituting our Solar System are slowly dissipating the
-forces they possess—if the Sun is losing his heat at a rate
-which, though insignificant as stated in terms of our chronology,
-will tell in millions of years—if geologic and meteorologic
-processes cannot but diminish in activity as the Sun’s
-radiations diminish—if with the diminution of these radiations
-there must also go on a diminution in the quantity of
-vegetal and animal existence—if Man and Society, however
-high the degree of evolution at which they arrive, are similarly
-dependent on this supply of force that is gradually
-coming to an end—if thus the highest, equally with the
-lowest, terrestrial life, must eventually dwindle and disappear;
-are we not manifestly progressing towards omnipresent
-death? And have we thus to contemplate, as the
-out-come of things, a universe of extinct suns round which
-circle planets devoid of life?”</p>
-
-<p class='c000'>That such a state must be the proximate end of the processes
-everywhere going on, seems beyond doubt. But the further
-question tacitly involved, whether this state will continue
-eternally, is quite a different one. To give a positive answer
-to this further question would be quite illegitimate; since to
-affirm any proposition into which unlimited time enters as
-one of the terms, is to affirm a proposition of which one term
-cannot be represented in consciousness—is to affirm an unthinkable
-proposition. At a first glance it may appear that
-the reverse conclusion must be equally illegitimate; and that
-so the question is altogether insoluble. But further consideration
-will show that this is not true. So long as the
-terms to which we confine our reasonings are finite, the finite
-conclusions reached are not necessarily illegitimate. Though,
-if the general argument, when carried out, left no apparent
-escape from the inference that the state of rest to
-<span class='pageno' id='Page_473'>473</span>which Evolution is carrying things, must, when arrived
-at, last for ever, this inference would be invalid, as transcending
-the scope of human intelligence; yet if, on pushing
-further the general argument, we bring out the inference
-that such a state will not last for ever, this inference is
-not necessarily invalid: since, by the hypothesis, it contains
-no terms necessarily transcending the scope of human
-intelligence. It is permissible therefore, to inquire, what
-are the probable ulterior results of this process which must
-bring Evolution to a close in Universal Death. Without
-being so rash as to form anything like a positive conclusion
-on a matter so vast and so far beyond the boundaries of
-exact science; we may still inquire what <em>seems</em> to be the
-remote future towards which the facts point.</p>
-
-<p class='c000'>It has been already shown that all equilibration, so far
-as we can trace it, is relative. The dissipation of a body’s
-motion by communication of it to surrounding matter, solid,
-liquid, gaseous, and ethereal, tends to bring the body to
-a fixed position in relation to the matter that abstracts its
-motion. But all its other motions continue as before. The
-arrest of a cannon-shot does not diminish its movement
-towards the East at a thousand miles an hour, along with the
-wall it has struck; and a gradual dispersion of the Earth’s
-rotatory motion, would abstract nothing from the million
-and a half miles per day through which the Earth speeds in
-its orbit. Further, we have to bear in mind that this
-motion, the disappearance of which causes relative equilibration,
-is not lost but simply transferred; and by continual
-division and subdivision finally reduced to ethereal undulations
-and radiated through space. Whether the sensible
-motion dissipated during relative equilibration, is directly
-transformed into insensible motion, as happens in the case of
-the Sun; or whether, as in the sensible motions going on
-around us, it is directly transformed into smaller sensible
-motions, and these into still smaller, until they become insensible,
-matters not. In every instance the ultimate result
-<span class='pageno' id='Page_474'>474</span>is, that whatever motion of masses is lost, re-appears as
-molecular motion pervading space. Thus the questions we
-have to consider, are—Whether after the completion of all
-the relative equilibrations above contemplated as bringing
-Evolution to a close, there remain any further equilibrations
-to be effected?—Whether there are any other motions of
-masses that must eventually be transformed into molecular
-motion?—And if there are such other motions, what must
-be the consequence when the molecular motion generated by
-their transformation, is added to that which already exists?</p>
-
-<p class='c000'>To the first of these questions the answer is, that there <em>do</em>
-remain motions which are undiminished by all the relative
-equilibrations thus far considered; namely, the motions of
-translation possessed by those vast masses of incandescent
-matter called stars—masses now known to be suns that are
-in all probability, like our own, surrounded by circling
-groups of planets. The belief that the stars are literally
-fixed, has long since been exploded: observation has proved
-many of them to have sensible proper motions. Moreover, it
-has been ascertained by measurement, that in relation to the
-stars nearest to us, our own star is moving at the rate of
-about half a million miles per day; and if, as is admitted to
-be not improbable by sundry astronomers, our own star is
-traversing space in the same direction with adjacent stars,
-its absolute velocity may be, and most likely is, immensely
-greater than this. Now no such changes as those taking
-place within the Solar System, even when carried to the
-extent of integrating the whole of its matter into one mass,
-and diffusing all its relative movements in an insensible
-form through space, can affect these sidereal movements.
-Hence, there appears no alternative but to infer, that these
-sidereal movements must remain to be equilibrated by some
-subsequent process.</p>
-
-<p class='c000'>The next question that arises, if we venture to inquire the
-probable nature of this process, is—To what law do sidereal
-motions conform? And to this question Astronomy replies—the
-<span class='pageno' id='Page_475'>475</span>law of gravitation. The relative motions of binary stars
-have proved this. When it was discovered that certain of
-the double stars are not optically double but physically
-double, and move round each other, it was at once suspected
-that their revolutions might be regulated by a mutual attraction
-like that which regulates the revolutions of planets
-and satellites. The requisite measurements having been
-from time to time made, the periodic times of sundry
-binary stars were calculated on this assumption; and the
-subsequent performances of their revolutions in the predicted
-periods, have completely verified the assumption.
-If, then, it is demonstrated that these remote bodies are
-centres of gravitation—if we infer that all other stars are
-centres of gravitation, as we may fairly do—and if we draw
-the unavoidable corollary, that this gravitative force which so
-conspicuously affects stars that are comparatively near each
-other, must affect remote stars; we find ourselves led to the
-conclusion that all the members of our Sidereal System gravitate,
-individually and as an aggregate.</p>
-
-<p class='c000'>But if these widely-dispersed moving masses mutually
-gravitate, what must happen? There appears but one tenable
-answer. Even supposing they were all absolutely equal
-in weight, and arranged into an annulus with absolute regularity,
-and endowed with exactly the amounts of centrifugal
-force required to prevent nearer approach to their common
-centre of gravity; the condition would still be one which the
-slightest disturbing force would destroy. Much more then
-are we driven to the inference, that our actual Sidereal System
-cannot preserve its present arrangement: the irregularities
-of its distribution being such as to render even a temporary
-moving equilibrium impossible. If the stars are so many
-centres of an attractive force that varies inversely as the
-square of the distance, there appears to be no escape from the
-conclusion, that the structure of our galaxy must be undergoing
-change; and must continue to undergo change.</p>
-
-<p class='c000'>Thus, in the absence of tenable alternatives, we are brought
-<span class='pageno' id='Page_476'>476</span>to the positions:—1, that the stars are in motion;—2, that they
-move in conformity with the law of gravitation;—3, that,
-distributed as they are, they cannot move in conformity
-with the law of gravitation, without undergoing change of
-arrangement. If now we permit ourselves to take a further
-step, and ask the nature of this change of arrangement, we
-find ourselves obliged to infer a progressive concentration.
-Whether we do or do not suppose the clustering which is
-now visible, to have been caused by mutual gravitation acting
-throughout past eras, as the hypothesis of Evolution implies,
-we are equally compelled to conclude that this clustering
-must increase throughout future eras. Stars at present
-dispersed, must become locally aggregated; existing aggregations,
-at the same time that they are enlarged by the
-drawing in of adjacent stars, must grow more dense; and
-aggregations must coalesce with each other: each greater
-degree of concentration augmenting the force by which
-further concentration is produced.</p>
-
-<p class='c000'>And now what must be the limit of this concentration?
-The mutual attraction of two individual stars, when it so far
-predominates over other attractions as to cause approximation,
-almost certainly ends in the formation of a binary
-star; since the motions generated by other attractions, prevent
-the two stars from moving in straight lines to their
-common centre of gravity. Between small clusters, too,
-having also certain proper motions as clusters, mutual attraction
-may lead, not to complete union, but to the formation
-of binary clusters. As the process continues however,
-and the clusters become larger, it seems clear that they must
-move more directly towards each other, thus forming clusters
-of increasing density; and that eventually all clusters must
-unite into one comparatively close aggregation. While,
-therefore, during the earlier stages of concentration, the
-probabilities are immense against the actual contact of these
-mutually-gravitating masses; it is tolerably manifest, that as
-the concentration increases, collision must become probable,
-<span class='pageno' id='Page_477'>477</span>and ultimately certain. This is an inference not lacking the
-support of high authority. Sir John Herschel, treating of
-those numerous and variously-aggregated clusters of stars
-revealed by the telescope, and citing with apparent approval
-his father’s opinion, that the more diffused and irregular of
-these, are “globular clusters in a less advanced state of condensation;”
-subsequently remarks, that “among a crowd of
-solid bodies of whatever size, animated by independent and
-partially opposing impulses, motions opposite to each other
-<em>must</em> produce collision, destruction of velocity, and subsidence
-or near approach towards the centre of preponderant attraction;
-while those which conspire, or which remain outstanding
-after such conflicts, <em>must</em> ultimately give rise to circulation
-of a permanent character.” Now what is here alleged
-of these minor sidereal aggregations, cannot be denied of the
-large aggregations; and thus the above-described process of
-concentration, appears certain to bring about an increasingly-frequent
-integration of masses.</p>
-
-<p class='c000'>We have next to consider the consequences of the accompanying
-loss of velocity. The sensible motion which disappears,
-cannot be destroyed; but must be transformed into
-insensible motion. What will be the effect of this insensible
-motion? Some approach to a conception of it, will be made
-by considering what would happen were the comparatively insignificant
-motion of our planet thus transformed. In his essay
-on “The Inter-action of Natural Forces,” Prof. Helmholtz
-states the thermal equivalent of the Earth’s movement
-through space; as calculated on the now received datum of
-Mr. Joule. “If our Earth,” he says, “were by a sudden
-shock brought to rest in her orbit,—which is not to be feared
-in the existing arrangement of our system—by such a shock
-a quantity of heat would be generated equal to that produced
-by the combustion of fourteen such Earths of solid
-coal. Making the most unfavourable assumption as to its
-capacity for heat, that is, placing it equal to that of water,
-the mass of the Earth would thereby be heated 11,200 degrees;
-<span class='pageno' id='Page_478'>478</span>it would therefore be quite fused, and for the most
-part reduced to vapour. If then the Earth, after having
-been thus brought to rest, should fall into the Sun, which of
-course would be the case, the quantity of heat developed by
-the shock would be 400 times greater.” Now so relatively
-small a momentum as that acquired by the Earth in falling
-through 95,000,000 of miles to the Sun, being equivalent to
-a molecular motion such as would reduce the Earth to gases
-of extreme rarity; what must be the molecular motion generated
-by the mutually-arrested momenta of two stars, that
-have moved to their common centre of gravity through spaces
-immeasurably greater? There seems no alternative but to
-conclude, that this molecular motion must be so great, as to
-reduce the matter of the stars to an almost inconceivable tenuity—a
-tenuity like that which we ascribe to nebular matter.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Such being the immediate effect of the integration
-of any two stars in a concentrating aggregate, what must
-be the ulterior effect on the aggregate as a whole? Sir John
-Herschel, in the passage above quoted, describing the collisions
-that must arise in a mutually-gravitating group of stars, adds
-that those stars “which remain outstanding after such conflicts,
-<em>must</em> ultimately give rise to circulation of a permanent
-character.” The problem, however, is here dealt with purely
-as a mechanical one: the assumption being, that the mutually-arrested
-masses will continue as masses—an assumption
-to which no objection was apparent at the time when Sir
-John Herschel wrote this passage; since the doctrine of the
-correlation of forces was not then recognized. But obliged
-as we now are to conclude, that stars moving at the high
-velocities acquired during concentration, will, by mutual
-arrest, be dissipated into gases of great tenuity, the problem
-becomes different; and a different inference appears unavoidable.
-For the diffused matter produced by such conflicts,
-must form a resisting medium, occupying that central region
-of the aggregate through which its members from time to
-time pass in describing their orbits—a resisting medium
-<span class='pageno' id='Page_479'>479</span>which they cannot move through without having their velocities
-diminished. Every further such collision, by augmenting
-this resisting medium, and making the losses of
-velocity greater, must further aid in preventing the establishment
-of that equilibrium which would else arise; and so
-must conspire to produce more frequent collisions. And the
-nebulous matter thus formed, presently enveloping and extending
-beyond the whole aggregate, must, by continuing to
-shorten their gyrations, entail an increasingly-active integration
-and re-active disintegration of the moving masses; until
-they are all finally dissipated. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;This, indeed, is the
-conclusion which, leaving out all consideration of the process
-gone through, presents itself as a simple deduction from
-the persistence of force. If the stars have been, and still
-are, concentrating however indirectly on their common centre
-of gravity, and must eventually reach it; it is a corollary
-from the persistence of force, that the quantities of motion
-they have severally acquired, must suffice to carry them away
-from the common centre of gravity to those remote regions
-whence they originally began to move towards it. And since,
-by the conditions of the case, they cannot return to these
-remote regions in the shape of concrete masses, they must
-return in the shape of diffused masses. Action and reaction
-being equal and opposite, the momentum producing dispersion,
-must be as great as the momentum acquired by aggregation;
-and being spread over the same quantity of matter,
-must cause an equivalent distribution through space, whatever
-be the form of the matter. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;One condition,
-however, essential to the literal fulfilment of this result, must
-be specified; namely, that the quantity of molecular motion
-produced and radiated into space by each star in the course
-of its formation from diffused matter, shall be compensated
-by an equal quantity of molecular motion radiated from other
-parts of space into the space which our Sidereal System occupies.
-In other words, if we set out with that amount of
-molecular motion implied by the existence of the matter of
-<span class='pageno' id='Page_480'>480</span>our Sidereal System in a nebulous form; then it follows from
-the persistence of force, that if this matter undergoes the re-distribution
-constituting Evolution, the quantity of molecular
-motion given out during the integration of each mass,
-plus the quantity of molecular motion given out during the
-integration of all the masses, must suffice again to reduce it
-to the same nebulous form. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Here indeed we arrive at
-an impassable limit to our reasonings; since we cannot know
-whether this condition is or is not fulfilled. On the hypothesis
-of an unlimited space, containing, at certain intervals,
-Sidereal Systems like our own, it may be that the quantity of
-molecular motion radiated into the region occupied by our
-Sidereal System, is equal to that which our Sidereal System
-radiates; in which case the quantity of motion possessed by
-it, remaining undiminished, our Sidereal System may continue
-during unlimited time, to repeat this alternate concentration
-and diffusion. But if, on the other hand, throughout boundless
-space there exist no other Sidereal Systems subject to like
-changes, or if such other Sidereal Systems exist at more than
-a certain average distance from each other; then it seems an
-unavoidable conclusion that the quantity of motion possessed,
-must diminish by radiation into unoccupied space; and that
-so, on each successive resumption of the nebulous form, the
-matter of our Sidereal System will occupy a less space;
-until at the end of an infinite time it reaches either a state
-in which its concentrations and diffusions are relatively small,
-or a state of complete aggregation and rest. Since, however,
-we have no evidence showing the existence or non-existence
-of Sidereal Systems throughout remote space; and since, even
-had we such evidence, a legitimate conclusion could not be
-drawn from premises of which one element (unlimited space)
-is inconceivable; we must be for ever without answer to this
-transcendent question. All we can say is, that so far as the
-data enable us to judge, the integration of our Sidereal System
-will be followed by disintegration; that such integration
-and disintegration will be repeated; and that, for anything
-<span class='pageno' id='Page_481'>481</span>we know to the contrary, the alternation of them may continue
-without limit.</p>
-
-<p class='c000'>But leaving this ultimate insoluble problem, and confining
-ourselves to the proximate and not necessarily insoluble one,
-we find reason for thinking that after the completion of those
-various equilibrations which bring to a close all the forms of
-Evolution we have contemplated, there must still continue
-an equilibration of a far wider kind. When that integration
-everywhere in progress throughout our Solar System, has
-reached its climax, there will remain to be effected the immeasurably
-greater integration of our Solar System, with all
-other such systems. As in those minor forms now going on
-around us, this integration with its concomitant equilibration,
-involves the change of aggregate motion into diffused
-motion; so in those vaster forms hereafter to be carried out,
-there must similarly be gained in molecular motion what is
-lost in the motion of masses; and the inevitable transformation
-of this motion of masses into molecular motion, cannot
-take place without reducing the masses to a nebulous form.
-Thus we seem led to the conclusion that the entire process of
-things, as displayed in the aggregate of the visible Universe,
-is analogous to the entire process of things as displayed in
-the smallest aggregates. Where, as in organic bodies, the whole
-series of changes constituting Evolution can be traced, we
-saw that, dynamically considered, Evolution is a change from
-molecular motion to the motion of masses; and this change,
-becoming more active during the ascending phase of Evolution
-while the masses increase in bulk and heterogeneity,
-eventually begins to get less active; until, passing through
-stages in which the integration grows greater, and the equilibrium
-more definite, it finally ceases; whereupon there
-arises, by an ulterior process, an increase of molecular motion,
-ending in the more or less complete dissolution of the
-aggregate. And here we find reason to believe that, along
-with each of the thousands of similar ones dispersed through
-the heavens, our Solar System, after passing through stages
-<span class='pageno' id='Page_482'>482</span>during which the motion of masses is produced at the expense
-of lost molecular motion, and during which there goes
-on an increasingly active differentiation and integration,
-arrives at a climax whence these changes, beginning to decline
-in activity, slowly bring about that complete integration and
-equilibration which in other cases we call death; and that
-there afterwards comes a time, when the still-remaining motions
-of masses are transformed into a molecular motion which
-causes dissolution of the masses. Motion as well as Matter
-being fixed in quantity, it would seem that the change in the
-distribution of Matter which Motion effects, coming to a limit
-in whichever direction it is carried, the indestructible Motion
-thereupon necessitates a reverse distribution. Apparently,
-the universally-coexistent forces of attraction and repulsion,
-which, as we have seen, necessitate rhythm in all minor
-changes throughout the Universe, also necessitate rhythm
-in the totality of its changes—produce now an immeasurable
-period during which the attractive forces predominating,
-cause universal concentration, and then an immeasurable
-period during which the repulsive forces predominating,
-cause universal diffusion—alternate eras of Evolution and
-Dissolution. And thus there is suggested the conception
-of a past during which there have been successive Evolutions
-similar to that which is now going on; and a
-future during which successive other such Evolutions may
-go on.</p>
-
-<p class='c000'>Let none suppose, however, that this is to be taken as anything
-more than a speculation. In dealing with times and
-spaces and forces so immensely transcending those of which
-we have definite experience, we are in danger of passing the
-limits to human intelligence. Though these times and
-spaces and forces cannot literally be classed as infinite; yet
-they are so utterly beyond the possibility of definite conception,
-as to be almost equally unthinkable with the infinite.
-What has been above said, should therefore be regarded simply
-as a possible answer to a possible doubt. When, pushing
-<span class='pageno' id='Page_483'>483</span>to its extreme the argument that Evolution must come
-to a close in complete equilibrium or rest, the reader suggests
-that for aught which appears to the contrary, the Universal
-Death thus implied will continue indefinitely; it is legitimate
-to point out how, on carrying the argument still further,
-we are led to infer a subsequent Universal Life. But while
-this last inference may fitly be accepted as a demurrer to the
-first, it would be unwise to accept it in any more positive
-sense.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 137. Returning from this parenthetical discussion, concerning
-the probable or possible state of things that may
-arise after Evolution has run its course; and confining ourselves
-to the changes constituting Evolution, with which
-alone we are immediately concerned; we have now to inquire
-whether the cessation of these changes, in common with all
-their transitional characteristics, admits of <i><span lang="fr" xml:lang="fr">à priori</span></i> proof. It
-will soon become apparent that equilibration, not less than
-the preceding general principles, is deducible from the persistence
-of force.</p>
-
-<p class='c000'>We have seen (§ 85) that phenomena are interpretable
-only as the results of universally-coexistent forces of attraction
-and repulsion. These universally-coexistent forces of attraction
-and repulsion, are, indeed, the complementary aspects
-of that absolutely persistent force which is the ultimate datum
-of consciousness. Just in the same way that the equality of
-action and re-action is a corollary from the persistence of
-force, since their inequality would imply the disappearance
-of the differential force into nothing, or its appearance out of
-nothing; so, we cannot become conscious of an attractive
-force without becoming simultaneously conscious of an equal
-and opposite repulsive force. For every experience of a
-muscular tension, (under which form alone we can immediately
-know an attractive force,) presupposes an equivalent
-resistance—a resistance shown in the counter-balancing pressure
-of the body against neighbouring objects, or in that
-<span class='pageno' id='Page_484'>484</span>absorption of force which gives motion to the body, or in
-both—a resistance which we cannot conceive as other than
-equal to the tension, without conceiving force to have either
-appeared or disappeared, and so denying the persistence of
-force. And from this necessary correlation, results our inability,
-before pointed out, of interpreting any phenomena
-save in terms of these correlatives—an inability shown alike
-in the compulsion we are under to think of the statical forces
-which tangible matter displays, as due to the attraction and
-repulsion of its atoms, and in the compulsion we are under to
-think of dynamical forces exercised through space, by regarding
-space as filled with atoms similarly endowed. Thus from
-the existence of a force that is for ever unchangeable in quantity,
-there follows, as a necessary corollary, the co-extensive
-existence of these opposite forms of force—forms under
-which the conditions of our consciousness oblige us to represent
-that absolute force which transcends our knowledge.</p>
-
-<p class='c000'>But the forces of attraction and repulsion being universally
-co-existent, it follows, as before shown, that all motion
-is motion under resistance. Units of matter, solid, liquid,
-aëriform, or ethereal, filling the space which any moving
-body traverses, offer to such body the resistance consequent
-on their cohesion, or their inertia, or both. In other words,
-the denser or rarer medium which occupies the places from
-moment to moment passed through by such moving body,
-having to be expelled from them, as much motion is abstracted
-from the moving body as is given to the medium in
-expelling it from these places. This being the condition
-under which all motion occurs, two corollaries result. The
-first is, that the deductions perpetually made by the communication
-of motion to the resisting medium, cannot but
-bring the motion of the body to an end in a longer or shorter
-time. The second is, that the motion of the body cannot
-cease until these deductions destroy it. In other words,
-movement must continue till equilibration takes place; and
-equilibration must eventually take place. Both these are
-<span class='pageno' id='Page_485'>485</span>manifest deductions from the persistence of force. To say
-that the whole or part of a body’s motion can disappear, save
-by transfer to something which resists its motion, is to say
-that the whole or part of its motion can disappear without
-effect; which is to deny the persistence of force. Conversely,
-to say that the medium traversed can be moved out of
-the body’s path, without deducting from the body’s motion,
-is to say that motion of the medium can arise out of nothing;
-which is to deny the persistence of force. Hence
-this primordial truth is our immediate warrant for the conclusions,
-that the changes which Evolution presents, cannot
-end until equilibrium is reached; and that equilibrium must
-at last be reached.</p>
-
-<p class='c000'>Equally necessary, because equally deducible from this
-same truth that transcends proof, are the foregoing propositions
-respecting the establishment and maintenance of moving
-equilibria, under their several aspects. It follows from
-the persistence of force, that the various motions possessed
-by any aggregate, either as a whole or among its parts, must
-be severally dissipated by the resistances they severally encounter;
-and that thus, such of them as are least in amount,
-or meet with greatest opposition, or both, will be brought to
-a close while the others continue. Hence in every diversely
-moving aggregate, there results a comparatively early dissipation
-of motions which are smaller and much resisted; followed
-by long-continuance of the larger and less-resisted
-motions; and so there arise dependent and independent
-moving equilibria. Hence also may be inferred the tendency
-to conservation of such moving equilibria; since,
-whenever the new motion given to the parts of a moving
-equilibrium by a disturbing force, is not of such kind and
-amount that it cannot be dissipated before the pre-existing
-motions (in which case it brings the moving equilibrium to
-an end) it must be of such kind and amount that it can be
-dissipated before the pre-existing motions (in which case the
-moving equilibrium is re-established).</p>
-
-<p class='c000'><span class='pageno' id='Page_486'>486</span>Thus from the persistence of force follow, not only the
-various direct and indirect equilibrations going on around,
-together with that cosmical equilibration which brings Evolution
-under all its forms to a close; but also those less
-manifest equilibrations shown in the re-adjustments of
-moving equilibria that have been disturbed. By this
-ultimate principle is proveable the tendency of every
-organism, disordered by some unusual influence, to return to
-a balanced state. To it also may be traced the capacity,
-possessed in a slight degree by individuals, and in a greater
-degree by species, of becoming adapted to new circumstances.
-And not less does it afford a basis for the inference, that
-there is a gradual advance towards harmony between man’s
-mental nature and the conditions of his existence. After
-finding that from it are deducible the various characteristics
-of Evolution, we finally draw from it a warrant for the
-belief, that Evolution can end only in the establishment of
-the greatest perfection and the most complete happiness.</p>
-
-<hr class='c015' />
-
-<div class='footnote' id='f18'>
-<p class='c000'><span class='label'><a href='#r18'>18</a>.&nbsp;&nbsp;</span>Sir David Brewster has recently been citing with approval, a calculation
-by M. Babinet, to the effect that on the hypothesis of nebular genesis, the
-matter of the Sun, when it filled the Earth’s orbit, must have taken 3181 years
-to rotate; and that therefore the hypothesis cannot be true. This calculation of
-M. Babinet may pair-off with that of M. Comte, who, contrariwise, made the
-time of this rotation agree very nearly with the Earth’s period of revolution
-round the Sun; for if M. Comte’s calculation involved a <i><span lang="la" xml:lang="la">petitio principii</span></i>, that of
-M. Babinet is manifestly based on two assumptions, both of which are gratuitous,
-and one of them totally inconsistent with the doctrine to be tested. He has evidently
-proceeded on the current supposition respecting the Sun’s internal density,
-which is not proved, and from which there are reasons for dissenting; and
-he has evidently taken for granted that all parts of the nebulous spheroid, when it
-filled the Earth’s orbit, had the same angular velocity; whereas if (as is implied
-in the nebular hypothesis, rationally understood) this spheroid resulted from the
-concentration of far more widely-diffused matter, the angular velocity of its
-equatorial portion would obviously be immensely greater than that of its central
-portion.</p>
-</div>
-
-<div class='footnote' id='f19'>
-<p class='c000'><span class='label'><a href='#r19'>19</a>.&nbsp;&nbsp;</span>See paper “On the Inter-action of Natural Forces,” by Prof. Helmholtz,
-translated by Prof. Tyndall, and published in the <cite>Philosophical Magazine</cite>, supplement
-to Vol. XI. fourth series.</p>
-</div>
-
-<div class='footnote' id='f20'>
-<p class='c000'><span class='label'><a href='#r20'>20</a>.&nbsp;&nbsp;</span>Until I recently consulted his “Outlines of Astronomy” on another question,
-I was not aware that so far back as 1833, Sir John Herschel had enunciated
-the doctrine that “the sun’s rays are the ultimate source of almost every
-motion which takes place on the surface of the earth.” He expressly includes
-all geologic, meteorologic, and vital actions; as also those which we produce by
-the combustion of coal. The late George Stephenson appears to have been
-wrongly credited with this last idea.</p>
-</div>
-
-<div>
- <span class='pageno' id='Page_487'>487</span>
- <h3 class='c001'>CHAPTER XVII.<br /> <span class='large'>SUMMARY AND CONCLUSION.</span></h3>
-</div>
-
-<p class='c006'>§ 138. In the chapter on “Laws in general,” after delineating
-the progress of mankind in recognizing uniformities
-of relation among surrounding phenomena—after showing
-how the actual succession in the establishment of different
-orders of co-existences and sequences, corresponds with the
-succession deducible <i><span lang="fr" xml:lang="fr">à priori</span></i> from the conditions to human
-knowledge—after showing how, by the ever-multiplying experiences
-of constant connections among phenomena, there
-has been gradually generated the conception of universal
-conformity to law; it was suggested that this conception
-will become still clearer, when it is perceived that there
-are laws of wider generality than any of those at present
-accepted.</p>
-
-<p class='c000'>The existence of such more general laws, is, indeed, almost
-implied by the <em>ensemble</em> of the facts set forth in the above-named
-chapter; since they make it apparent, that the process
-hitherto carried on, of bringing phenomena under fewer and
-wider laws, has not ceased, but is advancing with increasing
-rapidity. Apart, however, from evidence of this kind, the
-man of science, hourly impressed with new proof of uniformity
-in the relations of things, until the conception of
-uniformity has become with him a necessity of thought,
-tacitly entertains the conclusion that the minor uniformities
-which Science has thus far established, will eventually be
-<span class='pageno' id='Page_488'>488</span>merged in uniformities that are universal. Taught as he
-is by every observation and experiment, to regard phenomena
-as manifestations of Force; and learning as he does
-to contemplate Force as unchangeable in amount; there tends
-to grow up in him a belief in unchangeable laws common to
-Force under all its manifestations. Though he may not have
-formulated it to himself, he is prepared to recognize the
-truth, that, being fixed in quantity, fixed in its two ultimate
-modes of presentation (Matter and Motion), and fixed in the
-conditions under which it is presented (Time and Space);
-Force must have certain equally fixed laws of action, common
-to all the changes it produces.</p>
-
-<p class='c000'>Hence to the classes who alone are likely to read these
-pages, the hypothesis of a fundamental unity, extending
-from the simplest inorganic actions up to the most complex
-associations of thought and the most involved social
-processes, will have an <i><span lang="fr" xml:lang="fr">à priori</span></i> probability. All things being
-recognized as having one source, will be expected to exhibit
-one method. Even in the absence of a clue to uniformities
-co-extensive with all modes of Force, as the mathematical
-uniformities are co-extensive with Space and Time, it will be
-inferred that such uniformities exist. And thus a certain
-presumption will result in favour of any formula, of a generality
-great enough to include concrete phenomena of every
-order.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 139. In the chapters on the “Law of Evolution,” there
-was set forth a principle, which, so far as accessible evidence
-enables us to judge, possesses this universality. The order
-of material changes, first perceived to have certain constant
-characteristics in cases where it could be readily traced from
-beginning to end, we found to have these same characteristics
-in cases where it could be less readily traced; and we saw
-numerous indications that these same characteristics were
-displayed during past changes of which we have no direct
-knowledge. The transformation of the homogeneous into
-<span class='pageno' id='Page_489'>489</span>the heterogeneous, first observed by naturalists to be exhibited
-during the development of every plant and animal,
-proved to be also exhibited during the development of every
-society; both in its political and industrial organization, and
-in all the products of social life,—language, science, art,
-and literature. From the disclosures of geology, we drew
-adequate support for the conclusion, that in the structure of
-the Earth there has similarly been a progress from uniformity,
-through ever-increasing degrees of multiformity, to
-the complex state which we now see. And on the assumption
-of that nebular origin to which so many facts point, we
-inferred that a like transition from unity to variety of distribution,
-must have been undergone by our Solar System;
-as well as by that vast assemblage of such systems constituting
-the visible Universe. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;This definition of the metamorphosis,
-first asserted by physiologists of organic aggregates
-only, but which we thus found reason to think, holds of all
-other aggregates, proved on further inquiry to be too wide.
-Its undue width was shown to arise from the omission of
-certain other characteristics, that are, not less than the foregoing
-one, displayed throughout all kinds of Evolution. We
-saw that simultaneously with the change from homogeneity
-to heterogeneity, there takes place a change from indefiniteness
-of arrangement to definiteness of arrangement—a
-change everywhere equally traceable with that which it accompanies.
-Further consideration made it apparent, that
-the increasing definiteness thus manifested along with increasing
-heterogeneity, necessarily results from increasing
-integration of the parts severally rendered unlike. And
-thus we finally reached the conclusion, that there has been
-going on throughout an immeasurable past, is still going on,
-and will continue to go on, an advance from a diffused, indeterminate,
-and uniform distribution of Matter, to a concentrated,
-determinate, and multiform distribution of it.</p>
-
-<p class='c000'>At a subsequent stage of our inquiry, we discovered that
-this progressive change in the arrangement of Matter, is accompanied
-<span class='pageno' id='Page_490'>490</span>by a parallel change in the arrangement of
-Motion—that every increase in the structural complexity of
-things, involves a corresponding increase in their functional
-complexity. It was shown that along with the integration of
-molecules into masses, there arises an integration of molecular
-motion into the motion of masses; and that as fast as
-there results variety in the sizes and forms of aggregates and
-their relations to incident forces, there also results variety in
-their movements. Whence it became manifest, that the
-general process of things is from a confused simplicity to an
-orderly complexity, in the distribution of both Matter and
-Motion.</p>
-
-<p class='c000'>It was pointed out, however, that though this species of
-transformation is universal, in the sense of holding throughout
-all classes of phenomena, it is not universal in the sense
-of being continued without limit in all classes of phenomena.
-Those aggregates which exhibit the entire change from uniformity
-to multiformity of structure and function, in comparatively
-short periods, eventually show us a reverse set of
-changes: Evolution is followed by Dissolution. The differentiations
-and integrations of Matter and Motion, finally reach
-a degree which the conditions do not allow them to pass;
-and there then sets in a process of disintegration and assimilation,
-of both the parts and the movements that were before
-growing more united and more distinct.</p>
-
-<p class='c000'>But under one or the other of these processes, all observable
-modifications in the arrangement of things may be
-classed. Every change comes under the head of integration
-or disintegration, material or dynamical; or under the head
-of differentiation or assimilation, material or dynamical; or
-under both. Each inorganic mass is either undergoing increase
-by the combination with it of surrounding elements
-for which its parts have affinity; or undergoing decrease by
-the solvent and abraiding action of surrounding elements; or
-both one and the other in varied succession and combination.
-By perpetual additions and losses of heat, it is having its
-<span class='pageno' id='Page_491'>491</span>parts temporarily differentiated from each other, or temporarily
-assimilated to each other, in molecular state. And
-through the actions of divers agents, it is also undergoing
-certain permanent molecular re-arrangements; rendering it
-either more uniform or more multiform in structure. These
-opposite kinds of change, thus vaguely typified in every
-surrounding fragment of matter, are displayed in all aggregates
-with increasing distinctness in proportion as the conditions
-essential to re-arrangement of parts are fulfilled. So
-that universally, the process of things is either in the one
-direction or the other. There is in all cases going on that
-ever-complicating distribution of Matter and Motion which
-we call Evolution; save in those cases where it has been
-brought to a close and reversed by what we call Dissolution.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 140. Whether this omnipresent metamorphosis admits
-of interpretation, was the inquiry on which we next entered.
-Recognizing the changes thus formulated as consisting in
-Motions of Matter that are produced by Force, we saw that
-if they are interpretable at all, it must be by the affiliation
-of them on certain ultimate laws of Matter, Motion, and
-Force. We therefore proceeded to inquire what these ultimate
-laws are.</p>
-
-<p class='c000'>We first contemplated under its leading aspects, the principle
-of correlation and equivalence among forces. The
-genesis of sensible motion by insensible motion, and of insensible
-motion by sensible motion, as well as the like reciprocal
-production of those forms of insensible motion which constitute
-Light, Heat, Electricity, Magnetism, and Chemical
-Action, was shown to be a now accepted doctrine, that involves
-certain corollaries respecting the processes everywhere
-going on around us. Setting out with the probability that
-the insensible motion radiated by the Sun, is the transformed
-product of the sensible motion lost during the progressive
-concentration of the solar mass; we saw that by this insensible
-motion, are in turn produced the various kinds of sensible
-<span class='pageno' id='Page_492'>492</span>motion on the Earth’s surface. Besides the inorganic
-terrestrial changes, we found that the changes constituting
-organic life are thus originated. We were obliged to conclude
-that within this category, come the vital phenomena
-classed as mental, as well as those classed as physical. And
-it appeared inevitably to follow that of social changes, too,
-the like must be said. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;We next saw that phenomena
-being cognizable by us only as products of Force, manifested
-under the two-fold form of attraction and repulsion, there
-results the general law that all Motion must occur in the
-direction of least resistance, or in the direction of greatest
-traction, or in the direction of their resultant. It was
-pointed out that this law is every instant illustrated in the
-movements of the celestial bodies. The innumerable transpositions
-of matter, gaseous, liquid, and solid, going on over
-the Earth’s surface, were shown to conform to it. Evidence
-was given that this same ultimate principle of motion underlies
-the structural and functional changes of organisms.
-Throughout the succession of those nervous actions which
-constitute thought and feeling, as also in the discharge of
-feeling into action, we no less found this principle conspicuous.
-Nor did we discover any exception to it in the
-movements, temporary and permanent, that go on in
-societies. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;From the universal coexistence of opposing
-forces, there also resulted the rhythm of motion. It was
-shown that this is displayed from the infinitesimal vibrations
-of molecules up to the enormous revolutions and
-gyrations of planets; that it is traceable throughout all
-meteorologic and geologic changes; that the functions of every
-organic body exemplify it in various forms; that mental
-activities too, intellectual and emotional, exhibit periodicities
-of sundry kinds; and that actions and reactions illustrating
-this law under a still more complex form, pervade social
-processes.</p>
-
-<p class='c000'>Such being the principles to which conform all changes
-produced by Force on the distribution of Matter, and all
-<span class='pageno' id='Page_493'>493</span>changes re-actively produced by Matter on the distribution
-of Force, we proceeded to inquire what must be the consequent
-nature of any re-distributions produced: having first
-noted the limiting conditions between which such re-distributions
-are possible, and the medium conditions that are most
-favourable to them. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;The first conclusion arrived at,
-was, that any finite homogeneous aggregate must inevitably
-lose its homogeneity, through the unequal exposure of its
-parts to incident forces. We observed how this was shown
-in surrounding things, by the habitual establishment of differences
-between inner and outer parts, and parts otherwise
-dissimilarly circumstanced. It was pointed out that the
-production of diversities of structure by forces acting under
-diverse conditions, has been illustrated in astronomic evolution,
-supposing such evolution to have taken place; and
-that a like connection of cause and effect is seen in the large
-and small modifications undergone by our globe. In the
-early changes of organic germs, we discovered further evidence
-that unlikenesses of structure follow unlikenesses of
-relations to surrounding agencies—evidence enforced by the
-tendency of the differently-placed members of each species to
-diverge into varieties. We found that the principle is also
-conformed to in the establishment of distinctions among our
-ideas; and that the contrasts, political and industrial, that
-arise between the parts of societies are no less in harmony
-with it. The instability of the homogeneous thus caused,
-and thus everywhere exemplified, we also saw must hold of
-the unlike parts into which any uniform whole lapses; and
-that so the less heterogeneous must tend continually to become
-more heterogeneous—an inference which we also found
-to be everywhere confirmed by fact. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Carrying a step
-further our inquiry into these actions and reactions between
-Force and Matter, there was disclosed a secondary cause of
-increasing multiformity. Every differentiated part becomes,
-we found, a parent of further differentiations; not only in
-the sense that it must lose its own homogeneity in heterogeneity,
-<span class='pageno' id='Page_494'>494</span>but also in the sense that it must, in growing unlike
-other parts, become a centre of unlike reactions on incident
-forces; and by so adding to the diversity of forces at work,
-must add to the diversity of effects produced. This multiplication
-of effects, likewise proved to be manifest throughout
-all Nature. That forces modified in kind and direction by
-every part of every aggregate, are gradually expended in
-working changes that grow more numerous and more varied
-as the forces are subdivided, is shown in the actions and reactions
-going on throughout the Solar System, in the never-ceasing
-geologic complications, in the involved symptoms
-produced in organisms by disturbing influences, in the many
-thoughts and feelings generated by single impressions, and
-in the ever-ramifying results of each new agency brought to
-bear on a society. To which add the corollary, confirmed
-by abundant facts, that the multiplication of effects must increase
-in a geometrical progression, as the heterogeneity
-increases. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Completely to interpret the structural
-changes constituting Evolution, there remained to assign a
-reason for that increasingly-distinct demarcation of parts,
-which accompanies the production of differences between
-parts. This reason we discovered to be, the segregation of
-mixed units under the action of forces capable of moving
-them. We saw that when the parts of an aggregate have
-been made qualitatively unlike by unlike incident forces—that
-is, when they have become contrasted in the natures of
-their component units; there necessarily arises a tendency
-to separation of the dissimilar orders of units from each
-other, and to aggregation of those units which are similar.
-This cause of the integration that accompanies differentiation,
-turned out to be likewise exemplified by all kinds of
-Evolution—by the formation of celestial bodies, by the
-moulding of the Earth’s crust, by organic modifications, by
-the establishment of mental distinctions, by the genesis of
-social divisions. And we inferred, what we may everywhere
-see, that the segregation thus produced goes on so
-<span class='pageno' id='Page_495'>495</span>long as there remains a possibility of making it more complete.
-&#8196;&#8196;&#8196;&#8196;&#8196;&#8196;At length, to the query whether the processes
-thus traced out have any limit, there came the answer that
-they must end in equilibration. That continual division and
-subdivision of forces, which is instrumental in changing the
-uniform into the multiform and the multiform into the more
-multiform, we saw to be at the same time a process by which
-force is perpetually dissipated; and that dissipation, continuing
-as long as there remains any force unbalanced by an opposing
-force, must end in rest. It was shown that when, as
-happens with aggregates of various orders, a number of
-movements are going on in combination, the earlier dispersion
-of the smaller and more resisted movements, entails the
-establishment of different kinds of moving equilibria: forming
-transitional stages on the way to complete equilibrium.
-And further inquiry made it apparent that for the same
-reason, these moving equilibria have a certain self-conserving
-power; shown in the neutralization of perturbations, and the
-adjustment to new conditions. This general principle, like
-the preceding ones, proved to be traceable throughout all
-forms of Evolution—astronomic, geologic, biologic, mental
-and social. And our concluding inference was, that the
-penultimate stage of this process, in which the extremest
-degree of multiformity and completest form of moving
-equilibrium is established, must be one implying the highest
-conceivable state of humanity.</p>
-
-<p class='c000'>Thus it became apparent that this transformation of on
-indefinite, incoherent homogeneity into a definite coherent
-heterogeneity, which goes on everywhere, until it brings
-about a reverse transformation, is consequent on certain
-simple laws of force. Given those universal modes of action
-which are from moment to moment illustrated in the commonest
-changes around us, and it follows that there cannot
-but result the observed metamorphosis of an indeterminate
-uniformity into a determinate multiformity.</p>
-
-<hr class='c013' />
-
-<p class='c000'><span class='pageno' id='Page_496'>496</span>§ 141. Finally, we have asked whether, for these universal
-modes of action, any common cause is assignable—whether
-these wide truths are dependent on any single widest truth.
-And to this question we found a positive answer. These
-several principles are corollaries from that primordial principle
-which transcends human intelligence by underlying it.</p>
-
-<p class='c000'>In the first part of this work it was shown, by analysis of
-both our religious and our scientific ideas, that while knowledge
-of the cause which produces effects on our consciousness
-is impossible, the existence of a cause for these effects is
-a datum of consciousness. Though Being is cognizable by
-us only under limits of Time and Space, yet Being without
-limits of Time and Space was proved to be the indefinite
-cognition forming the necessary basis of our definite cognitions.
-We saw that the belief in an Omnipresent Power of
-which no commencement or cessation can be conceived, is
-that fundamental element in Religion which survives all its
-changes of form. We saw that all Philosophies avowedly or
-tacitly recognize this same ultimate truth:—that while the
-Relativist rightly repudiates those definite assertions which
-the Absolutist makes respecting real existence, he is yet at
-last compelled to unite with him in predicating real existence.
-And this inexpugnable consciousness in which Religion and
-Philosophy are at one with Common Sense, proved to be likewise
-that on which all exact Science is founded. We found
-that subjective Science can give no account of those conditioned
-modes of existence which constitute consciousness,
-without postulating unconditioned existence. And we found
-that objective Science can give no account of the existence
-which we know as external, without regarding its changes
-of form as manifestations of an existence that continues constant
-under all forms. Absolute Being, or Being which
-persists without beginning or end, was shown to be the
-common datum of all human thought; for the sufficient
-reason that the consciousness of it cannot be suppressed,
-without the suppression of consciousness itself.</p>
-
-<p class='c000'><span class='pageno' id='Page_497'>497</span>From this truth which transcends proof, we have seen that
-the general principles above set down, are deducible. That the
-power or force manifested to us in all phenomena, continues
-unaltered in quantity, however its mode of manifestation be
-altered, is a proposition in which these several propositions
-are involved. It was shown that on the Persistence of Force
-are based the demonstrations that Matter is indestructible
-and Motion continuous. When its proofs were examined,
-the correlation and equivalence of forces was found to follow
-from the Persistence of Force. The necessity we are under
-of conceiving Force under the two-fold form of attraction
-and repulsion, turns out to be but an implication of the
-necessity we are under of conceiving Force as persistent.
-On the Persistence of Force, we saw that the law of direction
-of Motion is dependent; and from it also we saw that the
-rhythm of Motion necessarily results. Passing to those
-changes of distribution which, by the Motion it generates,
-Force produces in Matter, it was pointed out that from the
-Persistence of Force are severally deducible, the instability of
-the homogeneous, the multiplication of effects, and that
-increasing definiteness of structure to which continuous
-differentiation and integration leads. And lastly we saw
-that Force being persistent, Evolution cannot cease until
-equilibrium is reached; and that equilibrium must eventually
-be reached.</p>
-
-<p class='c000'>So that given Force manifested in Time and Space, under
-the forms of Matter and Motion; and it is demonstrable, <i><span lang="fr" xml:lang="fr">à
-priori</span></i>, that there must go on such transformations as we find
-going on.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 142. See then the accumulation of proofs. The advance
-of human intelligence in establishing laws continually wider
-in generality, raises the presumption that there are all-comprehensive
-laws. Turning to the facts, we discern a pervading
-uniformity in the general course of things where this
-can be watched, and indications of such uniformity where it
-<span class='pageno' id='Page_498'>498</span>cannot be watched. Considering this uniformity analytically,
-we find it to result from certain simpler uniformities
-in the actions of Force. And these uniformities prove to be
-so many necessary implications of that primordial truth
-which underlies all knowledge—the Persistence of Force.
-The aspect of things raises a presumption; extended observations
-lead to an induction that fulfils this presumption;
-this induction is deductively confirmed; and the laws
-whence it is deduced are corollaries from that datum without
-which thought is impossible.</p>
-
-<p class='c000'>No higher degree of verification than this can be imagined.
-An induction based on facts so numerous and varied, and
-falling short of universality only where the facts are beyond
-observation, possesses of itself a validity greater than that of
-most scientific inductions. When it is shown that the proposition
-thus arrived at <i><span lang="fr" xml:lang="fr">à posteriori</span></i>, may also be arrived at
-<i><span lang="fr" xml:lang="fr">à priori</span></i>, starting from certain simple laws of force; it is
-raised to a level with those generalizations of concrete science
-which are accepted as proved. And when these simple laws
-of force are affiliated upon that ultimate truth which transcends
-proof; this dependent proposition takes rank with
-those propositions of abstract science which are our types of
-the greatest conceivable certainty.</p>
-
-<p class='c000'>Let no one suppose that any such degree of certainty is
-alleged of the various minor propositions brought in illustration
-of the general argument. Such an assumption would be
-so manifestly absurd, that it seems scarcely needful to disclaim
-it. But the truth of the doctrine as a whole, is unaffected
-by errors in the details of its presentation. As the
-first principles of mathematics are not invalidated by mistakes
-made in working out particular equations; so the first
-principles set forth in the foregoing pages, do not stand or
-fall with each special statement made in them. If it can be
-shown that the Persistence of Force is not a datum of consciousness;
-or if it can be shown that the several laws of
-force above specified are not corollaries from it; then, indeed,
-<span class='pageno' id='Page_499'>499</span>it will be shown that the theory of Evolution has not the
-certainty here claimed for it. But nothing short of this can
-invalidate the general conclusions arrived at.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 143. If these conclusions be accepted—if it be admitted
-that they inevitably follow from the truth transcending all
-others in authority—if it be agreed that the phenomena
-going on everywhere are parts of the general process of
-Evolution, save where they are parts of the reverse process
-of Dissolution; then it must be inferred that all phenomena
-receive their complete interpretation, only when recognized
-as parts of these processes. Regarded from the point of
-view here reached, each change that takes place, is an incident
-in the course of the ever-complicating distribution of
-Matter and Motion, except where it is an incident in the
-course of the reverse distribution; and each such change is
-fully understood, only when brought under those universal
-principles of change, to which these transformations necessarily
-conform. &#8196;&#8196;&#8196;&#8196;&#8196;&#8196;Whence, indeed, it appears to be
-an unavoidable conclusion, that the limit towards which
-Science is advancing, must be reached when these formulæ
-are made all-comprehensive. Manifestly, the perfection
-of Science, is a state in which all phenomena are seen
-to be necessary implications of the Persistence of Force. In
-such a state, the dependence of each phenomenon on the
-Persistence of Force, must be proved either directly or indirectly—either
-by showing that it is a corollary of the Persistence
-of Force, or by showing that it is a corollary from
-some general proposition deduced from the Persistence of
-Force. And since all phenomena are incidents in the re-distributions
-of Matter and Motion; and since there are certain
-general principles, deducible from the Persistence of Force,
-to which all these re-distributions conform; it seems inferrable
-that ultimately all phenomena, where not classed as
-consequences of the Persistence of Force, must be classed as
-consequences of these derivative principles.</p>
-
-<hr class='c013' />
-
-<p class='c000'><span class='pageno' id='Page_500'>500</span>§ 144. Of course this development of Science into an
-organized aggregate of direct and indirect deductions from
-the Persistence of Force, can be achieved only in the remote
-future; and indeed cannot be completely achieved even
-then. Scientific progress, is progress in that equilibration of
-thought and things which we saw is going on, and must continue
-to go on; but which cannot arrive at perfection in any
-finite period, because it advances more slowly the further
-it advances. But though Science can never be entirely reduced
-to this form; and though only at a far distant time
-can it be brought nearly to this form; yet much may even
-now be done in the way of rude approximation. Those who
-are familiar with the present aspects of Science, must recognize
-in them the broken outlines of a general organization.
-The possibility of arranging the facts already accumulated,
-into the order rudely exhibited in the foregoing
-pages, will itself incline them to the belief that our knowledge
-may be put into a more connected shape than it at
-present has. They will see the probability that many
-now isolated inductions, may be reduced to the form of deductions
-from first principles. They will suspect that inferences
-drawn from the ultimate laws of force, will lead to
-the investigation and generalization of classes of facts hitherto
-unexamined. And they will feel, not only that a greater
-degree of certainty must be acquired by Science, as fast as its
-propositions are directly or indirectly deduced from the
-highest of all truths; but also that it must so be rendered a
-more efficient agent of further inquiry.</p>
-
-<p class='c000'>To bring scientific knowledge to such degree of logical coherence
-as is at present possible, is a task to be achieved
-only by the combined efforts of many. No one man can
-possess that encyclopedic information required for rightly
-arranging even the truths already established. But as progress
-is effected by increments—as all organization, beginning
-in faint and blurred outlines, is completed by successive
-modifications and additions; advantage may accrue from an
-<span class='pageno' id='Page_501'>501</span>attempt, however rude, to reduce the facts already accumulated—or
-rather certain classes of them—to something like
-co-ordination. Such must be the plea for the several volumes
-which are to succeed this.</p>
-
-<hr class='c013' />
-
-<p class='c000'>§ 145. A few closing words must be said, concerning the
-general bearings of the doctrines that are now to be further
-developed. Before proceeding to interpret the detailed phenomena
-of Life, and Mind, and Society, in terms of Matter,
-Motion, and Force, the reader must be reminded in what
-sense the interpretations are to be accepted. In spite of
-everything said at the outset, there are probably some who
-have gained the impression that those most general truths
-set forth in the preceding chapters, together with the truths
-deducible from them, claim to be something more than relative
-truths. And, notwithstanding all evidence to the
-contrary, there will probably have arisen in not a few minds,
-the conviction that the solutions which have been given,
-along with those to be derived from them, are essentially
-materialistic. Let none persist in these misconceptions.</p>
-
-<p class='c000'>As repeatedly shown in various ways, the deepest truths
-we can reach, are simply statements of the widest uniformities
-in our experience of the relations of Matter, Motion, and
-Force; and Matter, Motion, and Force are but symbols of
-the Unknown Reality. That Power of which the nature
-remains for ever inconceivable, and to which no limits in
-Time or Space can be imagined, works in us certain effects.
-These effects have certain likenesses of kind, the most general
-of which we class together under the names of Matter,
-Motion, and Force; and between these effects there are
-likenesses of connection, the most constant of which we class
-as laws of the highest certainty. Analysis reduces these
-several kinds of effect to one kind of effect; and these
-several kinds of uniformity to one kind of uniformity. And
-the highest achievement of Science is the interpretation of
-all orders of phenomena, as differently-conditioned manifestations
-<span class='pageno' id='Page_502'>502</span>of this one kind of effect, under differently-conditioned
-modes of this one kind of uniformity. But when Science
-has done this, it has done nothing more than systematize our
-experience; and has in no degree extended the limits of our
-experience. We can say no more than before, whether the
-uniformities are as absolutely necessary, as they have become
-to our thought relatively necessary. The utmost possibility
-for us, is an interpretation of the process of things as it presents
-itself to our limited consciousness; but how this process
-is related to the actual process, we are unable to conceive,
-much less to know.</p>
-
-<p class='c000'>Similarly, it must be remembered that while the connection
-between the phenomenal order and the ontological order is
-for ever inscrutable; so is the connection between the conditioned
-forms of being and the unconditioned form of being,
-for ever inscrutable. The interpretation of all phenomena
-in terms of Matter, Motion, and Force, is nothing more than
-the reduction of our complex symbols of thought, to the
-simplest symbols; and when the equation has been brought
-to its lowest terms the symbols remain symbols still. Hence
-the reasonings contained in the foregoing pages, afford no
-support to either of the antagonist hypotheses respecting the
-ultimate nature of things. Their implications are no more
-materialistic than they are spiritualistic; and no more
-spiritualistic than they are materialistic. Any argument
-which is apparently furnished to either hypothesis, is neutralized
-by as good an argument furnished to the other. The
-Materialist, seeing it to be a necessary deduction from the
-law of correlation, that what exists in consciousness under
-the form of feeling, is transformable into an equivalent of
-mechanical motion, and by consequence into equivalents of
-all the other forces which matter exhibits; may consider it
-therefore demonstrated that the phenomena of consciousness
-are material phenomena. But the Spiritualist, setting out
-with the same data, may argue with equal cogency, that if
-the forces displayed by matter are cognizable only under the
-<span class='pageno' id='Page_503'>503</span>shape of those equivalent amounts of consciousness which
-they produce, it is to be inferred that these forces, when
-existing out of consciousness, are of the same intrinsic
-nature as when existing in consciousness; and that so is
-justified the spiritualistic conception of the external world,
-as consisting of something essentially identical with what
-we call mind. Manifestly, the establishment of correlation
-and equivalence between the forces of the outer and the
-inner worlds, may be used to assimilate either to the other;
-according as we set out with one or other term. But he
-who rightly interprets the doctrine contained in this work,
-will see that neither of these terms can be taken as ultimate.
-He will see that though the relation of subject and object
-renders necessary to us these antithetical conceptions of
-Spirit and Matter; the one is no less than the other to be
-regarded as but a sign of the Unknown Reality which underlies
-both.</p>
-
-<div class='nf-center-c1'>
-<div class='nf-center c002'>
- <div>THE END.</div>
- </div>
-</div>
-
-<div class='nf-center-c1'>
-<div class='nf-center c002'>
- <div>JOHN CHILDS AND SON, PRINTERS.</div>
- </div>
-</div>
-
-<div class='pbb'>
- <hr class='pb c003' />
-</div>
-<div class='tnotes'>
-
-<div class='chapter'>
- <h2 class='c005'>TRANSCRIBER’S NOTES</h2>
-</div>
- <ol class='ol_1 c002'>
- <li>Changed “which takes place” to “which take place” on p. <a href='#t315'>315</a>.
-
- </li>
- <li>Duplicated the large spaces in the original text.
-
- </li>
- <li>Silently corrected typographical errors.
-
- </li>
- <li>Retained anachronistic and non-standard spellings as printed.
- </li>
- </ol>
-
-</div>
-
-
-
-
-
-
-
-
-<pre>
-
-
-
-
-
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