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diff --git a/30495-h/30495-h.htm b/30495-h/30495-h.htm new file mode 100644 index 0000000..3fbb88a --- /dev/null +++ b/30495-h/30495-h.htm @@ -0,0 +1,8655 @@ +<?xml version="1.0" encoding="UTF-8"?> + +<!DOCTYPE html + PUBLIC "-//W3C//DTD XHTML 1.0 Strict//EN" + "http://www.w3.org/TR/xhtml1/DTD/xhtml1-strict.dtd" > + +<html xmlns="http://www.w3.org/1999/xhtml" lang="en"> + <head> + <title> + A History of Science, Vol. V by Henry Smith Williams + </title> + <style type="text/css" xml:space="preserve"> + + body { margin:5%; background:#faebd0; text-align:justify} + P { text-indent: 1em; margin-top: .25em; margin-bottom: .25em; } + H1,H2,H3,H4,H5,H6 { text-align: center; margin-left: 15%; margin-right: 15%; } + hr { width: 50%; text-align: center;} + .foot { margin-left: 20%; margin-right: 20%; text-align: justify; text-indent: -3em; font-size: 90%; } + blockquote {font-size: 97%; font-style: italic; margin-left: 10%; margin-right: 10%;} + .mynote {background-color: #DDE; color: #000; padding: .5em; margin-left: 10%; margin-right: 10%; font-family: sans-serif; font-size: 95%;} + .toc { margin-left: 10%; margin-bottom: .75em;} + .toc2 { margin-left: 20%;} + div.fig { display:block; margin:0 auto; text-align:center; } + div.middle { margin-left: 20%; margin-right: 20%; text-align: justify; } + .figleft {float: left; margin-left: 0%; margin-right: 1%;} + .figright {float: right; margin-right: 0%; margin-left: 1%;} + .pagenum {display:inline; font-size: 70%; font-style:normal; + margin: 0; padding: 0; position: absolute; right: 1%; + text-align: right;} + pre { font-style: italic; font-size: 90%; margin-left: 10%;} + +</style> + </head> + <body> +<div>*** START OF THE PROJECT GUTENBERG EBOOK 30495 ***</div> + <p> + <br /><br /> + </p> + <h1> + A HISTORY OF SCIENCE + </h1> + <h1> + Aspects Of Recent Science + </h1> + <p> + <br /> + </p> + <h2> + By Henry Smith Williams + </h2> + <h3> + Assisted By Edward H. Williams + </h3> + <h4> + In Five Volumes <br /><br /> VOLUME V. + </h4> + <p> + <br /> + </p> + <h5> + New York And London <br /> <br /> Harper And Brothers <br /> Copyright, 1904, + by Harper & Brothers. <br /> Published November, 1904. + </h5> + <p> + <br /> <br /> + </p> + <hr /> + <p> + <br /> <br /> + </p> +<pre xml:space="preserve"> + BOOK V +</pre> +<pre xml:space="preserve"> + CHAPTER I—THE BRITISH MUSEUM + + The founding of the British Museum, p. 4—Purchase of Sir Hans Sloane's + collection of curios by the English government, p. 4—Collection of + curios and library located in Montague Mansion, p. 5—Acquisition of + the collection of Sir William Hamilton, p. 5—Capture of Egyptian + antiquities by the English, p. 5—Construction of the present museum + building, p. 6—The Mesopotamian department, p. 8—The Museum of Natural + History in South Kensington, p. 8—Novel features in the structure of + the building, p. 9—Arrangement of specimens to illustrate evolution, + protective coloring, etc., p.— —Exhibits of stuffed specimens amid + their natural surroundings, p. 10—Interest taken by visitors in the + institution, p. 12. + + CHAPTER II—THE ROYAL SOCIETY OP LONDON FOR IMPROVING NATURAL KNOWLEDGE + + The Royal Society, p. 14—Weekly meetings of the society, p. 15—The tea + before the opening of the lecture, p. 15—Announcement of the beginning + of the lecture by bringing in the great mace, p. 16—The lecture-room + itself, p. 17—Comparison of the Royal Society and the Royal Academy + of Sciences at Berlin, p. 18—The library and reading-room, p. 19—The + busts of distinguished members, p. 20—Newton's telescope and Boyle's + air-pump, p. 21. + + CHAPTER III—THE ROYAL INSTITUTION AND LOW-TEMPERATURE RESEARCHES + + The founding of the Royal Institution, p. 29—Count Rumford, p. 30—His + plans for founding the Royal Institution, p. 32—Change in the spirit + of the enterprise after Rumford's death, p. 33—Attitude of the + earlier workers towards the question of heat as a form of motion, + p. 34—Experiments upon gases by Davy and Faraday, p. 35—Faraday's + experiments with low temperatures, p. 39—Other experiments to produce + lower temperature, p. 39—Professor De-war begins low-temperature + research, p. 39—His liquefaction of hydrogen, p. 43—Hampson's method + of producing low temperatures, p. 44—Dewar's invention of the vacuum + vessel, p. 53—Its use in retaining liquefied gases, p. 54—Changes in + physical properties of substances at excessively low temperatures, p. + 56—Magnetic phenomena at low temperatures, p. 56—Changes in the color + of substances at low temperatures, p. 57—Substances made luminous by + low temperatures, p. 58—Effect of low temperatures upon the strength of + materials, p. 59—Decrease of chemical activity at low temperatures, p. + 60—Olzewski's experiments with burning substances in liquid oxygen, + p. 61—Approach to the absolute zero made by liquefying hydrogen, p. + 69—Probable form of all matter at the absolute zero, p. 70—Uncertain + factors that enter into this determination, p. 71. + + CHAPTER IV—SOME PHYSICAL LABORATORIES AND PHYSICAL PROBLEMS + + Sir Norman Lockyer and Spectroscopic Studies of the Sun and Stars, p. + 73—Observations made at South Kensington by Sir Norman and his staff, + p. 74—His theories as to the influence of sun-spots and terrestrial + weather, p. 75—Spectroscopic studies of sun-spots, p. 76—Studies of + the so-called reverse lines of the spectrum, p. 78—Discovery of the new + star in the constellation of Perseus, p. 80—Spectroscopic studies + of the new star, p. 81—Professor Ramsay and the new gases, p. + 82—University College in London, p. 83—Professor Ramsay's laboratory + and its equipment, p. 84—The discovery of argon, p. 86—Professor + Ramsay's work on krypton, neon, and zenon, p. 87—Discoveries of new + constituents of the atmosphere, p. 88—Interesting questions raised + by these discoveries, p. 89—Professor J. J. Thomson and the nature + of electricity, p. 92—Study of gases in relation to the conduction + of electricity, p. 93—Electricity regarded as a form of matter, p. + 97—Radio-activity, p. 97—The nature of emanations from radio-active + bodies, p. 10a—The source of energy of radioactivity, p. + 106—Radio-activity and the structure of the atom, p. 108—Effect of + radio-activity upon heat-giving life of the sun and the earth, p. 111. + + CHAPTER V—THE MARINE BIOLOGICAL LABORATORY + + The aquarium, p. 113—The arrangement of the tanks and exhibits, p. + 114—The submarine effect of this arrangement, p. 115—Appearance of the + submarine dwellers in their natural surroundings, p. 116—The eels and + cuttle-fishes, p. 116—The octopuses, p. 117—The technical department + of the laboratory, p. 119—The work of Dr. Anton Dohrn, founder of the + laboratory, p. 121—The associates of Dr. Dohrn, p. 122—The collecting + of surface specimens, p. 123—Collecting specimens by dredging, p. + 124—Fauna of the Bay of Naples, p. 124—Abundance of the material for + biological study, p. 125—Advantages offered by marine specimens for + biological study, p. 126—Method of preserving jelly-fish and similar + fragile creatures, p. 127—Uses made of the specimens in scientific + study, p. 128—Different nationalities represented among the workers at + the laboratory, p. 130—Methods of investigation, p. 131—Dr. Diesch's + studies of heredity at the laboratory, p. 131—Other subjects under + scientific investigation, p. 132—The study of chromosomes, p. + 133—Professor Weismann's theory of heredity based on these studies, + p. 33—Experiments in the division of egg-cells, p. 134—Experiments + tending to refute Weismann's theory, p. 136—Dr. Dohrn*s theory of + the type of the invertebrate ancestor, p. 137—Publications of the + laboratory, p. 139—Meetings of the investigators at Signor Bifulco's, + p. 141—Marine laboratories of other countries, p. 142. + + CHAPTER VI—ERNST HAECKEL AND THE NEW ZOOLOGY + + The "dream city" of Jena, p. 145—The old market-place, p. 147—The + old lecture-halls of the university, p. 148—Ernst Haeckel, p. 151—His + discoveries of numerous species of radiolarians, p. 153—The part played + in evolution by radiolarians, p. 156—Haeckel's work on morphology, + and its aid to Darwinian philosophy, p. 156—Freedom of thought and + expression in the University of Jena, p. 157—Haeckel's laboratory, p. + 160—His method of working, p. 161—His methods of teaching, p. 164—The + import of the study of zoology, p. 166—Its bearing upon evolution, p. + 168—The present status of Haeckel's genealogical tree regarding the + ancestry of man, p. 171—Dubois's discovery of the skull of the ape-man + of Java, p. 173—Its close resemblance to the skull of the ape, p. + 173—Man's line of descent clearly traced by Haeckel, p. 175—The + "missing link" no longer missing, p. 176. + + CHAPTER VII—SOME MEDICAL LABORATORIES AND MEDICAL PROBLEMS + + The Boulevard Pasteur, p. 179—The Pasteur Institute, p. 180—The tomb + of Pasteur within the walls, p. 181—Aims and objects of the Pasteur + Institute, p. 182—Antirabic treatment given, p. 183—Methods of + teaching in the institute, p. 185—The director of the institute and his + associates, p. 185—The Virchow Institute of Pathology, p. 186—Studies + of the causes of diseases, p. 187—Organic action and studies of + cellular activities, p. 188—The discoveries of Rudolph Virchow, p. + 188—His work in pathology, p. 189—Character of the man, his ways of + living and working, p. 189—His methods of lecturing and teaching, p. + 191—The Berlin Institute of Hygiene, p. 193—Work of Professor Koch + as carried on in the institute, p. 194—Work of his successors in the + institute, p. 195—Investigations in hygiene, p. 196—Investigations + of the functions of the human body in their relations to everyday + environment, p. 197—The Museum of Hygiene, p. 198—Studies in methods + of constructing sewerage systems in large cities, p. 199—Studies in + problems of ventilation, p. 200. + + CHAPTER VIII—SOME UNSOLVED SCIENTIFIC PROBLEMS + + The ever-shifting ground of scientific progress, p. 203—Solar and + telluric problems, p. 205—Mayer's explanation of the continued heat + of the sun, p. 206—Helmholtz's suggestion as to the explanation, p. + 207—The estimate of the heat-giving life of the sun by Lord Kelvin + and Professor Tait, p. 208—Lockyer's suggestion that the chemical + combination of elements might account for the sun's heat, p. + 209—Computations as to the age of the earth's crust, p. 210—Lord + Kelvin's computation of the rigidity of the telluric structure, p. + 211—Estimates of the future life of the earth, p. 212—Physical + problems, p. 213—Attempts to explain the power of gravitation, + p. 214—The theory of Le Sage, p. 214—Speculations based upon the + hypothesis of the vortex atom, p. 216—Lord Kelvin's estimate of the + vortex theory, p. 217—Attempted explanation of the affinity of + atoms, p. 217—Solubility, as explained by Ostwald and Mendeleef, p. + 218—Professor Van 't Hoof's studies of the space relations of atoms, p. + 219—Life problems, p. 220—Question as to living forms on other worlds + besides our own, p. 21 x—The question of the "spontaneous generation" + of living protoplasm, p. 222—The question of the evolution from + non-vital to vital matter, p. 223—The possibility of producing organic + matter from inorganic in the laboratory, p. 224—Questions as to + the structure of the cell, p. 225—Van Beneden's discovery of the + centrosome, p. 226—Some problems of anthropology, p. 227. + + CHAPTER IX—RETROSPECT AND PROSPECT + + The scientific attitude of mind, p. 2 30—Natural versus supernatural, + p. 233—Inductive versus deductive reasoning, p. 235—Logical induction + versus hasty generalization, p. 239—The future of Darwinism, p. 241. + + APPENDIX + + A LIST OF SOURCES +</pre> + <p> + <br /> <br /> + </p> + <hr /> + <p> + <br /> <br /> + </p> + <h2> + Contents + </h2> + <p> + <a href="#link2H_4_0001"> <b>A HISTORY OF SCIENCE—BOOK V</b> </a><br /><br /> + <a href="#link2H_4_0002"> <b>ASPECTS OF RECENT SCIENCE</b> </a> + </p> + <table summary="" style="margin-right: auto; margin-left: auto"> + <tr> + <td> + <p class="toc"> + <a href="#link2H_4_0003"> I. THE BRITISH MUSEUM </a> + </p> + <p class="toc"> + <a href="#link2H_4_0004"> II. THE ROYAL SOCIETY OF LONDON FOR + IMPROVING NATURAL KNOWLEDGE </a> + </p> + <p class="toc"> + <a href="#link2H_4_0005"> III. THE ROYAL INSTITUTION AND THE + LOW-TEMPERATURE RESEARCHES </a> + </p> + <p class="toc"> + <a href="#link2H_4_0006"> IV. SOME PHYSICAL LABORATORIES AND + PHYSICAL PROBLEMS </a> + </p> + <p class="toc"> + <a href="#link2H_4_0007"> V. THE MARINE BIOLOGICAL LABORATORY AT + NAPLES </a> + </p> + <p class="toc"> + <a href="#link2H_4_0008"> VI. ERNST HAECKEL AND THE NEW ZOOLOGY </a> + </p> + <p class="toc"> + <a href="#link2H_4_0009"> VII. SOME MEDICAL LABORATORIES AND MEDICAL + PROBLEMS </a> + </p> + <p class="toc"> + <a href="#link2H_4_0010"> VII. SOME UNSOLVED SCIENTIFIC PROBLEMS + </a> + </p> + <p class="toc"> + <a href="#link2H_4_0011"> IX. RETROSPECT AND PROSPECT </a> + </p> + <p class="toc"> + <a href="#link2H_APPE"> APPENDIX </a> + </p> + </td> + </tr> + </table> + <p> + <a name="link2H_4_0001" id="link2H_4_0001"> + <!-- H2 anchor --> </a> + </p> + <div style="height: 4em;"> + <br /><br /><br /><br /> + </div> + <h2> + A HISTORY OF SCIENCE—BOOK V + </h2> + <p> + <a name="link2H_4_0002" id="link2H_4_0002"> + <!-- H2 anchor --> </a> + </p> + <div style="height: 4em;"> + <br /><br /><br /><br /> + </div> + <h2> + ASPECTS OF RECENT SCIENCE + </h2> + <p> + STUDENTS of the classics will recall that the old Roman historians were + accustomed to detail the events of the remote past in what they were + pleased to call annals, and to elaborate contemporary events into + so-called histories. Actuated perhaps by the same motives, though with no + conscious thought of imitation, I have been led to conclude this history + of the development of natural science with a few chapters somewhat + different in scope and in manner from the ones that have gone before. + </p> + <p> + These chapters have to do largely with recent conditions. Now and again, + to be sure, they hark back into the past, as when they tell of the origin + of such institutions as the British Museum, the Royal Society, and the + Royal Institution; or when the visitor in modern Jena imagines himself + transplanted into the Jena of the sixteenth century. But these reminiscent + moods are exceptional. Our chief concern is with strictly contemporary + events—with the deeds and personalities of scientific investigators + who are still in the full exercise of their varied powers. I had thought + that such outlines of the methods of contemporary workers, such glimpses + of the personalities of living celebrities, might form a fitting + conclusion to this record of progress. There is a stimulus in contact with + great men at first hand that is scarcely to be gained in like degree in + any other way. So I have thought that those who have not been privileged + to visit the great teachers in person might like to meet some of them at + second hand. I can only hope that something of the enthusiasm which I have + gained from contact with these men may make itself felt in the succeeding + pages. + </p> + <p> + It will be observed that these studies of contemporary workers are + supplemented with a chapter in which a hurried review is taken of the + field of cosmical, of physical, and of biological science, with reference + to a few of the problems that are still unsolved. As we have noted the + clearing up of mystery after mystery in the past, it may be worth our + while in conclusion thus to consider the hordes of mysteries which the + investigators of our own age are passing on to their successors. For the + unsolved problems of to-day beckon to the alluring fields of to-morrow. + </p> + <p> + <a name="link2H_4_0003" id="link2H_4_0003"> + <!-- H2 anchor --> </a> + </p> + <div style="height: 4em;"> + <br /><br /><br /><br /> + </div> + <h2> + I. THE BRITISH MUSEUM + </h2> + <p> + IN the year 1753 a remarkable lottery drawing took place in London. It was + authorized, through Parliament, by "his gracious Majesty" King George the + Second. Such notables as the archbishop of Canterbury and the lord + chancellor of the realm took official interest in its success. It was + advertised far and wide—as advertising went in those days—in + the <i>Gazette</i>, and it found a host of subscribers. Of the fifty + thousand tickets—each costing three pounds—more than four + thousand were to be of the class which the act of Parliament naively + describes as "fortunate tickets." The prizes aggregated a hundred thousand + pounds. + </p> + <p> + To be sure, state lotteries were no unique feature in the England of that + day. They formed as common a method of raising revenue in the island realm + of King George II. as they still do in the alleged continental portion of + his realm, France, and in the land of his nativity, Germany. Indeed, the + particular lottery in question was to be officered by the standing + committee on lotteries, whose official business was to "secure two and a + half million pounds for his Majesty" by this means. But the great lottery + of 1754 had interest far beyond the common run, for it aimed to meet a + national need of an anomalous kind—a purely intellectual need. The + money which it was expected to bring was to be used to purchase some + collections of curiosities and of books that had been offered the + government, and to provide for their future care and disposal as a public + trust for the benefit and use of the people. The lottery brought the + desired money as a matter of course, for the "fool's tax" is the one form + of revenue that is paid without stint and without grumbling. Almost fifty + thousand pounds remained in the hands of the archbishop of Canterbury and + his fellow-trustees after the prizes were paid. And with this sum the + institution was founded which has been increasingly famous ever since as + the British Museum. + </p> + <p> + The idea which had this splendid result had originated with Sir Hans + Sloane, baronet, a highly respected practising physician of Chelsea, who + had accumulated a great store of curios, and who desired to see the + collection kept intact and made useful to the public after his death. + Dying in 1753, this gentleman had directed in his will that the collection + should be offered to the government for the sum of twenty thousand pounds; + it had cost him fifty thousand pounds. The government promptly accepted + the offer—as why should it not, since it had at hand so easy a means + of raising the necessary money? It was determined to supplement the + collection with a library of rare books, for which ten thousand pounds was + to be paid to the Right Honorable Henrietta Cavendish Holies, Countess of + Oxford and Countess Mortimer, Relict of Edward, Earl of Oxford and Earl + Mortimer, and the Most Noble Margaret Cavendish, Duchess of Portland, + their only daughter. + </p> + <p> + The purchases were made and joined with the Cottonian library, which was + already in hand. A home was found for the joint collection, along with + some minor ones, in Montague Mansion, on Great Russell Street, and the + British Museum came into being. Viewed retrospectively, it seems a small + affair; but it was a noble collection for its day; indeed, the Sloane + collection of birds and mammals had been the finest private natural + history collection in existence. But, oddly enough, the weak feature of + the museum at first was exactly that feature which has been its strongest + element in more recent years—namely, the department of antiquities. + This department was augmented from time to time, notably by the + acquisition of the treasures of Sir William Hamilton in 1773; but it was + not till the beginning of the nineteenth century that the windfall came + which laid the foundation for the future incomparable greatness of the + museum as a repository of archaeological treasures. + </p> + <p> + In that memorable year the British defeated the French at Alexandria, and + received as a part of the conqueror's spoils a collection of Egyptian + antiquities which the savants of Napoleon's expedition had gathered and + carefully packed, and even shipped preparatory to sending them to the + Louvre. The feelings of these savants may readily be imagined when, + through this sad prank of war, their invaluable treasures were envoyed, + not to their beloved France, but to the land of their dearest enemies, + there to be turned over to the trustees of the British Museum. + </p> + <p> + The museum authorities were not slow to appreciate the value of the + treasures that had thus fallen into their hands, yet for the moment it + proved to them something of a white elephant. Montague Mansion was already + crowded; moreover, its floors had never been intended to hold such heavy + objects, so it became imperatively necessary to provide new quarters for + the collection. This was done in 1807 by the erection of a new building on + the old site. But the trustees of that day failed to gauge properly the + new impulse to growth that had come to the museum with the Egyptian + antiquities, for the new building was neither in itself sufficient for the + needs of the immediate future nor yet so planned as to be susceptible of + enlargement with reasonable architectural effect. The mistakes were soon + apparent, but, despite various tentatives and "meditatings," fourteen + years elapsed before the present magnificent building was planned. The + construction, wing by wing, began in 1823, but it was not until 1846 that + the last vestige of the old museum buildings had vanished, and in their + place, spreading clear across the spacious site, stood a structure really + worthy of the splendid collection for which it was designed. + </p> + <p> + But no one who sees this building to-day would suspect its relative youth. + Half a century of London air can rival a cycle of Greece or Italy in + weathering effect, and the fine building of the British Museum frowns out + at the beholder to-day as grimy and ancient-seeming as if its massive + columns dated in fact from the old Grecian days which they recall. + Regardless of age, however, it is one of the finest and most massive + specimens of Ionic architecture in existence. Forty-four massive columns, + in double tiers, form its frontal colonnade, jutting forward in a wing at + either end. The flight of steps leading to the central entrance is in + itself one hundred and twenty-five feet in extent; the front as a whole + covers three hundred and seventy feet. Capping the portico is a sculptured + tympanum by Sir Richard Westmacott, representing the "Progress of + Civilization" not unworthily. As a whole, the building is one of the few + in London that are worth visiting for an inspection of their exterior + alone. It seems admirably designed to be, as it is, the repository of one + of the finest collections of Oriental and classical antiquities in the + world. + </p> + <p> + There is an air of repose about the <i>ensemble</i> that is in itself + suggestive of the Orient; and the illusion is helped out by the pigeons + that flock everywhere undisturbed about the approaches to the building, + fluttering to be fed from the hand of some recognized friend, and scarcely + evading the feet of the casual wayfarer. With this scene before him, if + one will close his ears to the hum of the great city at his back he can + readily imagine himself on classical soil, and, dreaming of Greece and + Italy, he will enter the door quite prepared to find himself in the midst + of antique marbles and the atmosphere of by-gone ages. + </p> + <p> + I have already pointed out that the turning-point in the history of the + British Museum came just at the beginning of the century, with the + acquisition of the Egyptian antiquities. With this the institution threw + off its swaddling-clothes. Hitherto it had been largely a museum of + natural history; in future, without neglecting this department, it was to + become equally important as a museum of archaeology. The Elgin marbles, + including the wonderful Parthenon frieze, confirmed this character, and it + was given the final touch by the reception, about the middle of the + century, of the magnificent Assyrian collection just exhumed at the seat + of old Nineveh by Mr. (afterwards Sir Henry) Layard. Since then these + collections, with additions of similar character, have formed by far the + most important feature of the British Museum. But in the mean time + archaeology has become a science. + </p> + <p> + Within recent years the natural history collection has been removed <i>in + toto</i> from the old building to a new site far out in South Kensington, + and the casual visitor is likely to think of it as a separate institution. + The building which it occupies is very modern in appearance as in fact. It + is a large and unquestionably striking structure, and one that gives + opportunity for very radical difference of opinion as to its architectural + beauty. By some it is much admired; by others it is almost equally scoffed + at. Certain it is that it will hardly bear comparison with the parent + building in Great Russell Street. + </p> + <p> + Interiorly, the building of the natural history museum is admirably + adapted for its purpose. Its galleries are for the most part well lighted, + and the main central hall is particularly well adapted for an exhibition + of specimens, to which I shall refer more at length in a moment. For the + rest there is no striking departure from the conventional. Perhaps it is + not desired that there should be, since long experience seems to have + settled fairly well the problem of greatest economy of space, combined + with best lighting facilities, which always confronts the architect in + founding a natural history museum. + </p> + <p> + There is, however, one striking novel feature in connection with the + structure of the natural history museum at Kensington which must not be + overlooked. This is the quite unprecedented use of terra-cotta + ornamentation. Without there is a striking display of half-decorative and + half-realistic forms; while within the walls and pillars everywhere are + covered with terracotta bas-reliefs representing the various forms of life + appropriate to the particular department of the museum which they + ornament. This very excellent feature might well be copied elsewhere, and + doubtless will be from time to time. + </p> + <p> + As to the exhibits proper within the museum, it may be stated in a word + that they cover the entire range of the faunas and floras of the globe in + a variety and abundance of specimens that are hardly excelled anywhere, + and only duplicated by one or two other collections in Europe and two or + three in America. + </p> + <p> + It would be but a reiteration of what the catalogues of all large + collections exhibit were one to enumerate the various forms here shown, + but there are two or three exhibits in this museum which are more novel + and which deserve special mention. One of these is to be found in a set of + cases in the main central hall. Here are exhibited, in a delightfully + popular form, some of the lessons that the evolutionist has taught us + during the last half-century. Appropriately enough, a fine marble statue + of Darwin, whose work is the fountain-head of all these lessons, is placed + on the stairway just beyond, as if to view with approval this beautiful + exemplification of his work. + </p> + <p> + One of these cases illustrates the variations of animals under + domestication, the particular specimens selected being chiefly the + familiar pigeon, in its various forms, and the jungle-fowl with its + multiform domesticated descendants. + </p> + <p> + Another case illustrates very strikingly the subject of protective + coloration of animals. Two companion cases are shown, each occupied by + specimens of the same species of birds and animals—in one case in + their summer plumage and pelage and in the other clad in the garb of + winter. The surroundings in the case have, of course, been carefully + prepared to represent the true environments of the creatures at the + appropriate seasons. The particular birds and animals exhibited are the + willow-grouse, the weasel, and a large species of hare. All of these, in + their summer garb, have a brown color, which harmonizes marvellously with + their surroundings, while in winter they are pure white, to match the snow + that for some months covers the ground in their habitat. + </p> + <p> + The other cases of this interesting exhibit show a large variety of birds + and animals under conditions of somewhat abnormal variation, in the one + case of albinism and the other of melanism. These cases are, for the + casual visitor, perhaps the most striking of all, although, of course, + they teach no such comprehensive lessons as the other exhibits just + referred to. + </p> + <p> + The second of the novel exhibits of the museum to which I wish to refer is + to be found in a series of alcoves close beside the central cases in the + main hallway. + </p> + <p> + Each of these alcoves is devoted to a class of animals—one to + mammals, one to birds, one to fishes, and so on. In each case very + beautiful sets of specimens have been prepared, illustrating the anatomy + and physiology of the group of animals in question. Here one may see, for + example, in the alcove devoted to birds, specimens showing not only + details of the skeleton and muscular system, but the more striking + examples of variation of form of such members as the bill, legs, wings, + and tails. Here are preparations also illustrating, very strikingly, the + vocal apparatus of birds. Here, again, are finely prepared wings, in which + the various sets of feathers have been outlined with different-colored + pigments, so that the student can name them at a glance. In fact, every + essential feature of the anatomy of the bird may be studied here as in no + other collection that I know of. And the same is true of each of the other + grand divisions of the animal kingdom. This exhibit alone gives an + opportunity for the student of natural history that is invaluable. It is + quite clear to any one who has seen it that every natural history museum + must prepare a similar educational exhibit before it can claim to do full + justice to its patrons. + </p> + <p> + A third feature that cannot be overlooked is shown in the numerous cases + of stuffed birds, in which the specimens are exhibited, not merely by + themselves on conventional perches, but amid natural surroundings, usually + associated with their nests and eggs or young. These exhibits have high + artistic value in addition to their striking scientific worth. They teach + ornithology as it should be taught, giving such clews to the recognition + of birds in the fields as are not at all to be found in ordinary + collections of stuffed specimens. This feature of the museum has, to be + sure, been imitated in the American Museum of Natural History in New York, + but the South Kensington Museum was the first in the field and is still + the leader. + </p> + <p> + A few words should be added as to the use made by the public of the + treasures offered for their free inspection by the British Museum. I shall + attempt nothing further than a few data regarding actual visits to the + museum. In the year 1899 the total number of such visits aggregated + 663,724; in 1900 the figures rise to 689,249—well towards + three-quarters of a million. The number of visits is smallest in the + winter months, but mounts rapidly in April and May; it recedes slightly + for June and July, and then comes forward to full tide in August, during + which month more than ninety-five thousand people visited the museum in + 1901, the largest attendance in a single day being more than nine + thousand. August, of course, is the month of tourists—particularly + of tourists from America—but it is interesting and suggestive to + note that it is not the tourist alone who visits the British Museum, for + the flood-tide days of attendance are always the Bank holidays, including + Christmas boxing-day and Easter Monday, when the working-people turn out + <i>en masse</i>. On these days the number of visits sometimes mounts above + ten thousand. + </p> + <p> + All this, it will be understood, refers exclusively to the main building + of the museum on Great Russell Street. But, meantime, out in Kensington, + at the natural history museum, more than half a million visits each year + are also made. In the aggregate, then, about a million and a quarter of + visits are paid to the British Museum yearly, and though the bulk of the + visitors may be mere sight-seers, yet even these must carry away many + ideas of value, and it hardly requires argument to show that, as a whole, + the educational influence of the British Museum must be enormous. Of its + more direct stimulus to scientific work through the trained experts + connected with the institution I shall perhaps speak in another + connection. + </p> + <p> + <a name="link2H_4_0004" id="link2H_4_0004"> + <!-- H2 anchor --> </a> + </p> + <div style="height: 4em;"> + <br /><br /><br /><br /> + </div> + <h2> + II. THE ROYAL SOCIETY OF LONDON FOR IMPROVING NATURAL KNOWLEDGE + </h2> + <p> + A SESSION OF THE SOCIETY + </p> + <p> + THERE is one scientific institution in London more venerable and more + famous even than the British Museum. This, of course, is the Royal + Society, a world-famous body, whose charter dates from 1662, but whose + actual sessions began at Gresham College some twenty years earlier. One + can best gain a present-day idea of this famous institution by attending + one of its weekly meetings in Burlington House, Piccadilly—a great, + castle-like structure, which serves also as the abode of the Royal + Chemical Society and the Royal Academy of Arts. The formality of an + invitation from a fellow is required, but this is easily secured by any + scientific visitor who may desire to attend the meeting. The programme of + the meeting each week appears in that other great British institution, the + <i>Times</i>, on Tuesdays. + </p> + <p> + The weekly meeting itself is held on Thursday afternoon at half-past four. + As one enters the door leading off the great court of Burlington House a + liveried attendant motions one to the rack where great-coat and hat may be + left, and without further ceremony one steps into the reception-room + unannounced. It is a middle-sized, almost square room, pillared and formal + in itself, and almost without furniture, save for a long temporary table + on one side, over which cups of tea are being handed out to the guests, + who cluster there to receive it, and then scatter about the room to sip it + at their leisure. We had come to hear a lecture and had expected to be + ushered into an auditorium; but we had quite forgotten that this is the + hour when all England takes its tea, the <i>élite</i> of the scientific + world, seemingly, quite as much as the devotees of another kind of + society. Indeed, had we come unawares into this room we should never have + suspected that we had about us other than an ordinary group of cultured + people gathered at a conventional "tea," except, indeed, that suspicion + might be aroused by the great preponderance of men—there being only + three or four women present—and by the fact that here and there a + guest appears in unconventional dress—a short coat or even a velvet + working-jacket. For the rest there is the same gathering into clusters of + three or four, the same inarticulate clatter of many voices that mark the + most commonplace of gatherings. + </p> + <p> + But if one will withdraw to an inoffensive corner and take a critical view + of the assembly, he will presently discover that many of the faces are + familiar to him, although he supposed himself to be quite among strangers. + The tall figure, with the beautiful, kindly face set in white hair and + beard, has surely sat for the familiar portrait of Alfred Russel Wallace. + This short, thick-set, robust, business-like figure is that of Sir Norman + Lockyer. Yonder frail-seeming scholar, with white beard, is surely + Professor Crookes. And this other scholar, with tall, rather angular frame + and most kindly gleam of eye, is Sir Michael Foster; and there beyond is + the large-seeming though not tall figure, and the round, rosy, + youthful-seeming, beautifully benevolent face of Lord Lister. "What! a + real lord there?" said a little American girl to whom I enumerated the + company after my first visit to the Royal Society. "Then how did he act? + Was he very proud and haughty, as if he could not speak to other people?" + And I was happy to be able to reply that though Lord Lister, perhaps of + all men living, would be most excusable did he carry in his manner the + sense of his achievements and honors, yet in point of fact no man could + conceivably be more free from any apparent self-consciousness. As one + watches him now he is seen to pass from group to group with cordial + hand-shake and pleasant word, clearly the most affable of men, lord though + he be, and president of the Royal Society, and foremost scientist of his + time. + </p> + <p> + Presently an attendant passed through the tearoom bearing a tremendous + silver mace, perhaps five feet long, surmounted by a massive crown and + cross, and looking like nothing so much as a "gigantic war-club." This is + the mace which, when deposited on the president's desk in the lecture-room + beyond, will signify that the society is in session. "It is the veritable + mace," some one whispers at your elbow, "concerning which Cromwell gave + his classical command to 'Remove that bauble.'" But since the mace was not + made until 1663, some five years after Cromwell's death, this account may + lack scientific accuracy. Be that as it may, this mace has held its own + far more steadily than the fame of its alleged detractor, and its + transportation through the tea-room is the only manner of announcement + that the lecture is about to open in the hall beyond. Indeed, so + inconspicuous is the proceeding, and so quietly do the members that choose + to attend pass into the lecture-hall, leaving perhaps half the company + engaged as before, that the "stranger "—as the non-member is here + officially designated—might very readily fail to understand that the + séance proper had begun. In any event, he cannot enter until permission + has been formally voted by the society. + </p> + <p> + When he is allowed to enter he finds the meeting-room little different + from the one he has left, except that it is provided with a sort of throne + on a raised platform at one end and with cushioned benches for seats. On + the throne, if one may so term it, sits Lord Lister, scarcely more than + his head showing above what seems to be a great velvet cushion which + surmounts his desk, at the base of which, in full view of the society, + rests the mace, fixing the eye of the "stranger," as it is alleged to have + fixed that of Cromwell aforetime, with a peculiar fascination. On a lower + plane than the president, at his right and left, sit Sir Michael Foster + and Professor Arthur William Rucker, the two permanent secretaries. At Sir + Michael's right, and one stage nearer the audience, stands the lecturer, + on the raised platform and behind the desk which extends clear across the + front of the room. As it chances, the lecturer this afternoon is Professor + Ehrlich, of Berlin and Frankfort-on-the-Main, who has been invited to + deliver the Croonian lecture. He is speaking in German, and hence most of + the fellows are assisting their ears by following the lecture in a printed + translation, copies of which, in proof, were to be secured at the door. + </p> + <p> + The subject of the lecture is "Artificial Immunization from Disease." It + is clear that the reader is followed with interested attention, which now + and again gives rise to a subdued shuffle of applause. + </p> + <p> + The fact that the lecturer is speaking German serves perhaps to suggest + even more vividly than might otherwise occur to one the contrast between + this meeting and a meeting of the corresponding German society—the + Royal Academy of Sciences at Berlin. Each is held in an old building of + palatial cast and dimensions, of which Burlington House, here in + Piccadilly, is much the older—dating from 1664—although its + steam-heating and electric-lighting apparatus, when contrasted with the + tile stoves and candles of the other, would not suggest this. For the + rest, the rooms are not very dissimilar in general appearance, except for + the platform and throne. But there the members of the society are shut off + from the audience both by the physical barrier of the table and by the + striking effect of their appearance in full dress, while here the fellows + chiefly compose the audience, there being only a small company of + "strangers" present, and these in no way to be distinguished by dress or + location from the fellows themselves. It may be added that the custom of + the French Academy of Sciences is intermediate between these two. There + the visitors occupy seats apart, at the side of the beautiful hall, the + main floor being reserved for members. But the members themselves are not + otherwise distinguishable, and they come and go and converse together even + during the reading of a paper almost as if this were a mere social + gathering. As it is thus the least formal, the French meeting is also by + far the most democratic of great scientific gatherings. Its doors are open + to whoever may choose to enter. The number who avail themselves of this + privilege is not large, but it includes, on occasions, men of varied + social status and of diverse races and colors—none of whom, so far + as I could ever discern, attracts the slightest attention. + </p> + <p> + At the German meeting, again, absolute silence reigns. No one thinks of + leaving during the session, and to make any sound above a sigh would seem + almost a sacrilege. But at the Royal Society an occasional auditor goes or + comes, there are repeated audible signs of appreciation of the speaker's + words, and at the close of the discourse there is vigorous and prolonged + applause. There is also a debate, of the usual character, announced by the + president, in which "strangers" are invited to participate, and to which + the lecturer finally responds with a brief <i>Nachwort</i>, all of which + is quite anomalous from the German or French stand-points. After that, + however, the meeting is declared adjourned with as little formality in one + case as in the others, and the fellows file leisurely out, while the + attendant speedily removes the mace, in official token that the séance of + the Royal Society is over. + </p> + <p> + THE LIBRARY AND READING-ROOM + </p> + <p> + But the "stranger" must not leave the building without mounting to the + upper floor for an inspection of the library and reading-room. The rooms + below were rather bare and inornate, contrasting unfavorably with the + elegant meeting-room of the French institute. But this library makes full + amends for anything that the other rooms may lack. It is one of the most + charming—"enchanting" is the word that the Princess Christian is + said to have used when she visited it recently—and perhaps quite the + most inspiring room to be found in all London. It is not very large as + library rooms go, but high, and with a balcony supported by Corinthian + columns. The alcoves below are conventional enough, and the high tables + down the centre, strewn with scientific periodicals in engaging disorder, + are equally conventional. But the color-scheme of the decorations—sage-green + and tawny—is harmonious and pleasing, and the effect of the whole is + most reposeful and altogether delightful. + </p> + <p> + Chief distinction is given the room, however, by a row of busts on either + side and by certain pieces of apparatus on the centre tables. + </p> + <p> + The busts, as will readily be surmised, are portraits of distinguished + fellows of the Royal Society. There is, however, one exception to this, + for one bust is that of a woman—Mary Somerville, translator of the + <i>Mécanique Céleste</i>, and perhaps the most popular of the scientific + writers of her time. It is almost superfluous to state that the row of + busts begins with that of Newton. The place of honor opposite is held by + that of Faraday. Encircling the room to join these two one sees, among + others, the familiar visages of Dr. Gilbert; of Sir Joseph Banks, the + famous surgeon of the early nineteenth century, who had the honor of being + the only man that ever held the presidential chair of the Royal Society + longer than it was held by Newton; of James Watts, of "steam-engine" fame; + of Sabine, the astronomer, also a president of the society; and of Dr. + Falconer and Sir Charles Lyell, the famous geologists. + </p> + <p> + There are numerous other busts in other rooms, some of them stowed away in + nooks and crannies, and the list of those selected for the library does + not, perhaps, suggest that this is the room of honor, unless, indeed, the + presence of Newton and Faraday gives it that stamp. But in the presence of + the images of these two, and of Lyell, to go no farther, one feels a + certain sacredness in the surroundings. + </p> + <p> + If this is true of the mere marble images, what shall we say of the + emblems on the centre table? That little tubular affair, mounted on a + globe, the whole cased in a glass frame perhaps two feet high, is the + first reflecting telescope ever made, and it was shaped by the hand of + Isaac Newton. The brass mechanism at the end of the next table is the + perfected air-pump of Robert Boyle, Newton's contemporary, one of the + founders of the Royal Society and one of the most acute scientific minds + of any time. And here between these two mementos is a higher apparatus, + with crank and wheel and a large glass bulb that make it conspicuous. This + is the electrical machine of Joseph Priestley. There are other mementos of + Newton—a stone graven with a sun-dial, which he carved as a boy, on + the paternal manor-house; a chair, said to have been his, guarded here by + a silk cord against profanation; bits of the famous apple-tree which, as + tradition will have it, aided so tangibly in the greatest of discoveries; + and the manuscript of the <i>Principia</i> itself—done by the hand + of an amanuensis, to be sure, but with interlinear corrections in the + small, clear script of the master-hand itself. Here, too, is the famous + death-mask, so much more interesting than any sculptured portrait, and + differing so strangely in its broad-based nose and full, firm mouth from + the over-refined lineaments of the sculptured bust close at hand. In a + room not far away, to reach which one passes a score or two of portraits + and as many busts of celebrities—including, by-the-bye, both bust + and portrait of Benjamin Franklin—one finds a cabinet containing + other mementos similar to those on the library tables. Here is the first + model of Davy's safety-lamp; there a chronometer which aided Cook in his + famous voyage round the world. This is Wollaston's celebrated "Thimble + Battery." It will slip readily into the pocket, yet he jestingly showed it + to a visitor as "his entire laboratory." That is a model of the + double-decked boat made by Sir William Petty, and there beyond is a + specimen of almost, if not quite, the first radiometer devised by Sir + William Crookes. + </p> + <p> + As one stands in the presence of all these priceless relics, so vividly do + the traditions of more than two centuries of science come to mind that one + seems almost to have lived through them. One recalls, as if it were a + personal recollection, the founding of the Royal Society itself in 1662, + and the extraordinary scenes which the society witnessed during the years + of its adolescence. + </p> + <p> + As one views the mementos of Boyle and Newton, one seems to be living in + the close of the seventeenth century. It is a troublous time in England. + Revolution has followed revolution. Commonwealth has supplanted monarchy + and monarchy commonwealth. At last the "glorious revolution" of 1688 has + placed a secure monarch on the throne. But now one external war follows + another, and the new king, William of Orange, is leading the "Grand + Alliance" against the French despot Louis XIV. There is war everywhere in + Europe, and the treaty of Ryswick, in 1697, is but the preparation for the + war of the Spanish Alliance, which will usher in the new century. But amid + all this political turmoil the march of scientific discovery has gone + serenely on; or, if not serenely, then steadily, and perhaps as serenely + as could be hoped. Boyle has discovered the law of the elasticity of gases + and a host of minor things. Robert Hooke is on the track of many marvels. + But all else pales before the fact that Newton has just given to the world + his marvellous law of gravitation, which has been published, with + authority of the Royal Society, through the financial aid of Halley. The + brilliant but erratic Hooke lias contested the priority of discovery and + strenuously claimed a share in it. Halley eventually urges Newton to + consider Hooke's claim in some of the details, and Newton yields to the + extent of admitting that the great fact of gravitational force varying + inversely as the square of the distance had been independently discovered + by Hooke; but he includes also Halley himself and Sir Christopher Wren, + along with Hooke, as equally independent discoverers of the same + principle. To the twentieth-century consciousness it seems odd to hear + Wren thus named as a scientific discoverer; but in truth the builder of + St. Paul's began life as a professor of astronomy at Gresham College, and + was the immediate predecessor of Newton himself in the presidential chair + of the Royal Society. Now, at the very close of the seventeenth century, + Boyle is recently dead, but Hooke, Wren, Halley, and Newton still survive: + some of them are scarcely past their prime. It is a wonderful galaxy of + stars of the first magnitude, and even should no other such names come in + after-time, England's place among the scientific constellations is secure. + </p> + <p> + But now as we turn to the souvenirs of Cooke and Wollaston and Davy the + scene shifts by a hundred years. We are standing now in the closing epoch + of the eighteenth century. These again are troublous times. The great new + colony in the West has just broken off from the parent swarm. Now all + Europe is in turmoil. The French war-cloud casts its ominous shadow + everywhere. Even in England mutterings of the French Revolution are not + without an echo. The spirit of war is in the air. And yet, as before, the + spirit of science also is in the air. The strain of the political + relations does not prevent a perpetual exchange of courtesy between + scientific men and scientific bodies of various nations. Davy's dictum + that "science knows no country" is perpetually exemplified in practice. + And at the Royal Society, to match the great figures that were upon the + scene a century before, there are such men as the eccentric Cavendish, the + profound Wollaston, the marvellously versatile Priestley, and the equally + versatile and even keener-visioned Rumford. Here, too, are Herschel, who + is giving the world a marvellous insight into the constitution of the + universe; and Hutton, who for the first time gains a clear view of the + architecture of our earth's crust; and Jenner, who is rescuing his + fellow-men from the clutches of the most deadly of plagues; to say nothing + of such titanic striplings as Young and Davy, who are just entering the + scientific lists. With such a company about us we are surely justified in + feeling that the glory of England as a scientific centre has not dimmed in + these first hundred and thirty years of the Royal Society's existence. + </p> + <p> + And now, as we view the radiometer, the scene shifts by yet another + century, and we come out of cloud-land and into our own proper age. We are + at the close of the nineteenth century—no, I forget, we are fairly + entering upon the twentieth. Need I say that these again are troublous + times? Man still wages warfare on his fellow-man as he has done time out + of mind; as he will do—who shall say how long? But meantime, as of + yore, the men of science have kept steadily on their course. But recently + here at the Royal Society were seen the familiar figures of Darwin and + Lyell and Huxley and Tyndall. Nor need we shun any comparison with the + past while the present lists can show such names as Wallace, Kelvin, + Lister, Crookes, Foster, Evans, Rayleigh, Ramsay, and Lock-yer. What + revolutionary advances these names connote! How little did those great men + of the closing decades of the seventeenth and eighteenth centuries know of + the momentous truths of organic evolution for which the names of Darwin + and Wallace and Huxley stand! How little did they know a century ago, + despite Hutton's clear prevision, of these marvellous slow revolutions + through which, as Lyell taught us, the earth's crust had been built up! + Not even Jen-ner could foresee a century ago the revolution in surgery + which has been effected in our generation through the teachings of Lister. + </p> + <p> + And what did Rumford and Davy know of energy in its various manifestations + as compared with the knowledge of to-day, of Crookes and Rayleigh and + Ramsay and Kelvin? What would Joseph Priestley, the discoverer of oxygen, + and Cavendish, the discoverer of nitrogen, think could they step into the + laboratory of Professor Ramsay and see test-tubes containing argon and + helium and krypton and neon and zenon? Could they more than vaguely + understand the papers contributed in recent years to the Royal Society, in + which Professor Ramsay explains how these new constituents of the + atmosphere are obtained by experiments on liquid air. "Here," says + Professor Ramsay, in effect, in a late paper to the society, "is the + apparatus with which we liquefy hydrogen in order to separate neon from + helium by liquefying the former while the helium still remains gaseous." + Neon, helium, liquid air, liquid hydrogen—these would seem strange + terms to the men who on discovering oxygen and nitrogen named them + "dephlogisticated air" and "phlogisti-cated air" respectively. + </p> + <p> + Again, how elementary seems the teaching of Her-schel, wonderful though it + was in its day, when compared with our present knowledge of the sidereal + system as outlined in the theories of Sir Norman Lock-yer. Herschel + studied the sun-spots, for example, with assiduity, and even suggested a + possible connection between sun-spots and terrestrial weather. So far, + then, he would not be surprised on hearing the announcement of Professor + Lockyer's recent paper before the Royal Society on the connection between + sun-spots and the rainfall in India. But when the paper goes on to speak + of the actual chemical nature of the sun-spots, as tested by a + spectroscope; to tell of a "cool" stage when the vapor of iron furnishes + chief spectrum lines, and of a "hot" stage when the iron has presumably + been dissociated into unknown "proto-iron" constituents—then indeed + does it go far beyond the comprehension of the keenest eighteenth-century + intellect, though keeping within the range of understanding of the mere + scientific tyro of to-day. + </p> + <p> + Or yet again, consider a recent paper contributed by Professor Lockyer to + the Royal Society, entitled "The New Star in Perseus: Preliminary Note"—referring + to the new star that flashed suddenly on the vision of the terrestrial + observers at more than first magnitude on February 22, 1901. This "star," + the paper tells us, when studied by its spectrum, is seen to be due to the + impact of two swarms of meteors out in space—swarms moving in + different directions "with a differential velocity of something like seven + hundred miles a second." Every astronomer of to-day understands how such a + record is read from the displacement of lines on the spectrum, as recorded + on the photographic negative. But imagine Sir William Herschel, roused + from a century's slumber, listening to this paper, which involves a + subject of which he was the first great master. "Ebulae," he might say; + "yes, they were a specialty of mine; but swarms of meteors—I know + nothing of these. And 'spectroscopes,' 'photographs'—what, pray, are + these? In my day there were no such words or things as spectroscope and + photograph; to my mind these words convey no meaning." + </p> + <p> + But why go farther? These imaginings suffice to point a moral that he who + runs may read. Of a truth the march of science still goes on as it has + gone on with steady tread throughout the long generations of the Royal + Society's existence. If the society had giants among its members in the + days of its childhood and adolescence, no less are there giants still to + keep up its fame in the time of its maturity. The place of England among + the scientific constellations is secure through tradition, but not through + tradition alone. + </p> + <p> + <a name="link2H_4_0005" id="link2H_4_0005"> + <!-- H2 anchor --> </a> + </p> + <div style="height: 4em;"> + <br /><br /><br /><br /> + </div> + <h2> + III. THE ROYAL INSTITUTION AND THE LOW-TEMPERATURE RESEARCHES + </h2> + <p> + FOUNDATION AND FOUNDER + </p> + <p> + "GEORGE THE THIRD, by the Grace of God King of Great Britain, France, and + Ireland, Defender of the Faith, etc., to all to whom these presents shall + come, greeting. Whereas several of our loving subjects are desirous of + forming a Public Institution for diffusing the knowledge and facilitating + the general introduction of Useful Mechanical Inventions and Improvements; + and for teaching, by Courses of Philosophical Lectures and Experiments, + the Application of Science to the Common Purposes of Life, we do hereby + give and grant"—multifarious things which need not here be quoted. + Such are the opening words of the charter with which, a little more than a + century ago, the Royal Institution of Great Britain came into existence + and received its legal christening. If one reads on he finds that the + things thus graciously "given and granted," despite all the official + verbiage, amount to nothing more than royal sanction and approval, but + doubtless that meant more in the way of assuring popular approval than + might at first glimpse appear. So, too, of the list of earls, baronets, + and the like, who appear as officers and managers of the undertaking, and + who are described in the charter as "our right trusty and right + well-beloved cousins," "our right trusty and well-beloved counsellors," + and so on, in the skilfully graduated language of diplomacy. The + institution that had the King for patron and such notables for officers + seemed assured a bright career from the very beginning. In name and in + personnel it had the flavor of aristocracy, a flavor that never palls on + British palate. And right well the institution has fulfilled its promise, + though in a far different way from what its originator and founder + anticipated. + </p> + <p> + Its originator and founder, I say, and say advisedly; for, of course, + here, as always, there is one man who is the true heart and soul of the + movement, one name that stands, in truth, for the whole project, and to + which all the other names are mere appendages. You would never suspect + which name it is, in the present case, from a study of the charter, for it + appears well down the file of graded titles, after "cousins" and + "counsellors" have had their day, and is noted simply as "our trusty and + well-beloved Benjamin, Count of Rumford, of the Holy Roman Empire." Little + as there is to signalize it in the charter, this is the name of the sole + projector of the enterprise in its incipiency, of the projector of every + detail, of the writer of the charter itself even. The establishment thus + launched with royal title might with full propriety have been called, as + indeed it sometimes is called, the Rumford Institution. + </p> + <p> + The man who thus became the founder of this remarkable institution was in + many ways a most extraordinary person. He was an American by birth, and if + not the most remarkable of Americans, he surely was destined to a more + picturesque career than ever fell to the lot of any of his countrymen of + like eminence. Born on a Massachusetts farm, he was a typical "down-east + Yankee," with genius added to the usual shrewd, inquiring mind and native + resourcefulness. He was self-educated and self-made in the fullest sense + in which those terms can be applied. At fourteen he was an unschooled + grocer-lad—Benjamin Thompson by name—in a little New England + village; at forty he was a world-famous savant, as facile with French, + Italian, Spanish, and German as with his native tongue; he had become + vice-president and medallist of the Royal Society, member of the Berlin + National Academy of Science, of the French Institute, of the American + Academy of Science, and I know not what other learned bodies; he had been + knighted in Great Britain after serving there as under-secretary of state + and as an officer; and he had risen in Bavaria to be more than half a king + in power, with the titles, among others, of privy councillor of state, and + head of the war department, lieutenant-general of the Bavarian armies, + holder of the Polish order of St. Stanislas and the Bavarian order of the + White Eagle, ambassador to England and to France, and, finally, count of + the Holy Roman Empire. Once, in a time of crisis, Rumford was actually + left at the head of a council of regency, in full charge of Bavarian + affairs, the elector having fled. The Yankee grocer-boy had become more + than half a king. + </p> + <p> + Never, perhaps, did a man of equal scientific attainments enjoy a + corresponding political power. Never was political power wielded more + justly by any man. + </p> + <p> + For in the midst of all his political and military triumphs, Rumford + remained at heart to the very end the scientist and humanitarian. He + wielded power for the good of mankind; he was not merely a ruler but a + public educator. He taught the people of Bavaria economy and Yankee + thrift. He established kitchens for feeding the poor on a plan that was + adopted all over Europe; but, better yet, he created also workshops for + their employment and pleasure-gardens for their recreation. He actually + banished beggary from the principality. + </p> + <p> + It was in the hope of doing in some measure for London what he had done + for Munich that this large-brained and large-hearted man was led to the + project of the Royal Institution. He first discussed his plans with a + committee of the Society for Alleviating the Condition of the Poor, for it + was the poor, the lower ranks of society, whom he wished chiefly to + benefit. But he knew that to accomplish his object, he must work through + the aristocratic channels; hence the name of the establishment and the + charter with its list of notables. The word institution was selected by + Rumford, after much deliberation, as, on the whole, the least + objectionable title for the establishment, as having a general + inclusiveness not possessed by such words as school or college. Yet in + effect it was a school which Rumford intended to found—a school for + the general diffusion of useful knowledge. There were to be classes for + mechanics, and workshops, kitchens, and model-rooms, where the + "application of science to the useful purposes of life" might be directly + and practically taught; also a laboratory for more technical + investigations, with a "professor" in charge, who should also deliver + popular lectures on science. Finally, there was to be a scientific + library. + </p> + <p> + All these aims were put into effect almost from the beginning. The + necessary funds were supplied solely by popular subscription and by the + sale of lecture tickets (as all funds of the institution have been ever + since), and before the close of the year 1800 Rumford's dream had become + an actuality—as this practical man's dreams nearly always did. The + new machine did not move altogether without friction, of course, but on + the whole all went well for the first few years. The institution had found + a local habitation in a large building in Albemarle Street, the same + building which it still occupies, and for a time Rumford lived there and + gave the enterprise his undivided attention. He appointed the brilliant + young Humphry Davy to the professorship of chemistry, and the even more + wonderful Thomas Young to that of natural philosophy. He saw the workshops + and kitchens and model-rooms in running order—the entire enterprise + fully launched. Then other affairs, particularly an attachment for a + French lady, the widow of the famous chemist Lavoisier (whom he + subsequently married, to his sorrow), called him away from England never + to return. And the first chapter in the history of the Royal Institution + was finished. + </p> + <p> + METHOD AND RESULT + </p> + <p> + Rumford, the humanitarian, gone, a curious change came over the spirit of + the enterprise he had founded. The aristocrats who at first were merely + ballast for the enterprise now made their influence felt. With true + British reserve, they announced their belief that the education of the + masses involved a dangerous political tendency. Hence the mechanics' + school was suspended and the workshops and kitchens abolished; in a word, + the chief ends for which the institution was founded were annulled. The + library and the lectures remained, to be sure, but they were for the + amusement of the rich, not for the betterment of the poor. It was the West + End that made a fad of the institution and a society function of the + lectures of Sydney Smith and of the charming youth Davy. Thus the + institution came to justify its aristocratic title and its regal + patronage; and the poor seemed quite forgotten. + </p> + <p> + But indeed the institution itself was poor enough in these days, after the + first flush of enthusiasm died away, and it is but fair to remember that + without the support of its popular lectures its very existence would have + been threatened. Nor in any event are regrets much in order over the + possible might-have-beens of an institution whose laboratories were the + seat of the physical investigations of Thomas Young, through which the + wave theory of light first gained a footing, and of the brilliant chemical + researches of Davy, which practically founded the science of + electro-chemistry and gave the chemical world first knowledge of a galaxy + of hitherto unknown elements. Through the labors of these men, and through + the popular lecture-courses delivered at the institution by such other + notables of science as Wollaston, Dalton, and Rum-ford, the enterprise had + become world-famous before the close of the first decade of its existence. + </p> + <p> + From that day till this the character of the Royal Institution has not + greatly changed. The enterprise shifted around during its earliest years, + while it was gaining its place in the scheme of things; but once that was + found, like a true British institution it held its course with an inertia + that a mere century of time could not be expected to alter. Rumford was + the sole founder of the enterprise, but it was Davy who gave it the final + and definitive cast. He it was who established the tradition that the + Royal Institution was to be essentially a laboratory for brilliant + original investigations, the investigator to deliver a yearly course of + lectures, but to be otherwise untrammelled. It occupied, and has continued + to occupy, the anomalous position of a school to which pupils are on no + account admitted, and whose professors teach nothing except by a brief + course of lectures to which whoever cares to pay the admission price may + freely enter. + </p> + <p> + But the marvellous results achieved at the Royal Institution have more + than justified the existence of so anomalous an enterprise. Superlatives + are always dangerous, but it may well be doubted whether there is another + single institution in the world where so many novel original discoveries + in physical science have been made as have been brought to light in the + laboratories of the building on Albemarle Street during this first century + of its occupancy; for practically all that is to be credited to Thomas + Young, Humphry Davy, Michael Faraday, and John Tyndall, not to mention + living investigators, is to be credited also to the Royal Institution, + whose professorial chairs these great men have successively occupied. Davy + spent here the best years of his youth and prime. Faraday, his direct + successor, came to the institution in a subordinate capacity as a mere + boy, and was the life of the institution for half a century. Tyndall gave + it forty years of service. What wonder, then, that the Briton speaks of + the institution as the "Pantheon of Science"? + </p> + <p> + If you visit the Royal Institution to-day you will find it in most + exterior respects not unlike what it presumably was a century ago. Its + long, stone front, dinged with age, with its somewhat Pantheon-like + colonnade, has an appearance of dignity rather than of striking + impressiveness. The main entrance, jutting full on the sidewalk, is at the + street level, and the glass door gives hospitable glimpses of the + interior. Entering, one finds himself in a main central hall, at the foot + of the main central staircase. The air of eminent respectability so + characteristic of the British institution is over all; likewise the + pervasive hush of British reserve. But you will not miss also the + atmosphere of sincere if uneffusive British courtesy. + </p> + <p> + At your right, as you mount the stairway, is a large statue of Faraday; on + the wall right ahead is a bronze medallion of Tyndall, placed beneath a + large portrait of Davy. At the turn of the stairs is a marble bust of + Wollaston. Farther on, in hall and library, you will find other busts of + Faraday, other portraits of Davy; portraits of Faraday everywhere, and + various other busts of notables who have had connection with the + institution. You will be shown the lecture-hall where Davy, Faraday, and + Tyndall pronounced their marvellous discourses; the arrangement, the + seats, the cushions even if appearances speak truly, and certainly the + lecture-desk itself, unchanged within the century. You may see the crude + balance, clumsy indeed to modern eyes, with which Davy performed his + wonders. The names and the memories of three great men—Davy, + Faraday, and Tyndall—will be incessantly before you, and the least + impressionable person could not well escape a certain sense of + consecration of his surroundings. The hush that is over everything seems + but fitting. + </p> + <p> + All that is as it should be. But there are other memories connected with + these surroundings which are not so tangibly presented to the senses. For + where, amid all these busts and portraits, is the image of that other + great man, the founder of the institution, the sole originator of the + enterprise which has made possible the aggregation of all these names and + these memories? Where are the remembrances of that extraordinary man whom + the original charter describes as "our well-beloved Benjamin, Count of + Rumford?" Well, you will find a portrait of him, it is true, if you search + far enough, hung high above a doorway in a room with other portraits. But + one finds it hard to escape the feeling that there has been just a + trifling miscarriage of justice in the disposal. Doubtless there was no + such intention, but the truth seems to be that the glamour of the newer + fame of Faraday has dazzled a little the eyes of the rulers of the + institution of the present generation. But that, after all, is a small + matter about which to quibble. There is glory enough for all in the Royal + Institution, and the disposal of busts and portraits is unworthy to be + mentioned in connection with the lasting fame of the great men who are + here in question. It would matter little if there were no portrait at all + of Rumford here, for all the world knows that the Royal Institution itself + is in effect his monument. His name will always be linked in scientific + annals with the names of Young, Davy, Faraday, and Tyndall. And it is + worthy such association, for neither in native genius nor in realized + accomplishments was Rumford inferior to these successors. + </p> + <p> + FROM LIQUID CHLORINE TO LIQUID HYDROGEN + </p> + <p> + Nor is it merely by mutual association with the history of the Royal + Institution that these great names are linked. There was a curious and + even more lasting bond between them in the character of their scientific + discoveries. They were all pioneers in the study of those manifestations + of molecular activity which we now, following Young himself, term energy. + Thus Rumford, Davy, and Young stood almost alone among the prominent + scientists of the world at the beginning of the century in upholding the + idea that heat is not a material substance—a chemical element—but + merely a manifestation of the activities of particles of matter. Rumford's + papers on this thesis, communicated to the Royal Society, were almost the + first widely heralded claims for this then novel idea. Then Davy came + forward in support of Rumford, with his famous experiment of melting ice + by friction. It was perhaps this intellectual affinity that led Rumford to + select Davy for the professorship at the Royal Institution, and thus in a + sense to predetermine the character of the scientific work that should be + accomplished there—the impulse which Davy himself received from + Rum-ford being passed on to his pupil Faraday. There is, then, an + intangible but none the less potent web of association between the + scientific work of Rumford and some of the most important researches that + were conducted at the Royal Institution long years after his death; and + one is led to feel that it was not merely a coincidence that some of + Faraday's most important labors should have served to place on a firm + footing the thesis for which Rumford battled; and that Tyndall should have + been the first in his "beautiful book" called <i>Heat, a Mode of Motion</i>, + to give wide popular announcement to the fact that at last the scientific + world had accepted the proposition which Rumford had vainly demonstrated + three-quarters of a century before. + </p> + <p> + This same web of association extends just as clearly to the most important + work which has been done at the Royal Institution in the present + generation, and which is still being prosecuted there—the work, + namely, of Professor James Dewar on the properties of matter at + excessively low temperatures. Indeed, this work is in the clearest sense a + direct continuation of researches which Davy and Faraday inaugurated in + 1823 and which Faraday continued in 1844. In the former year Faraday, + acting on a suggestion of Davy's, performed an experiment which resulted + in the production of a "clear yellow oil" which was presently proved to be + liquid chlorine. Now chlorine, in its pure state, had previously been + known (except in a forgotten experiment of Northmore's) only as a gas. Its + transmutation into liquid form was therefore regarded as a very startling + phenomenon. But the clew thus gained, other gases were subjected to + similar conditions by Davy, and particularly by Faraday, with the result + that several of them, including sulphurous, carbonic, and hydrochloric + acids were liquefied. The method employed, stated in familiar terms, was + the application of cold and of pressure. The results went far towards + justifying an extraordinary prediction made by that extraordinary man, + John Dalton, as long ago as 1801, to the effect that by sufficient cooling + and compressing all gases might be transformed into liquids—a + conclusion to which Dalton had vaulted, with the sureness of supreme + genius, from his famous studies of the properties of aqueous vapor. + </p> + <p> + Between Dalton's theoretical conclusion, however, and experimental + demonstration there was a tremendous gap, which the means at the disposal + of the scientific world in 1823 did not enable Davy and Faraday more than + partially to bridge. A long list of gases, including the familiar oxygen, + hydrogen, and nitrogen, resisted all their efforts utterly—notwithstanding + the facility with which hydrogen and oxygen are liquefied when combined in + the form of water-vapor, and the relative ease with which nitrogen and + hydrogen, combined to form ammonia, could also be liquefied. Davy and + Faraday were well satisfied of the truth of Dalton's proposition, but they + saw the futility of further efforts to put it into effect until new means + of producing, on the one hand, greater pressures, and, on the other, more + extreme degrees of cold, should be practically available. So the + experiments of 1823 were abandoned. + </p> + <p> + But in 1844 Faraday returned to them, armed now with new weapons, in the + way of better air-pumps and colder freezing mixtures, which the labors of + other workers, chiefly Thilorier, Mitchell, and Natterer, had made + available. With these new means, and without the application of any + principle other than the use of cold and pressure as before, Faraday now + succeeded in reducing to the liquid form all the gases then known with the + exception of six; while a large number of these substances were still + further reduced, by the application of the extreme degrees of cold now + attained, to the condition of solids. The six gases which still proved + intractable, and which hence came to be spoken of as "permanent gases," + were nitrous oxide, marsh gas, carbonic oxide, oxygen, nitrogen, and + hydrogen. + </p> + <p> + These six refractory gases now became a target for the experiments of a + host of workers in all parts of the world. The resources of mechanical + ingenuity of the time were exhausted in the effort to produce low + temperatures on the one hand and high pressures on the other. Thus + Andrews, in England, using the bath of solid carbonic acid and ether which + Thilorier had discovered, and which produces a degree of cold of—80° + Centigrade, applied a pressure of five hundred atmospheres, or nearly four + tons to the square inch, without producing any change of state. Natterer + increased this pressure to two thousand seven hundred atmospheres, or + twenty-one tons to the square inch, with the same negative results. The + result of Andrews' experiments in particular was the final proof of what + Cagniard de la Tour had early suspected and Faraday had firmly believed, + that pressure alone, regardless of temperature, is not sufficient to + reduce a gas to the liquid state. In other words, the fact of a so-called + "critical temperature," varying for different substances, above which a + given substance is always a gas, regardless of pressure, was definitively + discovered. It became clear, then, that before the resistant gases would + be liquefied means of reaching extremely low temperatures must be + discovered. And for this, what was needed was not so much new principles + as elaborate and costly machinery for the application of a principle long + familiar—the principle, namely, that an evaporating liquid reduces + the temperature of its immediate surroundings, including its own + substance. + </p> + <p> + Ingenious means of applying this principle, in connection with the means + previously employed, were developed independently by Pictet in Geneva and + Cailletet in Paris, and a little later by the Cracow professors Wroblewski + and Olzewski, also working independently. Pictet, working on a commercial + scale, employed a series of liquefied gases to gain lower and lower + temperatures by successive stages. Evaporating sulphurous acid liquefied + carbonic acid, and this in evaporating brought oxygen under pressure to + near its liquefaction point; and, the pressure being suddenly released (a + method employed in Faraday's earliest experiments), the rapid expansion of + the compressed oxygen liquefies a portion of its substance. This result + was obtained in 1877 by Pictet and Cailletet almost simultaneously. + Cailletet had also liquefied the newly discovered acetylene gas. Five + years later Wroblewski liquefied marsh gas, and the following year + nitrogen; while carbonic oxide and nitrous oxide yielded to Olzewski in + 1884. Thus forty years of effort had been required to conquer five of + Faraday's refractory gases, and the sixth, hydrogen, still remains + resistant. Hydrogen had, indeed, been seen to assume the form of visible + vapor, but it had not been reduced to the so-called static state—that + is, the droplets had not been collected in an appreciable quantity, as + water is collected in a cup. Until this should be done, the final problem + of the liquefaction of hydrogen could not be regarded as satisfactorily + solved. + </p> + <p> + More than another decade was required to make this final step in the + completion, of Faraday's work. And, oddly enough, yet very fittingly, it + was reserved for Faraday's successor in the chair at the Royal Institution + to effect this culmination. Since 1884 Professor Dewar's work has made the + Royal Institution again the centre of low-temperature research. By means + of improved machinery and of ingenious devices for shielding the substance + operated on from the accession of heat, to which reference will be made + more in detail presently, Professor Dewar was able to liquefy the gas + fluorine, recently isolated by Moussan, and the recently discovered gas + helium in 1897. And in May, 1898, he was able to announce that hydrogen + also had yielded, and for the first time in the history of science that* + elusive substance, hitherto "permanently" gaseous, was held as a tangible + liquid in a cuplike receptacle; and this closing scene of the long + struggle was enacted in the same laboratory in which Faraday performed the + first liquefaction experiment with chlorine just three-quarters of a + century before. + </p> + <p> + It must be noted, however, that this final stage in the liquefaction + struggle was not effected through the use of the principle of evaporating + liquids which has just been referred to, but by the application of a quite + different principle and its elaboration into a perfectly novel method. + This principle is the one established long ago by Joule and Thomson (Lord + Kelvin), that compressed gases when allowed to expand freely are lowered + in temperature. In this well-known principle the means was at hand greatly + to simplify and improve the method of liquefaction of gases, only for a + long time no one recognized the fact. Finally, however, the idea had + occurred to two men almost simultaneously and quite independently. One of + these was Professor Linde, the well-known German experimenter with + refrigeration processes; the other, Dr. William Hampson, a young English + physician. Each of these men conceived the idea—and ultimately + elaborated it in practice—of accumulating the cooling effect of an + expanding gas by allowing the expansion to take place through a small + orifice into a chamber in which the coil containing the compressed gas was + held. In Dr. Hampson's words: + </p> + <p> + "The method consists in directing all the gas immediately after its + expansion over the coils which contain the compressed gas that is on its + way to the expansion-point. The cold developed by expansion in the first + expanded gas is thus communicated to the oncoming compressed gas, which + consequently expands from, and therefore to, a lower temperature than the + preceding portion. It communicates in the same way its own intensified + cold to the succeeding portion of compressed gas, which, in its turn, is + made colder, both before and after expansion, than any that had gone + before. This intensification of cooling goes on until the + expansion-temperature is far lower than it was at starting; and if the + apparatus be well arranged the effect is so powerful that even the smaller + amount of cooling due to the free expansion of gas through a + throttle-valve, though pronounced by Siemens and Coleman incapable of + being utilized, may be made to liquefy air without using other + refrigerants." + </p> + <p> + So well is this principle carried out in Dr. Hamp-son's apparatus for + liquefying air that compressed air passing into the coil at ordinary + temperature without other means of refrigeration begins to liquefy in + about six minutes—a result that seems almost miraculous when it is + understood that the essential mechanism by which this is brought about is + contained in a cylinder only eighteen inches long and seven inches in + diameter. + </p> + <p> + As has been said, it was by adopting this principle of self-intensive + refrigeration that Professor Dewar was able to liquefy hydrogen. More + recently the same result has been attained through use of the same + principle by Professor Ramsay and Dr. Travers at University College, + London, who are to be credited also with first publishing a detailed + account of the various stages of the process. It appears that the use of + the self-intensification principle alone is not sufficient with hydrogen + as it is with the less volatile gases, including air, for the reason that + at all ordinary temperatures hydrogen does not cool in expanding, but + actually becomes warmer. It is only after the compressed hydrogen has been + cooled by immersion in refrigerating media of very low temperature that + this gas becomes amenable to the law of cooling on expansion. In the + apparatus used at University College the coil of compressed hydrogen is + passed successively through (1) a jar containing alcohol and solid + carbonic acid at a temperature of—80° Centigrade; (2) a chamber + containing liquid air at atmospheric pressure, and (3) liquid air boiling + in a vacuum bringing the temperature to perhaps 2050 Centigrade before + entering the Hampson coil, in which expansion and the self-intensive + refrigeration lead to actual liquefaction. With this apparatus Dr. Travers + succeeded in producing an abundant quantity of liquid hydrogen for use in + the experiments on the new gases that were first discovered in the same + laboratory through the experiments on liquid air—gases about which I + shall have something more to say in another chapter. + </p> + <p> + PRINCIPLES AND EXPERIMENTS + </p> + <p> + At first blush it seems a very marvellous thing, this liquefaction of + substances that under all ordinary conditions are gaseous. It is certainly + a little startling to have a cup of clear, water-like liquid offered one, + with the assurance that it is nothing but air; still more so to have the + same air presented in the form of a white "avalanche snow." In a certain + sense it is marvellous, because the mechanical difficulties that have been + overcome in reducing the air to these unusual conditions are great. Yet, + in another and broader view, there is nothing more wonderful about liquid + air than about liquid water, or liquid mercury, or liquid iron. Long + before air was actually liquefied, it was perfectly understood by men of + science that under certain conditions it could be liquefied just as surely + as water, mercury, iron, and every other substance could be brought to a + similar state. This being known, and the principles involved understood, + had there been nothing more involved than the bare effort to realize these + conditions all the recent low-temperature work would have been mere + scientific child's-play, and liquid air would be but a toy of science. But + in point of fact there are many other things than this involved; new + principles were being searched for and found in the course of the + application of the old ones; new light was being thrown into many dark + corners; new fields of research, some of them as yet barely entered, were + being thrown open to the investigator; new applications of energy, of vast + importance not merely in pure science but in commercial life as well, were + being made available. That is why the low-temperature work must be + regarded as one of the most important scientific accomplishments of our + century. + </p> + <p> + At the very outset it was this work in large measure which gave the final + answer to the long-mooted question as to the nature of heat, demonstrating + the correctness of Count Rumford's view that heat is only a condition not + itself a substance. Since about the middle of the century this view, known + as the mechanical theory of heat, has been the constant guide of the + physicists in all their experiments, and any one who would understand the + low-temperature phenomena must keep this conception of the nature of heat + clearly and constantly in mind. To understand the theory, one must think + of all matter as composed of minute isolated particles or molecules, which + are always in motion—vibrating, if you will. He must mentally + magnify and visualize these particles till he sees them quivering before + him, like tuning-forks held in the hand. Remember, then, that, like the + tuning-fork, each molecule would, if left to itself, quiver less and less + violently, until it ran down altogether, but that the motion thus + lessening is not really lost. It is sent out in the form of ether waves, + which can set up like motion in any other particles which they reach, be + they near or remote; or it is transmitted as a direct push—a kick, + if you will—to any other particle with which the molecule comes in + physical contact. + </p> + <p> + But note now, further, that our molecule, while incessantly giving out its + energy of motion in ether waves and in direct pushes, is at the same time + just as ceaslessly receiving motion from the ether waves made by other + atoms, and by the return push of the molecules against which it pushes. In + a word, then, every molecule of matter is at once a centre for the + distribution of motion (sending out impulses which affect, sooner or + later, every other atom of matter in the universe), and, from the other + point of view, also a centre for the reception of motion from every + direction and from every other particle of matter in the universe. Whether + any given molecule will on the whole gain motion or lose it depends + clearly on the simple mechanical principles of give and take. + </p> + <p> + From equally familiar mechanical principles, it is clear that our + vibrating molecule, in virtue of its vibrations, is elastic, tending to be + thrown back from every other molecule with which it comes in contact, just + as a vibrating tuning-fork kicks itself away from anything it touches. And + of course the vigor of the recoil will depend upon the vigor of the + vibration and the previous movements. But since these movements constitute + temperature, this is another way of saying that the higher the temperature + of a body the more its molecules will tend to spring asunder, such + separation in the aggregate constituting expansion of the mass as a whole. + Thus the familiar fact of expansion of a body under increased temperature + is explained. + </p> + <p> + But now, since all molecules are vibrating, and so tending to separate, it + is clear that no unconfined mass of molecules would long remain in + contiguity unless some counter influence tended to draw them together. + Such a counter influence in fact exists, and is termed the "force" of + cohesion. This force is a veritable gravitation influence, drawing every + molecule towards every other molecule. Possibly it is identical with + gravitation. It seems subject to some law of decreasing in power with the + square of the distance; or, at any rate, it clearly becomes less potent as + the distance through which it operates increases. + </p> + <p> + Now, between this force of cohesion which tends to draw the molecules + together, and the heat vibrations which tend to throw the molecules + farther asunder, there seems to be an incessant battle. If cohesion + prevails, the molecules are held for the time into à relatively fixed + system, which we term the solid state. If the two forces about balance + each other, the molecules move among themselves more freely but maintain + an average distance, and we term the condition the liquid state. But if + the heat impulse preponderates, the molecules (unless restrained from + without) fly farther and farther asunder, moving so actively that when + they collide the recoil is too great to be checked by cohesion, and this + condition we term the gaseous state. + </p> + <p> + Now after this statement, it is clear that what the low-temperature worker + does when he would liquefy a gas is to become the champion of the force of + cohesion. He cannot directly aid it, for so far as is known it is an + unalterable quantity, like gravitation. But he can accomplish the same + thing indirectly by weakening the power of the rival force. Thus, if he + encloses a portion of gas in a cylinder and drives a piston down against + it, he is virtually aiding cohesion by forcing the molecules closer + together, so that the hold of cohesion, acting through a less distance, is + stronger. What he accomplishes here is not all gain, however, for the + bounding molecules, thus jammed together, come in collision with one + another more and more frequently, and thus their average activity of + vibration is increased and not diminished; in other words, the temperature + of the gas has risen in virtue of the compression. Compression alone, + then, will not avail to enable cohesion to win the battle. + </p> + <p> + But the physicist has another resource. He may place the cylinder of gas + in a cold medium, so that the heat vibrations sent into it will be less + vigorous than those it sends out. That is a blow the molecule cannot + withstand. It is quite impotent to cease sending out the impulses however + little comes in return; hence the aggregate motion becomes less and less + active, until finally the molecule is moving so sluggishly that when it + collides with its fellow cohesion is able to hold it there. Cohesion, + then, has won the battle, and the gas has become a liquid. + </p> + <p> + Such, stated in terms of the mechanical theory of heat, is what is brought + to pass when a gas is liquefied in the laboratory of the physicist. It + remains only to note that different chemical substances show the widest + diversity as to the exact point of temperature at which this balance of + the expansive and cohesive tendencies is affected, but that the point, + under uniform conditions of pressure, is always the same for the same + substance. This diversity has to do pretty clearly with the size of the + individual molecules involved; but its exact explanation is not yet + forthcoming, and, except in a general way, the physicist would not be able + to predict the "critical temperature" of any new gas presented to him. But + once this has been determined by experiment, he always knows just what to + expect of any given substance. He knows, for example, that in a mixture of + gases hydrogen would still remain gaseous after all the others had assumed + the liquid state, and most of them the solid state as well. + </p> + <p> + These mechanical conceptions well in mind, it is clear that what the + would-be liquefier of gases has all along sought to attain is merely the + insulation of the portion of matter with which he worked against the + access of heat-impulse from its environment. It is clear that were any + texture known which would permit a heat-impulse to pass through it in one + direction only, nothing more would be necessary than to place a portion of + gas in such a receptacle of this substance, so faced as to permit egress + but not entrance of the heat, and the gas thus enclosed, were it hydrogen + itself, would very soon become liquid and solid, through spontaneous + giving off of its energy, without any manipulation whatever. Contrariwise, + were the faces of the receptacle reversed, a piece of iron placed within + it would be made red-hot and melted though the receptacle were kept packed + in salt and ice and no heat applied except such as came from this freezing + mixture. One could cook a beefsteak with a cake of ice had he but such a + material as this with which to make his stove. Not even Rumford or our + modern Edward Atkinson ever dreamed of such economy of fuel as that. + </p> + <p> + But, unfortunately, no such substance as this is known, nor, indeed, any + substance that will fully prevent the passage of heat-impulses in either + direction. Hence one of the greatest tasks of the experimenters has been + to find a receptacle that would insulate a cooled substance even partially + from the incessant bombardment of heat-impulses from without. It is + obvious that unless such an insulating receptacle could be provided none + of the more resistent gases, such as oxygen, could be long kept liquid, + even when once brought to that condition, since an environment of + requisite frigidity could not practicably be provided. + </p> + <p> + But now another phase of the problem presents itself to the experimenter. + Oxygen has assumed the quiescent liquid state, to be sure, but in so doing + it has fallen below the temperature of its cooling medium; hence it is now + receiving from that medium more energy of vibration than it gives, and + unless this is prevented very soon its particles will again have power to + kick themselves apart and resume the gaseous state. Something, then, must + be done to insulate the liquefied gas, else it will retain the liquid + state for too short a time to be much experimented with. How might such + insulation be accomplished? + </p> + <p> + The most successful attack upon this important problem has been made by + Professor Dewar. He invented a receptacle for holding liquefied gases + which, while not fulfilling the ideal conditions referred to above, yet + accomplishes a very remarkable degree of heat insulation. In consists of a + glass vessel with double walls, the space between which is rendered a + vacuum of the highest practicable degree. This vacuum, containing + practically no particles of matter, cannot, of course, convey + heat-impulses to or from the matter in the receptacle with any degree of + rapidity. Thus one of the two possible means of heat transfer is shut off + and a degree of insulation afforded the liquefied substance. But of course + the other channel, ether radiation, remains. Even this may be blocked to a + large extent, however, by leaving a trace of mercury vapor in the vacuum + space, which will be deposited as a fine mirror on the inner surface of + the chamber. This mirror serves as an admirable reflector of the heat-rays + that traverse the vacuum, sending more than half of them back again. So, + by the combined action of vacuum and mirror, the amount of heat that can + penetrate to the interior of the receptacle is reduced to about + one-thirtieth of what would enter an ordinary vessel. In other words, a + quantity of liquefied gas which would evaporate in one minute from an + ordinary vessel will last half an hour in one of Professor Dewar's best + vacuum vessels. Thus in one of these vessels a quantity of liquefied air, + for example, can be kept for a considerable time in an atmosphere at + ordinary temperature, and will only volatilize at the surface, like water + under the same conditions, though of course more rapidly; whereas the same + liquid in an ordinary vessel would boil briskly away, like water over a + fire. Only, be it remembered, the air in "boiling" is at a temperature of + about one hundred and eighty degrees below zero, so that it would + instantly freeze almost any substance placed into it. A portion of alcohol + poured on its surface will be changed quickly into a globule of ice, which + will rattle about the sides of the vessel like a marble. That is not what + one ordinarily thinks of as a "boiling" temperature. + </p> + <p> + If the vacuum vessel containing a liquefied gas be kept in a cold medium, + and particularly if two vacuum tubes be placed together, so that no + exposed surface of liquid remains, a portion of liquefied air, for + example, may be kept almost indefinitely. Thus it becomes possible to + utilize the liquefied gas for experimental investigation of the properties + of matter at low temperatures that otherwise would be quite impracticable. + Great numbers of such experiments have been performed in the past decade + or so by all the workers with low temperatures already mentioned, and by + various others, including, fittingly enough, the holder of the Rumford + professorship of experimental physics at Harvard, Professor Trowbridge. + The work of Professor Dewar has perhaps been the most comprehensive and + varied, but the researches of Pictet, Wroblewski, and Olzewski have also + been important, and it is not always possible to apportion credit for the + various discoveries accurately, since the authorities themselves are in + unfortunate disagreement in several questions of priority. But in any + event, such questions of exact priority have no great interest for any one + but the persons directly involved. We may quite disregard them here, + confining attention to the results themselves, which are full of interest. + </p> + <p> + The questions investigated have to do with the physical properties, such + as electrical conductivity, magnetic condition, light-absorption, + cohesion, and chemical affinities of matter at excessively low + temperatures. It is found that in all these regards most substances are + profoundly modified when excessively cooled. Thus if a piece of any pure + metal is placed in an electric circuit and plunged into liquid air, its + resistance to the passage of the electricity steadily decreases as the + metal cools, until at the temperature of the liquid it is very trifling + indeed. The conclusion seems to be justified that if the metal could be + still further cooled until it reached the theoretical "absolute zero," or + absolutely heatless condition, the electrical resistance would also be + nil. So it appears that the heat vibrations of the molecules of a pure + metal interfere with the electrical current. The thought suggests itself + that this may be because the ether waves set up by the vibrating molecules + conflict with the ether strain which is regarded by some theorists as + constituting the electrical "current." But this simple explanation falters + before further experiments which show, paradoxically enough, that the + electrical resistance of carbon exactly reverses what has just been said + of pure metals, becoming greater and greater as the carbon is cooled. If + an hypothesis were invented to cover this case there would still remain a + puzzle in the fact that alloys of metals do not act at all like the pure + metals themselves, the electrical resistance of such alloys being, for the + most part, unaffected by changed temperature. On the whole, then, the + facts of electrical conduction at low temperatures are quite beyond the + reach of present explanation. They must await a fuller knowledge of + molecular conditions in general than is at present available—a + knowledge to which the low-temperature work itself seems one of the surest + channels. + </p> + <p> + Even further beyond the reach of present explanation are the facts as to + magnetic conditions at low temperatures. Even as to the facts themselves + different experimenters have differed somewhat, but the final conclusion + of Professor Dewar is that, after a period of fluctuation, the power of a + magnet repeatedly subjected to a liquid-air bath becomes permanently + increased. Various substances not markedly magnetic at ordinary + temperatures become so when cooled. Among these, as Professor Dewar + discovered, is liquid oxygen itself. Thus if a portion of liquid air be + further cooled until it assumes a semi-solid condition, the oxygen may be + drawn from the mass by a magnet, leaving a pure nitrogen jelly. These + facts are curious enough, and full of suggestion, but like all other + questions having to do with magnetism, they hold for the present + generation the double fascination of insoluble mystery. To be sure, one + may readily enough suggest that if magnetism be really a whirl in the + ether, this whirl is apparently interfered with by the waves of radiant + heat; or, again, that magnetism is presumably due to molecular motions + which are apparently interfered with by another kind of molecular motions + which we call heat vibrations; but there is a vagueness about the terms of + such guesses that leaves them clearly within the category of explanations + that do not explain. + </p> + <p> + When it comes to the phenomena of light, we can, as is fitting, see our + way a little more clearly, since, thanks to Thomas Young and his + successors, we know pretty definitely what light really is. So when we + learn that many substances change their color utterly at low temperatures—red + things becoming yellow and yellow things white, for example—we can + step easily and surely to at least a partial explanation. We know that the + color of any object depends simply upon the particular ether waves of the + spectrum which that particular substance absorbs; and it does not seem + anomalous that molecules packed close together at—180° of + temperature should treat the ether waves differently than when relatively + wide apart at an ordinary temperature. Yet, after all, that may not be the + clew to the explanation. The packing of the molecules may have nothing to + do with it. The real explanation may lie in the change of the ether waves + sent out by the vibrating molecule; indeed, the fact that the waves of + radiant heat and those of light differ only in amplitude lends color to + this latter supposition. So the explanation of the changed color of the + cooled substance is at best a dubious one. + </p> + <p> + Another interesting light phenomenon is found in the observed fact that + very many substances become markedly phosphorescent at low temperatures. + Thus, according to Professor Dewar, "gelatine, celluloid, paraffine, + ivory, horn, and india-rubber become distinctly luminous, with a bluish or + greenish phosphorescence, after cooling to—180° and being stimulated + by the electric light." The same thing is true, in varying degrees, of + alcohol, nitric acid, glycerine, and of paper, leather, linen, + tortoise-shell, and sponge. Pure water is but slightly luminous, whereas + impure water glows brightly. On the other hand, alcohol loses its + phosphorescence when a trace of iodine is added to it. In general, colored + things are but little phosphorescent. Thus the white of egg is very + brilliant but the yolk much less so. Milk is much brighter than water, and + such objects as a white flower, a feather, and egg-shell glow brilliantly. + The most remarkable substances of all, says Professor Dewar, whom I am all + along quoting, are "the platinocyanides among inorganic compounds and the + ketonic compounds among organic. Ammonium platinocyanide, cooled while + stimulated by arc light, glows fully at—180°; but on warming it + glows like a lamp. It seems clear," Professor Dewar adds, "that the + substance at this low temperature must have acquired increased power of + absorption, and it may be that at the same time the factor of molecular + friction or damping may have diminished." The cautious terms in which this + partial explanation is couched suggest how far we still are from a full + understanding of the interesting phenomena of phosphorescence. That a + molecule should be able to vibrate in such a way as to produce the short + waves of light, dissevered from the usual linking with the vibrations + represented by high temperature, is one of the standing puzzles of + physics. And the demonstrated increase of this capacity at very low + temperatures only adds to the mystery. + </p> + <p> + There are at least two of the low-temperature phenomena, however, that + seem a little less puzzling—the facts, namely, that cohesion and + rigidity of structure are increased when a substance is cooled and that + chemical activity is very greatly reduced, in fact almost abolished. This + is quite what one would expect <i>a priori</i>—though no wise man + would dwell on his expectation in advance of the experiments—since + the whole question of liquids and solids <i>versus</i> gases appears to be + simply a contest between cohesive forces that are tending to draw the + molecules together and the heat vibration which is tending to throw them + apart. As a substance changes from gas to liquid, and from liquid to + solid, contracting meantime, simply through the lessening of the heat + vibrations of its molecules, we might naturally expect that the solid + would become more and more tenacious in structure as its molecules came + closer and closer together, and at the same time became less and less + active, as happens when the solid is further cooled. And for once + experiment justifies the expectation. Professor De-war found that the + breaking stress of an iron wire is more than doubled when the wire is + cooled to the temperature of liquid air, and all other metals are largely + strengthened, though none other to quite the same degree. He found that a + spiral spring of fusible metal, which at ordinary temperature was quickly + drawn out into a straight wire by a weight of one ounce, would, when + cooled to -182 deg, support a weight of two pounds, and would vibrate like + a steel spring so long as it was cool. A bell of fusible metal has a + distinct metallic ring at this low temperature; and balls of iron, tin, + lead, or ivory cooled to -182 deg and dropped from a height, "in all cases + have the rebound greatly increased. The flattened surface of the lead is + only one-third what it would be at ordinary temperature." "These + conditions are due solely to the cooling, and persist only while the low + temperature lasts." + </p> + <p> + If this increased strength and hardness of a contracted metal are what one + would expect on molecular principles, the decreased chemical activity at + low temperatures is no less natural-seeming, when one reflects how + generally chemical phenomena are facilitated by the application of heat. + In point of fact, it has been found that at the temperature of liquid + hydrogen practically all chemical activity is abolished, the unruly + fluorine making the only exception. The explanation hinges on the fact + that every atom, of any kind, has power to unite with only a limited + number of other atoms. When the "affinities" of an atom are satisfied, no + more atoms can enter into the union unless some atoms already there be + displaced. Such displacement takes place constantly, under ordinary + conditions of temperature, because the vibrating atoms tend to throw + themselves apart, and other atoms may spring in to take the places just + vacated—such interchange, in fact, constituting the essence of + chemical activity. But when the temperature is reduced the heat-vibration + becomes insufficient to throw the atoms apart, hence any unions they + chance to have made are permanent, so long as the low temperature is + maintained. Thus it is that substances which attack one another eagerly at + ordinary temperatures will lie side by side, utterly inert, at the + temperature of liquid air. + </p> + <p> + Under certain conditions, however, most interesting chemical experiments + have been made in which the liquefied gases, particularly oxygen, are + utilized. Thus Olzewski found that a bit of wood lighted and thrust into + liquid oxygen burns as it would in gaseous oxygen, and a red-hot iron wire + thrust into the liquid burns and spreads sparks of iron. But more novel + still was Dewar's experiment of inserting a small jet of ignited hydrogen + into the vessel of liquid oxygen; for the jet continued to burn, forming + water, of course, which was carried away as snow. The idea of a gas-jet + burning within a liquid, and having snow for smoke, is not the least + anomalous of the many strange conceptions that the low-temperature work + has made familiar. + </p> + <p> + PRACTICAL RESULTS AND ANTICIPATIONS + </p> + <p> + Such are some of the strictly scientific results of the low-temperature + work. But there are other results of a more directly practical kind—neither + more important nor more interesting on that account, to be sure, but more + directly appealing to the generality of the non-scientific public. Of + these applications, the most patent and the first to be made available was + the one forecast by Davy from the very first—namely, the use of + liquefied gases in the refrigeration of foods. Long before the more + resistant gases had been liquefied, the more manageable ones, such as + ammonia and sulphurous acid, had been utilized on a commercial scale for + refrigerating purposes. To-day every brewery and every large cold-storage + warehouse is supplied with such a refrigerator plant, the temperature + being thus regulated as is not otherwise practicable. Many large halls are + cooled in a similar manner, and thus made comfortable in the summer. Ships + carrying perishables have the safety of their cargoes insured by a + refrigerator plant. In all large cities there are ice manufactories using + the same method, and of late even relatively small establishments, hotels, + and apartment houses have their ice-machine. It seems probable that before + long all such buildings and many private dwellings will be provided with a + cooling apparatus as regularly as they are now equipped with a heating + apparatus. + </p> + <p> + The exact details of the various refrigerator machines of course vary, but + all of them utilize the principles that the laboratory workers first + established. Indeed, the entire refrigerator industry, now assuming + significant proportions, may be said to be a direct outgrowth of that + technical work which Davy and Faraday inaugurated and prosecuted at the + Royal Institution—a result which would have been most gratifying to + the founder of the institution could he have forecast it. The usual means + of distributing the cooling fluids in the commercial plants is by the + familiar iron pipes, not dissimilar in appearance (when not in operation) + to the familiar gas, water, and steam pipes. When operating, however, the + pipes themselves are soon hidden from view by the thick coating of frost + which forms over them. In a moist beer-cellar this coating is often + several inches in thickness, giving a very characteristic and unmistakable + appearance. + </p> + <p> + Another commercial use to which refrigerator machines are now put is in + the manufacture of various drugs, where absolute purity is desirable. As + different substances congeal at different temperatures, but the same + substances at uniform pressure always at the same temperature, a means is + afforded of freeing a drug from impurities by freezing, where sometimes + the same result cannot be accomplished with like thoroughness by any other + practicable means. Indeed, by this means impurities have been detected + where not previously suspected. And Professor Ramsay has detected some new + elementary substances even, as constituents of the air, which had + previously not been dissociated from the nitrogen with which they are + usually mixed. + </p> + <p> + Such applications of the refrigerator principles as these, however, though + of vast commercial importance, are held by many enthusiasts to be but a + bagatelle compared with other uses to which liquefied gases may some time + be put. Their expectations are based upon the enormous potentialities that + are demonstrably stored in even a tiny portion of, say, liquefied air. + These are, indeed, truly appalling. Consider, for example, a portion of + air at a temperature above its critical point, to which, as in Thilorier's + experiments, a pressure of thirty-one tons to the square inch of the + encompassing wall is being applied. Recall that action and reaction are + equal, and it is apparent that the gas itself is pushing back—struggling + against being compressed, if you will—with an equal power. Suppose + the bulk of the gas is such that at this pressure it occupies a cubical + space six inches on a side—something like the bulk of a child's toy + balloon, let us say. Then the total outward pressure which that tiny bulk + of gas exerts, in its desperate molecular struggle, is little less than + five thousand tons. It would support an enormous building without budging + a hair's-breadth. If the building weighed less than five thousand tons it + would be lifted by the gas; if much less it would be thrown high into the + air as the gas expanded. It gives one a new sense of the power of numbers + to feel that infinitesimal atoms, merely by vibrating in unison, could + accomplish such a result. + </p> + <p> + But now suppose our portion of gas, instead of being placed under our + hypothetical building, is plunged into a cold medium, which will permit + its heat-vibrations to exhaust themselves without being correspondingly + restored. Then, presently, the temperature is lowered below the critical + point, and, presto! the mad struggle ceases, the atoms lie amicably + together, and the gas has become a liquid. What a transformed thing it is + now. Instead of pressing out with that enormous force, it has voluntarily + contracted as the five thousand tons pressure could not make it do; and it + lies there now, limpid and harmless-seeming, in the receptacle, for all + the world like so much water. + </p> + <p> + And, indeed, the comparison with water is more than superficial, for in a + cup of water also there are wonderful potentialities, as every + steam-engine attests. But an enormous difference, not in principle but in + practical applications, exists in the fact that the potentialities of the + water cannot be utilized until relatively high temperatures are reached. + Costly fuel must be burned and the heat applied to the water before it can + avail to do its work. But suppose we were to place our portion of liquid + air, limpid and water-like, in the cylinder of a locomotive, where the + steam of water ordinarily enters. Then, though no fuel were burned—though + the entire engine stood embedded in the snow of an arctic winter—it + would be but a few moments before the liquid air would absorb even from + this cold medium heat enough to bring it above its critical temperature; + and, its atoms now dancing apart once more and re-exerting that enormous + pressure, the piston of the engine would be driven back and then the + entire cylinder burst into fragments as the gas sought exit. In a word, + then, a portion of liquid air has a store of potential energy which can be + made kinetic merely by drawing upon the boundless and free supply of heat + which is everywhere stored in the atmosphere we breathe and in every + substance about us. The difficulty is, not to find fuel with which to + vaporize it, as in case of water, but to keep the fuel from finding it + whether or no. Were liquid air in sufficient quantities available, the + fuel problem would cease to have any significance. But of course liquid + air is not indefinitely available, and exactly here comes the difficulty + with the calculations of many enthusiasts who hail liquefied gas as the + motive power of the near future. For of course in liquefying the air power + has been applied, for the moment wasted, and unless we can get out of the + liquid more energy than we have applied to it, there is no economy of + power in the transaction. Now the simplest study of the conditions, with + the mechanical theory of matter in mind, makes it clear that this is + precisely what one can never hope to accomplish. Action and reaction are + equal and in opposite directions at all stages of the manipulation, and + hence, under the most ideal conditions, we must expect to waste as much + work in condensing a gas (in actual practice more) as the condensed + substance can do in expanding to the original volume. Those enthusiasts + who have thought otherwise, and who have been on the point of perfecting + an apparatus which will readily and cheaply produce liquid air after the + first portion is produced, are really but following the old + perpetual-motion-machine will-o'-the-wisp. + </p> + <p> + It does not at all follow from this, however, that the energies of + liquefied air may not be utilized with enormous advantage. It is not + always the cheapest form of power-transformer that is the best for all + purposes, as the use of the electrical storage battery shows. And so it is + quite within the possibilities that a multitude of uses may be found for + the employment of liquid air as a motive power, in which its condensed + form, its transportability or other properties will give it precedence + over steam or electricity. It has been suggested, for example, that + liquefied gas would seem to afford the motive power par excellence for the + flying-machine, once that elusive vehicle is well in harness, since one of + the greatest problems here is to reduce the weight of the motor apparatus. + In a less degree the same problem enters into the calculations of ships, + particularly ships of war; and with them also it may come to pass that a + store of liquid air (or other gas) may come to take the place of a far + heavier store of coal. It is even within the possibilities that the + explosive powers of the same liquid may take the place of the great + magazines of powder now carried on war-ships; for, under certain + conditions, the liquefied gas will expand with explosive suddenness and + violence, an "explosion" being in any case only a very sudden expansion of + a confined gas. The use of the compressed air in the dynamite guns, as + demonstrated in the Cuban campaign, is a step in this direction. And, + indeed, the use of compressed air in many commercial fields already + competing with steam and electricity is a step towards the use of air + still further compressed, and cooled, meantime, to a condition of + liquidity. The enormous advantages of the air actually liquefied, and so + for the moment quiescent, over the air merely compressed, and hence + requiring a powerful retort to hold it, are patent at a glance. But, on + the other hand, the difficulty of keeping it liquid is a disadvantage that + is equally patent. How the balance will be struck between these contending + advantages and disadvantages it remains for the practical engineering + inventors of the future—the near future, probably—to + demonstrate. + </p> + <p> + Meantime there is another line of application of the ideas which the + low-temperature work has brought into prominence which has a peculiar + interest in the present connection because of its singularly Rumfordian + cast, so to speak, I mean the idea of the insulation of cooled or heated + objects in the ordinary affairs of life, as, for example, in cooking. The + subject was a veritable hobby with the founder of the Royal Institution + all his life. He studied the heat-transmitting and heat-reflecting + properties of various substances, including such directly practical + applications as rough surfaces <i>versus</i> smooth surfaces for stoves, + the best color for clothing in summer and in winter, and the like. He + promulgated his ideas far and wide, and demonstrated all over Europe the + extreme wastefulness of current methods of using fuel. To a certain extent + his ideas were adopted everywhere, yet on the whole the public proved + singularly apathetic; and, especially in America, an astounding + wastefulness in the use of fuel is the general custom now as it was a + century ago. A French cook will prepare an entire dinner with a splinter + of wood, a handful of charcoal, and a half-shovelful of coke, while the + same fuel would barely suffice to kindle the fire in an American + cook-stove. Even more wonderful is the German stove, with its great bulk + of brick and mortar and its glazed tile surface, in which, by keeping the + heat in the room instead of sending it up the chimney, a few bits of + compressed coal do the work of a hodful. + </p> + <p> + It is one merit of the low-temperature work, I repeat, to have called + attention to the possibilities of heat insulation in application to "the + useful purposes of life." If Professor Dewar's vacuum vessel can reduce + the heat-transmitting capacity of a vessel by almost ninety-seven per + cent., why should not the same principle, in modified form, be applied to + various household appliances—to ice-boxes, for example, and to + cooking utensils, even to ovens and cook-stoves? Even in the construction + of the walls of houses the principles of heat insulation might + advantageously be given far more attention than is usual at present; and + no doubt will be so soon as the European sense of economy shall be brought + home to the people of the land of progress and inventions. The principles + to be applied are already clearly to hand, thanks largely to the technical + workers with low temperatures. It remains now for the practical inventors + to make the "application to the useful purposes of life." The technical + scientists, ignoring the example which Rumford and a few others have set, + have usually no concern with such uninteresting concerns. + </p> + <p> + For the technical scientists themselves, however, the low-temperature + field is still full of inviting possibilities of a strictly technical + kind. The last gas has indeed been liquefied, but that by no means implies + the last stage of discovery. With the successive conquest of this gas and + of that, lower and lower levels of temperature have been reached, but the + final goal still lies well beyond. This is the north pole of the + physicist's world, the absolute zero of temperature—the point at + which the heat-vibrations of matter are supposed to be absolutely stilled. + Theoretically this point lies 2720 below the Centigrade zero. With the + liquefaction of hydrogen, a temperature of about -253 deg or -254 deg + Centigrade has been reached. So the gap seems not so very great. But like + the gap that separated Nansen from the geographical pole, it is a very + hard road to travel. How to compass it will be the study of all the + low-temperature explorers in the immediate future. Who will first reach + it, and when, and how, are questions for the future to decide. + </p> + <p> + And when the goal is reached, what will be revealed? That is a question as + full of fascination for the physicist as the north-pole mystery has ever + been for the generality of mankind. In the one case as in the other, any + attempt to answer it to-day must partake largely of the nature of a guess, + yet certain forecasts may be made with reasonable probability. Thus it can + hardly be doubted that at the absolute zero all matter will have the form + which we term solid; and, moreover, a degree of solidity, of tenacity and + compactness greater than ever otherwise attained. All chemical activity + will presumably have ceased, and any existing compound will retain + unaltered its chemical composition so long as absolute zero pertains; + though in many, if not in all cases, the tangible properties of the + substance—its color, for example, and perhaps its crystalline + texture—will be so altered as to be no longer recognizable by + ordinary standards, any more than one would ordinarily recognize a mass of + snowlike crystals as air. + </p> + <p> + It has, indeed, been suggested that at absolute zero all matter may take + the form of an impalpable powder, the forces of cohesion being destroyed + with the vibrations of heat. But experiment seems to give no warrant to + this forecast, since cohesion seems to increase exactly in proportion to + the decrease of the heat-vibrations. The solidity of the meteorites which + come to the earth out of the depths of space, where something approaching + the zero temperature is supposed to prevail, also contradicts this + assumption. Still less warrant is there for a visionary forecast at one + time entertained that at absolute zero matter will utterly disappear. This + idea was suggested by the observation, which first gave a clew to the + existence of the absolute zero, that a gas at ordinary temperatures and at + uniform pressure contracts by 1-27 2d of its own bulk with each successive + degree of lowered temperature. If this law held true for all temperatures, + the gas would apparently contract to nothingness when the last degree of + temperature was reached, or at least to a bulk so insignificant that it + would be inappreciable by standards of sense. But it was soon found by the + low-temperature experimenters that the law does not hold exactly at + extreme temperatures, nor does it apply at all to the rate of contraction + which the substance shows after it assumes the liquid and solid + conditions. So the conception of the disappearance of matter at zero falls + quite to the ground. + </p> + <p> + But one cannot answer with so much confidence the suggestion that at zero + matter may take on properties hitherto quite unknown, and making it, + perhaps, differ as much from the conventional solid as the solid differs + from the liquid, or this from the gas. The form of vibration which + produces the phenomena of temperature has, clearly, a determining share in + the disposal of molecular relations which records itself to our senses as + a condition of gaseousness, liquidity, or solidity; hence it would be rash + to predict just what inter-molecular relations may not become possible + when the heat-vibration is altogether in abeyance. That certain other + forms of activity may be able to assert themselves in unwonted measure + seems clearly forecast in the phenomena of increased magnetism, and of + phosphorescence at low temperatures above outlined. Whether still more + novel phenomena may put in an appearance at the absolute zero, and if so, + what may be their nature, are questions that must await the verdict of + experiment. But the possibility that this may occur, together with the + utter novelty of the entire subject, gives the low-temperature work + precedence over almost every other subject now before the world for + investigation (possible exceptions being radio-activity and bacteriology). + The quest of the geographical pole is but a child's pursuit compared with + the quest of the absolute zero. In vital interest the one falls as far + short of the other as the cold of frozen water falls short of the cold of + frozen air. + </p> + <p> + Where, when, and by whom the absolute zero will be first reached are + questions that may be answered from the most unexpected quarter. But it is + interesting to know that great preparations are being made today in the + laboratories of the Royal Institution for a further attack upon the + problem. Already the research equipment there is the best in the world in + this field, and recently this has been completely overhauled and still + further perfected. It would not be strange, then, in view of past + triumphs, if the final goal of the low-temperature workers should be first + reached in the same laboratory where the outer territories of the unknown + land were first penetrated three-quarters of a century ago. There would + seem to be a poetic fitness in the trend of events should it so transpire. + But of course poetic fitness does not always rule in the land of science. + </p> + <p> + <a name="link2H_4_0006" id="link2H_4_0006"> + <!-- H2 anchor --> </a> + </p> + <div style="height: 4em;"> + <br /><br /><br /><br /> + </div> + <h2> + IV. SOME PHYSICAL LABORATORIES AND PHYSICAL PROBLEMS + </h2> + <p> + SIR NORMAN LOCKYER AND SOLAR CHEMISTRY + </p> + <p> + SIR NORMAN LOCKYER is professor of astronomical physics and director of + the solar observatory at the Royal College of Science in South Kensington. + Here it is that his chief work has been done for some thirty years past. + The foundation-stone of that work is spectroscopic study of the sun and + stars. In this study Professor Lockyer was a pioneer, and he has for years + been recognized as the leader. But he is no mere observer; he is a + generalizer as well; and he long since evolved revolutionary ideas as to + the origin of the sidereal and solar systems. + </p> + <p> + For a man whose chief occupation is the study of the sun and stars, smoky, + foggy, cloudy London may seem a strange location. I asked Professor + Lockyer about this, and his reply was most characteristic. "The fact is," + he said, "the weather here is too fine from one point of view: my working + staff is so small, and the number of working nights so large, that most of + the time there is no one about to do anything during the day. Then, + another thing, here at South Kensington I am in touch with my colleagues + in the other departments—physics, chemistry, and so forth—and + can at once draw upon their special knowledge for aid on any obscure point + in their lines that may crop up. If we were out in the country this would + not be so. You see, then, that it is a choice between weather and brains. + I prefer the brains." + </p> + <p> + Professor Lockyer went on to state, however, that he is by no means + altogether dependent upon the observations made at South Kensington. For + certain purposes the Royal Observatory at Greenwich is in requisition, and + there are three observatories at different places in India at which + photographs of the sun-spots and solar spectra are taken regularly. From + these combined sources photographs of the sun are forthcoming practically + every day of the year; to be accurate, on three hundred and sixty days out + of the three hundred and sixty-five. It was far otherwise when Professor + Lockyer first began his studies of the sun, as observations were then made + and recorded on only about one-third of the days in each year. + </p> + <p> + Exteriorly the observatory at South Kensington is not at all such a place + as one might expect to find. It is, in Professor Lockyer's own words, + "little more than a collection of sheds," but within these alleged sheds + may be found an excellent equipment of telescopes, both refracting and + reflecting, and of all other things requisite to the peculiar study which + forms the subject of special research here. + </p> + <p> + I have had occasion again and again to call attention to this relatively + meagre equipment of the European institutions, but in no case, perhaps, is + the contrast more striking between the exterior appearance of a famous + scientific institution and the work that is being accomplished within it + than is shown in the case of the South Kensington observatory. It should + be added that this remark does not apply to the chief building of the + Royal College of Science itself. + </p> + <p> + The theories for which Professor Lockyer has so long been famous are well + known to every one who takes much interest in the progress of scientific + ideas. They are notably the theory that there is a direct causal + association between the prevalence of sun-spots and terrestrial weather; + the theory of the meteoritic origin of all members of the sidereal family; + and the dissociation theory of the elements, according to which our + so-called elements are really compounds, capable of being dissociated into + simpler forms when subjected to extreme temperatures, such as pertain in + many stars. As I have said, these theories are by no means new. Professor + Lockyer has made them familiar by expounding them for a full quarter of a + century or more. But if not new, these theories are much too important to + have been accepted at once without a protest from the scientific world. In + point of fact, each of them has been met with most ardent opposition, and + it would, perhaps, not be too much to say that not one of them is, as yet, + fully established. It is of the highest interest to note, however, that + the multitudinous observations bearing upon each of these topics during + the past decade have tended, in Professor Lockyer's opinion, strongly to + corroborate each one of these opinions. + </p> + <p> + Two or three years ago Sir Norman Lockyer, in association with his son, + communicated to the Royal Society a paper in which the data recently + obtained as to the relation between sun-spots and the weather in India—the + field of observations having been confined to that territory—are + fully elaborated. A remarkable feature of the recent work in that + connection has been the proof, or seeming proof, that the temperature of + the sun fluctuates from year to year. At times when the sun-spots are + numerous and vigorous in their action, the spectrum of the elements in + these spots becomes changed. During the times of minimum sun-spot activity + the spectrum shows, for example, the presence of large quantities of iron + in these spots—of course in a state of vapor. But in times of + activity this iron disappears, and the lines which previously vouched for + it are replaced by other lines spoken of as the enhanced lines of iron—that + is to say, the lines which are believed to represent the unknown substance + or substances into which the iron has been decomposed; and what is true of + iron is true of various other elements that are detected in the sun-spots. + The explanation of this phenomena, if Professor Lockyer reads the signs + aright, is that during times of minimum sun-spot activity the temperature + of the sun-spots is relatively cool, and that in times of activity the + temperature becomes greatly increased. One must come, therefore, to + speaking of hot spots and cool spots on the sun; although the cool spots, + it will be understood, would hardly be considered cool in the terrestrial + sense, since their temperature is sufficient to vaporize iron. + </p> + <p> + Now the point of the recent observations is that the fluctuations in the + sun's heat, due to the periodic increase and subsidence of sun-spot + disturbances—such fluctuations having been long recognized as having + regular cyclic intervals of about eleven years—are instrumental in + effecting changes in the terrestrial weather. According to the paper just + mentioned, it would appear to be demonstrated that the periods of + decreased rainfall in India have a direct and relatively unvarying + relationship to the prevalence of the sun-spots, and that, therefore, it + has now become possible, within reasonable limits, to predict some years + in advance the times of famine in India. So important a conclusion as this + is certainly not to be passed over lightly, and all the world, scientific + and unscientific alike, will certainly watch with acute interest for the + verification of this seemingly startling practical result of so occult a + science as solar spectroscopy. + </p> + <p> + The theory of the decomposition of the elements is closely bound up with + the meteoritic theory. In a word, it may be said of each that Professor + Lockyer is firmly convinced that all the evidence that has accumulated in + recent years is so strongly in favor as to bring these theories almost to + a demonstration. The essence of the meteoritic theory, it will be + recalled, is that all stars have their origin in nebulae which consist + essentially of clouds of relatively small meteorites. It will be recalled + further that Professor Lockyer long ago pointed out that stars pass + through a regular series of changes as to temperature, with corresponding + changes of structure, becoming for a time hotter and hotter until a + maximum is reached, and then passing through gradual stages of cooling + until their light dies out altogether. Very recently Professor Lockyer has + been enabled, through utilization of the multiform records accumulated + during years of study, to define the various typical stages of the + sidereal evolution; and not merely to define them but to illustrate them + practically by citing stars which belong to each of these stages, and to + give them yet clearer definition by naming the various elements which the + spectroscope reveals as present in each. + </p> + <p> + His studies have shown that the elements do not always give the same + spectrum under all conditions; a result quite at variance with the earlier + ideas on the subject. Even in the terrestrial laboratory it is possible to + subject various metals, including iron, to temperatures attained with the + electric spark at which the spectrum becomes different from that, for + example, which was attained with the lower temperature of the electric + arc. Through these studies so-called series-spectra have been attained for + various elements, and a comparison of these series-spectra with the + spectra of various stars has led to the conclusion that many of the + unknown lines previously traced in the spectra of such stars are due to + the decomposition products of familiar elements; all of which, of course, + is directly in line of proof of the dissociation hypothesis. + </p> + <p> + Another important result of Professor Lockyer's very recent studies has + come about through observation of the sun in eclipse. A very interesting + point at issue all along has been the question as to what layers of the + sun's atmosphere are efficient in producing the so-called reverse lines of + the spectrum. It is now shown that the effect is not produced, as formerly + supposed, by the layers of the atmosphere lying just above the region + which Professor Lockyer long ago named the chromosphere, but by the gases + of higher regions. Reasoning from analogy, it may be supposed that a + corresponding layer of the atmosphere of other stars is the one which + gives us the reverse spectrum of those stars. The exact composition of + this layer of the sidereal atmosphere must, of course, vary with the + temperature of the different stars, but in no case can we expect to + receive from the spectroscope a full record of all the substances that may + be present in other layers of the atmosphere or in the body of the star + itself. Thus, for example, the ordinary Freuenhofer spectrum of the sun + shows us no trace of the element helium, though through other observations + at the time of eclipse Professor Lockyer had discovered that element + there, as we have seen, some thirty years before anything was known of it + on the earth. + </p> + <p> + In a recent eclipse photographs were taken of the spectra of the lower + part of the sun's atmosphere by itself, and it was found that the spectrum + of this restricted area taken by itself gave the lines which specialize + the spectra of so different a star as Procyon. "I recognize in the + result," says Professor Lockyer, "a veritable Rosetta Stone which will + enable us to read the celestial hieroglyphics presented to us in stellar + spectra, and help us to study the spectra and to get at results much more + distinctly and certainly than ever before." + </p> + <p> + But the most striking confirmation which the meteoritic hypothesis has + received has come to hand through study of the spectrum of the new star + which appeared in the constellation Perseus in February, 1901, and which + was so widely heralded everywhere in the public press. This star was + discovered on the morning of February 22d by star-gazers in Scotland, and + in America almost simultaneously. It had certainly not been visible a few + hours before, and it had blazed up suddenly to a greater brilliancy than + that of a first-magnitude star. At first it was bluish-white in color, + indicating an extremely high temperature, but it rapidly subsided in + brilliancy and assumed a red color as it cooled, passing thus, in the + course of a few days, through stages for which ordinary stars require + periods of many millions of years. + </p> + <p> + The most interesting feature of the spectrum of this new star was the fact + that it showed both light and dark lines for the same substances, the two + lying somewhat apart. This means, being interpreted, that some portions of + a given substance are giving out light, thus producing the bright lines of + the spectrum, and that other portions of the same substance are stopping + certain rays of transmitted light, thus producing the dark lines. The + space between the bright and dark lines, being measured, indicated that + there was a differential motion between the two portions of substance thus + recorded of something like seven hundred miles a second. This means, + according to theory—and it seems hardly possible to explain it + otherwise—that two sidereal masses, one at least of which was moving + at an enormous rate of speed, had collided, such collision, of course, + being the cause of the incandescence that made the mass suddenly visible + from the earth as a new star. + </p> + <p> + New stars are by no means every-day affairs, there having been but + thirty-two of them recorded in the world's history, and of these only two + have exceeded the present one in brilliancy. As a mere spectacle, + therefore, this new star was of great interest; but a far greater + importance attaches to it through the fact that it conforms so admirably + to the course that meteoritic hypothesis would predict for it. "That is + what confounds my opponents," said Professor Lockyer, in talking to me + about the new star. "Most of those who oppose my theory have not taken the + trouble to make observations for themselves, but have contented themselves + with falling back apparently on the postulate that because a theory is new + it must be wrong. Then, outside the scientific world, comparatively few + people appreciate the extreme parsimony of nature. They expect, therefore, + that when such a phenomenon as the appearance of a new star occurs, the + new-comer will establish new rules for itself and bring chaos into the + scientific world. But in point of fact nature never does things in two + ways if she can possibly do them in one, and the most striking thing about + the new stars is that all the phenomena they present conform so admirably + to the laws built up through observation of the old familiar stars. As to + our particular theories, we here at South Kensington"—it will be + understood that this use of the editorial "we" is merely a modest + subterfuge on the part of Professor Lockyer—"have no regard for them + at all simply as ours. Like all scientists worthy the name, we seek only + the truth, and should new facts come along that seem to antagonize our + theory we should welcome them as eagerly as we welcome all new facts of + whatever bearing. But the truth is that no such new facts have appeared in + all these years, but that, on the contrary, the meteoritic hypothesis has + received ever-increasing support from most unexpected sources, from none + more brilliantly or more convincingly than from this new star in Perseus." + And I suspect that as much as this at least—if not indeed a good + deal more—will be freely admitted by every candid investigator of + Sir Norman Lockyer's theory. + </p> + <p> + SIR WILLIAM RAMSAY AND THE NEW GASES + </p> + <p> + The seat of Sir William Ramsay's labors is the University College, London. + The college building itself, which is located on Gower Street, is, like + the British Museum, reminiscent or rather frankly duplicatory in its + columned architecture of the classical. Interiorly it is like so many + other European institutions in its relative simplicity of equipment. One + finds, for example, Professor Ramsay and Dr. Travers generating the + hydrogen for their wonderful experiments in an old beer-cask. Professor + Ramsay himself is a tall, rather spare man, just entering the gray stage + of life, with the earnest visage of the scholar, the keen, piercing eye of + the investigator—yet not without a twinkle that justifies the + lineage of the "canny Scot." He is approachable, affable, genial, full of + enthusiasm for his work, yet not taking it with such undue seriousness as + to rob him of human interest—in a word, the type of a man of science + as one would picture him in imagination, and would hope, with confident + expectation, to find him in reality. + </p> + <p> + I have said that the equipment of the college is somewhat primitive, but + this must not be taken too comprehensively. Such instances as that of the + beer-cask show, to be sure, an adaptation of means to ends on economical + lines; yet, on the other hand, it should not be forgotten that the + beer-cask serves its purpose admirably; and, in a word, it may be said + that Professor Ramsay's laboratory contains everything that is needed to + equip it fully for the special work to which it has been dedicated for + some years past. In general, it looks like any other laboratory—glass + tubes, Bunsen burners, retorts and jars being in more or less meaningless + tangles; but there are two or three bits of apparatus pretty sure to + attract the eye of the casual visitor which deserve special mention. One + of these is a long, wooden, troughlike box which extends across the room + near the ceiling and is accessible by means of steps and a platform at one + end. Through this boxlike tube the chief expert in spectroscopy (Dr. + Bay-ley) spies on the spectrum of the gas, and learns some of its + innermost secrets. But an even more mystifying apparatus is an elaborate + array of long glass tubes, some of them carried to the height of several + feet, interspersed with cups of mercury and with thermometers of various + sizes and shapes. The technical scientist would not make much of this + description, but neither would an untechnical observer make much of the + apparatus; yet to Dr. Travers, its inventor, it is capable of revealing + such extraordinary things as the temperature of liquid hydrogen—a + temperature far below that at which the contents of even an alcoholic + thermometer are solidified; at which, indeed, the prime constituents of + the air suffer a like fate. The responsible substance which plays the part + of the familiar mercury, or alcohol, in Dr. Travers's marvellous + thermometer is hydrogen gas. The principle by which it is utilized does + not differ, in its rough essentials, from that of ordinary thermometers, + but the details of its construction are much too intricate to be + elaborated here. + </p> + <p> + But if you would see the most wonderful things in this laboratory—or + rather, to be quite accurate, I should say, if you would stand in the + presence of the most wonderful things—you must go with Professor + Ramsay to his own private laboratory, and be introduced to some little + test-tubes that stand inverted in cups of mercury decorating a shelf at + one end. You would never notice these tubes of your own accord were you to + browse ever so long about the room. Even when your attention is called to + them you still see nothing remarkable. These are ordinary test-tubes + inverted over ordinary mercury. They contain something, since the mercury + does not rise in them completely, but if that something be other than + ordinary air there is nothing about its appearance, or rather lack of + appearance, to demonstrate it. But your interest will hardly fail to be + arrested when Professor Ramsay, indicating one and another of these little + tubes, says: "Here you see, or fail to see, all the krypton that has ever + been in isolated existence in the world, and here all the neon, and here, + again, all the zenon." + </p> + <p> + You will understand, of course, that krypton, neon, and zenon are the new + gases of the atmosphere whose existence no one suspected until Professor + Ramsay ferreted them out a few years ago and isolated them. In one sense + there should be nothing mysterious about substances that every + air-breathing creature on the globe has been imbibing pretty constantly + ever since lungs came into fashion. But in another view the universal + presence of these gases in the air makes it seem all the more wonderful + that they could so long have evaded detection, considering that chemistry + has been a precise science for more than a century. During that time + thousands of chemists have made millions of experiments in the very midst + of these atmospheric gases, yet not one of the experimenters, until + recently, suspected their existence. This proves that these gases are no + ordinary substances—common though they be. Personally I have + examined many scientific exhibits in many lands, but nowhere have I seen + anything that filled my imagination with so many scientific visions as + these little harmless test-tubes at the back of Professor Ramsay's desk. + Perhaps I shall attempt to visualize some of these imaginings before + finishing this paper, but for the moment I wish to speak of the <i>modus + operandi</i> of the discovery of these additions to the list of elements. + </p> + <p> + The discovery of argon came about in a rather singular way. Lord Rayleigh, + of the Royal Institution, had noticed in experiments with nitrogen that + when samples of this element were obtained from chemicals, such samples + were uniformly about one per cent, lighter in weight than similar + quantities of nitrogen obtained from the atmosphere. This discrepancy led + him to believe that the atmospheric nitrogen must contain some impurity. + </p> + <p> + Curiously enough, the experiments of Cavendish, the discoverer of nitrogen—experiments + made more than a century ago—had seemed to show quite conclusively + that some gaseous substance different from nitrogen was to be found mixed + with the samples of this gas as he obtained it from the atmosphere. This + conclusion of Cavendish, put forward indeed but tentatively, had been + quite ignored by his successors. Now, however, it transpired, by + experiments made jointly by Lord Rayleigh and Professor Ramsay, that the + conclusion was quite justified, it being shown presently that there + actually exists in every portion of nitrogen, as extracted from the + atmosphere, a certain quantity of another gas, hitherto unknown, and which + now received the name of argon. It will be recalled with what astonishment + the scientific and the unscientific world alike received the announcement + made to the Royal Society in 1895 of the discovery of argon, and the proof + that this hitherto unsuspected constituent of the atmosphere really + constitutes about one per cent, of the bulk of atmospheric nitrogen, as + previously estimated. + </p> + <p> + The discovery here on the earth of a substance which Professor Lockyer had + detected as early as 1868 in the sun, and which he had provisionally named + helium, excited almost equal interest; but this element was found in + certain minerals, and not as a constituent of the atmosphere. + </p> + <p> + Having discovered so interesting a substance as argon, Professor Ramsay + and his assistants naturally devoted much time and attention to + elucidating the peculiarities of the new substance. In the course of these + studies it became evident to them that the presence of argon alone did not + fully account for all the phenomena they observed in handling liquefied + air, and in 1898 Professor Ramsay was again able to electrify his audience + at the Royal Society by the announcement of the discovery, in pretty rapid + succession, of three other elementary substances as constituents of the + atmosphere, these three being the ones just referred to—krypton, + neon, and zenon. + </p> + <p> + It is a really thrilling experience, standing in the presence of the only + portions of these new substances that have been isolated, to hear + Professor Ramsay and Dr. Travers, his chief assistant, tell the story of + the discovery—how they worked more and more eagerly as they found + themselves, so to say, on a "warmer scent," following out this clew and + that until the right one at last brought the chase to a successful issue. + "It was on a Sabbath morning in June, if I remember rightly, when we + finally ran zenon down," says Dr. Travers, with a half smile; and + Professor Ramsay, his eyes twinkling at the recollection of this very + unorthodox procedure, nods assent. "And have you got them all now?" I + queried, after hearing the story. "Yes; we think so," replied Professor + Ramsay. "And I am rather glad of it," he adds, with a half sigh, "for it + was wearisome even though fascinating work." Just how wearisome it must + have been only a professional scientific investigator can fully + comprehend; but the fascination of it all may be comprehended in some + measure by every one who has ever attempted creative work of whatever + grade or in whatever field. + </p> + <p> + I have just said that the little test-tubes contain the only bit of each + of the substances named that has ever been isolated. This statement might + lead the untechnical reader to suppose that these substances, once + isolated, have been carefully stored away and jealously guarded, each in + its imprisoning test-tubes. Jealously guarded they have been, to be sure, + but there has not been, by any means, the solitary confinement that the + words might seem to imply. On the contrary, each little whiff of gas has + been subjected to a variety of experiments—made to pass through + torturing-tubes under varying conditions of temperature, and brought + purposely in contact with various other substances, that its physical and + chemical properties might be tested. But in each case the experiment ended + with the return of the substance, as pure as before, to its proper tube. + The precise results of all these experiments have been communicated to the + Royal Society by Professor Ramsay. Most of these results are of a + technical character, hardly appealing to the average reader. There is one + very salient point, however, in regard to which all the new substances, + including argon and helium, agree; and it is that each of them seems to + be, so far as present experiments go, absolutely devoid of that + fundamental chemical property, the power to combine with other elements. + All of them are believed to be monatomic—that is to say, each of + their molecules is composed of a single atom. This, however, is not an + absolutely novel feature as compared with other terrestrial elements, for + the same thing is true, for example, of such a familiar substance as + mercury. But the incapacity to enter into chemical combinations seems very + paradoxical; indeed it is almost like saying that these are chemical + elements which lack the most fundamental of chemical properties. + </p> + <p> + It is this lack of combining power, of course, that explains the + non-discovery of these elements during all these years, for the usual way + of testing an element is to bring it in contact with other substances + under conditions that permit its atoms to combine with other atoms to the + formation of new substances. But in the case of new elements such + experiments as this have not proved possible under any conditions as yet + attained, and reliance must be had upon other physical tests—such as + variation of the bulk of the gas under pressure, and under varying + temperatures, and a study of the critical temperatures and pressures under + which each gas becomes a liquid. The chief reliance, however, is the + spectroscope—the instrument which revealed the presence of helium in + the sun and the stars more than a quarter of a century before Professor + Ramsay ferreted it out as a terrestrial element. Each whiff of colorless + gas in its test-tube interferes with the light passing through it in such + a way that when viewed through a prism it gives a spectrum of altogether + unique lines, which stamp it as krypton, neon, or zenon as definitely as + certain familiar and more tangible properties stamp the liquid which + imprisons it as mercury. + </p> + <p> + QUERIES SUGGESTED BY THE NEW GASES + </p> + <p> + Suppose that a few years ago you had asked some chemist, "What are the + constituents of the atmosphere?" He would have responded, with entire + confidence, "Oxygen and nitrogen chiefly, with a certain amount of + water-vapor and of carbonic-acid gas and a trace of ammonia." If + questioned as to the chief properties of these constituents, he would have + replied, with equal facility, that these are among the most important + elements; that oxygen might almost be said to be the life-giving + principle, inasmuch as no air-breathing creature could get along without + it for many moments together; and that nitrogen is equally important to + the organism, though in a different way, inasmuch as it is not taken up + through the lungs. As to the water-vapor, that, of course, is a compound + of oxygen and hydrogen, and no one need be told of its importance, as + every one knows that water makes up the chief bulk of protoplasm; + carbonic-acid gas is also a compound of oxygen, the other element this + time being carbon, and it plays a quite different rôle in the economy of + the living organism, inasmuch as it is produced by the breaking down of + tissues, and must be constantly exhaled from the lungs to prevent the + poisoning of the organism by its accumulation; while ammonia, which exists + only in infinitesimal quantities in the air, is a compound of nitrogen and + hydrogen, introducing, therefore, no new element. + </p> + <p> + If one studies somewhat attentively the relation which these elements + composing the atmosphere bear to the living organism he cannot fail to be + struck with it; and it would seem a safe inductive reasoning from the + stand-point of the evolutionist that the constituents of the atmosphere + have come to be all-essential to the living organism, precisely because + all their components are universally present. But, on the other hand, if + we consider the matter in the light of these researches regarding the new + gases, it becomes clear that perhaps the last word has not been said on + this subject; for here are four or five other elementary substances which, + if far less abundant than oxygen and nitrogen, are no less widely + distributed and universally present in the atmosphere, yet no one of which + apparently takes any chemical share whatever in ministering to the needs + of the living organism. This surely is an enigma. + </p> + <p> + Taking another point of view, let us try to imagine the real status of + these new gases of the air. We think of argon as connected with nitrogen + because in isolation experiments it remains after the oxygen has been + exhausted, but in point of fact there is no such connection between argon + and nitrogen in nature. The argon atom is just as closely in contact with + the oxygen in the atmosphere as with the nitrogen; it simply repels each + indiscriminately. But consider a little further; the argon atom not only + repels all advance on the part of oxygen and nitrogen, but it equally + holds itself aloof from its own particular kindred atoms. The oxygen or + nitrogen atom never rests until it has sought out a fellow, but the argon + atom declines all fellowship. When the chemist has played his tricks upon + it, it finds itself crowded together with other atoms of the same kind; + but lift up the little test-tube and these scurry off from one another in + every direction, each losing its fellows forever as quickly as possible. + </p> + <p> + As one ponders this one is almost disposed to suggest that the atom of + argon (or of krypton, helium, neon, or zenon, for the same thing applies + to each and all of these) seems the most perfect thing known to us in the + world, for it needs no companionship, it is self-sufficing. There is + something sublime about this magnificient isolation, this splendid + self-reliance, this undaunted and undauntable self-sufficiency—these + are traits which the world is wont to ascribe to beings more than mortal. + But let us pause lest we push too far into the old, discredited territory + of metaphysics. + </p> + <p> + PROFESSOR J. J. THOMPSON AND THE NATURE OP ELECTRICITY + </p> + <p> + Many fascinating questions suggest themselves in connection with these + strange, new elements—new, of course, only in the sense of human + knowledge—which all these centuries have been about us, yet which + have managed until now to keep themselves as invisible and as intangible + as spirits. Have these celibate atoms remained thus always isolated, + taking no part in world-building? Are they destined throughout the sweep + of time to keep up this celibate existence? And why do these elements + alone refuse all fellowship, while the atoms of all the other seventy-odd + known elements seek out mates under proper conditions with unvarying + avidity? + </p> + <p> + It is perhaps not possible fully to answer these questions as yet, but + recent studies in somewhat divergent fields give us suggestive clews to + some of them. I refer in particular to the studies in reference to the + passage of electricity through liquids and gases and to the observations + on radioactivity. The most conspicuous worker in the field of electricity + is Professor J. J. Thompson, who for many years has had charge of the + Cavendish laboratory at Cambridge. In briefly reviewing certain phases of + his work we shall find ourselves brought into contact with some of the + same problems raised by workers in the other fields of physics, and shall + secure some very interesting bits of testimony as to the solution of + questions already outlined. + </p> + <p> + The line of observation which has led to the most striking results has to + do, as already suggested, with the conduction of electricity through + liquids and gases. It has long been known that many liquids conduct + electricity with relative facility. More recently it has been observed + that a charge of electricity carried by any liquid bears a curious + relation to the atomic composition of that liquid. If the atom in question + is one of the sort that can combine with only a single other atom (that is + to say, a monovalent atom), each atom conveys a unit charge, which is + spoken of as an ion of electricity. But if a divalent atom is in question + the charge carried is double, and, similarly, a trivalent atom carries a + triple charge. As there are no intermediate charges it is obvious that + here a very close relation is suggested between electrical units and the + atomic units of matter. + </p> + <p> + This, however, is only a beginning. Far more interesting are the results + obtained by the study of gases in their relation to the conduction of + electricity. As is well known, gases under ordinary conditions are + nonconductors. But there are various ways in which a gas may be changed so + as to become a conductor; for example, by contact with incandescent metals + or with flame, or by treating with ultra-violet light, with Rôntgen rays, + or with the rays of a radio-active substance. Now the all-important + question is as to just what change has taken place in the gas so treated + to make it a conductor of electricity. I cannot go into details here as to + the studies that have been addressed to the answer of this question, but I + will briefly epitomize what, for our present purpose, are the important + results. First and foremost of these is the fact that a gas thus rendered + conductive contains particles that can be filtered out of it by passing + the gas through wool or through water. These particles are the actual + agents of conduction of electricity, since the gas when filtered ceases to + be conductive. But there is another way in which the particles may be + removed—namely, by action of electricity itself. If the gas be + caused to pass between two metal plates, one of them insulated and + attached to an electrometer, a charge of positive electricity at high + potential sent through the other plate will drive part of the particles + against the insulated plate. This proves that the particles in question + are positively electrified. The amount of the charge which they carry may + be measured by the electrometer. + </p> + <p> + The aggregate amount of the electrical charge carried by these minute + particles in the gas being known, it is obvious that could we know the + number of particles involved the simplest calculation would determine the + charge of each particle. Professor Thompson devised a singularly ingenious + method of determining this number. The method was based on the fact + discovered by C. T. R. Wilson that charged particles acted as nuclei round + which small drops of water condense much as dust particles serve the same + purpose. "In dust-free air," says Professor Thompson, "as Aitken showed, + it is very difficult to get a fog when damp air is cooled, since there are + no nuclei for the drops to condense round. If there are charged particles + in dust-free air, however, the fog will be deposited round these by + super-saturation far less than that required to produce any appreciable + fog when no charged particles are present. + </p> + <p> + "Thus, in sufficiently supersaturated damp air a cloud is deposited on + these charged particles and they are thus rendered visible. This is the + first step towards counting them. The drops are, however, far too small + and too numerous to be counted directly. We can, however, get their number + indirectly as follows: suppose we have a number of these particles in + dust-free air in a closed vessel, the air being saturated with + water-vapor; suppose now that we produce a sudden expansion of the air in + the vessel; this will cool the air, it will be supersaturated with vapor, + and drops will be deposited round the charged particles. Now if we know + the amount of expansion produced we can calculate the cooling of the gas, + and, therefore, the amount of water deposited. Thus we know the volume of + water in the form of drops, so that if we know the volume of one drop we + can deduce the number of drops. To find the size of a drop, we make use of + the investigations made by Sir George Stokes on the rate at which small + spheres fall through the air. In consequence of the viscosity of the air + small bodies fall exceedingly slowly, and the smaller they are the slower + they fall." * + </p> + <p> + Professor Thompson gives us the formula by which Stokes made his + calculation. It is a relatively simple algebraic one, but need not be + repeated here. For us it suffices that with the aid of this formula, by + merely measuring the actual descent of the top of a vapor cloud, Professor + Thompson was able to find the volume of the drops and thence the number of + particles. The number of particles being known, the charge of electricity + carried by each could be determined, as already suggested. Experiments + were made with air, hydrogen, and carbonic acid, and it was found that the + particles had the same charge in all of these gases. "A strong argument," + says Professor Thompson, "in favor of the atomic character of + electricity." When we add that the charge in question was found to be the + same as the unit charge of an ion in a liquid, it will be seen that the + experiment has other points of interest and suggestiveness. + </p> + <p> + Even more interesting in some regards were the results of computation as + to the actual masses of the charged particles in question. Professor + Thompson found that the carrier of a negative charge could have only about + one-thousandth part of the mass of a hydrogen atom, which latter had been + regarded as the smallest mass able to have an independent existence. + Professor Thompson gave the name corpuscle to these units of negative + electricity; they are now more generally termed electrons. "These + corpuscles," he says, "are the same however the electrification may have + risen or wherever they may be found. Negative electricity in a gas at a + low pressure has thus a structure analogous to that of a gas, the + corpuscles taking the place of the molecules. The 'negative electric + fluid,' to use the old notation, resembles the gaseous fluid with a + corpuscular instead of a molecular structure.'" Professor Thompson does + not hesitate to declare that we now "know more about 'electric fluid' than + we know about such fluids as air or water."*3* The results of his studies + lead him, he declares, "to a view of electrification which has a striking + resemblance to that of Franklin's <i>One Fluid Theory of Electricity</i>. + Instead of taking, as Franklin did, the electric fluid to be positive + electricity," he says, "we take it to be negative. The 'electric fluid' of + Franklin corresponds to an assemblage of corpuscles, negative + electrification being a collection of these corpuscles. The transference + of electrification from one place to another is effected by the motion of + corpuscles from the place where there is a gain of positive + electrification to the place where there is a gain of negative. A + positively electrified body is one that has lost some of its + corpuscles."*4* According to this view, then, electricity is not a form of + energy but a form of matter; or, to be more precise, the electrical + corpuscle is the fundamental structure out of which the atom of matter is + built. This is a quite different view from that scarcely less recent one + which regards electricity as the manifestation of ether strain, but it + must be admitted that the corpuscular theory is supported by a marvellous + array of experimental evidence, though it can perhaps hardly be claimed + that this brings the theory to the plane of demonstration. But all roads + of physical science of late years have seemed to lead towards the + electron, as will be made further manifest when we consider the phenomena + of radio-activity, to which we now turn. + </p> + <p> + RADIO-ACTIVITY + </p> + <p> + In 1896, something like a year after the discovery of the X-ray, + Niewenglowski reported to the French Academy of Sciences that the + well-known chemical compound calcium sulphide, when exposed to sunlight, + gave off rays that penetrated black paper. He had made his examinations of + this substance, since, like several others, it was known to exhibit strong + fluorescent or phosphorescent effects when exposed to the cathode rays, + which are known to be closely connected with the X-rays. This discovery + was followed very shortly by confirmatory experiments made by Becquerel, + Troost, and Arnold, and these were followed in turn by the discovery of Le + Bon, made almost simultaneously, that certain bodies when acted upon by + sunlight give out radiations which act upon a photographic plate. These + manifestations, however, are not the effect of radio-activity, but are + probably the effects of short ultra-violet light waves, and are not + produced spontaneously by the substances. The radiations, or emanations, + of the radio-active substances, on the other hand, are given out + spontaneously, pass through substances opaque to ordinary light, such as + metal plates, act upon photographic plates, and discharge electrified + bodies. The substances uranium, thorium, polonium, radium, and their + compounds are radioactive, radium being by far the most active. + </p> + <p> + The first definite discovery of such a radio-active substance was made by + M. Henri Becquerel, in 1896, while making some experiments upon the + peculiar ore pitch-blende. Pitch-blende is a heavy, black, pitchy-looking + mineral, found principally at present in some parts of Saxony and Bohemia + on the Continent, in Cornwall in Great Britain, and in Colorado in + America. It is by no means a recently discovered mineral, having been for + some years the source of uranium and its compounds, which, on account of + their brilliant colors, have been used in dye-stuffs and some kinds of + stained glass. It is a complex mineral, containing at least eight or ten + elements, which can be separated from it only with great difficulty and by + complicated chemical processes. + </p> + <p> + Becquerers discovery was brought about by a lucky accident, although, like + so many other apparently accidental scientific discoveries, it was the + outcome of a long series of scientific experiments all trending in the + same direction. He had found that uranium, when exposed to the sun's rays, + appeared to possess the property of absorbing them and of then acting upon + a photographic plate. Since pitch-blende contained uranium, or uranium + salts, he surmised that a somewhat similar result might be obtained with + the ore itself. He therefore prepared a photographic plate wrapped in + black paper, intending to attempt making an impression on the plate of + some metal body interposed between it and the pitch-blende. For this + purpose he had selected a key; but as the day proved to be cloudy he put + the plate, with the key and pitch-blende resting upon it, in a dark drawer + in his desk, and did not return to the experiment for several days. Upon + doing so, however, he developed the plate without further exposure, when + to his astonishment he found that the developed negative showed a distinct + impression of the key. Clearly this was the manifestation of a property + heretofore unknown in any natural substance, and was strikingly similar to + the action of the Roentgen rays. Further investigations by Lord Kelvin, + Beattie, Smolan, and Rutherford confirmed the fact that, like the Roentgen + rays, the uranium rays not only acted upon the photographic plate but + discharged electrified bodies. And what seemed the more wonderful was the + fact that these "Becquerel rays," as they were now called, emanated + spontaneously from the pitch-blende. But although this action is analogous + to the Roentgen rays, at least as regards its action upon the photographic + plate and its influence on the electric field, its action is extremely + feeble in comparison, the Roentgen rays producing effects in minutes, or + even seconds, which require days of exposure to uranium rays. The + discovery of the radio-active properties of uranium was followed about two + years later by the discovery that thorium, and the minerals containing + thorium, possess properties similar to those of uranium. This discovery + was made independently and at about the same time by Schmidt and Madame + Skaldowska Curie. But the importance of this discovery was soon completely + overshadowed by the discovery of radium by Madame Curie, working with her + husband, Professor Pierre Curie, at the École Polytechnique in Paris. + Madame Curie, stimulated by her own discoveries and those of the other + scientists just referred to, began a series of examinations upon various + substances by numerous complicated methods to try and find a possible new + element, as certain peculiarities of the substances found in the + pitch-blende seemed to indicate the presence of some hitherto unknown + body. The search proved a most difficult one on account of the peculiar + nature of the object in question, but the tireless enthusiasm of Madame + Curie knew nothing of insurmountable obstacles, and soon drew her husband + into the search with her. Her first discovery was that of the substance + polonium—so named by Madame Curie after her native country, Poland. + This proved to be another of the radio-active substances, differing from + any other yet discovered, but still not the sought-for element. In a short + time, however, the two Curies made the great discovery of the element + radium—a substance which, according to their estimate, is some one + million eight hundred thousand times more radioactive than uranium. The + name for this element, <i>radium</i>, was proposed by Madame Curie, who + had also suggested the term "radio-activity." + </p> + <p> + The bearing of the discovery of radium and radioactivity upon theories of + the atom and matter will be considered in a moment; first the more + tangible qualities of this wonderful substance may be briefly referred to. + The fact that radio-active emanations traverse all forms of matter to + greater or less depth—that is, pass through wood and iron with + something the same ease that light passes through a window-glass—makes + the subject one of greatest interest; and particularly so as the + demonstration of this fact is so tangible. While the rays given out by + radium cannot, of course, be seen by the unaided eye, the effects of these + rays upon certain substances, which they cause to phosphoresce, are + strikingly shown. One of such substances is the diamond, and a most + striking illustration of the power of radium in penetrating opaque + substances has been made by Mr. George F. Kunz, of the American Museum of + Natural History. Mr. Kunz describes this experiment as follows: + </p> + <p> + "Radium bromide of three hundred thousand activity was placed in a sealed + glass tube inside a rubber thermometer-holder, which was tightly screwed + to prevent any emanation of any kind from passing through the joints. This + was placed under a heavy silver tureen fully one-sixteenth of an inch in + thickness; upon this were placed four copper plates, such as are used for + engraving; upon these a heavy graduated measuring-glass 10 cm. in + diameter; this was filled with water to a depth of six inches. A diamond + was suspended in the water and immediately phosphoresced. Whenever the + tube of radium was drawn away more than two or three feet the phosphoresce + ceased; whenever it was placed under the tureen the diamond immediately + phosphoresced again. This experiment proves that the active power of the + radium penetrated the following substances: + </p> + <p> + "Glass in the form of a tube, sealed at both ends; the rubber + thermometer-holder; silver tureen; four copper plates; a glass vase or + measuring-glass one-quarter of an inch in thickness; three inches of + water. There is no previously known substance or agent, whether it be even + light or electricity, that possesses such wonderfully penetrative + powers."*5* + </p> + <p> + THE NATURE OF EMANATIONS FROM RADIO-ACTIVE BODIES + </p> + <p> + What, then, is the nature of these radiations? Are they actually material + particles hurled through the ether? Or are they like light—and + possibly the Roentgen rays—simply undulations in the ether? As yet + this question is an open one, although several of the leading + investigators have postulated tentative hypotheses which at least serve as + a working basis until they are either confirmed or supplanted. On one + point, however, there seems to be unanimity of opinion—there seems + to be little question that there are at least three different kinds of + rays produced by radio-active substances. According to Sir William + Crookes, the first of these are free electrons, or matter in an + ultra-gaseous state, as shown in the cathode stream. These particles are + extremely minute. They carry a negative charge of electricity, and are + identified with the electric corpuscles of Thompson. Rays of the second + kind are comparable in size to the hydrogen atom, and are positively + electrified. These are easily checked by material obstructions, although + they render the air a conductor and affect photographic plates. The third + are very penetrating rays, which are not deflected by electricity and + which are seemingly identical with Roentgen rays. Professor E. Rutherford + has named these rays beta (B), alpha (a), and gamma (v) rays respectively. + Of these the beta rays are deviated strongly by the magnetic field, the + alpha much less so—very slightly, in fact—while the gamma rays + are not affected at all. The action of these three different sets of rays + upon certain substances is not the same, the beta and gamma rays acting + strongly upon barium platinocyanide, but feebly on Sidot's blende, while + the alpha rays act exactly the reverse of this, acting strongly on Sidot's + blende. + </p> + <p> + If a surface is coated with Sidot's blende and held near a piece of radium + nitrate, the coated surface begins to glow. If now it is examined with a + lens, brilliant sparks or points can be seen. As the radium is brought + closer and closer these sparks increase in number, until, as Sir William + Crookes says, we seem to be witnessing a bombardment of flying atoms + hurled from the radium against the surface of the blende. A little + instrument called a spinthariscope, devised by Dr. Crookes and on sale at + the instrument and optical-goods shops, may be had for a trifling sum. It + is fitted with a lens focused upon a bit of Sidot's blende and radium + nitrate, and in a dark room shows these beautiful scintillations "like a + shower of stars." A still less expensive but similar device is now made in + the form of a microscopic slide, to be used with the ordinary lens. + </p> + <p> + As we said a moment ago, radium appears to be an elementary substance, as + shown by its spark-spectrum being different from that of any other known + substance—the determinative test as fixed by the International + Chemical Congress. A particle of radium free from impurities should, + therefore, according to the conventional conception of an element, remain + unchanged and unchangeable. If any such change did actually take place it + would mean that the conception of the Daltonian atom as the ultimate + particle of matter is definitively challenged from a new direction. This + is precisely what has taken place. In July of 1903 Sir William Ramsay and + Mr. Soddy, in making some experiments with radium, saw produced, + apparently from radium emanations, another quite different and distinct + substance, the element helium. The report of such a revolutionary + phenomenon was naturally made with scientific caution. Though the + observation seemed to prove the actual transformation of one element into + another, Professor Ramsay himself was by no means ready to declare the + absolute certainty of this. Yet the presumption in favor of this + interpretation of the observed phenomena is very strong; and so cautious a + reasoner as Professor Rutherford has declared recently that "there can be + no doubt that helium is derived from the emanations of radium in + consequence of changes of some kind occurring in it."*6* + </p> + <p> + "In order to explain the presence of helium in radium on ordinary chemical + lines," says Professor Rutherford, "it has been suggested that radium is + not a true element, but a molecular compound of helium with some substance + known or unknown. The helium compound gradually breaks down, giving rise + to the helium observed. It is at once obvious that this postulated helium + compound is of an entirely different character to any other compound + previously observed in chemistry. Weight for weight, it emits during its + change an amount of energy at least one million times greater than any + molecular compound known. In addition, it must be supposed that the rate + of breaking up of the helium compound is independent of great ranges of + temperature—a result never before observed in any molecular change. + The helium compound in its breaking up must give rise to the peculiar + radiations and also pass through the successive radio-active change + observed in radium.... On the other hand, radium, as far as it has been + examined, has fulfilled every test required of an element. It has a + well-marked and characteristic spectrum, and there is no reason to suppose + that it is not an element in the ordinarily accepted sense of the + term."*7* + </p> + <p> + THE SOURCE OF ENERGY OF RADIO-ACTIVITY + </p> + <p> + In 1903 Messrs. Curie and Laborde*8* made the remarkable announcement that + a crystal of radium is persistently warmer than its surrounding medium; in + other words, that it is perpetually giving out heat without apparently + becoming cooler. At first blush this seemed to contradict the great + physical law of the conservation of energy, but physicists were soon + agreed that a less revolutionary explanation of the phenomenon is + perfectly tenable. The giving off of heat is indeed only an additional + evidence of the dissipation of energy to which the radio-active atom is + subjected. And no one now believes that radio-activity can persist + indefinitely without actually exhausting the substance of the atom. Even + so, the evidence of so great a capacity to give out energy is startling, + and has given rise to various theories (all as yet tentative) in + explanation. Thus J. Perrin*9* has suggested that atoms may consist of + parts not unlike a miniature planetary system, and in the atoms of the + radio-elements the parts more distant from the centre are continually + escaping from the central attraction, thus giving rise to the radiations. + Monsieur and Madame Curie have suggested that the energy may be borrowed + from the surrounding air in some way, the energy lost by the atom being + instantly regained. Pilipo Re,*10* in 1903, advanced the theory that the + various parts of the atom might at first have been free particles + constituting an extremely tenuous nebula. + </p> + <p> + These parts gradually becoming collected around condensed centres have + formed what we know as the atoms of elements, the atom thus becoming like + an extinct sun of the solar system. From this point of view the + radio-active atoms represent an intermediate stage between nebulae and + chemical atoms, the process of contraction giving rise to the heat + emissions. + </p> + <p> + Lord Kelvin has called attention to the fact that when two pieces of + paper, one white and the other black, are placed in exactly similar glass + vessels of water and exposed to light, the temperature of the vessel + containing the black paper is raised slightly higher than the other. This + suggests the idea that in a similar manner radium may keep its temperature + higher than the surrounding air by the absorption of other radiations as + yet unknown. + </p> + <p> + Professor J. J. Thompson believes that the source of energy is in the atom + itself and not external to it. "The reason," he says, "which induces me to + think that the source of the energy is in the atom of radium itself and + not external to it is that the radio-activity of substances is in all + cases in which we have been able to localize it a transient property. No + substance goes on being radio-active very long. It may be asked, how can + this statement be reconciled with the fact that thorium and radium keep up + their activity without any appreciable falling off with time. The answer + to this is that, as Rutherford and Soddy have shown in the case of + thorium, it is only an exceedingly small fraction of the mass which is at + any one time radio-active, and that this radio-active portion loses its + activity in a few hours, and has to be replaced by a fresh supply from the + non-radio-active thorium."*11* + </p> + <p> + If Professor Thompson's view be correct, the amount of potential energy + inherent in the atom must be enormous. + </p> + <p> + RADIO-ACTIVITY AND THE STRUCTURE OF THE ATOM + </p> + <p> + But whatever the source of the energy displayed by the radio-active + substances, it is pretty generally agreed that the radio-activity of the + radio-elements results in the disruption of their atoms. Since all + substances appear to be radio-active in a greater or less degree, it would + seem that, unless there be a very general distribution of radio-active + atoms throughout all substances, all atoms must be undergoing disruption. + Since the distribution of radio-active matter throughout the earth is so + great, however, it is as yet impossible to determine whether this may not + account for the radio-activity of all substances. + </p> + <p> + As we have just seen, recent evidence seems to point to the cause of the + disruption of radio-active atoms as lying in the atoms themselves. This + view is quite in accord with modern ideas of the instability of certain + atoms. It has been suggested that some atoms may undergo a slower + disintegration without necessarily throwing off part of their systems with + great velocity. It is even possible that all matter may be undergoing + transformation, this transformation tending to simplify and render more + stable the constituents of the earth. The radio-active bodies, however, + are the only ones that have afforded an opportunity for studying this + transformation. In these the rapidity of the change would be directly + proportionate to their radioactivity. Radium, according to the recent + estimate of the Curies, would be disintegrating over a million times more + rapidly than uranium. Since the amount of transformation occurring in + radium in a year amounts to from 1-2000 to 1-10,000 of the total amount, + the time required for the complete transformation of an atom of uranium + would be somewhere between two billion and ten billion years—figures + quite beyond the range of human comprehension. + </p> + <p> + Various hypotheses have been postulated to account for the instability of + the atom. Perhaps the most thinkable of these to persons not specially + trained in dealing with abstruse subjects is that of Professor Thompson. + It has the additional merit, also, of coming from one of the best-known + investigators in this particular field. According to this hypothesis the + atom may be considered as a mass of positively and negatively charged + particles, all in rapid motion, their mutual forces holding them in + equilibrium. In case of a very complex structure of this kind it is + possible to conceive of certain particles acquiring sufficient kinetic + energy to be projected from the system. Or the constraining forces may be + neutralized momentarily, so that the particle is thrown off at the same + velocity that it had acquired at the instant it is released. The primary + cause of this disintegration of the atom may be due to electro-magnetic + radiation causing loss of energy of the atomic system. + </p> + <p> + Sir Oliver Lodge suggests that this instability of the atom may be the + result of the atom's radiation of energy. "Lodge considered the simple + case of a negatively charged electron revolving round an atom of mass + relatively large but having an equal positive charge and held in + equilibrium by electrical forces. This system will radiate energy, and + since the radiation of energy is equivalent to motion in a resisting + medium, the particle tends to move towards the centre and its speed + consequently increases. The rate of radiation of energy will increase + rapidly with the speed of the electron. When the speed of the electron + becomes very nearly equal to the velocity of light, according to Lodge, + the system is unstable. It has been shown that the apparent mass of an + electron increases very rapidly as the speed of light is approached, and + is theoretically infinite at the speed of light. There will be at this + stage a sudden increase of the mass of the revolving atom, and, on the + supposition that this stage can be reached, a consequent disturbance of + the balance of forces holding the system together. Lodge considers it + probable that under these conditions the parts of the system will break + asunder and escape from the sphere of one another's influence. + </p> + <p> + "It is probable," adds Rutherford, "that the primary cause of the + disintegration of the atom must be looked for in the 1 ss of energy of the + atomic system due to electro-magnetic radiation."*12* + </p> + <p> + Several methods have been devised for testing the amount of heat given off + by radium and its compounds, and for determining its actual rise in + temperature above that of the surrounding atmosphere. One of these methods + is to place some substance, such as barium chloride, in a calorimeter, + noting at what point the mercury remains stationary. Radium is then + introduced, whereupon the mercury in the tube gradually rises, falling + again when the radium is removed. By careful tests it has been determined + that a gram of radium emits about twenty-four hundred gram-calories in + twenty-four hours. On this basis a gram of radium in a year emits enough + energy to dissociate about two hundred and twenty-five grams of water. + </p> + <p> + What seems most remarkable about this constant emission of heat by the + radium atom is that it does not apparently draw upon external sources for + it, but maintains it by the internal energy of the atom itself. This + latent energy must be enormous, but is only manifested when the atom is + breaking up. In this process of disruption many of the particles are + thrown off; but the greater part seem to be stopped in their flight in the + radium itself, so that their energy of motion is manifested in the form of + heat. Thus, if this explanation is correct, the temperature of the radium + is maintained above that of surrounding substances by the bombardment of + its own particles. Since the earth and the atmosphere contain appreciable + quantities of radio-active matter, this must play a very important part in + determining the temperature of the globe—so important a part, + indeed, that all former estimates as to the probable length of time during + which the earth and sun will continue to radiate heat are invalidated. + Such estimates, for example, as that of Lord Kelvin as to the probable + heat-giving life of the sun must now be multiplied from fifty to five + hundred times. + </p> + <p> + In like manner the length of time that the earth has been sufficiently + cool to support animal and vegetable life must be re-estimated. Until the + discovery of radium it seemed definitely determined that the earth was + gradually cooling, and would continue to cool, un til, like the moon, it + would become too cold to support any kind of vegetable or animal life + whatever. But recent estimates of the amount of radio-active matter in the + earth and atmosphere, and the amount of heat constantly given off from + this source, seem to indicate that the loss of heat is (for the moment) + about evenly balanced by the heat given out by radio-active matter. Thus + at the beginning of the new century we see the phenomenon of a single + discovery in science completely overturning certain carefully worked out + calculations, although not changing the great principles involved. It is + but the repetition of the revolutionary changes that occur at intervals in + the history of science, a simple discovery setting at naught some of the + most careful calculations of a generation. + </p> + <p> + <a name="link2H_4_0007" id="link2H_4_0007"> + <!-- H2 anchor --> </a> + </p> + <div style="height: 4em;"> + <br /><br /><br /><br /> + </div> + <h2> + V. THE MARINE BIOLOGICAL LABORATORY AT NAPLES + </h2> + <p> + THE AQUARIUM + </p> + <p> + MANY tourists who have gone to Naples within recent years will recall + their visit to the aquarium there among their most pleasant experiences. + It is, indeed, a place worth seeing. Any Neapolitan will direct you to the + beautiful white building which it occupies in the public park close by the + water's side. The park itself, statue-guarded and palm-studded, is one of + the show-places of the city; and the aquarium building, standing isolated + near its centre, is worthy of its surroundings. As seen from the bay, it + gleams white amid the half-tropical foliage, with the circling rampart of + hills, flanked by Vesuvius itself, for background. And near at hand the + picturesque cactus growth scrambling over the walls gives precisely the + necessary finish to the otherwise rather severe type of the architecture. + The ensemble prepares one to be pleased with whatever the structure may + have to show within. + </p> + <p> + It prepares one also, though in quite another way, for a surprise; for + when one has crossed the threshold and narrow vestibule, while the gleam + of the outside brightness still glows before his eyes, he is plunged + suddenly into what seems at first glimpse a cavern of Egyptian darkness, + and the contrast is nothing less than startling. To add to the effect, one + sees all about him, near the walls of the cavern, weird forms of moving + creatures, which seem to be floating about lazily in the air, in grottos + which glow with a dim light or sparkle with varied colors. One is really + looking through glass walls into tanks of water filled with marine life; + but both glass and water are so transparent that it is difficult at first + glimpse to realize their presence, unless a stream of water, with its + attendant bubbles, is playing into the tanks. And even then the effect is + most elusive; for the surface of the water, which you are looking up to + from below, mirrors the contents of the tanks so perfectly that it is + difficult to tell where the reality ends and the image begins, were it not + that the duplicated creatures move about with their backs downward in a + scene all topsy-turvy. The effect is most fantastic. + </p> + <p> + More than that, it is most beautiful as well. You are, in effect, at the + bottom of the ocean—or rather, at the bottom of many oceans in one. + No light comes to you except through the grottos about you—grottos + haunted by weird forms of the deep, from graceful to grotesque, from + almost colorless to gaudy-hued. To your dilated pupils the light itself + has the weird glow of unreality. It is all like the wonders of the Arabian + Nights made tangible or like a strange spectacular dream. If one were in a + great diving-bell at the bottom of the veritable ocean he could hardly + feel more detached from the ordinary aerial world of fact. + </p> + <p> + As one recovers his senses and begins to take definite note of things + about him he sees that each one of the many grottos has a different set of + occupants, and that not all of the creatures there are as unfamiliar as at + first they seemed. Many of the fishes, for example, and the lobsters, + crabs, and the like, are familiar enough under other conditions, but even + these old acquaintances look strange under these changed circumstances. + But for the rest there are multitudes of forms that one had never seen or + imagined, for the sea hides a myriad of wonders which we who sail over its + surface, and at most glance dimly a few feet into its depths, hardly dream + of. Even though one has seen these strange creatures "preserved" in + museums, he does not know them, for the alleged preservation there has + retained little enough of essential faciès of the real creature, which the + dead shell can no more than vaguely suggest. + </p> + <p> + Here, however, we see the real thing. Each creature lives and moves in a + habitat as nearly as may be like that which it haunted when at liberty, + save that tribes that live at enmity with one another are here separated, + so that the active struggle for existence, which plays so large a part in + the wild life of sea as well as land, is not represented. For the rest the + creatures of the deep are at home in these artificial grottos, and disport + themselves as if they desired no other residence. For the most part they + pay no heed whatever to the human inspectors without their homelike + prisons, so one may watch their activities under the most favorable + conditions. + </p> + <p> + It is odd to notice how curiously sinuous are all the movements, not alone + of the fish, but of a large proportion of the other forms of moving life + of the waters. The curve, the line of beauty, is the symbol of their every + act; there are no angles in their world. They glide hither and yon, + seemingly without an effort, and always with wavy, oscillating + gracefulness. The acme of this sinuosity of movement is reached with those + long-drawn-out fishes the eels. Of these there are two gigantic species + represented here—the conger, a dark-skinned, rather ill-favored + fellow, and the beautiful Italian eel, with a velvety, leopard-spotted + skin. These creatures are gracefulness itself. They are ribbon-like in + tenuousness, and to casual glance they give the impression of long, narrow + pennants softly waving in a gentle breeze. The great conger—five or + six feet in length—has, indeed, a certain propensity to extend + himself rigidly in a fishlike line and lie immovable, but the other + species is always true to his colors, so to say—his form is always + outlined in curves. + </p> + <p> + The eels attract their full share of attention from the visitors, but + there is one family of creatures which easily holds the palm over all the + others in this regard. These are the various representatives of the great + cult of squids and cuttle-fishes. The cuttle-fish proper—who, of + course, is no fish at all—is shaped strangely like a diminutive + elephant, with a filmy, waving membrane along its sides in lieu of legs. + Like the other members of his clan, he can change his color variously. + Sometimes he is of a dull brown, again prettily mottled; then, with almost + kaleidoscopic suddenness, he will assume a garb beautifully striped in + black and white, rivalled by nothing but the coat of the zebra. The + cuttle-fish is a sluggish creature, seeking out the darker corners of his + grotto, and often lying motionless for long periods together. But not so + the little squid. He does not thrive in captivity, and incessantly wings + his way back and forth, with slow, wavy flappings of his filmy appendages, + until he wears himself out and dies unreconciled. + </p> + <p> + In marked contrast with both cuttle-fish and squid is their cousin the + octopus—a creepy, crawly creature, like eight serpents in one—at + once the oddest and the most fascinating creature in the entire aquarium. + You will find a crowd almost always before his grotto watching his curious + antics. Usually slow and deliberate in movement, he yet has capacity for a + certain agility. Now and again he dives off suddenly, head first, through + the water, with the directness if not quite with the speed of an arrow. A + moment later, tired of his flight, he sprawls his eight webbed legs out in + every direction, breaking them seemingly into a thousand joints, and + settles back like an animated parachute awreck. Then perchance he perches + on a rock knowingly, with the appearance of owl-like wisdom, albeit his + head looks surprisingly like a frog's. Anon he holds his head erect and + stretches out his long arms in what is most palpably a yawn. Then, for + pure diversion, he may hold himself half erect on his umbrella frame of + legs and sidle along a sort of quadrille—a veritable "eight hands in + round." + </p> + <p> + But all the while he conveys distinctly the impression of a creature to + the last degree blasé. Even when a crab is let down into his grotto by an + attendant for the edification of the visitors the octopus seems to regard + it with only lukewarm interest. If he deigns to go in pursuit, it is with + the air of one who says, "Anything to oblige," rather than of eagerness + for a morsel of food. Yet withal, even though unhurried, he usually falls + upon the victim with surprising sureness of aim, encompassing it in his + multiform net. Or perhaps, thinking the game hardly worth so much effort, + he merely reaches out suddenly with one of his eight arms—each of + which is a long-drawn-out hand as well—and grasps the victim and + conveys it to his distensible maw without so much as changing his + attitude. + </p> + <p> + All this of the giant octopus—brown and warty and wrinkled and + blasé. But the diminutive cousin in the grotto with the jellyfishes is a + bird of quite another feather. Physically he is constructed on the same + model as the other, but his mentality is utterly opposed. No grand rôles + for him; his part is comedy. He finds life full of interest. He is + satisfied with himself and with the world. He assumes an aspect of + positive rakishness, and intelligence, so to say, beams from his every + limb. All day long he must be up and doing. For want of better business he + will pursue a shrimp for hours at a time with the zest of a true + sportsman. Now he darts after his intended prey like a fox-hound. Again he + resorts to finesse, and sidles off, with eyes fixed in another direction, + like a master of stratagem. To be sure, he never catches the shrimp—but + what of that? The true sportsman is far removed from the necessity for + mere material profit. I half suspect that little octopus would release the + shrimp if once he caught him, as the true fisherman throws back the excess + of his catch. It is sport, not game, that he covets. + </p> + <p> + THE LABORATORY AND ITS FOUNDER + </p> + <p> + When one has made the circuit of the aquarium he will have seen and + marvelled at some hundreds of curious creatures utterly unlike anything to + be found above water. Brightly colored starfishes, beautiful sea-urchins, + strange stationary ascidians, and flower-like sea-anemones, quaint + sea-horses, and filmy, fragile jellyfishes and their multiform kin—all + seem novel and wonderful as one sees them in their native element. Things + that appear to be parts of the rocky or sandy bed of the grottos startle + one by moving about, and thus discovering themselves as living creatures, + simulating their environment for purposes of protection. Or perhaps what + seems to be a giant snail suddenly unfurls wings from its seeming shell, + and goes waving through the water, to the utter bewilderment of the + beholder. Such freaks as this are quite the rule among the strange tribes + of the deep, for the crowding of population there makes the struggle for + existence keen, and necessitates all manner of subterfuges for the + preservation of species. + </p> + <p> + Each and every one of the thirty-odd grottos will repay long observation, + even on the part of the most casual visitor, and when one has seen them + all, he will know more at first hand of the method of life of the + creatures of the sea than all the books could teach him. He will depart + fully satisfied, and probably, if he be the usual sight-seer, he will + never suspect that what he has seen is really but an incidental part of + the institution whose building he has entered. Even though he note + casually the inscription "Stazione Zoôlogica" above the entrance, he may + never suspect that the aquarium he has just visited is only an adjunct—the + popular exhibit, so to speak—of the famous institution of technical + science known to the English-speaking world as the Marine Biological + Laboratory at Naples. Yet such is the fact. The aquarium seems worthy + enough to exist by and for itself. It is a great popular educator as well + as amuser, yet its importance is utterly insignificant compared with the + technical features of the institution of which it is an adjunct. + </p> + <p> + This technical department, the biological laboratory proper, has its local + habitation in the parts of the building not occupied by the aquarium—parts + of which the general public, as a rule, sees nothing. There is, indeed, + little to see that would greatly interest the casual inspector, for in its + outward aspects one laboratory is much like another, a seeming hodgepodge + of water-tanks, glass jars of specimens, and tables for microscopes. The + real status of a laboratory is not determined by the equipment. + </p> + <p> + And yet it will not do to press this assertion too far, for in one sense + it is the equipment of the Naples laboratory that has made it what it is. + Not, however, the equipment in the sense of microscopes and other working + paraphernalia. These, of course, are the best of their kind, but machinery + alone does not make a great institution, any more than clothes make the + man. The all-essential and distinctive equipment of the laboratory reveals + itself in its personnel. In the present case, as always in a truly great + institution of any kind, there is one dominating personality, one moving + spirit. This is Dr. Anton Dohrn, founder of the laboratory, and still its + controller and director, in name and in fact. + </p> + <p> + More than twenty-five years ago Dr. Dohrn, then a young man fresh from the + universities of his native Germany, discovered what he felt to be a real + need in the biological world. He was struck with the fact that nowhere in + the world could be found an establishment affording good opportunities for + the study of marine life. Water covers three-fifths of the earth's + surface, as everybody knows, and everywhere this water teems with life, so + that a vast preponderance of the living things of the globe find their + habitat there. Yet the student who might desire to make special studies of + this life would find himself balked at the threshold for want of + opportunity. + </p> + <p> + It was no great thing to discover this paucity, which, indeed, fairly + beckoned the discoverer. The great thing was to supply the deficiency, and + this was what Dr. Dohrn determined to do. He selected Naples as the best + location for the laboratory he proposed to found, because of its climate + and its location beside the teeming waters of the Mediterranean. He + organized a laboratory; he called about him a corps of able assistants; he + made the Marine Biological Laboratory at Naples famous, the Mecca of all + biological eyes throughout the world. It was not all done in a day. It was + far enough from being done without opposition and discouragement; but + these are matters of history which Dr. Dohrn now prefers not to dwell + upon. Suffice it that the result aimed at was finally achieved, and in far + greater measure than could at first be hoped for. + </p> + <p> + And from that day till this Naples has been the centre of that branch of + biological inquiry which has for its object the investigation of problems + best studied with material gathered from the sea. And this, let me hasten + to add, includes far more than a mere study of the life histories of + marine animals and plants as such. It includes problems of cell activity, + problems of heredity, life problems of many kinds, having far wider + horizons than the mere question as to how a certain fish or crustacean + lives and moves and has its being. + </p> + <p> + Dr. Dohrn's chief technical associates are all Germans, like their leader, + but, like him also, all gifted with a polyglot mastery of tongues that has + stood them in good stead in their intercourse with the biologists of many + nationalities who came to work at the laboratory. I must not pause to + dwell upon the personnel of the staff in general, but there is one other + member who cannot be overlooked even in the most casual survey of the work + of the institution. One might almost as well forget Dr. Dohrn himself as + to overlook Signor Lo Bianco, chief of the collecting department. Signor + Bianco it is who, having expert knowledge of the haunts and habits of + every manner of marine creature, can direct his fishermen where to find + and how to secure whatever rare specimen any worker at the laboratory may + desire. He it is, too, who, by studying old methods and inventing new + ones, has learned how to preserve the delicate forms for subsequent study + in lifelike ensemble that no one else can quite equal. Signor Bianco it + is, in short, who is the indispensable right-hand man of the institution + in all that pertains to its practical working outside the range of the + microscope. Each night Signor Lo Bianco directs his band of fishermen as + to what particular specimens are most to be sought after next day to meet + the needs of the workers in the laboratory. Before sunrise each day, + weather permitting, the little scattered fleet of boats is far out on the + Bay of Naples; for the surface collecting, which furnishes a large share + of the best material, can be done only at dawn, as the greater part of the + creatures thus secured sink into the retirement of the depths during the + day, coming to the surface to feed only at night. You are not likely to + see the collecting party start out, therefore, but if you choose you may + see them return about nine or ten o'clock by going to the dock not far + from the laboratory. The boats come in singly at about this hour, their + occupants standing up to row, and pushing forward with the oars, after the + awkward Neapolitan fashion. Many of the fishermen are quaint enough in + appearance; some of them have grown old in the service of the laboratory. + The morning's catch is contained in glass jars placed in baskets + especially constructed for the purpose. The baskets have handles, but + these are quite superfluous except to lift them from the boats, for in the + transit to the laboratory the baskets are carried, as almost everything + else is carried in Naples, on the head. To the novitiate it seems a + striking risk to pile baskets of fragile glass and even more fragile + specimens one above another, and attempt to balance the whole on the head, + but nothing could be easier, or seemingly more secure, for these experts. + Arrived at the laboratory, the jars are turned over to Signer Lo Bianco + and his assistants, who sort the material, and send to each investigator + in the workrooms whatever he may have asked for. + </p> + <p> + Of course surface-skimming is not the only method of securing material for + the laboratory. The institution owns a steam-launch named the <i>Johannes + Müller</i>, in honor of the great physiologist, which operates a powerful + dredge for securing all manner of specimens from the sea-bottom. Then + ordinary lines and nets are more or less in requisition for capturing + fish. And in addition to the regular corps of collectors, every fisherman + of the neighborhood has long since learned to bring to the laboratory all + rare specimens of any kind that he may chance to capture. So in one way + and another the institution makes sure of having in tribute all that the + richly peopled waters of the Mediterranean can offer. And this + well-regulated system of collecting, combined with the richness of the + fauna and flora of the Bay of Naples, has no small share in the success of + the marine laboratory. But these, of course, were factors that Dr. Dohrn + took into account from the beginning. + </p> + <p> + Indeed, it was precisely with an eye to these important factors that + Naples was selected as the site of the future laboratory in the days when + the project was forming. + </p> + <p> + The Bay of Naples is most happily located for the needs of the zoologist. + It is not too far south to exclude the fauna of the temperate zone, yet + far enough south to furnish a habitat for many forms of life almost + tropical in character. It has, in short, a most varied and abundant fauna. + And, on the other hand, the large colony of Neapolitan fishermen made it + certain that skilled collectors would always be at hand to make available + the wealth of material. It requires no technical education to appreciate + the value of this to the original investigator, particularly to the + student of life problems. A skilful worker may do much with a single + specimen, as, for example, Johannes Mûller did half a century ago with the + one available specimen of amphioxus, the lowest of vertebrates, then + recently discovered. What Mûller learned from that one specimen seems + almost miraculous. But what if he had had a bucketful of the little + boneless creatures at his disposal, as the worker at Naples now may have + any day for the asking? + </p> + <p> + When it comes to problems of development, of heredity, a profusion of + material is almost a necessity. But here the creatures of the sea respond + to the call with amazing proficiency. Most of them are, of course, + oviparous, and it is quite the rule for them to deposit their eggs by + hundreds of thousands, by millions even. Everybody knows, since Darwin + taught us, that the average number of offspring of any given species of + animal or plant bears an inverse proportion to the liability of that + species to juvenile fatalities. When, therefore, we find a fish or a + lobster or other pelagic creature depositing innumerable eggs, we may feel + perfectly sure that the vast majority of the eggs themselves, or the + callow creatures that come out of them, will furnish food for their + neighbors at an early day. It is an unkind world into which the resident + of the deep is born. But his adversity is his human contemporary's gain, + and the biologist will hardly be blamed, even by the most tender-hearted + anti-vivisectionist, for availing himself freely of material which + otherwise would probably serve no better purpose than to appease the + appetite of some rapacious fish. + </p> + <p> + Their abundance is not the only merit, however, of the eggs of pelagic + creatures, in the eyes of the biologist. By equal good-fortune it chances + that colorless things are at a premium in the sea, since to escape the eye + of your enemy is a prime consideration. So the eggs in question are + usually transparent, and thus, shielded from the vision of marine enemies, + are beautifully adapted for the observation of the biologist. As a final + merit, they are mostly of convenient size for manipulation under the + microscope. For many reasons, then, the marine egg offers incomparable + advantages to the student of cell life, an egg being the typical cell. And + since nowadays the cell is the very focus of attention in the biological + world, the importance of marine laboratories has been enhanced + proportionately. + </p> + <p> + But of course not all the work can be done with eggs or with living + specimens of any kind. It is equally important on occasion to examine the + tissues of adult specimens, and for this, as a rule, the tissues must + first be subjected to some preserving and hardening process preliminary to + the cutting of sections for microscopical examination. This is done simply + enough in the case of some organisms, but there is a large class of filmy, + tenuous, fragile creatures in the sea population of which the jellyfish + may be mentioned as familiar examples. Such creatures, when treated in an + ordinary way, by dropping them into alcohol, shrivel up, coming to + resemble nothing in particular, and ceasing to have any value for the + study of normal structures. How to overcome this difficulty was one of the + problems attacked from the beginning at the Naples laboratory. The chief + part of the practical work of these experiments fell to the share of + Signor Lo Bianco. The success that attended his efforts is remarkable. + To-day you may see at the laboratory all manner of filmy, diaphanous + creatures preserved in alcohol, retaining every jot of their natural + contour, and thus offering unexampled opportunities for study <i>en masse</i>, + or for being sectioned for the microscope. The methods by which this + surprising result has been accomplished are naturally different for + different creatures; Signor Lo Bianco has written a book telling how it + all has been done. Perhaps the most important principle involved with a + majority of the more tenuous forms is to stupefy the animal by gradually + adding small quantities of a drug, such as chloral, to the water in which + the creature is detained. When by this means the animal has been rendered + so insensible that it responds very sluggishly to stimuli, it is plunged + into a toxic solution, usually formaline, which kills it so suddenly that + its muscles in their benumbed state have not time to contract. + </p> + <p> + Any one who has ever tried to preserve a jellyfish, for example, by + ordinary methods will recall the sorry result, and be prepared to + appreciate Signor Lo Bianco's wonderfully beautiful specimens. Naturalists + have come from all over the world to Naples to learn "just how" the + miracle is accomplished, for it must be understood that the mere citation + of the <i>modus operandi</i> by no means enables the novitiate to apply it + successfully at once. In the case of some of the long-drawn-out forms of + clustered ascidians and the like, the delicacy of manipulation required to + make successful preservations raises the method as practised at Naples + almost to the level of a fine art. It is a boon to naturalists everywhere + that the institution here is able sometimes to supply other laboratories + less favorably situated with duplicates from its wealth of beautifully + preserved specimens. + </p> + <p> + METHODS AND RESULTS + </p> + <p> + These, then, are some of the material conditions that have contributed to + make the results of the scientific investigations at the Naples laboratory + notable. But of course, even with a superabundance of material, + discoveries do not make themselves. "Who uses this material?" is, after + all, the vital question. And in this regard the laboratory at Naples + presents, for any one who gets at its heart, so to speak, an ensemble that + is distinctive enough; for the men who work in the light and airy rooms of + the laboratory proper have come for the purpose from all corners of the + civilized globe, and not a few of them are men of the highest distinction + in their various lines of biological science. A large proportion are + professors in colleges and universities of their various countries; and + for the rest there is scarcely one who is not in some sense master of the + biological craft. For it must be understood that this laboratory at Naples + is not intended as a training-school for the apprentice. It offers in the + widest sense a university course in biology, and that alone. There is no + instructor here who shows the new-comer how to use the microscope, how to + utilize the material, how to go about the business of discovery. The + worker who comes to Naples is supposed to have learned all these things + long before. He is merely asked, then, what class of material he desires, + and, this being furnished him, he is permitted to go his own way + unmolested. He may work much or little, or not at all; he may make epochal + discoveries or no discoveries of any sort, and it will be all one to the + management. No one will ask him, in any event, what he has done or why he + has not done otherwise. In a word, the worker in the laboratory here, + while being supplied with opportunities for study such as he could hardly + find elsewhere, retains all the freedom of his own private laboratory. + </p> + <p> + Little wonder, then, that it is regarded as a rare privilege to be allowed + to work in this laboratory. Fortunately, however, it is a privilege that + may be obtained by almost any earnest worker who, having learned the + technique of the craft elsewhere, desires now to prosecute special + original studies in biology. Most of the tables here are leased in + perpetuity, for a fixed sum per annum, by various public or private + institutions of different countries. Thus, for example, America has the + right of use of several tables, the Smithsonian Institution leasing one, + Columbia University another, a woman's league a third, and so on. Any + American desiring to work at Naples should make application to one of + these various sources, stating the exact time when he would like to go, + and if there be a vacancy for that time the properly accredited applicant + is almost sure to receive the privilege he asks for. Failing in this, + however, there is still a court of last appeal in Dr. Dohrn himself, who + may have a few unoccupied tables at his disposal, and who will surely + extend the courtesy of their occupancy, for a reasonable period, to any + proper applicant, come he whence he may. + </p> + <p> + Thus it chances that one finds men of all nations working in the Naples + laboratory—biologists from all over Europe, including Russia, from + America, from Australia, from Japan. One finds women also, but these, I + believe, are usually from America. Biologists who at home are at the head + of fully equipped laboratories come here to profit by the wealth of + material, as well as to keep an eye upon the newest methods of their + craft, and to gain the inspiration of contact with other workers in allied + fields. Many of the German university teachers, for example, make regular + pilgrimages to Naples during their vacations, and more than one of them + have made the original investigations here that have given them an + international reputation. + </p> + <p> + As to the exact methods of study employed by the individual workers here, + little need be said. In this regard, as in regard to instrumental + equipment, one biological laboratory is necessarily much like another, and + the general conditions of original scientific experiment are pretty much + the same everywhere. What is needed is, first, an appreciation of the + logical bearings of the problem to be solved; and, secondly, the skill and + patience to carry out long lines of experiments, many of which necessarily + lead to no tangible result. The selection of material for the experiments + planned, the watching and cultivating of the living forms in the + laboratory tanks, the cutting of numberless filmy sections for + microscopical examination—these things, variously modified for each + case, make up the work of the laboratory student of general biology. And + just in proportion as the experiments are logically planned and carefully + executed will the results be valuable, even though they be but negative. + Just in proportion as the worker, by inclusion and exclusion, attains + authentic results—results that will bear the test of repetition—does + his reputation as a dependable working biologist become established. + </p> + <p> + The subjects attacked in the marine laboratory first and last are + practically coextensive with the range of general biology, bacteriology + excepted. Naturally enough, the life histories of marine forms of animals + and plants have come in for a full share of attention. But, as I have + already intimated, this zoological work forms only a small part of the + investigations undertaken here, for in the main the workers prefer to + attack those general biological problems which in their broader outlines + apply to all forms of living beings, from highest to lowest. For example, + Dr. Driesch, the well-known Leipzig biologist, spends several months of + each year at the laboratory, and has made here most of those studies of + cell activities with which his name is associated. The past season he has + studied an interesting and important problem of heredity, endeavoring to + ascertain the respective shares of the male and female parents in the + development of the offspring. The subjects of his experiments have been + various species of sea-urchins, but the principles discovered will + doubtless be found to apply to most, or perhaps all, forms of vertebrate + life as well. + </p> + <p> + While these studies were under way another developmental problem was being + attacked in a neighboring room of the laboratory by Professor Kitasato, of + the University of Tokio, Japan. The subjects this time were the embryos of + certain fishes, and the investigation had to do with the development of + instructive monstrosities through carefully designed series of injuries + inflicted upon the embryo at various stages of its development. Meantime + another stage of the developmental history of organic things—this + time a microscopical detail regarding the cell divisions of certain plants—has + been studied by Professor Mottier, of Indiana; while another American + botanist, Professor Swingle, of the Smithsonian Institution, has been + going so far afield from marine subjects as to investigate the very + practical subject of the fertilization of figs as practised by the + agriculturists about Naples. + </p> + <p> + Even from these few citations it will appear how varied are the lines of + attack of a single biological problem; for here we see, at the hands of a + few workers, a great variety of forms of life—radiates, insects, + vertebrates, low marine plants and high terrestrial ones—made to + contribute to the elucidation of various phases of one general topic, the + all-important subject of heredity. All these studies are conducted in + absolute independence, and to casual inspection they might seem to have + little affinity with one another; yet in reality they all trench upon the + same territory, and each in its own way tends to throw light upon a topic + which, in some of its phases, is of the utmost practical importance to the + human family. It is a long vault from the embryo of an obscure sea-weed to + the well-being of man, yet it may well happen—so wide in their + application are the general life principles—that study of the one + may point a practical moral for the other. + </p> + <p> + Indeed, it constantly happens that the student of biology, while gazing + through his microscope, hits upon discoveries that have the most + far-removed implications. Thus a few years ago it was discovered that when + a cell is about to bisect itself and become two cells, its nucleus + undergoes a curious transformation. Within the nuclear substance little + bodies are developed, usually threadlike in form, which take on a deep + stain, and which the biologist calls chromosomes. These chromosomes vary + in number in the cells of different animals, but the number is always the + same for any given species of animal. If one were to group animate beings + in classes according to this very fundamental quality of the cells he + would have some very curious relations established. Thus, under the + heading "creatures whose cells have twenty-four chromosomes," one would + find beings so different as "the mouse, the salamander, the trout, and the + lily," while the sixteen-chromosome group would introduce the very + startling association of the ox, the guinea-pig, the onion, and man + himself. But whatever their number, the chromosomes are always exactly + bisected before the cell divides, one-half being apportioned to each of + the two cells resulting from the division. + </p> + <p> + Now the application is this: It was the study of these odd nuclear + structures and their peculiar manouvrings that, in large measure, led + Professor Weismann to his well-known theory of heredity, according to + which the acquired traits of any being are not transmissible to the + offspring. Professor Weismann came to believe that the apportionment of + the nuclear substance, though quantitatively impartial, is sometimes + radically uneven in quality; in particular, that the first bisection of + the egg-cell, which marks the beginning of embryonic development, produces + two cells utterly different in potentiality, the one containing the "body + plasm," which is to develop the main animal structures, the other + encompassing the "germ plasm," by which the racial integrity is [to be + preserved. Throughout the life of the individual, he believed, this + isolation continued; hence the assumed lack of influence of acquired + bodily traits upon the germ plasm and its engendered offspring. Hence, + also, the application of the microscopical discovery to the deepest + questions of human social evolution. + </p> + <p> + Every one will recall that this theory, born of the laboratory, made a + tremendous commotion in the outside world. Its application to the welfare + and progress of humanity gave it supreme interest, and polemics unnumbered + were launched in its favor and in its condemnation. Eager search was made + throughout the fields of botany and zoology for new evidence pro or con. + But the definitive answer came finally from the same field of exploration + in which the theory had been originated—the world of the cell—and + the Marine Biological Laboratory was the seat of the new series of + experiments which demonstrated the untenability of the Weismannian + position. Most curious experiments they were, for in effect they consisted + of the making of two or more living creatures out of one, in the case of + beings so highly organized as the sea-urchins, the little fishlike + vertebrate, amphioxus, and even the lower orders of true fishes. Of course + the division of one being to form two is perfectly familiar in the case of + those lowly, single-celled creatures such as the protozoa and the + bacteria, but it seems quite another matter when one thinks of cutting a + fish in two and having two complete living fish remaining. Yet this is + virtually what the biologists did. + </p> + <p> + Let me hasten to add that the miraculous feat was not accomplished with an + adult fish. On the contrary, it is found necessary to take the subject + quite at the beginning of its career, when it consists of an egg-cell in + the earliest stages of proliferation. Yet the principle is quite the same, + for the adult organism is, after all, nothing more than an aggregation of + cells resulting from repeated divisions (growth accompanying) and + redivisions of that original egg-cell. Considering its potentialities, the + egg-cell, seemingly, is as much entitled to be considered an individual as + is the developed organism. Yet it transpires that the biologist has been + able so to manipulate a developing egg-cell, after its bisection, that the + two halves fall apart, and that each half (now become an independent cell) + develops into a complete individual, instead of the half-individual for + which it seemed destined. A strange trick, that, to play with an + individual <i>Ego</i>, is it not? The traditional hydra with its + reanimating heads was nothing to this scientific hydra, which, when + bisected bodily, rises up calmly as two whole bodies. + </p> + <p> + But even this is not the full measure of the achievement, for it has been + found that in some cases the experiment may be delayed until the + developing egg has made a second bisection, thus reaching the four-cell + stage, when four completely formed individuals emerge from the dismembered + egg. And in the case of certain medusae, success has attended experiments + made at the eight-cell and even at the sixteen-cell stage of development, + the creature which had got thus far on its career in single blessedness + becoming eight or sixteen individuals at the wave of the enchanted wand—that + is to say, the dissecting-needle—of the biologist. All of which + savors of conjury, but is really only matter-of-fact biological experiment—experiment, + however, of which the implications by no means confine themselves to + matters of fact biological. For clearly the fact that the separated + egg-cells grow into complete individuals shows that Weismann's theory, + according to which one of the cells contained only body plasm, the other + only germ plasm, is quite untenable. Thus the theory of the + non-transmissibility of acquired characters is deprived of its supposed + anatomical support and left quite in the air, to the imminent peril of a + school of sociologists who had built thereon new theories of human + progress. Also the question of the multiplied personalities clearly + extends far beyond the field of the biologist, and must be turned over to + the consideration of the psychologist—if, indeed, it does not fall + rather within the scope of the moralist. + </p> + <p> + But though it thus often chances that the biologist, while gazing + stoically through his microscope, may discover things in his microcosm + that bear very closely upon the practical interests of the most + unscientific members of the human family, it would be a mistake to suppose + that it is this class of facts that the worker is particularly seeking. + The truth is that, as a rule, the pure biologist is engaged in work for + the love of it, and nothing is further from his thoughts than the + "practical" bearings or remote implications of what he may discover. + Indeed, many of his most hotly pursued problems seem utterly divorced from + what an outsider would call practical bearings, though, to be sure, one + can never tell just what any new path may lead to. Such, for example, is + the problem which, next to questions of cell activities, comes in for + perhaps as large a share of attention nowadays as any other one biological + topic;—namely, the question as to just which of the various orders + of invertebrate creatures is the type from which vertebrates were evolved + in the past ages—in other words, what invertebrate creature was the + direct ancestor of the vertebrates, including man. Clearly it can be of + very little practical importance to man of to-day as to just who was his + ancestor of several million years ago. But just as clearly the question + has interest, and even the layman can understand something of the + enthusiasm with which the specialist attacks it. + </p> + <p> + As yet, it must be admitted, the question is not decisively answered, + several rival theories contending for supremacy in the case. One of the + most important of these theories had its origin at the Naples laboratory; + indeed, Dr. Dohrn himself is its author. This is the view that the type of + the invertebrate ancestor is the annelid—a form whose most familiar + representative is the earth-worm. The many arguments for and against + accepting the credentials of this unaristocratic ancestor cannot be dwelt + upon here. But it may be consolatory, in view of the very plebeian + character of the earth-worm, to know that various of the annelids of the + sea have a much more aristocratic bearing. Thus the filmy and delicately + beautiful structures that decorate the pleasant home of the quaint little + seahorse in the aquarium—structures having more the appearance of + miniature palm-trees than of animals—are really annelids. One can + view Dr. Dohrn's theory with a certain added measure of equanimity after + he learns this, for the marine annelids are seen, some of them, to be very + beautiful creatures, quite fitted to grace their distinguished offspring + should they make good their ancestral claims. + </p> + <p> + These glimpses will suffice, perhaps, to give at least a general idea of + the manner of thing which the worker at the marine laboratory is seeking + to discover when he interrogates the material that the sea has given him. + In regard to the publication of the results of work done at the Naples + laboratory, the same liberal spirit prevails that actuates the conduct of + the institution from first to last. What the investigator dis* covers is + regarded as his own intellectual property, and he is absolutely free, so + far as the management of this institution is concerned, to choose his own + medium in giving it to the world. He may, and often does, prefer to make + his announcements in periodicals or books issued in his own country and + having no connection whatever with the Naples laboratory. But, on the + other hand, his work being sufficiently important, he may, if he so + desire, find a publisher in the institution itself, which issues three + different series of important publications, under the editorship of + Professor Mayer. + </p> + <p> + One of these, entitled <i>Mittheilungen aus der Zoologische Station zu + Neapel</i>, permits the author to take his choice among four languages—German, + English, French, or Italian. It is issued intermittently, as occasion + requires. The second set of publications consists of ponderous monographs + upon the fauna and flora of the Gulf of Naples. These are beautifully + illustrated in color, and sometimes a single volume costs as much as + seventeen thousand dollars to issue. Of course only a fraction of that sum + is ever recovered through sale of the book. The third publication, called + <i>Zoologischen Jahresbericht</i>, is a valuable résumé of biological + literature of all languages, keeping the worker at the laboratory in touch + with the discoveries of investigators elsewhere. + </p> + <p> + The latter end is attained further by the library of the institution, + which is supplied with all the periodicals of interest to the biologist + and with a fine assortment of technical books. The library-room, aside + from its printed contents, is of interest because of its appropriate mural + decorations, and because of the bronze portrait busts of the two patron + saints of the institution, Von Baer and Darwin, which look down + inspiringly upon the reader. + </p> + <p> + All in all, then, it would be hard to find a deficiency in the Stazione + Zoologica as an instruement of biological discovery. A long list might be + cited of the revelations first brought to light within its walls. And yet, + as it seems to me, the greatest value of this institution as an + educational factor in science—as a biological lever of progress—does + not depend so much upon the tangible revelations of fact that have come + out of its laboratories as upon other of its influences. Scientific ideas, + like all other forms of human thought, move more or less in shoals. Very + rarely does a great discovery emanate from an isolated observer. The man + who cannot come in contact with other workers in kindred lines becomes + more or less insular, narrow, and unfitted for progress. Nowadays, of + course, the free communication between different quarters of the globe + takes away somewhat from the insularity of any quarter, and each scientist + everywhere knows something of what the others are doing, through + wide-spread publications. But this can never altogether take the place of + personal contact and the inspirational communication from man to man. + Hence it is that a rendezvous, where all the men of a craft go from time + to time and meet their fellows from all over the world, has an influence + for the advancement of the guild which is enormous and unequivocal, even + though difficult of direct demonstration. + </p> + <p> + This feature, then, it seems to me, gives Dr. Dohrn's laboratory its + greatest value as an educational factor, as a moving force in the + biological world. It is true that the new-comer there is likely to be + struck at first with a sense of isolation, and to wonder at the seeming + exclusiveness of the workers, the self-absorption of each and every one. + Outside the management, whom he meets necessarily, no one pays the + slightest attention to him at first, or seems to be aware of his + existence. He is simply assigned to a room or table, told to ask for what + he wants, and left to his own devices. As he walks along the hallways he + sees tacked on the doors the cards of biologists from all over the world, + exposing names with which he has long been familiar. He understands that + the bearers of the names are at work within the designated rooms, but no + one offers to introduce him to them, and for some time, perhaps, he does + not so much as see them, nor would he recognize them if he did. He feels + strange and isolated in the midst of this stronghold of his profession. + </p> + <p> + But soon this feeling leaves him. He begins to meet his fellow-workers + casually here and there—in the hallways, at the distributing-tanks, + in the library. There are no formal gatherings, and there are some workers + who never seem to affiliate at all with the others; but in the long-run, + here as elsewhere, kindred spirits find one another out; and even the + unsocial ones take their share, whether or no, in the indefinable but very + sensible influence of massed numbers. Presently some one suggests to the + new-comer that he join some of the others of a Wednesday or Saturday + evening, at a rendezvous where a number of them meet regularly. He goes, + under escort of his sponsor, and is guided through one of those narrow, + dark, hill-side streets of Naples where he would hardly feel secure to go + alone, to a little wine-shop in what seems a veritable dungeon—a + place which, if a stranger in Naples, he would never even remotely think + of entering. But there he finds his confrères of the laboratory gathered + about a long table, with the most conglomerate groups of Neapolitans of a + seemingly doubtful class at their elbows. Each biologist has a caraffa of + light wine on the table before him, and all are smoking. And, staid men of + science that they are, they are chattering away on trivial topics with the + animation of a company of school-boys. The stock language is probably + German, for this bohemian gathering is essentially a German institution; + but the Germans are polyglots, and you will hardly find yourself lost in + their company, whatever your native tongue. + </p> + <p> + Your companions will tell you that for years the laboratory fraternity + have met twice a week at this homely but hospitable establishment. The + host, honest Dominico Vincenzo Bifulco, will gladly corroborate the + statement by bringing out for inspection a great blank-book in which + successive companies of his guests from the laboratory have scrawled their + names, written epigrams, or made clever sketches. That book will some day + be treasured in the library of a bibliophile, but that will not be until + Bifulco is dead, for while he lives he will never part with it. + </p> + <p> + One comes to look upon this bohemian wine-shop as an adjunct of the + laboratory, and to feel that the free-and-easy meetings there are in their + way as important for the progress of science as the private séances of the + individual workers in the laboratory itself. Not because scientific topics + are discussed here, though doubtless that sometimes happens, but because + of that vitalizing influence of the contact of kindred spirits of which I + am speaking, and because this is the one place where a considerable number + of the workers at the laboratory meet together with regularity. + </p> + <p> + The men who enter into such associations go out from them revitalized, + full of the spirit of propaganda. Returned to their own homes, they + agitate the question of organizing marine laboratories there; and it is + largely through the efforts of the graduates, so to say, of the Naples + laboratory that similar institutions have been established all over the + world. + </p> + <p> + Thanks largely to the original efforts of Dr. Dohrn, nearly all civilized + countries with a coast-line now have their marine laboratories. France has + half a dozen, two of them under government control. Russia has two on the + Black Sea and one on the French Mediterranean coast. Great Britain has + important stations at St. Andrews, at Liverpool, and at Plymouth. The + Scandinavian peninsula has also three important stations. Germany shows a + paucity by comparison, which, however, is easily understood when one + reflects that the mother-laboratory at Naples is essentially a German + institution despite its location. + </p> + <p> + The American stations are located at Woods' Holl and at Cold Spring + Harbor, on opposite coasts of Long Island Sound. The Japanese station is + an adjunct of Tokio University. For the rest, the minor offspring of the + Naples laboratory are too numerous to be cited here. Nor can I enter into + any details regarding even the more important ones. Each in its way enters + into the same general line of work, varying the details according to the + bent of mind of individual directors and the limitations of individual + resources. But in the broader outlines the aim of all is the same, and + what we have seen at Naples is typical of what is best in all the others. + </p> + <p> + <a name="link2H_4_0008" id="link2H_4_0008"> + <!-- H2 anchor --> </a> + </p> + <div style="height: 4em;"> + <br /><br /><br /><br /> + </div> + <h2> + VI. ERNST HAECKEL AND THE NEW ZOOLOGY + </h2> + <p> + THE DREAM CITY + </p> + <p> + THE train crept on its tortuous way down the picturesque valley of the + little Saale. At last we saw, high above us, on a jutting crag, three + quaint old castles, in one of which, as we knew from our <i>Baedeker</i>; + Goethe at one time lived. We were entering the region of traditions. Soon + we knew we should be passing that famous battle-field on which Napoleon, + in 1806, sealed the fate of Germany for a generation. But this spot, as + seen from the car window, bore no emblem to distinguish it, and before we + were quite sure that we had reached it we had in point of fact passed on, + and the train was coming to a stop. "Jena!" called the guard, and the + scramble for "luggage" began, leaving us for the moment no place for other + thoughts than to make sure that all our various parcels were properly + dragged out along with ourselves. For a wonder no Dienstman appeared to + give us aid—showing how unexpected is the arrival of any wayfarer at + this untoward season—and for a moment one seemed in danger of being + reduced to the unheard-of expedient of carrying one's own satchel. But, + fortunately, one is rescued from this most un-German predicament by the + porter of a waiting hotel omnibus, and so at last we have time to look + about us, and to awaken to a realizing sense that we have reached the land + of traditions; that we have come to Mecca; that we are in the quondam home + of Guericke, Fichte, Goethe, Schiller, Oken, and Gagenbaur; in the present + home of Haeckel. + </p> + <p> + The first glimpse of a mountain beaming down at us from across the way was + in admirable conformity with our expectations, but for the rest, the + vicinage of the depot presented a most distressing air of modernity. A + cluster of new buildings—some of them yet unfinished—stared + back at us and the mountain with the most barefaced aspect of + cosmopolitanism. Was this, then, Jena, the home of traditions? Or were we + entering some Iowa village, where the first settlers still live who but + yesterday banished the prairie-dog and the buffalo? + </p> + <p> + But this disappointment and its ironical promptings were but fleeting. + Five minutes' drive and we were in the true Jena with the real flavor of + mediaeval-ism about us. Here is the hostelry where Luther met the Swiss + students in 1522. There is nothing in that date to suggest our Iowa + village, nor in the aspect of the hostelry itself, thank fortune. And + there rises the spire of the city church, up the hill yonder, which was + aging, as were most of the buildings that still flank it, when Luther made + that memorable visit. America was not discovered, let alone Iowa, when + these structures were erected. Now, sure enough, we are in the dream city. + </p> + <p> + A dream city it truly seems, when one comes to wander through its narrow, + tortuous streets, between time-stained walls, amid its rustic population. + Coming from Berlin, from Dresden, from Leipzig—not to mention + America—one feels as if he had stepped suddenly back two or three + centuries into the past. There are some evidences of modernity that mar + the illusion, to be sure; but the preponderance of the old-time emblems is + sufficient to leave the mind in a delightful glow of reminiscences. As a + whole, the aspect of the central portion of the village—of the true + Jena—cannot greatly have changed since the days when Luther stopped + here on his way to Wittenberg; surely not since 1662, when the mighty + young Leibnitz, the Aristotle of Germany, came to Jena to study under + Weigel, the most famous of German mathematicians of that century. Here and + there an old house has been demolished, to be sure; even now you may see + the work of destruction going on, as a new street is being cut through a + time-honored block close to the old church. But in the main the old + thoroughfares run hither and thither, seemingly at random, as of old, + disclosing everywhere at their limits a sky-line of picturesque gables, + and shut in by walls that often are almost canon-like in narrowness; while + the heavy, buttressed doors and the small, high-placed windows speak of a + time when every house partook of the nature of the fortress. + </p> + <p> + The footway of the thoroughfares has no doubt vastly changed, for it is + for the most part paved now—badly enough, to be sure, yet, after + all, paved as no city was in the good old days when garbage filled the + streets and cleanliness was an unknown virtue. The Jena streets of to-day + are very modern in their cleanliness; yet a touch of medievalism is + retained in that the main work of cleaning is done by women. But, for that + matter, it seems to the casual observer as if the bulk of all the work + here were performed by the supposedly weaker sex. Certainly woman is here + the chief beast of burden. In every direction she may be seen, in rustic + garb, struggling cheerily along under the burden of a gigantic basket + strapped at her back. You may see the like anywhere else in Germany, to be + sure, but not often elsewhere in such preponderant numbers. And scarcely + elsewhere does the sight jar so little on one's New-World sensibilities as + in the midst of this mediaeval setting. One is even able to watch the old + women sawing and splitting wood in the streets here, with no thought of + anything but the picturesque-ness of the incident. + </p> + <p> + If one follows a band of basket-laden women, he will find that their goal + is that focal-point of every old-time city, the market-place. There + arrived, he will witness a scene common enough in Europe but hardly to be + duplicated anywhere in America. Hundreds of venders of meat, fish, + vegetables, cloths, and household utensils have their open-air booths + scattered all across the wide space, and other hundreds of purchasers are + there as well. Quaint garbs and quainter faces are everywhere, and the + whole seems quite in keeping with the background of fifteenth-century + houses that hedges it in on every side. Could John the Magnanimous, who + rises up in bronze in the midst of the assembly, come to life, he would + never guess that three and a half centuries have passed since he fell into + his last sleep. + </p> + <p> + This same John the Magnanimous it was who founded the institution which + gives Jena its fame and distinguishes it from all the other quaint + hypnotic clusters of houses that nestle similarly here and there in other + picturesque valleys of the Fatherland—I mean, of course, its + world-renowned university. It is but a few minutes' walk from the + market-place, past the home where Schiller once lived and through the + "street" scarcely more than arms'-breadth wide beyond, to the site of the + older buildings of the university. Inornate, prosaic buildings they are, + unrelieved even by the dominant note of picturesqueness; rescued, however, + from all suggestion of the commonplace by the rugged ruins of the famed + "powder-tower" jutting out from the crest of the hill just above, by the + spire of the old church which seems to rise from the oldest university + building itself, and by the mountain peaks that jut up into view far + beyond. + </p> + <p> + If you would enter one of the old buildings there is naught to hinder. Go + into one of the lecture-halls which chances at the moment to be + unoccupied, and you will see an array of crude old benches for seats that + look as if they might have been placed there at the very inaugural of the + institution. The boards that serve for desks, if you scan them closer, you + will find scarred all over with the marks of knives, showing how some + hundreds of successive classes of listeners have whiled away the weary + lecture-hours. Not a square inch can you find of the entire desk surface + that is un-scarred. If one would woo a new sensation, he has but to seat + himself on one of these puritanical old benches and conjure up in + imagination the long series of professors that may have occupied the + raised platform in front, recalling the manner of thought and dogma that + each laid down as verity. He of the first series appears in the garb of + the sixteenth century, with mind just eagerly striving to peer a little + way out of the penumbra of the Renaissance. The students who carve the + first gashes in the new desks will learn, if perchance they listen in + intervals of whittling, that this World on which they live is perhaps not + flat, but actually round, like a ball. It is debatable doctrine, to be + sure, but we must not forget that Signor Columbus, recently dead, found + land off to the west which is probably a part of the Asiatic continent. If + the earth be indeed a ball, then the sun and stars whirl clear around it + in twenty-four hours, travelling thus at an astonishing speed, for the + sphere in which they are fastened is situated hundreds of miles away. The + sun must be a really great ball of fire—perhaps a mile even in + diameter. The moon, as is plain to see, is nearly as large. The stars, of + course, are only sparks, though of great brilliancy. They are fixed in a + different sphere from that of the sun. In still other spheres are the + moon, and a small set of large stars called planets, of which latter there + are four, in order that, with the sun, the moon, and the other stars, + there may be made seven orders of heavenly bodies—seven being, of + course, the magic number in accordance with which the universe is planned. + </p> + <p> + This is, in substance, the whole subject of astronomy, as that first + professor must have taught it, even were he the wisest man of his time. Of + the other sciences, except an elementary mathematics, there was hardly so + much as an inkling taught that first class of students. You will find it + appalling, as you muse, to reflect upon the amazing mixture of utter + ignorance and false knowledge which the learned professor of that day + brought to the class-room, and which the "educated" student carried away + along with his degree. The one and the other knew Greek, Latin, and Bible + history and doctrine. Beyond that their minds were as the minds of babes. + Yet no doubt the student who went out from the University of Jena in the + year 1550 thought himself upon the pinnacles of learning. So he was in his + day and age, but could he come to life to-day, in the full flush of his + scholarship, yonder wood-vender, plying her saw out here in front of the + university building, would laugh in derision at his simplicity and + ignorance. So it seems that, after all, the subjects of John the + Magnanimous have changed more than a little during the three hundred and + odd years that John himself, done in bronze, has been standing out there + in the market-place. + </p> + <p> + THE CAREER OF A ZOOLOGIST + </p> + <p> + Had one time for it, there would be real interest in noting the steps by + which the mental change in question has been brought about; in particular + to note the share which the successive generations of Jena professors have + taken in the great upward struggle. But we must not pause for that here. + Our real concern, despite the haunting reminiscences, is not with the Jena + of the past, but with the Jena of to-day; not with ghosts, but with the + living personality who has made the Jena of our generation one of the + greatest centres of progress in human thought in all the world. Jena is + Jena to-day not so much because Guericke and Fichte and Hegel and Schiller + and Oken taught here in the past, as because it has for thirty-eight years + been the seat of the labors of Germany's greatest naturalist, one of the + most philosophical zoologists of any country or any age, Professor Ernst + Haeckel. It is of Professor Haeckel and his work that I chiefly mean to + write, and if I have dwelt somewhat upon Jena itself, it is because this + quaint, retired village has been the theatre of Haeckel's activities all + the mature years of his life, and because the work he has here + accomplished could hardly have been done so well elsewhere; some of it, + for reasons I shall presently mention, could hardly have been done + elsewhere at all—at least in another university. + </p> + <p> + It was in 1861 that young Dr. Haeckel came first to Jena as a teacher. He + had made a tentative effort at the practice of medicine in Berlin, then + very gladly had turned from a distasteful pursuit to the field of pure + science. His first love, before he took up the study of medicine, had been + botany, though pictorial art, then as later, competed with science for his + favorable attention. But the influence of his great teacher, Johannes + Müller, together with his medical studies, had turned his attention more + directly to the animal rather than vegetable life, and when he left + medicine it was to turn explicitly to zoology as a life study. Here he + believed he should find a wider field than in art, which he loved almost + as well, and which, it may be added, he has followed all his life as a + dilettante of much more than amateurish skill. Had he so elected, Haeckel + might have made his mark in art quite as definitely as he has made it in + science. Indeed, even as the case stands, his draughtsman's skill has been + more than a mere recreation to him, for without his beautiful drawings, + often made and reproduced in color, his classical monographs on various + orders of living creatures would have lacked much of their present value. + </p> + <p> + Moreover, quite aside from these merely technical drawings, Professor + Haeckel has made hundreds of paintings purely for recreation and the love + of it, illustrating—and that too often with true artistic feeling + for both form and color—the various lands to which his zoological + quests have carried him, such as Sicily, the Canaries, Egypt, and India. + From India alone, after a four-months' visit, Professor Haeckel brought + back two hundred fair-sized water-colors, a feat which speaks at once for + his love of art and his amazing industry. + </p> + <p> + I dwell upon this phase of Professor Haeckel's character and temperament + from the very outset because I wish it constantly to be borne in mind, in + connection with some of the doctrines to be mentioned presently, that here + we have to do with no dry-as-dust scientist, cold and soulless, but with a + broad, versatile, imaginative mind, one that links the scientific and the + artistic temperaments in rarest measure. Charles Darwin, with whose name + the name of Haeckel will always be linked, told with regret that in his + later years he had become so steeped in scientific facts that he had lost + all love for or appreciation of art or music. There has been no such + mental warping and atrophy in the mind of Ernst Haeckel. Yet there is + probably no man living to-day whose mind contains a larger store of + technical scientific facts than his, nor a man who has enriched zoology + with a larger number of new data, the result of direct personal + observation in field or laboratory. + </p> + <p> + How large Haeckel's contribution in this last regard has been can be but + vaguely appreciated by running over the long list of his important + publications, though the list includes more than one hundred titles, + unless it is understood that some single titles stand for monographs of + gigantic proportions, which have involved years of labor in the + production. Thus the text alone of the monograph on the radiolarians, a + form of microscopic sea-animalcule (to say nothing of the volume of + plates), is a work of three gigantic volumes, weighing, as Professor + Haeckel laughingly remarks, some thirty pounds, and representing twelve + years of hard labor. This particular monograph, by-the-bye, is written in + English (of which, as of several other languages, Professor Haeckel is + perfect master), and has a history of more than ordinary interest. It + appears that the radiolarians were discovered about a half-century ago by + Johannes Müller, who made an especial-study of them, which was uncompleted + at the time of his death in 1858. His monograph, describing the fifty + species then known, was published posthumously. Haeckel, on whom the + mantle of the great teacher was to fall, and who had been Müller's last + pupil, took up the work his revered master had left unfinished as his own + first great original <i>Arbeit</i>. He went to Messina and was delighted + to find the sea there replete with radiolarians, of which he was able to + discover one or two new species almost every day, until he had added one + hundred and fifty all told to Müller's list, or more than triple the whole + number previously known. The description of these one hundred and fifty + new radiolarians constituted Haeckel's first great contribution to + zoology, and won him his place as teacher at Jena in 1861. + </p> + <p> + Henceforth Haeckel was, of course, known as the greatest authority on this + particular order of creatures. For this reason it was that Professor + Murray, the naturalist of the famous expedition which the British + government sent around the world in the ship <i>Challenger</i>, asked + Haeckel to work up the radiolarian material that had been gathered during + that voyage. Murray showed Haeckel a little bottle containing water, with + a deposit of seeming clay or mud in the bottom. "That mud," he said, "was + dredged up from the bottom of the ocean, and every particle of it is the + shell of a radiolarian." "Impossible," said Haeckel. "Yet true," replied + Murray, "as the microscope will soon prove to you." + </p> + <p> + So it did, and Professor Haeckel spent twelve years examining that mud + under the microscope, with the result that, before he had done, he had + discovered no fewer than four thousand new species of radiolarians, all of + which, of course, had to be figured, described, and christened. Think of + baptizing four thousand creatures, finding a new, distinct, and + appropriate Latin name for each and every one, and that, too, when the + creatures themselves are of microscopic size, and the difference between + them often so slight that only the expert eye could detect it. Think, too, + of the deadly tedium of labor in detecting these differences, in sketching + them, and in writing out, to the length of three monster volumes, + technical dissertations upon them. + </p> + <p> + To the untechnical reader that must seem a deadly, a veritably + mind-sapping task. And such, indeed, it would prove to the average + zoologist. But with the mind of a Haeckel it is far otherwise. To him a + radiolarian, or any other creature, is of interest, not so much on its own + account as for its associations. He sees it not as an individual but as a + link in the scale of organic things, as the bearer of a certain message of + world-history. Thus the radiolarians, insignificant creatures though they + seem, have really taken an extraordinary share in building up the crust of + the earth. The ooze at the bottom of the sea, which finally becomes + metamorphosed into chalk or stone, is but the aggregation of the shells of + dead radiolarians. In the light of such a rôle the animalcule takes on a + new interest. + </p> + <p> + But even greater is the interest that attaches to every creature in regard + to the question of its place in the organic scale of evolution. What are + the homologies of this form and that? What its probable ancestry? What + gaps does it bridge? What can it tell us of the story of animal creation? + These and such like are the questions that have been ceaselessly before + Haeckel's mind in all his studies of zoology. Hence the rich fountain of + philosophical knowledge that has welled up from what otherwise might have + been the most barren of laboratory borings. Thus from a careful + investigation of the sponge Haeckel was led to his famous gastrula theory, + according to which the pouchlike sponge-animalcule—virtually a + stomach without members—is the type of organism on which all high + organisms are built, so to speak—that is, out of which all have + evolved. + </p> + <p> + This gastrula theory, now generally accepted, is one of Haeckel's two + great fundamental contributions to the evolution philosophy with the + history of which his life work is so intimately linked. The other + contribution is the theory, even more famous and now equally undisputed, + that every individual organism, in its em-bryological development, + rehearses in slurred but unmistakable epitome the steps of evolution by + which the ancestors of that individual came into racial being. That is to + say, every mammal, for example, originating in an egg stage, when it is + comparable to a protozoon, passes through successive stages when it is + virtually in succession a gastrula, a fish, and an amphibian before it + attains the mammalian status, because its direct ancestors were in + succession, through the long geological ages, protozoons, gastrulae, + fishes, amphibians before the true mammal was evolved. This theory cast a + flood of light into many dark places of the Darwinian philosophy. It was + propounded in 1866 in Professor Haeckel's great work on morphology, and it + has ever since been a guiding principle in his important philosophical + studies. + </p> + <p> + It was through this same work on morphology that Haeckel first came to be + universally recognized as the great continental champion of Darwinism—the + Huxley of Germany. Like Huxley, Haeckel had at once made the logical + application of the Darwinian theory to man himself, and he sought now to + trace the exact lineage of the human family as no one had hitherto + attempted to fathom it. Utilizing his wide range of zoological and + anatomical knowledge, he constructed a hypothetical tree of descent—or, + if you prefer, ascent—from the root in a protozoon to the topmost + twig or most recent offshoot, man. From that day till this Haeckel's + persistent labors have been directed towards the perfection of that + genealogical tree. + </p> + <p> + This work on morphology was much too technical to reach the general + public, but in 1868 Haeckel prepared, at the instigation of his friend and + confrère Gagenbaur, what was practically a popular abridgment of the + technical work, which was published under the title of <i>The Natural + History of Creation</i>. This work created a furor at once. It has been + translated into a dozen languages, and has passed through nine editions in + the original German. Through it the name of Haeckel became almost a + household word the world over, and subject for mingled applause and + opprobrium—applause from the unprejudiced for its great merit; + opprobrium from the bigoted because of the unprecedented candor with which + it followed the Darwinian hypothesis to its logical goal. + </p> + <p> + The same complete candor of expression has marked every stage of the + unfolding of Professor Haeckel's philosophical pronouncements. This fact + is the more remarkable because Professor Haeckel is, so far as I am aware, + the only scientist of our generation who has felt at liberty to announce, + absolutely without reserve, the full conclusions to which his philosophy + has carried him, when these conclusions ran counter to the prevalent + prejudices of his time. Some one has said that the German universities are + oases of freedom. The remark is absolutely true of Jena. It is not true, I + believe, in anything like the same degree of any other German university, + or of any other university in the world. One thing before others that has + endeared Jena to Haeckel, and kept him there in the face of repeated + flattering calls to other universities, is that full liberty of spirit has + been accorded him there, as he knew it would not be accorded elsewhere. + "When a man comes into the atmosphere of Jena," says Professor Haeckel, + "he perforce begins to think—there is no escape from it. And he is + free to let his thoughts carry him whithersoever they honestly may. My + beliefs," he added, "are substantially the beliefs of my colleagues in + science everywhere, as I know from private conversations; but they, unlike + myself, are not free to speak the full truth as they see it. I myself + would not be tolerated elsewhere, as I am well aware. Had I desired to + remain in Berlin, for example, I must have kept silent. But here in Jena + one is free." + </p> + <p> + And he smiles benignly as he says it. The controversies through which he + has passed and the calumnies of which he has been the target have left no + scars upon this broad, calm spirit. + </p> + <p> + HAECKEL AS MAN AND TEACHER + </p> + <p> + It is indeed a delightful experience to meet Professor Haeckel in the + midst of his charming oasis of freedom, his beloved Jena. To reach his + laboratory you walk down a narrow lane, past Schiller's house, and the + garden where Schiller and Goethe used to sit and where now the new + observatory stands. Haeckel's laboratory itself is a simple oblong + building of yellowish brick, standing on a jutting point of land high + above the street-level. Entering it, your eye is first caught by a set of + simple panels in the wall opposite the door bearing six illustrious names: + Aristotle, Linne, Lamarck, Cuvier, Müller, Darwin—a Greek, a Swede, + two Frenchmen, a German, and an Englishman. Such a list is significant; it + tells of the cosmopolitan spirit that here holds sway. + </p> + <p> + The ground-floor of the building is occupied by a lecture-room and by the + zoological collection. The latter is a good working-collection, and + purports to be nothing else. Of course it does not for a moment compare + with the collections of the museums in any large city of Europe or + America, nor indeed is it numerically comparable with many private + collections, or collections of lesser colleges in America. Similarly, when + one mounts the stairs and enters the laboratory proper, he finds a room of + no great dimensions and nowise startling in its appointments. It is + admirably lighted, to be sure, and in all respects suitably equipped for + its purpose, but it is by no means so large or so luxurious as the average + college laboratory of America. Indeed, it is not to be mentioned in the + same breath with the laboratories of a score or two of our larger + colleges. Yet, with Haeckel here, it is unquestionably the finest + laboratory in which to study zoology that exists in the world to-day, or + has existed for the last third of a century. + </p> + <p> + Haeckel himself is domiciled, when not instructing his classes, in a + comfortable but plain room across the hall—a room whose windows look + out across the valley of the Saale on an exquisite mountain landscape, + with the clear-cut mountain that Schiller's lines made famous at its + focus. As you enter the room a big, robust man steps quickly forward to + grasp your hand. Six feet or more in height, compactly built, without + corpulence; erect, vigorous, even athletic; with florid complexion and + clear, laughing, light-blue eyes that belie the white hair and whitening + beard; the ensemble personifying at once kindliness and virility, + simplicity and depth, above all, frank, fearless honesty, without a trace + of pose or affectation—such is Ernst Haeckel. There is something + about his simple, frank, earnest, sympathetic, yet robust, masculine + personality that reminds one instinctively, as does his facial contour + also, of Walt Whitman. + </p> + <p> + A glance about the room shows you at once that it is a place for study, + and also that it is the room of the most methodical of students. There are + books and papers everywhere, yet not the slightest trace of disorder. + Clearly every book and every parcel of papers has a place, and is kept in + that place. The owner can at any moment lay his hand upon anything he + desires among all these documents. This habit of orderliness has had no + small share, I take it, in contributing to Professor Haeckel's success in + carrying forward many lines of research at the same time, and carrying all + to successful terminations. Then there goes with it, as a natural + accompaniment, a methodical habit of working, without which no single man + could have put behind him the multifarious accomplishments that stand to + Professor Haeckers credit. + </p> + <p> + Orderliness is not a more pronounced innate gift with Professor Haeckel + than is the gift of initial energy to undertake and carry on work which + leads to accomplishment—a trait regarding which men, even active + men, so widely differ. But Professor Haeckel holds that whatever his + normal bent in this direction, it was enormously strengthened in boyhood + by the precepts of his mother—from whom, by-the-bye, he chiefly + inherits his talents. "My mother," he says, "would never permit me to be + idle for a moment. If I stood at a window day-dreaming, she would always + urge me to be up and doing. 'Work or play,' she would urge, 'but do not + stand idle.' Through this reiterated admonition, physical activity became + a life-long habit with me, and work almost a necessity of my being. If I + have been able to accomplish my full share of labors, this is the reason. + I am never idle, and I scarcely know the meaning of <i>ennui</i>." + </p> + <p> + This must not be interpreted as meaning, however, that Professor Haeckel + takes up a task and works at it all day long unceasingly. That is not the + German method of working, and in this regard Professor Haeckel is a + thorough German. "When I was a young man," he says, "I at one time, thanks + to the persuasions of some English friends, became a convert to the + English method of working, and even attempted to introduce it into + Germany. But I soon relinquished it, and lapsed back into our German + method, which I am convinced will produce better results for the average + worker. The essential of this method is the long midday rest, which + enables one late in the afternoon to begin what is virtually a new + day's-work, and carry it out with vigor and without undue fatigue. Thus I, + who am an early riser, begin work at five in summer and six in winter, + after the customary light breakfast of coffee and rolls. I do not take a + second breakfast at ten or eleven, as many Germans do, but work + continuously until one o'clock, when I have dinner. This, with me, as with + all Germans, is the hearty meal of the day. After dinner I perhaps take a + half-hour's nap; then read the newspaper, or chat with my family for an + hour, and perhaps go for a long walk. At about four, like all Germans, I + take my cup of coffee, but without cake or other food. Then, at four, + having had three full hours of brain-rest and diversion, I am ready to go + to work again, and can accomplish four hours more of work without undue + fatigue. At eight I have my rather light supper, and after that I attempt + no further work, giving the evening to reading, conversation, or other + recreation. I do not retire till rather late, as I require only five or + six hours' sleep." + </p> + <p> + Such is the method of labor division that enables not Professor Haeckel + only, but a host of other German brain-workers to accomplish enormous + labors, yet to thrive on the accomplishment and to carry the ruggedness + and health of youth far into the decades that are too often with our own + workers given over to decrepitude. Haeckel at sixty-five looks as if he + were good for at least a score of years of further effort. And should he + fulfil the promise of his present rugged-ness, he will do no more than + numbers of his colleagues in German universities have done and are doing. + When one runs over the list of octogenarians, and considers at the same + time the amount of the individual output of the best German workers, he is + led to feel that Professor Haeckel was probably right in giving up the + continuous-day method of labor and reverting to the German method. + </p> + <p> + In addition to the original researches that Professor Haeckel has carried + out, to which I have already made some reference, there has, of course, + been all along another large item of time-consumption to be charged up to + his duties as a teacher. These, to be sure, are somewhat less exacting in + the case of a German university professor than they are in corresponding + positions in England or America. Thus, outside the hours of teaching, + Professor Haeckel has all along been able to find about eight hours a day + for personal, original research. When he told Professor Huxley so in the + days of their early friendship, Huxley exclaimed: "Then you ought to be + the happiest man alive. Why, I can find at most but two hours a day to use + for myself." + </p> + <p> + So much for the difference between German methods of teaching, where the + university professor usually confines his contact with the pupils to an + hour's lecture each day, and the English system, according to which the + lecturer is a teacher in other ways as well. Yet it must be added that in + this regard Professor Haeckel is not an orthodox German, for his contact + with his students is by no means confined to the lecture-hour. Indeed, if + one would see him at his best, he must go, not to the lecture-hall, but to + the laboratory proper during the hours when Professor Haeckel personally + presides there, and brings knowledge and inspiration to the eager band of + young dissectors who gather there. It will perhaps seem strange to the + reader to be told that the hours on which this occurs are from nine till + one o'clock of a day which is perhaps not devoted to class-room exercises + in any other school of Christendom whatever—namely, the Sabbath. It + is interesting to reflect what would be the comment on such a procedure in + London, for example, where the underground railway trains even must stop + running during the hours of morning service. But Jena is not London, and, + as Professor Haeckel says, "In Jena one is free. It pleases us to have our + Sabbath service in our tabernacle of science." + </p> + <p> + All questions of time aside, it is a favored body of young men who occupy + the benches in the laboratory during Professor Haeckel's unique + Sunday-morning service. Each student has before him a microscope and a + specimen of the particular animal that is the subject of the morning's + lesson. Let us say that the subject this morning is the crawfish. Then in + addition to the specimens with which the students are provided, and which + each will dissect for himself under the professor's guidance, there are + scattered about the room, on the various tables, all manner of specimens + of allied creatures, such as crabs, lobsters, and the like. There are + dissected specimens also of the crawfish, each preparation showing a + different set of organs, exhibited in preserving fluids. Then there are + charts hung all about the room illustrating on a magnified scale, by + diagram and picture, all phases of the anatomy of the subjects under + discussion. The entire atmosphere of the place this morning smacks of the + crawfish and his allies. + </p> + <p> + The session begins with a brief off-hand discussion of the general + characteristics and affinities of the group of arthropoda, of which the + crawfish is a member. Then, perhaps, the professor calls the students + about him and gives a demonstration of the curious phenomena of hypnotism + as applied to the crawfish, through which a living specimen, when held for + a few moments in a constrained attitude, will pass into a rigid "trance," + and remain standing on its head or in any other grotesque position for an + indefinite period, until aroused by a blow on the table or other shock. + Such are some of the little asides, so to speak, with which the virile + teacher enlivens his subject and gives it broad, human interest. Now each + student turns to his microscope and his individual dissection, and the + professor passes from one investigator to another with comment, + suggestion, and criticism; answering questions, propounding anatomical + enigmas for solution—enlivening, vivifying, inspiring the entire + situation. + </p> + <p> + As the work proceeds, Professor Haeckel now and again calls the attention + of the entire class to some particular phase of the subject just passing + under their individual observation, and in the most informal of talks, + illustrated on blackboard and chart, clears up any lurking mysteries of + the anatomy, or enlivens the subject with an incursion into physiology, + embryology, or comparative morphology of the parts under observation. Thus + by the close of the session the student has something far more than a mere + first-hand knowledge of the anatomy of the crawfish—though that in + itself were much. He has an insight also into a half-dozen allied + subjects. He has learned to look on the crawfish as a link in a living + chain—a creature with physiological, psychological, ontological + affinities that give it a human interest not hitherto suspected by the + novitiate. And when the entire series of Sunday-morning "services" has + been carried through, one order after another of the animal kingdom being + similarly made tribute, the favored student has gone far towards the goal + of a truly philosophical zoology, as different from the old-time dry-bones + anatomy as the living crawfish is different from the dead shell which it + casts off in its annual moulting time. + </p> + <p> + THE NEW ZOOLOGY + </p> + <p> + What, then, is the essence of this "philosophical zoology" of which + Haeckel is the greatest living exponent and teacher and of which his + pupils are among the most active promoters? In other words, what is the + real status, and the import and meaning, the <i>raison d'être</i>, if you + will, of the science of zoology to-day? + </p> + <p> + To clear the ground for an answer to that question, one must glance + backward, say half a century, and note the status of the zoology of that + day, that one may see how utterly the point of view has changed since + then; what a different thing zoology has become in our generation from + what it was, for example, when young Haeckel was a student at Jena back in + the fifties. At that time the science of zoology was a conglomeration of + facts and observations about living things, grouped about a set of + specious and sadly mistaken principles. It was held, following Cuvier, + that the beings of the animal kingdom had been created in accordance with + five preconceived types: the vertebrate, with a spinal column; the + articulate, with jointed body and members, as represented by the familiar + crustaceans and insects; the mollusk, of which the oyster and the snail + are familiar examples; the radiate, with its axially disposed members, as + seen in the starfish; and the low, almost formless protozoon, most of + whose representatives are of microscopic size. Each of these so-called + classes was supposed to stand utterly isolated from the others, as the + embodiment of a distinct and tangible idea. So, too, of the lesser groups + or orders within each class, and of the still more subordinate groups, + named technically families, genera; and, finally, the individual species. + That the grouping of species into these groups was more or less arbitrary + was of course to some extent understood, yet it was not questioned by the + general run of zoologists that a genus, for example, represented a truly + natural group of species that had been created as variations upon one idea + or plan, much as an architect might make a variety of houses, no one + exactly like any other, yet all conforming to a particular type or genus + of architecture—for example, the Gothic or the Romanesque. That each + of the groups defined by the classifiers had such status as this was the + stock doctrine of zoology, as also that the individual species making up + the groups, and hence the groups themselves, maintained their individual + identity absolutely unaltered from the moment of their creation, + throughout all successive generations, to the end of their racial + existence. + </p> + <p> + Such being the fundamental conception of zoology, it remained only for the + investigator to study each individual species with an eye to its + affinities with other species, that each might be assigned by a scientific + classification to the particular place in the original scheme of creation + which it was destined to occupy. Once such affinities had been correctly + determined and interpreted for all species, the zoological classification + would be complete for all time. A survey of the completed schedule of + classification would then show at a glance the details of the preconceived + system in accordance with which the members of the animal kingdom were + created, and zoology would be a "finished" science. + </p> + <p> + In the application of this relatively simple scheme, to be sure, no end of + difficulties were encountered. Each higher animal is composed of so many + members and organs, of such diverse variations, that naturalists could + never agree among themselves as to just where a balance of affinities + between resemblances and differences should be struck; whether, for + example, a given species varied so much from the type species of a genus—say + the genus Gothic house—as to belong properly to an independent genus—say + Romanesque house; or whether, on the other hand, its divergencies were + still so outweighed by its resemblances as to permit of its retention as + an aberrant member of genus number one. Perpetual quibbling over these + matters was quite the order of the day, no two authorities ever agreeing + as to details of classification. The sole point of agreement was that + preconceived types were in question—if only the zoologists could + ever determine just what these types were. Meantime, the student who + supposed classifications to be matters of moment, and who laboriously + learned to label the animals and birds of his acquaintance with an + authoritative Latin name, was perpetually obliged to unlearn what he had + acquired, as a new classifier brought new resources of hair-splitting + pursuit of a supposed type or ideal to bear on the subject. Where, for + example, our great ornithologists of the early part of the century, such + as Wilson and Audubon, had classed all our numerous hawks in a genus + falco, later students split the group up into numerous genera—just + how many it is impossible to say, as no two authorities agreed on that + point. Wilson, could he have come back a generation after his death, would + have found himself quite at a loss to converse with his successors about + the birds he knew and loved so well, using their technical names—though + the birds themselves had not changed. + </p> + <p> + Notwithstanding all the differences of opinion about matters of detail, + however, there was, nevertheless, substantial agreement about the broader + outlines of classifications, and it might fairly enough have been hoped + that some day, when longer study had led to finer discrimination, the + mysteries of all the types of creation would be fathomed. But then, while + this hope still seemed far enough from realization, Charles Darwin came + forward with his revolutionizing doctrine—and the whole time-honored + myth of "types" of creation vanished in thin air. It became clear that the + zoologists had been attempting a task utterly Sisyphean. They had sought + to establish "natural groups" where groups do not exist in nature. They + were eagerly peering after an ideal that had no existence outside their + imagination. Their barriers of words could not be made to conform to + barriers of nature, because in nature there are no barriers. + </p> + <p> + What, then, was to be done? Should the whole fabric of classification be + abandoned? Clearly not, since there can be no science without + classification of facts about labelled groupings, however arbitrary. + Classifications then must be retained, perfected; only in future it must + be remembered that any classification must be more or less arbitrary, and + in a sense false; that it is at best only a verbal convenience, not the + embodiment of a final ideal. If, for example, we consider the very + "natural" group of birds commonly called hawks, we are quite justified in + dividing this group into several genera or minor groups, each composed of + several species more like one another than like the members of other + groups of species—that is, of other genera. But in so doing we must + remember that if we could trace the ancestry of our various species of + hawks we should find that in the remote past the differences that now + separate the groups had been less and less marked, and originally quite + non-existent, all the various species having sprung from a common + ancestor. The genera of to-day are cousin-groups, let us say; but the + parents of the existing species were of one brood, brothers and sisters. + And what applies to the minor groups called genera applies also, going + farther into the past, to all larger groups as well, so that in the last + analysis, all existing creatures being really the evolved and modified + descendants of one primordial type, it may be said that all animate + creation is but a single kind. In this broadened view the details of + classification ceased to have the importance once ascribed to them, and + the quibblings of the classifiers seem amusing rather than serious. Yet + the changed point of view left the subject by no means barren of interest. + For if the multitudinous creatures of the living world are but diversified + twig-lets of a great tree of ascent, spread by branching from a common + root, at least it is worth knowing what larger branches each group of + twiglets—representing a genus, let us say—has sprung from. In + particular, since the topmost twig of the tree is represented by man + himself and his nearest relatives, is it of human interest to inquire just + what branches and main stems will be come upon in tracing back the lineage + of this particular offshoot. This attempt had, perhaps, no vast, vital + importance in the utilitarian sense in which these terms are oftenest + used, but at least it had human interest. Important or otherwise, it was + the task that lay open to zoology, and apparently its only task, so soon + as the Darwinian hypothesis had made good its status. The man who first + took this task in hand, and who has most persistently and wisely followed + it, and hence the man who became the recognized leader in the field of the + new zoology, was, as I have already intimated, Professor Haeckel. His + hypothetical tree of man's lineage, tracing the ancestry of the human + family back to the earliest geological times and the lowest orders of + beings, has been familiar now for just a third of a century. It was at + first confessedly only a tentative genealogy, with many weak limbs and + untraced branches. It was perfected from time to time, as new data came to + hand, through studies of paleontology, of embryology, and of comparative + anatomy. It will be of interest, then, to inquire just what is its status + today and to examine briefly Professor Haeckel's own most recent + pronouncement regarding it. + </p> + <p> + Perhaps it is not worth our while here to go too far down towards the root + of the genealogical tree to begin our inquiry. So long as it is admitted + that the remote ancestry is grounded in the lowest forms of organisms, it + perhaps does not greatly matter to the average reader that there are dark + places in the lineage during the period when our ancestor had not yet + developed a spinal column—when, in other words, he had not attained + the dignity of the lowest fish. Neither, perhaps, need we mourn greatly + that the exact branch by which our reptilian or amphibian non-mammalian + ancestor became the first and most primitive of mammals is still hidden in + unexplored recesses of early strata. The most patrician monarch of to-day + would not be greatly disturbed as to just who were his ancestors of the + days of the cave-dweller. It is when we come a little nearer home that the + question begins to take on its seemingly personal significance. Questions + of grandparents and great-grandparents concern the patrician very closely. + And so all along, the question that has interested the average casual + investigator of the Darwinian theory has been the question as to man's + immediate ancestor—the parents and grandparents of our race, so to + speak. Hence the linking of the word "monkey" with the phrase "Darwinian + theory" in the popular mind; and hence, also, the interpretation of the + phrase "missing link" in relation to man's ancestry, as applying only to + our ancestor and not to any other of the gaps in the genealogical chain. + </p> + <p> + What, then, is the present status of Haeckel's genealogical tree regarding + man's most direct ancestor? Prom what non-human parent did the human race + directly spring? That is a question that has proved itself of lasting, + vital human interest. It is a question that long was answered only with an + hypothesis, but which Professor Haeckel to-day professes to be able to + answer with a decisive and affirmative citation not of theories but of + facts. In a word, it is claimed that man's immediate ancestor is now + actually upon record, that the much-heralded "missing link" is missing no + longer. The principal single document, so to speak, on which this claim is + based consists of the now famous skull and thigh-bone which the Dutch + surgeon, Dr. Eugene Dubois, discovered in the year 1891 in the tertiary + strata of the island of Java. Tertiary strata, it should be explained, had + never hitherto yielded any fossils bordering on the human type, but this + now famous skeleton was unmistakably akin to the human. The thigh in + particular, taken by itself, would have been pronounced by any competent + anatomist to be of human origin. Unquestionably the individual who bore it + had been accustomed to take an erect attitude in walking. And yet the + skull was far inferior in size and shape to that of any existing tribe of + man—was, indeed, rather of a simian type, though, on the other hand, + of about twice the capacity of any existing ape. In a word, it seemed + clear that the creature whose part skeleton had been found by Dr. Dubois + was of a type intermediate between the lowest existing man and the highest + existing man-apes. It was, in short, the actual prototype of that + hypothetical creature which Haeckel, in his genealogical tree, had + christened <i>pithecanthropus</i>, the ape-man. As such it was christened + <i>Pithecanthropus erectus</i>, the erect ape-man. + </p> + <p> + Now the discovery of this remarkable form did not make Professor Haeckel + any more certain that some such form had existed than he was thirty years + before when he christened a hypothetical subject with the title now taken + by a tangible claimant. But, after all, there is something very taking + about a prophecy fulfilled, and so the appearance of <i>Pithecanthropus + erectus</i> created no small sensation in the zoological world. He was + hailed by Haeckel and his followers as the veritable "missing link," and + as such gained immediate notoriety. But, on the other hand, a reactionary + party at once attacked him with the most bitter animadversions, denouncing + him as no true ancestor of man with a bitterness that is hard to + understand, considering that the origin of man from <i>some</i> lower form + has long ceased to be matter of controversy. "<i>Pithecanthropus</i> is at + least half an ape," they cried, with the clear implication of "anything + but an ape for an ancestor!" + </p> + <p> + I confess I have always found it hard to understand just why this peculiar + aversion should always be held against the unoffending ape tribe. Why it + would not be quite as satisfactory to find one's ancestor in an ape as in + the alternative lines of, for example, the cow, or the hippopotamus, or + the whale, or the dog has always been a mystery. Yet the fact of this + prejudice holds. Probably we dislike the ape because of the very patency + of his human affinities. The poor relation is objectionable not so much + because he is poor as because he is a relation. So, perhaps, it is not the + apeness, so to speak, of the ape that is objectionable, but rather the + human-ness. In any event, the aversion has been matter of common notoriety + ever since the Darwinian theory became fully accepted; it showed itself + now with renewed force against poor <i>pithecanthropus</i>. A half-score + of objections were launched against him. It is needless to rehearse them + now, since they were all met valiantly, and the final verdict saw the + new-comer triumphantly ensconced in man's ancestral halls as the oldest + sojourner there who has any title to be spoken of as "human." He is only + half human, to be sure—a veritable ape-man, as his name implies—but + exactly therein lies his altogether unique distinction. He is the + embodiment of that "missing link" whose nonappearance had hitherto given + so much comfort to the sceptical. + </p> + <p> + Perhaps some crumbs of comfort may be found by the reactionists in the + fact that it is not held by Professor Haeckel, or by any other competent + authority, that the link which <i>pithecanthropus</i> supplies welds man + directly with any existing man-ape—with gorilla, chimpanzee, or + orang. It is held that these highest existing apes are side branches, so + to say, of the ancestral tree, who developed, in their several ways, + contemporaneously with our direct ancestors, but are not themselves + directly of the royal line. The existing ape that has clung closest to the + direct ancestral type of our own race, it appears, is the gibbon—a + creature far less objectionable in that rôle because of the very paucity + of his human characteristics, as revealed to the casual observer. + Gibbon-like fossil apes are known, in strata representing a time some + millions of years antecedent to the epoch of <i>pithecanthropus</i> even, + which are held to be directly of the royal line through which <i>pithecanthropus</i>, + and the hypothetical <i>Homo stupidus</i>, and the known <i>Homo + neanderthalensis</i>, and, lastly, proud <i>Homo sapiens</i> himself have + descended. Thus Professor Haeckel is able to make the affirmation, as he + did recently before the International Zoological Congress in Cambridge, + that man's line of descent is now clearly traced, from a stage back in the + Eocene time when our ancestor was not yet more than half arrived to the + ape's estate, down to the time of true human development. "There no longer + exists," he says, "a 'missing link.' The phyletic continuity of the + primate stem, from the oldest lemurs down to man himself, is an historical + fact." + </p> + <p> + It should, perhaps, be added that the force of this rather startling + conclusion rests by no means exclusively upon the finding of <i>pithecanthropus</i> + and the other fossils, nor indeed upon any paleontological evidence + whatever. These, of course, furnish data of a very tangible and convincing + kind; but the evidence in its totality includes also a host of data from + the realms of embryology and comparative anatomy—data which, as + already suggested, enabled Professor Haeckel to predicate the existence of + <i>pithecanthropus</i> long in advance of his actual discovery. Whether + the more remote gaps in the chain of man's ancestry will be bridged in a + manner similarly in accord with Professor Haeckel's predications, it + remains for future discoveries of zoologist and paleontologist to + determine. In any event, the recent findings have added an increment of + glory to that philosophical zoology of which Professor Haeckel is the + greatest living exponent. + </p> + <p> + This tracing of genealogies is doubtless the most spectacular feature of + the new zoology, yet it must be clear that the establishment of lines of + evolution is at best merely a preparation for the all-important question, + Why have these creatures, man included, evolved at all? That question goes + to the heart of the new zoological philosophy. A partial answer was, of + course, given by Darwin in his great doctrine of natural selection. But + this doctrine, while explaining the preservation of favorable variations, + made no attempt to account for the variations themselves. Professor + Haeckel's contribution to the subject consisted in the revival of the + doctrine of Lamarck, that individual variations, in response to + environmental influences, are transmitted to the offspring, and thus + furnish the material upon which, applying Darwin's principle, evolution + may proceed. This Lamarck-Haeckel doctrine was under a cloud for a recent + decade, during the brief passing of the Weismannian myth, but it has now + emerged, and stands as the one recognized factor in the origin of those + variations whose cumulative preservation through natural selection has + resulted in the evolution of organic forms. + </p> + <p> + But may there not be other factors, as yet unrecognized, that supplement + the Lamarckian and Darwinian principles in bringing about this marvellous + evolution of beings? That, it would seem, is the most vital question that + the philosophical zoology of our generation must hand on to the twentieth + century. For today not even Professor Haeckel himself can give it answer. + </p> + <p> + <a name="link2H_4_0009" id="link2H_4_0009"> + <!-- H2 anchor --> </a> + </p> + <div style="height: 4em;"> + <br /><br /><br /><br /> + </div> + <h2> + VII. SOME MEDICAL LABORATORIES AND MEDICAL PROBLEMS + </h2> + <p> + THE PASTEUR INSTITUTE + </p> + <p> + THE national egotism that characterizes the French mind is not without its + compensations. It leads, for example, to the tangible recognition of the + merits of the great men of the nation and to the promulgation of their + names in many public ways. Thus it would be hard to mention a truly + distinguished Frenchman of the older generations whose name has not been + given to a street in Paris. Of the men of science thus honored, one + recalls off-hand the names of Buffon, Cuvier, Geoffroy Saint-Hilaire, + Pinel, Esquirol, Lamarck, Laplace, Lavoisier, Arago, Claude Bernard, Broca—indeed, + one could readily extend the list to tiresome dimensions. Moreover, it is + a list that is periodically increased by the addition of new names, as + occasion offers, for the Parisian authorities never hesitate to rechristen + a street or a portion of a street, regardless of former associations. + </p> + <p> + One of the most recent additions to this roll of fame is the name of + Pasteur. The boulevard that bears that famous name is situated in a + somewhat out-of-the-way corner of the city, though to reach it one has but + to traverse the relatively short course of the Avenue de Breteuil from so + central a position as the tomb of Napoleon. The Boulevard Pasteur itself + is a not long but very spacious thoroughfare, which will some day be very + beautiful, when the character of its environing buildings has somewhat + changed and its quadruple rows of trees have had time for development. At + present its chief distinction, in the eyes of most observers, would + probably be found in the fact that it is the location of the famous <i>fête + forain</i> at one of the annually recurring stages of the endless + itinerary of that noted function. During the period of this distinction, + which falls in the month of May, the boulevard becomes transformed into a + veritable Coney Island of merry-go-rounds, shooting-galleries, + ginger-bread booths, and clap-trap side-shows, to the endless delight of + throngs of pleasure-seekers. There is no sight in all Paris worthier + inspection for the foreigner than the Boulevard Pasteur offers at this + season, for one gains a deep insight into the psychology of a people + through observation of the infantile delight with which the adult + population here throws itself into the spirit of amusements which with + other nations are for the most part reserved for school-children. Only a + race either in childhood or senescence, it would seem, could thus give + itself over with undisguised delight to the enchantments of wooden horses, + cattle, cats, and pigs; to the catching of wooden fish with hooks; to the + shooting at targets that one could almost touch with the gun-muzzle, and + to the grave observation of sideshow performances that would excite the + risibilities of the most unsophisticated audience that could be found in + the Mississippi Valley. + </p> + <p> + As we move among this light-hearted and lightheaded throng we shall + scarcely escape a feeling of good-humored contempt for what seems an + inferior race. It will be wholesome, therefore, for us to turn aside from + the boulevard into the Rue Dotot, which leads from it near its centre, and + walk a few hundred yards away from the pleasure-seekers, where an evidence + of a quite different and a no less characteristic phase of the national + psychology will be before us. For here, within easy sound of the jangling + discords of the organs that keep time for the march of the <i>cheveaux de + bois</i>, rises up a building that is in a sense the monument of a man who + was brother in blood and in sentiment to the revellers we have just left + in the boulevard, yet whose career stamped him as one of the greatest men + of genius of any race or any time. That man was Louis Pasteur. The + building before us is the famous institute that bears his name. + </p> + <p> + In itself this building is a simple and unimposing structure, yet of + pleasing contour. It is as well placed as the surroundings permit, on a + grassed terrace, a little back from the street, where a high iron fence + guards it and gives it a degree of seclusion. There are other buildings + visible in the rear, which, as one learns on entering, are laboratories + and the like, where the rabbits and guinea-pigs and dogs that are so + essential to the work of the laboratory are kept. On the terrace in front + is a bronze statue of a boy struggling with a rabid dog—a reminder + of the particular labor of the master-worker which led directly to the + foundation of the institution. It will be remembered that it was primarily + to give Pasteur a wider opportunity to apply his newly discovered + treatment for the prevention of rabies that the subscription was + undertaken which led finally to the erection of the buildings before us + and brought the Pasteur Institute in its present form into being. Of the + other aims and objects of the institution I shall speak more at length in + a moment. + </p> + <p> + I have just said that the building before us is in effect the monument of + the great savant. This is true in a somewhat more literal sense than might + be supposed, for the body of Pasteur rests in a crypt at its base. The + personal labors of the great discoverer were practically ended at the time + when the institute was opened in 1888, on which occasion, as will be + remembered, the scientific representatives of all nations gathered in + Paris to do honor to the greatest Frenchman of his generation. He was + spared to the world, however, for seven years more, during which time he + fully organized the work of the institution along the lines it has since + followed, and was, of course, the animating spirit of all the labors + undertaken there by his devoted students and assistants. He is the + animating spirit of the institution still, and it is fitting that his body + should rest in the worthy mausoleum within the walls of that building + whose erection was the tangible culmination of his life labors. The + sarcophagus is a shrine within this temple of science which will serve to + stimulate generations of workers here to walk worthily in the footsteps of + the great founder of the institution. For he must be an unimaginative + person indeed who, passing beneath that arch bearing the simple + inscription "Ici Repose Pasteur," could descend into the simple but + impressive mausoleum and stand beside the massive granite sarcophagus + without feeling the same kind of mental uplift which comes from contact + with a great and noble personality. The pretentious tomb of Galileo in the + nave of Santa Croce at Florence, and the crowded resting-place of Newton + and Darwin in Westminster Abbey, have no such impressiveness as this + solitary vault where rests the body of Pasteur, isolated in death as the + mightier spirits must always be in life. + </p> + <p> + AIMS AND OBJECTS OF THE PASTEUR INSTITUTE + </p> + <p> + If one chances to come to the institute in the later hours of the morning + he will perhaps be surprised to find a motley company of men, women, and + children, apparently of many nationalities and from varied walks of life, + gathered about one of the entrances or sauntering near by. These are the + most direct beneficiaries of the institution, the unfortunate victims of + the bites of rabid dogs, who have come here to take the treatment which + alone can give them immunity from the terrible consequences of that + mishap. Rabies, or hydrophobia as it is more commonly termed with us, is + well known to be an absolutely fatal malady, there being no case on record + of recovery from the disease once fully established. Even the treatment + which Pasteur developed and which is here carried out cannot avail to save + the victim in whom the active symptoms of the malady are actually present. + But, fortunately, the disease is peculiarly slow in its onset, sometimes + not manifesting itself for weeks or months after the inoculation; and this + delay, which formerly was to the patient a period of fearful doubt and + anxiety, now suffices, happily, for the application of the protective + inoculations which enable the person otherwise doomed to resist the poison + and go unscathed. Thus it is that the persons who gather here each day to + the number of fifty, or even one hundred, have the appearance of and the + feelings of average health, though a large proportion of them bear in + their systems, on arrival, the germs of a disease that would bring them + speedily to a terrible end were it not that the genius of Pasteur had + found a way to give them immunity. The number of persons who have been + given the anti-rabic treatment here is more than twenty-five thousand. To + have given safety to such an army of unfortunates is, indeed, enough merit + for any single institution; but it must not be supposed that this record + is by any manner of means the full measure of the benefits which the + Institut Pasteur has conferred upon humanity. In point of fact, the + preparation and use of the anti-rabic serum is only one of many aims of + the institution, whose full scope is as wide as the entire domain of + contagious diseases. Pasteur's personal discoveries had demonstrated the + relation of certain lower organisms, notably the bacteria, to the + contagious diseases, and had shown the possibility of giving immunity from + certain of these diseases through the use of cultures of the noxious + bacteria themselves. He believed that these methods could be extended and + developed until all the contagious diseases, which hitherto have accounted + for so startling a proportion of all deaths, were brought within the + control of medical science. His deepest thought in founding the institute + was to supply a tangible seat of operations for this attempted conquest, + where the brilliant assistants he had gathered about him, and their + successors in turn, might take a share in this great struggle, unhampered + by the material drawbacks which so often confront the would-be worker in + science. + </p> + <p> + He desired also that the institution should be a centre of education along + the lines of its work, adding thus an indirect influence to the score of + its direct achievements. In both these regards the institution has been + and continues to be worthy of its founder. The Pasteur Institute is in + effect a school of bacteriology, where each of the professors is at once a + teacher and a brilliant investigator. The chief courses of instruction + consist of two series each year of lectures and laboratory demonstrations + on topics within the field of bacteriology. These courses, at which all + the regular staff of the institution assist more or less, are open to + physicians and other competent students regardless of nationality, and + they suffice to inculcate the principles of bacteriology to a large band + of seekers each year. + </p> + <p> + But more important, perhaps, than this form of educational influence is + the impetus given by the institute to the researches of a small, select + band of investigators who have taken up bacteriology for a life work, and + who come here to perfect themselves in the final niceties of the technique + of a most difficult profession. Thus such men as Calmette, the discoverer + of the serum treatment of serpent-poisoning, and Yersin, famous for his + researches in the prevention and cure of cholera by inoculation, are + "graduates" of the Pasteur Institute. Indeed, almost all the chief + laborers in this field in the world to-day, including the directors of + practically all the daughter institutes bearing the same name that are now + scattered all over the world, have had at least a share of their training + in the mother institute here in Paris. + </p> + <p> + Of the work of the men who form the regular staff of the Pasteur Institute + only a few words need be said here. Doctors Roux, Grancher, Metchnikoff, + and Chamberland all had the privilege of sharing Pasteur's labors during + the later years of the master's life, and each of them is a worthy + follower of the beloved leader and at the same time a brilliant original + investigator.*1* Roux is known everywhere in connection with the serum + treatment of diphtheria, which he was so largely instrumental in + developing. Grancher directs the anti-rabic department and allied fields. + Metchnikoff, a Russian by birth and Parisian by adoption, is famous as the + author of the theory that the white blood-corpuscles of the blood are the + efficient agents in combating bacteria. Chamberland directs the field of + practical bacteriology in its applications to hygiene, including the + department in which protective serums are developed for the prevention of + various diseases of domesticated animals, notably swine fever and anthrax. + About one million sheep and half as many cattle are annually given + immunity from anthrax by the serum here produced. + </p> + <p> + Of the patient and unremitting toil demanded of the investigator in this + realm of the infinitely little; of the skill in manipulation, the + fertility of resource, the scrupulous exactness of experiment that are + absolutely prerequisite to success; of the dangers that attend + investigations which deal with noxious germs, every one who knows anything + of the subject has some conception, but those alone can have full + comprehension who have themselves attempted to follow the devious and + delicate pathways of bacteriology. But the goals to which these pathways + lead have a tangibility that give them a vital interest for all the world. + The hopes and expectations of bacteriology halt at nothing short of the + ultimate extirpation of contagious diseases. The way to that goal is long + and hard, yet in time it will be made passable. And in our generation + there is no company of men who are doing more towards that end than the + staff of that most famous of bacteriological laboratories the Pasteur + Institute. + </p> + <p> + THE VIRCHOW INSTITUTE OF PATHOLOGY + </p> + <p> + Even were the contagious diseases well in hand, there would still remain a + sufficient coterie of maladies whose origin is not due to the influence of + living germs. There are, for example, many diseases of the digestive, + nutritive, and excretory systems, of the heart and arteries, of the brain + and nerves, and various less clearly localized abnormal conditions, that + owe their origin to inherent defects of the organism, or to various + indiscretions of food or drink, to unhygienic surroundings, to material + injuries, or to other forms of environmental stress quite dissociated from + the action of bacteria. It is true that one would need to use extreme care + nowadays in defining more exactly the diseases that thus lie without the + field of the bacteriologist, as that prying individual seems prone to + claim almost everything within sight, and to justify his claim with the + microscope; but after that instrument has done its best or worst, there + will still remain a fair contingent of maladies that cannot fairly be + brought within the domain of the ever-present "germ." On the other hand, + all germ diseases have of course their particular effects upon the system, + bringing their results within the scope of the pathologist. Thus while the + bacteriologist has no concern directly with any disease that is not of + bacterial origin, the pathologist has a direct interest in every form of + disease whatever; in other words, bacteriology, properly considered, is + only a special department of pathology, just as pathology itself is only a + special department of general medicine. + </p> + <p> + Whichever way one turns in science, subjects are always found thus + dovetailing into one another and refusing to be sharply outlined. + Nevertheless, here as elsewhere, there are theoretical bounds that suffice + for purposes of definition, if not very rigidly lived up to in practice; + and we are justified in thinking of the pathologist (perhaps I should say + the pathological anatomist) as the investigator of disease who is directly + concerned with effects rather than with causes, who aims directly at the + diseased tissue itself and reasons only secondarily to the causes. His + problem is: given a certain disease (if I may be permitted this + personified form of expression), to find what tissues of the body are + changed by it from the normal and in what manner changed. + </p> + <p> + It requires but a moment's reflection to make it clear that a certain + crude insight into the solution of this problem, as regards all common + diseases, must have been the common knowledge of medical men since the + earliest times. Thus not even medical knowledge was needed to demonstrate + that the tissues of an in: flamed part become red and swollen; and + numerous other changes of diseased tissues are almost equally patent. But + this species of knowledge, based on microscopic inspection, was very vague + and untrustworthy, and it was only after the advent of the perfected + microscope, some three-quarters of a century ago, that pathological + anatomy began to have any proper claim to scientific rank. Indeed, it was + not until about the year 1865 that the real clew was discovered which gave + the same impetus to pathology that the demonstration of the germ theory of + disease gave at about the same time to etiology, or the study of causes of + disease. This clew consisted of the final demonstration that all organic + action is in the last resort a question of cellular activities, and, + specifically, that all abnormal changes in any tissues of the body, due to + whatever disease, can consist of nothing more than the destruction, or the + proliferation, or the alteration of the cells that compose that tissue. + </p> + <p> + That seems a simple enough proposition nowadays, but it was at once + revolutionary and inspiring in the day of its original enunciation some + forty years ago. The man who had made the discovery was a young German + physician, professor in the University of Freiburg, by name Rudolph + Virchow. The discovery made him famous, and from that day to this the name + of Virchow has held somewhat the same position in the world of pathology + that the name of Pasteur occupied in the realm of bacteriology. Virchow + was called presently to a professorship in the University of Berlin. In + connection with this chair he established his famous Institute of + Pathology, which has been the Mecca of all students of pathology ever + since. He did a host of other notable things as well, among others, + entering the field of politics, and becoming a recognized leader there no + less than in science. Indeed, it seemed during the later decades of his + life as if one encountered Virchow in whatever direction one turned in + Berlin, and one feels that it was not without reason that his compatriots + spoke of him as "the man who knows everything." To the end he retained all + the alertness of intellect and the energy of body that had made him what + he was. One found him at an early hour in the morning attending to the + routine of his hospital duties, his lectures, and clinical demonstrations. + These finished, he rushed off, perhaps to his parliamentary duties; thence + to a meeting of the Academy of Sciences, or to preside at the Academy of + Medicine or at some other scientific gathering. And in intervals of these + diversified pursuits he was besieged ever by a host of private callers, + who sought his opinion, his advice, his influence in some matter of + practical politics, of statecraft, or of science, or who, perhaps, had + merely come the length of the continent that they might grasp the hand of + the "father of pathology." + </p> + <p> + In whatever capacity one sought him out, provided the seeking were not too + presumptuous, one was sure to find the great savant approachable, + courteous, even cordial. A man of multifarious affairs, he impressed one + as having abundance of time for them all, and to spare. There is a + leisureliness about the seeming habit of existence on the Continent that + does not pertain in America, and one felt the flavor of it quite as much + in the presence of this great worker as among those people who from our + stand-point seem never really to work at all. This is to a certain extent + explained if one visited Virchow in his home, and found to his + astonishment that the world-renowned physician, statesman, pathologist, + anthropologist was domiciled in a little apartment of the most modest + equipment, up two flights, in a house of most unpretentious character. + Everything was entirely respectable, altogether comfortable, to be sure; + but it was a grade of living which a man of corresponding position in + America could not hold to without finding himself quite out of step with + his confrères and the subject of endless comment. But in this city of + universal apartment-house occupancy and relatively low average of display + in living it is quite otherwise. Virchow lived on the same plane, + generally speaking, with the other scientists of Europe; it is only from + the American standpoint that there is any seeming disparity between his + fame and his material station in life; nor do I claim this as a merit of + the American stand-point. + </p> + <p> + Be that as it may, however, our present concern lies not with these + matters, but with Virchow the pathologist and teacher. To see the great + scientist at his best in this rôle, it was necessary to visit the + Institute of Pathology on a Thursday morning at the hour of nine. On the + morning of our visit we found the students already assembled and gathered + in clusters all about the room, examining specimens of morbid anatomy, + under guidance of various laboratory assistants. This was to give them a + general familiarity with the appearances of the disease-products that + would be described to them in the ensuing lecture. But what is most + striking about the room was the very unique method of arrangement of the + desk or table on which the specimens rested. It was virtually a + long-drawn-out series of desks winding back and forth throughout the + entire room, but all united into one, so that a specimen passed along the + table from end to end will make a zigzag tour of the room, passing finally + before each person in the entire audience. To facilitate such transit, + there was a little iron railway all along the centre of the table, with + miniature turn-tables at the corners, along which microscopes, with + adjusted specimens for examination, might be conveyed without danger of + maladjustment or injury. This may seem a small detail, but it is really an + important auxiliary in the teaching by demonstration with specimens for + which this room was peculiarly intended. The ordinary lectures of + Professor Virchow were held in a neighboring amphitheatre of conventional + type. + </p> + <p> + Of a sudden there was a hush in the hum of voices, as a little, thin, + frail-seeming man entered and stepped briskly to the front of the room and + upon the low platform before the blackboard in the corner. A moment's + pause for the students to take their places, and the lecturer, who of + course was Virchow himself, began, in a clear, conversational voice, to + discourse on the topic of the day, which chanced to be the formation of + clots in blood-vessels. There was no particular attempt at oratory; rather + the lecturer proceeded as if talking man to man, with no thought but to + make his meaning perfectly clear. He began at once putting specimens in + circulation, as supplied on his demand by his assistants from a rather + grewsome-looking collection before him. Now he paused to chaff the + assistant who was making the labels, poking good-humored jokes at his + awkwardness, but with no trace of sting. Again he became animated, his + voice raised a little, his speech more vehement, as he advanced his own + views on some contested theory or refuted the objections that some + opponent had urged against him, always, however, with a smile lurking + about his eyes or openly showing on his lips. + </p> + <p> + Constantly the lecturer turned to the blackboard to illustrate with + colored, crayons such points of his discourse as the actual specimens in + circulation might leave obscure. Everything must be made plain to every + hearer or he would not be satisfied. One can but contrast such teaching as + this with the lectures of the average German professor, who seems not to + concern himself in the least as to whether anything is understood by any + one. But Virchow had the spirit of the true teacher. He had the air of + loving his task, old story as it was to him. Most of his auditors were + mere students, yet he appealed to them as earnestly as if they were + associates and equals. He seemed to try to put himself on their level—to + make his thought near to them. Physically he was near to them as he + talked, the platform on which he stood being but a few inches in height, + and such physical nearness conduces to a familiarity of discourse that is + best fitted for placing lecturer and hearers <i>en rapport</i>. All in + all, appealing as it does almost equally to ear and eye, it is a type of + what a lecturer should be. Not a student there but went away with an added + fund of information, which is far more than can be said of most of the + lectures in a German university. + </p> + <p> + Needless to say, there are other departments to the Institute of + Pathology. There are collections of beautifully preserved specimens for + examination; rooms for practical experimentation in all phases of the + subject, the chemical side included; but these are not very different from + the similar departments of similar institutions everywhere. What was + unique and characteristic about this institution was the personality of + the director. Now he is gone, but his influence will not soon be + forgotten. The pupils of a great teacher are sure to carry forward the + work somewhat in the spirit of the master for at least a generation. + </p> + <p> + THE BERLIN INSTITUTE OP HYGIENE + </p> + <p> + I purposely refrain from entering into any details as to the character of + the technical work done at the Virchow Institute, because the subject of + pathology, despite its directly practical bearings, is in itself + necessarily somewhat removed from the knowledge of the general reader. One + cannot well understand the details of changes in tissues under abnormal + conditions unless one first understands the normal conditions of the + tissues themselves, and such knowledge is reserved for the special + students of anatomy. For the nonprofessional observer the interest of the + Virchow Institute must lie in its general scope rather than in the details + of the subjects there brought under investigation, which latter have, + indeed, of necessity, a somewhat grewsome character despite the beneficent + results that spring from them. It is quite otherwise, however, with the + work of the allied institution of which I now come to speak. The Institute + of Hygiene deals with topics not very remote from those studied in the + Virchow Institute, part of its work, indeed, falling clearly within the + scope of pathology; but it differs in being clearly comprehensible to the + general public and of immediate and tangible interest from the most + strictly utilitarian stand-point, hygiene being, in effect, the tangible + link between the more abstract medical sciences and the affairs of + every-day life. + </p> + <p> + The Institute of Hygiene has also the interest that always attaches to + association with a famous name, for it was here that Professor Koch made + the greater part of those investigations which made his name the best + known, next to that of Pasteur, of any in the field of bacteriology. In + particular, the researches on the cholera germ, and those even more widely + heralded researches that led to the discovery of the bacillus of + tuberculosis, and the development of the remedy tuberculin, of which so + much was at first expected, were made by Professor Koch in the + laboratories of the antiquated building which was then and is still the + seat of the Institute of Hygiene. More recently Professor Koch has severed + his connection with the institution after presiding over it for many + years, having now a semi-private laboratory just across from the Virchow + Institute, in connection with the Charité Hospital; but one still thinks + of the Institute of Hygiene as peculiarly the "Koch Institute" without + injustice, so fully does its work follow the lines laid out for it by the + great leader. + </p> + <p> + But however much the stamp of any individual personality may rest upon the + institute, it is officially a department of the university, just as is the + Virchow Institute. Like the latter, also, its local habitation is an + antiquated building, strangely at variance, according to American ideas, + with its reputation, though by no means noteworthy in this regard in the + case of a German institution. It is situated in a part of the city distant + from any other department of the university, and there is nothing about it + exteriorly to distinguish it from other houses of the solid block in which + it stands. Interiorly, it reminds one rather of a converted dwelling than + a laboratory proper. Its rooms are well enough adapted to their purpose, + but they give one the impression of a makeshift. The smallest American + college would be ill-satisfied with such an equipment for any department + of its work. Yet in these dingy quarters has been accomplished some of the + best work in the new science of bacteriology that our century will have to + boast. + </p> + <p> + The actual equipment of the bacteriological laboratory here is not, + indeed, quite as meagre as it seems at first, there being numerous rooms, + scattered here and there, which in the aggregate give opportunity for work + to a large number of investigators, though no single room makes an + impressive appearance. There is one room, however, large enough to give + audience to a considerable class, and here lectures were given by + Professor Koch and continue to be given by his successors to the special + students of bacteriology who come from all over the world, as well as to + the university students who take the course as a part of their regular + medical curriculum. In regard to this feature of its work, the Institute + of Hygiene differs in no essential respect from the Pasteur Institute and + other laboratories of bacteriology. The same general routine of work + pertains: the patient cultivation of the minute organisms in various + mediums, their careful staining by special processes, and their + investigation under the microscope mark the work of the bacteriologist + everywhere. Many details of the special methods of culture or treatment + originated here with Professor Koch, but such matters are never kept + secret in science, so one may see them practised quite as generally and as + efficiently in other laboratories as in this one. Indeed, it may frankly + be admitted that, aside from its historical associations with the pioneer + work in bacteriology, which will always make it memorable, there is + nothing about the bacteriological laboratory here to give it distinction + over hundreds of similar ones elsewhere; while in point of technical + equipment, as already noted, it is remarkable rather for what it lacks + than for what it presents. + </p> + <p> + The department of bacteriology, however, is only one of several important + features of the institute. One has but to ascend another flight of stairs + to pass out of the sphere of the microbe and enter a department where + attention is directed to quite another field. We have now come to what may + be considered the laboratory of hygiene proper, since here the + investigations have to do directly with the functionings of the human body + in their relations to the every-day environment. Here again one is struck + with the meagre equipment with which important results may be attained by + patient and skilled investigators. In only one room does one find a really + elaborate piece of apparatus. This exceptional mechanism consists + essentially of a cabinet large enough to give comfortable lodgment to a + human subject—a cabinet with walls of peculiar structure, partly of + glass, and connected by various pipes with sundry mysterious-seeming + retorts. This single apparatus, however, is susceptible of being employed + for the investigation of an almost endless variety of questions pertaining + to the functionings of the human body considered as a working mechanism. + </p> + <p> + Thus, for example, a human subject to be experimented upon may remain for + an indefinite period within this cabinet, occupied in various ways, taking + physical exercise, reading, engaged in creative mental labor, or sleeping. + Meantime, air is supplied for respiration in measured quantities, and of a + precisely determined composition, as regards chemical impurities, + moisture, and temperature. The air after passing through the chamber being + again analyzed, the exact constituents added to it as waste products of + the human machine in action under varying conditions are determined. It + will readily be seen that by indefinitely varying the conditions of such + experiments a great variety of data may be secured as to the exact + physiological accompaniments of various bodily and mental activities. Such + data are of manifest importance to the physiologist and pathologist on the + one hand, while at the same time having a direct bearing on such eminently + practical topics as the construction of shops, auditoriums, and dwellings + in reference to light, heat, and ventilation. It remains only for + practical architecture to take advantage of the unequivocal data thus + placed at its disposal—an opportunity of which practical + architecture, in Germany as elsewhere on the Continent, has hitherto been + very slow to avail itself. + </p> + <p> + THE MUSEUM OF HYGIENE + </p> + <p> + The practical lessons thus given in the laboratory are supplemented in an + even more tangible manner, because in a way more accessible to the public, + in another department of the institution which occupies a contiguous + building, and is known as the Museum of Hygiene. This, unlike the other + departments of the institute, is open to the general public on certain + days of each week, and it offers a variety of exhibits of distinctly novel + character and of high educational value. The general character of the + exhibits may be inferred from the name, but perhaps the scope is even + wider than might be expected. In a word, it may be said that scarcely + anything having to do with practical hygiene has been overlooked. Thus one + finds here numberless models of dwelling-houses, showing details of + lighting, heating, and ventilation; models not merely of individual + dwellings, but also of school-buildings, hospitals, asylums, and even + prisons. Sometimes the models represent merely ideal buildings, but more + generally they reproduce in miniature actual habitations. In the case of + the public buildings, the model usually includes not merely the structures + themselves but the surroundings—lawns, drives, trees, out-buildings—so + that one can get a very good idea of the more important hospitals, + asylums, and prisons of Germany by making a tour of the Museum of Hygiene. + Regarding the details of structure, one can actually gain a fuller + knowledge in many cases than he could obtain by actual visits to the + original institutions themselves. + </p> + <p> + The same thing is true of various other features of the subjects + represented. Thus there is a very elaborate model here exhibited of the + famous Berlin system of sewage-disposal. As is well known, the essential + features of this system consist of the drainage of sewage into local + reservoirs, from which it is forced by pumps, natural drainage not + sufficing, to distant fields, where it is distributed through tile pipes + laid in a network about a yard beneath the surface of the soil. The fields + themselves, thus rendered fertile by the waste products of the city, are + cultivated, and yield a rich harvest of vegetables and grains of every + variety suitable to the climate. The visitor to this field sees only rich + farms and market-gardens under ordinary process of cultivation. The system + of pipes by which the land is fertilized is as fully hidden from his view + as are, for example, the tributary sewage-pipes beneath the city + pavements. The average visitor to Berlin knows nothing, of course, about + one or the other, and goes away, as he came, ignorant of the important + fact that Berlin has reached a better solution of the great sewage problem + than has been attained by any other large city. Such, at least, is likely + to be the case unless the sight-seer chance to pay a visit to the Museum + of Hygiene, in which case a few minutes' inspection of the model there + will make the matter entirely clear to him. It is to be regretted that the + authorities of other large cities do not make special visits to Berlin for + this purpose; though it should be added that some of them have done so, + and that the Berlin system of "canalization" has been adopted in various + places in America. But many others might wisely follow their example, + notably the Parisians, whose sewerage system, despite the boasted + exhibition canal-sewer, is, like so many other things Parisian, of the + most primitive character and a reproach to present-day civilization. + </p> + <p> + It may be added that there are plenty of things exhibited in this museum + which the Germans themselves might study to advantage, for it must be + understood that the other hygienic conditions pertaining to Berlin are by + no means all on a par with the high modern standard of the sewerage + system. In the matter of ventilation, for example, one may find admirable + models in the museum, showing just how the dwelling and shop and + school-room should make provision for a proper supply of pure air for + their occupants. But if one goes out from the museum and searches in the + actual dwelling or shop or school-room for the counterparts of these + models, one will be sorely puzzled where to find them. The general + impression which a casual inspection will leave in his mind is that the + word ventilation must be as meaningless to the German mind as it is, for + example, to the mind of a Frenchman or an Italian. This probably is not + quite just, since the German has at least reached the stage of having + museum models of ventilated houses, thus proving that the idea does exist, + even though latent, in his mental equipment, whereas the other continental + nationalities seem not to have reached even this incipient stage of + progress. All over Europe the people fear a current of air as if veritable + miasm must lurk in it. They seem quite oblivious to any systematic + necessity for replenishing the oxygen supply among large assemblies, as + any one can testify who has, for example, visited their theatres or + schools. And as to the private dwellings, after making them as nearly + air-tight as practicable, they endeavor to preserve the <i>status quo</i> + as regards air supply seemingly from season to season. They even seem to + have passed beyond a mere negative regard for the subject of fresh air, + inasmuch as they will bravely assure you that to sleep in a room with an + open window will surely subject you to the penalty of inflamed eyes. + </p> + <p> + In a country like France, where the open fireplace is the usual means + employed to modify the temperature (I will not say warm the room), the + dwellings do of necessity get a certain amount of ventilation, + particularly since the windows are not usually of the best construction. + But the German, with his nearly air-tight double windows and his even more + nearly sealed tile stove, spends the winter in an atmosphere suggestive of + the descriptions that arctic travellers give us of the air in the hut of + an Eskimo. It is clear, then, that the models in the Museum of Hygiene + have thus far failed of the proselyting purpose for which they were + presumably intended. How it has chanced that the inhabitants of the + country maintain so high an average of robust health after this open + defiance is a subject which the physiological department of the Institute + of Hygiene might well investigate. + </p> + <p> + Even though the implied precepts of the Museum of Hygiene are so largely + disregarded, however, it must be admitted that the existence of the museum + is a hopeful sign. It is a valuable educational institution, and if its + salutary lessons are but slowly accepted by the people, they cannot be + altogether without effect. At least the museum proves that there are + leaders in science here who have got beyond the range of + eighteenth-century thought in matters of practical living, and the sign is + hopeful for the future, though its promise will perhaps not be fulfilled + in our generation. + </p> + <p> + <a name="link2H_4_0010" id="link2H_4_0010"> + <!-- H2 anchor --> </a> + </p> + <div style="height: 4em;"> + <br /><br /><br /><br /> + </div> + <h2> + VII. SOME UNSOLVED SCIENTIFIC PROBLEMS + </h2> + <p> + IN recent chapters we have witnessed a marvellous development in many + branches of pure science. In viewing so wonderfully diversified a field, + it has of course been impossible to dwell upon details, or even to glance + at every minor discovery. At best one could but summarize the broad sweep + of progress somewhat as a battle might be described by a distant + eye-witness, telling of the general direction of action, of the movements + of large masses, the names of leaders of brigades and divisions, but + necessarily ignoring the lesser fluctuations of advance or recession and + the individual gallantry of the rank and file. In particular, interest has + centred upon the storming of the various special strongholds of ignorant + or prejudiced opposition, which at last have been triumphantly occupied by + the band of progress. In each case where such a stronghold has fallen, the + victory has been achieved solely through the destructive agency of newly + discovered or newly marshalled facts—the only weapons which the + warrior of science seeks or cares for. Facts must be marshalled, of + course, about the guidon of a hypothesis, but that guidon can lead on to + victory only when the facts themselves support it. Once planted + victoriously on the conquered ramparts the hypothesis becomes a theory—a + generalization of science—marking a fresh coign of vantage, which + can never be successfully assailed unless by a new host of antagonistic + facts. Such generalizations, with the events leading directly up to them, + have chiefly occupied our attention. + </p> + <p> + But a moment's reflection makes it clear that the battle of science, thus + considered, is ever shifting ground and never ended. Thus at any given + period there are many unsettled skirmishes under way; many hypotheses are + yet only struggling towards the stronghold of theory, perhaps never to + attain it; in many directions the hosts of antagonistic facts seem so + evenly matched that the hazard of war appears uncertain; or, again, so few + facts are available that as yet no attack worthy the name is possible. + Such unsettled controversies as these have, for the most part, been + ignored in our survey of the field. But it would not be fair to conclude + our story without adverting to them, at least in brief; for some of them + have to do with the most comprehensive and important questions with which + science deals, and the aggregate number of facts involved in these + unfinished battles is often great, even though as yet the marshalling has + not led to final victory for any faction. In some cases, doubtless, the + right hypothesis is actually in the field, but its supremacy not yet + conclusively proved—perhaps not to be proved for many years or + decades to come. Some of the chief scientific results of the nineteenth + century have been but the gaining of supremacy for hypotheses that were + mere forlorn hopes, looked on with general contempt, if at all heeded, + when the eighteenth century came to a close—witness the doctrines of + the great age of the earth, of the immateriality of heat, of the + undulatory character of light, of chemical atomicity, of organic + evolution. Contrariwise, the opposite ideas to all of these had seemingly + a safe supremacy until the new facts drove them from the field. Who shall + say, then, what forlorn hope of to-day's science may not be the conquering + host of to-morrow? All that one dare attempt is to cite the pretensions of + a few hypotheses that are struggling over the still contested ground. + </p> + <p> + SOLAR AND TELLURIC PROBLEMS + </p> + <p> + Our sun being only a minor atom of the stellar pebble, solar problems in + general are of course stellar problems also. But there are certain special + questions regarding which we are able to interrogate the sun because of + his proximity, and which have, furthermore, a peculiar interest for the + residents of our little globe because of our dependence upon this + particular star. One of the most far-reaching of these is as to where the + sun gets the heat that he gives off in such liberal quantities. We have + already seen that Dr. Mayer, of conservation-of-energy fame, was the first + to ask this question. As soon as the doctrine of the persistence and + convertibility of energy was grasped, about the middle of the century, it + became clear that this was one of the most puzzling of questions. It did + not at all suffice to answer that the sun is a ball of fire, for + computation showed that, at the present rate of heat-giving, if the sun + were a solid mass of coal, he would be totally consumed in about five + thousand years. As no such decrease in size as this implies had taken + place within historic times, it was clear that some other explanation must + be sought. + </p> + <p> + Dr. Mayer himself hit upon what seemed a tenable solution at the very + outset. Starting from the observed fact that myriads of tiny meteorites + are hurled into the earth's atmosphere daily, he argued that the sun must + receive these visitants in really enormous quantities—sufficient, + probably, to maintain his temperature at the observed limits. There was + nothing at all unreasonable about this assumption, for the amount of + energy in a swiftly moving body capable of being transformed into heat if + the body be arrested is relatively enormous. Thus it is calculated that a + pound of coal dropped into the sun from the mathematician's favorite + starting-point, infinity, would produce some six thousand times the heat + it could engender if merely burned at the sun's surface. In other words, + if a little over two pounds of material from infinity were to fall into + each square yard of the sun's surface each hour, his observed heat would + be accounted for; whereas almost seven tons per square yard of stationary + fuel would be required each hour to produce the same effect. + </p> + <p> + In view of the pelting which our little earth receives, it seemed not an + excessive requisition upon the meteoric supply to suppose that the + requisite amount of matter may fall into the sun, and for a time this + explanation of his incandescence was pretty generally accepted. But soon + astronomers began to make calculations as to the amount of matter which + this assumption added to our solar system, particularly as it aggregated + near the sun in the converging radii, and then it was clear that no such + mass of matter could be there without interfering demonstrably with the + observed course of the interior planets. So another source of the sun's + energy had to be sought. It was found forthwith by that other great + German, Helmholtz, who pointed out that the falling matter through which + heat may be generated might just as well be within the substance of the + sun as without—in other words, that contraction of the sun's heated + body is quite sufficient to account for a long-sustained heat-supply which + the mere burning of any known substance could not approach. Moreover the + amount of matter thus falling towards the sun's centre being enormous—namely, + the total substance of the sun—a relatively small amount of + contraction would be theoretically sufficient to keep the sun's furnace at + par, so to speak. + </p> + <p> + At first sight this explanation seemed a little puzzling to many laymen + and some experts, for it seemed to imply, as Lord Kelvin pointed out, that + the sun contracts because it is getting cooler, and gains heat because it + contracts. But this feat is not really as paradoxical as it seems, for it + is not implied that there is any real gain of heat in the sun's mass as a + whole, but quite the reverse. All that is sought is an explanation of a + maintenance of heat-giving capacity relatively unchanged for a long, but + not an interminable, period. Indeed, exactly here comes in the novel and + startling feature of. Helmholtz's calculation. According to Mayer's + meteoric hypothesis, there were no data at hand for any estimate whatever + as to the sun's permanency, since no one could surmise what might be the + limits of the meteoric supply. But Helmholtz's estimate implied an + incandescent body cooling—keeping up a somewhat equable temperature + through contraction for a time, but for a limited time only; destined + ultimately to become liquid, solid; to cool below the temperature of + incandescence—to die. Not only so, but it became possible to + calculate the limits of time within which this culmination would probably + occur. It was only necessary to calculate the total amount of heat which + could be generated by the total mass of our solar system in falling + together to the sun's centre from "infinity" to find the total heat-supply + to be drawn upon. Assuming, then, that the present observed rate of + heat-giving has been the average maintained in the past, a simple division + gives the number of years for which the original supply is adequate. The + supply will be exhausted, it will be observed, when the mass comes into + stable equilibrium as a solid body, no longer subject to contraction, + about the sun's centre—such a body, in short, as our earth is at + present. + </p> + <p> + This calculation was made by Lord Kelvin, Professor Tait, and others, and + the result was one of the most truly dynamitic surprises of the century. + For it transpired that, according to mathematics, the entire limit of the + sun's heat-giving life could not exceed something like twenty-five + millions of years. The publication of that estimate, with the appearance + of authority, brought a veritable storm about the heads of the physicists. + The entire geological and biological worlds were up in arms in a trice. + Two or three generations before, they hurled brickbats at any one who even + hinted that the solar system might be more than six thousand years old; + now they jeered in derision at the attempt to limit the life-bearing + period of our globe to a paltry fifteen or twenty millions. + </p> + <p> + The controversy as to solar time thus raised proved one of the most + curious and interesting scientific disputations of the century. The scene + soon shifted from the sun to the earth; for a little reflection made it + clear that the data regarding the sun alone were not sufficiently + definite. Thus Dr. Croll contended that if the parent bodies of the sun + had chanced to be "flying stars" before collision, a vastly greater supply + of heat would have been engendered than if the matter merely fell + together. Again, it could not be overlooked that a host of meteors are + falling into the sun, and that this source of energy, though not in itself + sufficient to account for all the heat in question, might be sufficient to + vitiate utterly any exact calculations. Yet again, Professor Lockyer + called attention to another source of variation, in the fact that the + chemical combination of elements hitherto existing separately must produce + large quantities of heat, it being even suggested that this source alone + might possibly account for all the present output. On the whole, then, it + became clear that the contraction theory of the sun's heat must itself + await the demonstration of observed shrinkage of the solar disk, as viewed + by future generations of observers, before taking rank as an incontestable + theory, and that computations as to time based solely on this hypothesis + must in the mean time be viewed askance. + </p> + <p> + But the time controversy having taken root, new methods were naturally + found for testing it. The geologists sought to estimate the period of time + that must have been required for the deposit of the sedimentary rocks now + observed to make up the outer crust of the earth. The amount of sediment + carried through the mouth of a great river furnishes a clew to the rate of + denudation of the area drained by that river. Thus the studies of Messrs. + Humphreys and Abbot, made for a different purpose, show that the average + level of the territory drained by the Mississippi is being reduced by + about one foot in six thousand years. The sediment is, of course, being + piled up out in the Gulf at a proportionate rate. If, then, this be + assumed to be an average rate of denudation and deposit in the past, and + if the total thickness of sedimentary deposits of past ages were known, a + simple calculation would show the age of the earth's crust since the first + continents were formed. But unfortunately these "ifs" stand mountain-high + here, all the essential factors being indeterminate. Nevertheless, the + geologists contended that they could easily make out a case proving that + the constructive and destructive work still in evidence, to say nothing of + anterior revolutions, could not have been accomplished in less than from + twenty-five to fifty millions of years. + </p> + <p> + This computation would have carried little weight with the physicists had + it not chanced that another computation of their own was soon made which + had even more startling results. This computation, made by Lord Kelvin, + was based on the rate of loss of heat by the earth. It thus resembled the + previous solar estimate in method. But the result was very different, for + the new estimate seemed to prove that a period of from one hundred to two + hundred millions of years has elapsed since the final crust of the earth + formed. + </p> + <p> + With this all controversy ceased, for the most grasping geologist or + biologist would content himself with a fraction of that time. But the case + for the geologist was to receive yet another prop from the studies of + radio-activity, which seem to prove that the atom of matter has in store a + tremendous, supply of potential energy which may be drawn on in a way to + vitiate utterly all the computations to which I have just referred. Thus a + particle of radium is giving out heat incessantly in sufficient quantity + to raise its own weight of water to the boiling-point in an hour. The + demonstrated wide distribution of radio-active matter—making it at + least an open question whether all matter does not possess this property + in some degree—has led to the suggestion that the total heat of the + sun may be due to radio-active matter in its substance. Obviously, then, + all estimates of the sun's age based on the heat-supply must for the + present be held quite in abeyance. What is more to the point, however, is + the fact, which these varying estimates have made patent, that + computations of the age of the earth based on any data at hand are little + better than rough guesses. Long before the definite estimates were + undertaken, geologists had proved that the earth is very, very old, and it + can hardly be said that the attempted computations have added much of + definiteness to that proposition. They have, indeed, proved that the + period of time to be drawn upon is not infinite; but the nebular + hypothesis, to say nothing of common-sense, carried us as far as that long + ago. + </p> + <p> + If the computations in question have failed of their direct purpose, + however, they have been by no means lacking in important collateral + results. To mention but one of these, Lord Kelvin was led by this + controversy over the earth's age to make his famous computation in which + he proved that the telluric structure, as a whole, must have at least the + rigidity of steel in order to resist the moon's tidal pull as it does. + Hopkins had, indeed, made a somewhat similar estimate as early as 1839, + proving that the earth's crust must be at least eight hundred or a + thousand miles in thickness; but geologists had utterly ignored this + computation, and the idea of a thin crust on a fluid interior had + continued to be the orthodox geological doctrine. Since Lord Kelvin's + estimate was made, his claim that the final crust of the earth could not + have formed until the mass was solid throughout, or at least until a + honeycomb of solid matter had been bridged up from centre to + circumference, has gained pretty general acceptance. It still remains an + open question, however, as to what proportion the lacunas of molten matter + bear at the present day to the solidified portions, and therefore to what + extent the earth will be subject to further shrinkage and attendant + surface contortions. That some such lacunae do exist is demonstrated daily + by the phenomena of volcanoes. So, after all, the crust theory has been + supplanted by a compromise theory rather than completely overthrown, and + our knowledge of the condition of the telluric depths is still far from + definite. If so much uncertainty attends these fundamental questions as to + the earth's past and present, it is not strange that open problems as to + her future are still more numerous. We have seen how, according to + Professor Darwin's computations, the moon threatens to come back to earth + with destructive force some day. Yet Professor Darwin himself urges that + there are elements of fallibility in the data involved that rob the + computation of all certainty. Much the same thing is true of perhaps all + the estimates that have been made as to the earth's ultimate fate. Thus it + has been suggested that, even should the sun's heat not forsake us, our + day will become month-long, and then year-long; that all the water of the + globe must ultimately filter into its depths, and all the air fly off into + space, leaving our earth as dry and as devoid of atmosphere as the moon; + and, finally, that ether-friction, if it exist, or, in default of that, + meteoric friction, must ultimately bring the earth back to the sun. But in + all these prognostications there are possible compensating factors that + vitiate the estimates and leave the exact results in doubt. The last word + of the cosmic science of our generation is a prophecy of evil—if + annihilation be an evil. But it is left for the science of another + generation to point out more clearly the exact terms in which the prophecy + is most likely to be fulfilled. + </p> + <p> + PHYSICAL PROBLEMS + </p> + <p> + In regard to all these cosmic and telluric problems, it will be seen, + there is always the same appeal to one central rule of action—the + law of gravitation. When we turn from macrocosm to microcosm it would + appear as if new forces of interaction were introduced in the powers of + cohesion and of chemical action of molecules and atoms. But Lord Kelvin + has argued that it is possible to form such a conception of the forms and + space relations of the ultimate particles of matter that their mutual + attractions may be explained by invoking that same law of gravitation + which holds the stars and planets in their course. What, then, is this + all-compassing power of gravitation which occupies so central a position + in the scheme of mechanical things? + </p> + <p> + The simple answer is that no man knows. The wisest physicist of to-day + will assure you that he knows absolutely nothing of the why of gravitation—that + he can no more explain why a stone tossed into the air falls back to earth + than can the boy who tosses the stone. But while this statement puts in a + nutshell the scientific status of explanations of gravitation, yet it is + not in human nature that speculative scientists should refrain from the + effort to explain it. Such efforts have been made; yet, on the whole, they + are surprisingly few in number; indeed, there are but two that need claim + our attention here, and one of these has hardly more than historical + interest. One of these is the so-called ultramundane-corpuscle hypothesis + of Le Sage; the other is based on the vortex theory of matter. + </p> + <p> + The theory of Le Sage assumes that the entire universe is filled with + infinitely minute particles flying in right lines in every direction with + inconceivable rapidity. Every mass of tangible matter in the universe is + incessantly bombarded by these particles, but any two non-contiguous + masses (whether separated by an infinitesimal space or by the limits of + the universe) are mutually shielded by one another from a certain number + of the particles, and thus impelled towards one another by the excess of + bombardment on their opposite sides. What applies to two masses applies + also, of course, to any number of masses—in short, to all the matter + in the universe. To make the hypothesis workable, so to say, it is + necessary to assume that the "ultramundane" particles are possessed of + absolute elasticity, so that they rebound from one another on collision + without loss of speed. It is also necessary to assume that all tangible + matter has to an almost unthinkable degree a sievelike texture, so that + the vast proportion of the coercive particles pass entirely through the + body of any mass they encounter—a star or world, for example—without + really touching any part of its actual substance. This assumption is + necessary because gravitation takes no account of mere corporeal bulk, but + only of mass or ultimate solidarity. Thus a very bulky object may be so + closely meshed that it retards relatively few of the corpuscles, and hence + gravitates with relative feebleness—or, to adopt a more familiar + mode of expression, is light in weight. + </p> + <p> + This is certainly heaping hypotheses together in a reckless way, and it is + perhaps not surprising that Le Sage's conception did not at first arouse + any very great amount of interest. It was put forward about a century ago, + but for two or three generations remained practically unnoticed. The + philosophers of the first half of our century seem to have despaired of + explaining gravitation, though Faraday long experimented in the hope of + establishing a relation between gravitation and electricity or magnetism. + But not long after the middle of the century, when a new science of + dynamics was claiming paramount importance, and physicists were striving + to express all tangible phenomena intenus of matter in motion, the theory + of Le Sage was revived and given a large measure of attention. It seemed + to have at least the merit of explaining the facts without conflicting + with any known mechanical law, which was more than could be said of any + other guess at the question that had ever been made. + </p> + <p> + More recently, however, another explanation has been found which also + meets this condition. It is a conception based, like most other physical + speculations of the last generation, upon the hypothesis of the vortex + atom, and was suggested, no doubt, by those speculations which consider + electricity and magnetism to be conditions of strain or twist in the + substance of the universal ether. In a word, it supposes that gravitation + also is a form of strain in this ether—a strain that may be likened + to a suction which the vortex atom is supposed to exert on the ether in + which it lies. According to this view, gravitation is not a push from + without, but a pull from within; not due to exterior influences, but an + inherent and indissoluble property of matter itself. The conception has + the further merit of correlating gravitation with electricity, magnetism, + and light, as a condition of that strange ethereal ocean of which modern + physics takes so much account. But here, again, clearly, we are but + heaping hypothesis upon hypothesis, as before. Still, an hypothesis that + violates no known law and has the warrant of philosophical probability is + always worthy of a hearing. But we must not forget that it is hypothesis + only, not conclusive theory. + </p> + <p> + The same caution applies, manifestly, to all the other speculations which + have the vortex atom, so to say, for their foundation-stone. Thus + Professors Stewart and Tait's inferences as to the destructibility of + matter, based on the supposition that the ether is not quite frictionless; + Professor Dolbear's suggestions as to the creation of matter through the + development of new ether ripples, and the same thinker's speculations as + to an upper limit of temperature, based on the mechanical conception of a + limit to the possible vibrations of a vortex ring, not to mention other + more or less fascinating speculations based on the vortex hypothesis, must + be regarded, whatever their intrinsic interest, as insecurely grounded, + until such time as new experimental methods shall give them another + footing. Lord Kelvin himself holds all such speculations utterly in + abeyance. "The vortex theory," he says, "is only a dream. Itself unproven, + it can prove nothing, and any speculations founded upon it are mere dreams + about a dream."*1* + </p> + <p> + That certainly must be considered an unduly modest pronouncement regarding + the only workable hypothesis of the constitution of matter that has ever + been imagined; yet the fact certainly holds that the vortex theory, the + great contribution of the nineteenth century towards the solution of a + world-old problem, has not been carried beyond the stage of hypothesis, + and must be passed on, with its burden of interesting corollaries, to + another generation for the experimental evidence that will lead to its + acceptance or its refutation. Our century has given experimental proof of + the existence of the atom, but has not been able to fathom in the same way + the exact form or nature of this ultimate particle of matter. + </p> + <p> + Equally in the dark are we as to the explanation of that strange affinity + for its neighbors which every atom manifests in some degree. If we assume + that the power which holds one atom to another is the same which in the + case of larger bodies we term gravitation, that answer carries us but a + little way, since, as we have seen, gravitation itself is the greatest of + mysteries. But again, how chances it that different atoms attract one + another in such varying degrees, so that, for example, fluorine unites + with everything it touches, argon with nothing? And how is it that + different kinds of atoms can hold to themselves such varying numbers of + fellow-atoms—oxygen one, hydrogen two, and so on? These are + questions for the future. The wisest chemist does not know why the + simplest chemical experiment results as it does. Take, for example, a + water-like solution of nitrate of silver, and let fall into it a few drops + of another water-like solution of hydrochloric acid; a white insoluble + precipitate of chloride of silver is formed. Any tyro in chemistry could + have predicted the result with absolute certainty. But the prediction + would have been based purely upon previous empirical knowledge—solely + upon the fact that the thing had been done before over and over, always + with the same result. Why the silver forsook the nitrogen atom and + grappled the atom of oxygen no one knows. Nor can any one as yet explain + just why it is that the new compound is an insoluble, colored, opaque + substance, whereas the antecedent ones were soluble, colorless, and + transparent. More than that, no one can explain with certainty just what + is meant by the familiar word soluble itself. That is to say, no one knows + just what happens when one drops a lump of salt or sugar into a bowl of + water. We may believe with Professor Ostwald and his followers that the + molecules of sugar merely glide everywhere between the molecules of water, + without chemical action; or, on the other hand, dismissing this mechanical + explanation, we may say with Mendeleef that the process of solution is the + most active of chemical phenomena, involving that incessant interplay of + atoms known as dissociation. But these two explanations are mutually + exclusive, and nobody can say positively which one, if either, is right. + Nor is either theory at best more than a half explanation, for the why of + the strange mechanical or chemical activities postulated is quite ignored. + How is it, for example, that the molecules of water are able to loosen the + intermolecular bonds of the sugar particles, enabling them to scamper + apart? + </p> + <p> + But, for that matter, what is the nature of these intermolecular bonds in + any case? And why, at the same temperature, are some substances held + together with such enormous rigidity, others so loosely? Why does not a + lump of iron dissolve as readily as the lump of sugar in our bowl of + water? Guesses may be made to-day at these riddles, to be sure, but + anything like tenable solutions will only be possible when we know much + more than at present of the nature of intermolecular forces and of the + mechanism of molecular structures. As to this last, studies are under way + that are full of promise. For the past ten or fifteen years Professor Van + 't Hoof of Amsterdam (now of Berlin), with a company of followers, has + made the space relations of atoms a special study, with the result that + so-called stereo-chemistry has attained a firm position. A truly amazing + insight has been gained into the space relations of the molecules of + carbon compounds in particular, and other compounds are under + investigation. But these results, wonderful though they seem when the + intricacy of the subject is considered, are, after all, only tentative. It + is demonstrated that some molecules have their atoms arranged in perfectly + definite and unalterable schemes, but just how these systems are to be + mechanically pictured—whether as miniature planetary systems or what + not—remains for the investigators of the future to determine. + </p> + <p> + It appears, then, that whichever way one turns in the realm of the atom + and molecule, one finds it a land of mysteries. In no field of science + have more startling discoveries been made in the past century than here; + yet nowhere else do there seem to lie wider realms yet unfathomed. + </p> + <p> + LIFE PROBLEMS + </p> + <p> + In the life history of at least one of the myriad star systems there has + come a time when, on the surface of one of the minor members of the group, + atoms of matter have been aggregated into such associations as to + constitute what is called living matter. A question that at once suggests + itself to any one who conceives even vaguely the relative uniformity of + conditions in the different star groups is as to whether other worlds than + ours have also their complement of living forms. The question has + interested speculative science more perhaps in our generation than ever + before, but it can hardly be said that much progress has been made towards + a definite answer. At first blush the demonstration that all the worlds + known to us are composed of the same matter, subject to the same general + laws, and probably passing through kindred stages of evolution and decay, + would seem to carry with it the reasonable presumption that to all primary + planets, such as ours, a similar life-bearing stage must come. But a + moment's reflection shows that scientific probabilities do not carry one + safely so far as this. Living matter, as we know it, notwithstanding its + capacity for variation, is conditioned within very narrow limits as to + physical surroundings. Now it is easily to be conceived that these + peculiar conditions have never been duplicated on any other of all the + myriad worlds. If not, then those more complex aggregations of atoms which + we must suppose to have been built up in some degree on all cooling globes + must be of a character so different from what we term living matter that + we should not recognize them as such. Some of them may be infinitely more + complex, more diversified in their capacities, more widely responsive to + the influences about them, than any living thing on earth, and yet not + respond at all to the conditions which we apply as tests of the existence + of life. + </p> + <p> + This is but another way of saying that the peculiar limitations of + specialized aggregations of matter which characterize what we term living + matter may be mere incidental details of the evolution of our particular + star group, our particular planet even—having some such relative + magnitude in the cosmic order, as, for example, the exact detail of + outline of some particular leaf of a tree bears to the entire subject of + vegetable life. But, on the other hand, it is also conceivable that the + conditions on all planets comparable in position to ours, though never + absolutely identical, yet pass at some stage through so similar an epoch + that on each and every one of them there is developed something measurably + comparable, in human terms, to what we here know as living matter; + differing widely, perhaps, from any particular form of living being here, + yet still conforming broadly to a definition of living things. In that + case the life-bearing stage of a planet must be considered as having far + more general significance; perhaps even as constituting the time of + fruitage of the cosmic organism, though nothing but human egotism gives + warrant to this particular presumption. + </p> + <p> + Between these two opposing views every one is free to choose according to + his preconceptions, for as yet science is unable to give a deciding vote. + Equally open to discussion is that other question, as to whether the + evolution of universal atoms into a "vital" association mass from which + all the diversified forms evolved, or whether such shifting from the + so-called non-vital to the vital was many times repeated—perhaps + still goes on incessantly. It is quite true that the testimony of our + century, so far as it goes, is all against the idea of "spontaneous + generation" under existing conditions. It has been clearly enough + demonstrated that the bacteria and other low forms of familiar life which + formerly were supposed to originate "spontaneously" had a quite different + origin. But the solution of this special case leaves the general problem + still far from solved. Who knows what are the conditions necessary to the + evolution of the ever-present atoms into "vital" associations? Perhaps + extreme pressure may be one of these conditions; and, for aught any man + knows to the contrary, the "spontaneous generation" of living protoplasms + may be taking place incessantly at the bottom of every ocean of the globe. + </p> + <p> + This of course is a mere bald statement of possibilities. It may be met by + another statement of possibilities, to the effect that perhaps the + conditions necessary to the evolution of living matter here may have been + fulfilled but once, since which time the entire current of life on our + globe has been a diversified stream from that one source. Observe, please, + that this assumption does not fall within that category which I mention + above as contraband of science in speaking of the origin of worlds. The + existence of life on our globe is only an incident limited to a relatively + insignificant period of time, and whether the exact conditions necessary + to its evolution pertained but one second or a hundred million years does + not in the least matter in a philosophical analysis. It is merely a + question of fact, just as the particular temperature of the earth's + surface at any given epoch is a question of fact, the one condition, like + the other, being temporary and incidental. But, as I have said, the + question of fact as to the exact time of origin of life on our globe is a + question that science as yet cannot answer. + </p> + <p> + But, in any event, what is vastly more important than this question as to + the duration of time in which living matter was evolved is a comprehension + of the philosophical status of this evolution from the "non-vital" to the + "vital." If one assumes that this evolution was brought about by an + interruption of the play of forces hitherto working in the universe—that + the correlation of forces involved was unique, acting then and then only—by + that assumption he removes the question of the origin of life utterly from + the domain of science—exactly as the assumption of an initial push + would remove the question of the origin of worlds from the domain of + science. But the science of to-day most emphatically demurs to any such + assumption. Every scientist with a wide grasp of facts, who can think + clearly and without prejudice over the field of what is known of cosmic + evolution, must be driven to believe that the alleged wide gap between + vital and non-vital matter is largely a figment of prejudiced human + understanding. In the broader view there seem no gaps in the scheme of + cosmic evolution—no break in the incessant reciprocity of atomic + actions, whether those atoms be floating as a "fire mist" out in one part + of space, or aggregated into the brain of a man in another part. And it + seems well within the range of scientific expectation that the laboratory + worker of the future will learn how so to duplicate telluric conditions + that the universal forces will build living matter out of the inorganic in + the laboratory, as they have done, and perhaps still are doing, in the + terrestrial oceans. + </p> + <p> + To the timid reasoner that assumption of possibilities may seem startling. + But assuredly it is no more so than seemed, a century ago, the assumption + that man has evolved, through the agency of "natural laws" only, from the + lowest organism. Yet the timidity of that elder day has been obliged by + the progress of the past century to adapt its conceptions to that assured + sequence of events. And some day, in all probability, the timidity of + to-day will be obliged to take that final logical step which to-day's + knowledge foreshadows as a future if not a present necessity. + </p> + <p> + THE MECHANISM OF THE CELL + </p> + <p> + Whatever future science may be able to accomplish in this direction, + however, it must be admitted that present science finds its hands quite + full, without going farther afield than to observe the succession of + generations among existing forms of life. Since the establishment of the + doctrine of organic evolution, questions of heredity, always sufficiently + interesting, have been at the very focus of attention of the biological + world. These questions, under modern treatment, have resolved themselves, + since the mechanism of such transmission has been proximately understood, + into problems of cellular activity. And much as has been learned about the + cell of late, that interesting microcosm still offers a multitude of + intricacies for solution. + </p> + <p> + Thus, at the very threshold, some of the most elementary principles of + mechanical construction of the cell are still matters of controversy. On + the one hand, it is held by Professor O. Butschli and his followers that + the substance of the typical cell is essentially alveolar, or foamlike, + comparable to an emulsion, and that the observed reticular structure of + the cell is due to the intersections of the walls of the minute ultimate + globules. But another equally authoritative school of workers holds to the + view, first expressed by Frommann and Arnold, that the reticulum is really + a system of threads, which constitute the most important basis of the cell + structure. It is even held that these fibres penetrate the cell walls and + connect adjoining cells, so that the entire body is a reticulum. For the + moment there is no final decision between these opposing views. Professor + Wilson of Columbia has suggested that both may contain a measure of truth. + </p> + <p> + Again, it is a question whether the finer granules seen within the cell + are or are not typical structures, "capable of assimilation, growth, and + division, and hence to be regarded as elementary units of structure + standing between the cell and the ultimate molecules of living matter." + The more philosophical thinkers, like Spencer, Darwin, Haeckel, Michael + Foster, August Weismann, and many others, believe that such "intermediate + units must exist, whether or not the microscope reveals them to view." + Weismann, who has most fully elaborated a hypothetical scheme of the + relations of the intracellular units, identifies the larger of these units + not with the ordinary granules of the cell, but with a remarkable + structure called chromatin, which becomes aggregated within the cell + nucleus at the time of cellular division—a structure which divides + into definite parts and goes through some most suggestive manoeuvres in + the process of cell multiplication. All these are puzzling structures; and + there is another minute body within the cell, called the centro-some, that + is quite as much so. This structure, discovered by Van Beneden, has been + regarded as essential to cell division, yet some recent botanical studies + seem to show that sometimes it is altogether wanting in a dividing cell. + </p> + <p> + In a word, the architecture of the cell has been shown by modern + researches to be wonderfully complicated, but the accumulating researches + are just at a point where much is obscure about many of the observed + phenomena. The immediate future seems full of promise of advances upon + present understanding of cell processes. But for the moment it remains for + us, as for preceding generations, about the most incomprehensible, + scientifically speaking, of observed phenomena, that a single microscopic + egg cell should contain within its substance all the potentialities of a + highly differentiated adult being. The fact that it does contain such + potentialities is the most familiar of every-day biological observations, + but not even a proximal explanation of the fact is as yet attainable. + </p> + <p> + THE ANCESTRY OF THE MAMMALS + </p> + <p> + Turning from the cell as an individual to the mature organism which the + cell composes when aggregated with its fellows, one finds the usual + complement of open questions, of greater or less significance, focalizing + the attention of working biologists. Thus the evolutionist, secure as is + his general position, is yet in doubt when it comes to tracing the exact + lineage of various forms. He does not know, for example, exactly which + order of invertebrates contains the type from which vertebrates sprang, + though several hotly contested opinions, each exclusive of the rest, are + in the field. Again, there is like uncertainty and difference of opinion + as to just which order of lower vertebrates formed the direct ancestry of + the mammals. Among the mammals themselves there are several orders, such + as the whales, the elephants, and even man himself, whose exact lines of + more immediate ancestry are not as fully revealed by present paleontology + as is to be desired. + </p> + <p> + THE NEW SCIENCE OF ANTHROPOLOGY + </p> + <p> + All these, however, are details that hardly take rank with the general + problems that we are noticing. There are other questions, however, + concerning the history and present evolution of man himself that are of + wider scope, or at least seemingly greater importance from a human + stand-point, which within recent decades have come for the first time + within the scope of truly inductive science. These are the problems of + anthropology—a science of such wide scope, such far-reaching + collateral implications, that as yet its specific field and functions are + not as clearly defined or as generally recognized as they are probably + destined to be in the near future. The province of this new science is to + correlate the discoveries of a wide range of collateral sciences—paleontology, + biology, medicine, and so on—from the point of view of human history + and human welfare. To this end all observable races of men are studied as + to their physical characteristics, their mental and moral traits, their + manners, customs, languages, and religions. A mass of data is already at + hand, and in process of sorting and correlating. Out of this effort will + probably come all manner of useful generalizations, perhaps in time + bringing sociology, or the study of human social relations, to the rank of + a veritable science. But great as is the promise of anthropology, it can + hardly be denied that the broader questions with which it has to deal—questions + of race, of government, of social evolution—are still this side the + fixed plane of assured generalization. No small part of its interest and + importance depends upon the fact that the great problems that engage it + are as yet unsolved problems. In a word, anthropology is perhaps the most + important science in the entire hierarchy to-day, precisely because it is + an immature science. Its position to-day is perhaps not unlike that of + paleontology at the close of the eighteenth century. May its promise find + as full fruition! + </p> + <p> + <a name="link2H_4_0011" id="link2H_4_0011"> + <!-- H2 anchor --> </a> + </p> + <div style="height: 4em;"> + <br /><br /><br /><br /> + </div> + <h2> + IX. RETROSPECT AND PROSPECT + </h2> + <p> + THE SCIENTIFIC ATTITUDE OF MIND + </p> + <p> + ANY one who has not had a rigid training in science may advantageously + reflect at some length upon the meaning of true scientific induction. + Various illustrations in our text are meant to convey the idea that + logical thinking consists simply in drawing correct conclusions as to the + probable sequence of events in nature. It will soon be evident to any one + who carefully considers the subject that we know very little indeed about + cause and effect in a rigid acceptance of these words. We observe that + certain phenomena always follow certain other phenomena, and these + observations fix the idea in our mind that such phenomena bear to one + another the relation of effect and cause. The conclusion is a perfectly + valid one so long as we remember that in the last analysis the words + "cause" and "effect" have scarcely greater force than the terms + "invariable antecedent" and "invariable consequent"—that is to say, + they express an observed sequence which our experience has never + contradicted. + </p> + <p> + Now the whole structure of science would be hopelessly undermined had not + scientific men come to have the fullest confidence in the invariability of + certain of these sequences of events. Let us, for example, take the + familiar and fundamental observation that any unsupported object, having + what we term weight, invariably falls directly towards the centre of the + earth. We express this fact in terms of a so-called law of gravitation, + and every one, consciously or unconsciously, gives full deference to this + law. So firmly convinced are we that the gravitation pull is a cause that + works with absolute, unvarying uniformity that we should regard it as a + miracle were any heavy body to disregard the law of gravitation and rise + into the air when not impelled by some other force of which we have + knowledge. Thanks to Newton, we know that this force of gravitation is not + at all confined to the earth, but affects the whole universe, so that + every two bits of matter, regardless of location, pull at each other with + a force proportionate to their mass and inversely as the square of their + distance. + </p> + <p> + Were this so-called law of gravitation to cease to operate, the entire + plan of our universe would be sadly disarranged. The earth, for example, + and the other planets would leave their elliptical orbits and hurtle away + on a tangential course. We should soon be beyond the reach of the sun's + beneficent influence; an arctic chill would pervade polar and tropical + regions alike, and the term of man's existence would come suddenly to a + close. Here, then, is a force at once the most comprehensible and most + important from a human stand-point that can be conceived; yet it cannot be + too often repeated, we know nothing whatever as to the nature of this + force. We do not know that there may not be other starlike clusters beyond + our universe where this force does not prevail. We do not know that there + may not come a period when this force will cease to operate in our + universe, and when, for example, it will be superseded by the universal + domination of a force of mutual repulsion. For aught we know to the + contrary, our universe may be a pulsing organism, or portion of an + organism, all the particles of which are at one moment pulled together and + the next moment hurled apart—the moments of this computation being, + of course, myriads of years as we human pygmies compute time. + </p> + <p> + To us it would be a miracle if a heavy body, unsupported, should fly off + into space instead of dropping towards the centre of the earth; yet the + time may come when all such heavy objects will thus fly off into space, + and when the observer, could there be such, must marvel at the miracle of + seeing a heavy object fall towards the earth. Such thoughts as these + should command the attention of every student of science who would really + understand the meaning of what are termed natural laws. But, on the other + hand, such suggestions must be held carefully in check by the observation + that scientific imagining as to what may come to pass at some remote + future time must in no wise influence our practical faith in the + universality of certain natural laws in the present epoch. We may imagine + a time when terrestrial gravitation no longer exerts its power, but we + dare not challenge that power in the present. There could be no science + did we not accept certain constantly observed phenomena as the effect of + certain causes. The whole body of science is made up solely of such + observations and inferences. Natural science is so called because it has + to do with observed phenomena of nature. + </p> + <p> + NATURAL VERSUS SUPERNATURAL + </p> + <p> + A further word must be said as to this word "natural," and its + complementary word "supernatural." I have said in an early chapter that + prehistoric man came, through a use of false inductions, to the belief in + supernatural powers. Let us examine this statement in some detail, for it + will throw much light on our later studies. The thing to get clearly in + mind is the idea that when we say "natural" phenomena we mean merely + phenomena that have been observed to occur. From a truly scientific + stand-point there is no preconception as to what manner of phenomenon may, + or may not, occur. All manner of things do occur constantly that would + seem improbable were they not matters of familiar knowledge. The simplest + facts in regard to gravitation involve difficulties that were + stumbling-blocks to many generations of thinkers, and which continue + stumbling-blocks to the minds of each generation of present-day children. + </p> + <p> + Thus most of us can recall a time when we first learned with astonishment + that the earth is "round like a ball"; that there are people walking about + on the other side of the world with their feet towards ours, and that the + world itself is rushing through space and spinning rapidly about as it + goes. Then we learn, further, that numberless familiar phenomena would be + quite different could we be transported to other globes. That, for + example, a man who can spring two or three feet into the air here would be + able, with the same muscular exertion, to vault almost to the house-tops + if he lived on a small planet like the moon; but, on the other hand, would + be held prone by his own weight if transported to a great planet like + Jupiter. + </p> + <p> + When, further, we reflect that with all our capacity to measure and + estimate this strange force of gravitation we, after all, know absolutely + nothing as to its real nature; that we cannot even imagine how one portion + of matter can act on another across an infinite abysm (or, for that + matter, across the smallest space), we see at once that our most + elementary scientific studies bring us into the presence of inscrutable + mysteries. In whatever direction we turn this view is but emphasized. + Electricity, magnetism, the hypothetical ether, the inscrutable forces + manifested everywhere in the biological field—all these are, as + regard their ultimate nature, altogether mysterious. + </p> + <p> + In a word, the student of nature is dealing everywhere with the wonderful, + the incomprehensible. Yet all the manifestations that he observes are + found to repeat themselves in certain unvarying sequences. Certain + applications of energy will produce certain movements of matter. We may + not know the nature of the so-called cause, but we learn to measure the + result, and in other allied cases we learn to reason back or infer the + cause from observation of results. The latter indeed is the essence of + scientific inquiry. When certain series of phenomena have been classified + together as obviously occurring under the domination of the same or + similar causes, we speak of having determined a law of nature. For + example, the fact that any body in motion tends to go on at the same rate + of speed in a direct line forever, expresses such a law. The fact that the + gravitation pull is directly as the mass and inversely as the square of + the distance of the bodies it involves, expresses another such law. The + fact that the planetary bodies of the solar system revolve in elliptical + orbits under the joint influence of the two laws just named, expresses yet + another law. In a word, then, these so-called "laws" are nothing more than + convenient formulae to express the classification of observed facts. + </p> + <p> + INDUCTIVE VERSUS DEDUCTIVE REASONING + </p> + <p> + The ancient thinkers indulged constantly in what we now speak of as + deductive reasoning. They gave heed to what we term metaphysical + preconceptions as to laws governing natural phenomena. The Greeks, for + example, conceived that the circle is the perfect body, and that the + universe is perfect; therefore, sun and moon must be perfect spheres or + disks, and all the orbits of the heavenly bodies must be exactly circular. + We have seen that this metaphysical conception, dominating the world for + many centuries, exerted a constantly hampering influence upon the progress + of science. There were numerous other instances of the same retarding + influence of deductive reasoning. Modern science tries to cast aside all + such preconceptions. It does not always quite succeed, but it makes a + strenuous effort to draw conclusions logically from observed phenomena + instead of trying to force observations into harmony with a preconeived + idea. Herein lies the essential difference between the primitive method + and the perfected modern method. Neither the one nor the other is intended + to transcend the bounds of the natural. That is to say, both are concerned + with the sequence of actual events, with the observation of actual + phenomena; but the modern observer has the almost infinite advantage of + being able to draw upon an immense store of careful and accurate + observations. A knowledge of the mistakes of his predecessors has taught + him the value of caution in interpreting phenomena that seem to fall + outside the range of such laws of nature as experience has seemed to + demonstrate. Again and again the old metaphysical laws have been forced + aside by observation; as, for example, when Kepler showed that the + planetary orbits are not circular, and Galileo's telescope proved that the + spot-bearing sun cannot be a perfect body in the old Aristotelian sense. + </p> + <p> + New means of observation have from time to time opened up new fields, yet + with all the extensions of our knowledge we come, paradoxically enough, to + realize but the more fully the limitations of that knowledge. We seem + scarcely nearer to-day to a true understanding of the real nature of the + "forces" whose operation we see manifested about us than were our most + primitive ancestors. But in one great essential we have surely progressed. + We have learned that the one true school is the school of experience; that + metaphysical causes are of absolutely no consequence unless they can gain + support through tangible observations. Even so late as the beginning of + the nineteenth century, the great thinker, Hegel, retaining essentially + the Greek cast of thought, could make the metaphysical declaration that, + since seven planets were known, and since seven is the perfect number, it + would be futile to search for other planets. But even as he made this + declaration another planet was found. It would be safe to say that no + thinker of the present day would challenge defeat in quite the + Aristotelian or Hegelian manner; but, on the other hand, it is equally + little open to doubt that, in matters slightly less susceptible of + tangible demonstration, metaphysical conceptions still hold sway; and as + regards the average minds of our time, it is perhaps not an unfair + estimate to say they surely have not advanced a jot beyond the + Aristotelian stand-point. Untrained through actual experience in any field + of inductive science, they remain easy victims of metaphysical reasoning. + Indeed, since the conditions of civilization throw a protecting influence + about us, and make the civilized man less amenable to results of illogical + action than was the barbarian, it may almost be questioned whether the + average person of to-day is the equal, as a scientific reasoner, of the + average man of the Stone Age. + </p> + <p> + A few of the more tangible superstitions of primitive man have been + banished from even the popular mind by the clear demonstration of science, + but a host remains. I venture to question whether, if the test could be + made in the case of ten thousand average persons throughout Christendom, + it would not be found that a majority of these persons entertain more + utterly mistaken metaphysical ideas regarding natural phenomena than they + do truly scientific conceptions. We pride ourselves on the enlightenment + of our age, but our pride is largely based on an illusion. Mankind at + large is still in the dark age. The historian of the remote future will + see no radical distinction between the superstitions of the thirteenth + century and the superstitions of the nineteenth century. But he will + probably admit that a greater change took place in the world of thought + between the year 1859 and the close of the nineteenth century than had + occurred in the lapse of two thousand years before If this estimate be + correct, it is indeed a privilege to be living in this generation, for we + are on the eve of great things, and beyond question the revolution that is + going on about us denotes the triumph of science and its inductive method. + Just in proportion as we get away from the old metaphysical + preconceptions, substituting for them the new inductive method, just in + that proportion do we progress. The essence of the new method is to have + no preconceptions as to the bounds of nature; to regard no phenomenon, no + sequence of phenomena, as impossible; but, on the other hand, to accept no + alleged law, no theory, no hypothesis, that has not the warrant of + observed phenomena in its favor. + </p> + <p> + The great error of the untrained mind of the primitive man was that he did + not know the value of scientific evidence. He made wide leaps from + observed phenomena to imagined causes, quite overlooking the proximal + causes that were near to hand. The untrained observer of to-day makes the + same mistake; hence the continued prevalence of those superstitious + misconceptions which primitive man foisted upon our race. But each new + generation of to-day is coming upon the field better trained in at least + the rudiments of scientific method than the preceding generation, and this + is perhaps the most hopeful feature of present-day education. Some day + every one will understand that there is no valid distinction between the + natural and the supernatural; in fact, that no such thing as a + supernatural phenomenon, in the present-day acceptance of the word, can + conceivably exist. + </p> + <p> + All conceivable manifestations of nature are natural, nor can we doubt + that all are reducible to law—that is to say, that they can be + classified and reduced to systems. But the scientific imagination, as + already pointed out, must admit that any and every scientific law of our + present epoch may be negatived in some future epoch. It is always + possible, also, that a seeming law of to-day may be proved false + to-morrow, which is another way of saying that man's classification + improves from generation to generation. For a "natural law," let it be + repeated, is not nature's method, but man's interpretation of that method. + </p> + <p> + LOGICAL INDUCTION VERSUS HASTY GENERALIZATION + </p> + <p> + A great difficulty is found in the fact that men are forever making + generalizations—that is, formulating laws too hastily. A few + phenomena are observed and at once the hypothesis-constructing mind makes + a guess as to the proximal causes of these phenomena. The guess, once + formulated and accepted, has a certain influence in prejudicing the minds + of future observers; indeed, where the phenomena involve obscure + principles the true explanation of which is long deferred, a false + generalization may impress itself upon mankind with such force as to + remain a stumbling-block for an indefinite period. Thus the Ptolemaic + conception of the universe dominated the thought of Europe for a thousand + years, and could not be substituted by the true theory without a fierce + struggle; and, to cite an even more striking illustration, the early + generalizations of primitive man which explain numberless phenomena of + nature as due to an influence of unseen anthropomorphic beings remain to + this day one of the most powerful influences that affect our race—an + influence from which we shall never shake ourselves altogether free until + the average man—and particularly the average woman—learns to + be a good observer and a logical reasoner. + </p> + <p> + Something towards this end is being accomplished by the introduction of + experimental research and scientific study in general in our schools and + colleges. It is hoped that something towards the same end may be + accomplished through study of the history of the development of science. + Scarcely anything is more illuminative than to observe critically the + mistakes of our predecessors, noting how natural the mistakes were and how + tenaciously they were held to, how strenuously defended. Most of all it + would be of value to note that the false inductions which have everywhere + hampered the progress of science have been, from the stand-point of the + generation in which they originated, for the most part logical inductions. + We have seen that the Ptolemaic scheme of the universe, false though it + was in its very essentials, yet explained in what may be termed a + thoroughly scientific fashion the observed phenomena. It is one way of + expressing a fact to say that the sun moves across the heavens from the + eastern to the western horizon; and for most practical purposes this + assumption answers perfectly. It is only when we endeavor to extend the + range of theoretical astronomy, and to gain a correct conception of the + mechanism of the universe as a whole, that the essentially faulty + character of the geocentric conception becomes apparent. + </p> + <p> + And so it is in many another field; the false generalizations and hasty + inductions serve a temporary purpose. Our only quarrel with them is that + they tend through a sort of inertia to go forever unchanged. It requires a + powerful thrust to divert the aggregate mind of our race from a given + course, nor is the effect of a new impulse immediately appreciable; that + is why the masses of the people always lag a generation or two behind the + advanced thinkers. A few receptive minds, cognizant of new observations + that refute an old generalization, accept new laws, and, from the + vantage-ground thus gained, reach out after yet other truths. But, for the + most part, the new laws thus accepted by the leaders remain unknown to the + people at large for at least one or two generations. It required about a + century for the heliocentric doctrine of Copernicus to begin to make its + way. + </p> + <p> + In this age of steam and electricity, progress is more rapid, and the + greatest scientific conception of the nineteenth century, the Darwinian + theory, may be said to have made something that approaches an absolute + conquest within less than half a century. This seems a marvellously sudden + conquest, but it must be understood that it is only the crude and more + tangible bearings of the theory that have thus made their way. The remoter + consequences of the theory are not even suspected by the great majority of + those who call themselves Darwinians to-day. It will require at least + another century for these ideas to produce their full effect. Then, in all + probability, it will appear that the nineteenth century was the most + revolutionary epoch by far that the history of thought has known. And it + owes this proud position to the fact that it was the epoch in all history + most fully subject to the dominant influence of inductive science. Thanks + to this influence, we of the new generation are able to start out on a + course widely divergent from the path of our ancestors. Our leaders of + thought have struggled free from the bogs of superstition, and are + pressing forward calmly yet with exultation towards the heights. + </p> + <p> + <a name="link2H_APPE" id="link2H_APPE"> + <!-- H2 anchor --> </a> + </p> + <div style="height: 4em;"> + <br /><br /><br /><br /> + </div> + <h2> + APPENDIX + </h2> +<pre xml:space="preserve"> + (p. 95). J. J. Thompson, D.Sc., LL.D., Ph.D., F.R.S.,etc., Electricity + and Matter, p. 75 ff., New York, 1904. The Silli-man Lectures, delivered + at Yale University, May, 1903. + + (p. 96). Ibid., pp. 88, 89. 3 (p- 97)- Ibid., p. 89. + + (p. 97). Ibid., p. 87. + + (p. 102). George F. Kunz, "Radium and its Wonders," in the Review of + Reviews for November, 1903, p. 589. + + (p. 105). E. Rutherford, Radio-Activity, p. 330, Cambridge, 1904. + + (p. 106). Ibid., p. 330. + + (p. 106). Compte Rendu, pp. 136, 673, Paris, 1903. + + (p. 106). Revue Scientifique, April 13, 1901. 10 (p. 106). Compte Rendu, + p. 136, Paris, 1903. +</pre> +<pre xml:space="preserve"> + (p. 108). J. J. Thompson, Electricity and Matter, p. 162, New York, + 1904. + + (p. —). E. Rutherford, Radio-Activity, p. 340, Cambridge, 1904. + + (p. 185). Dr. Duclaux, who was one of Pasteur's chief assistants, and + who succeeded him in the directorship of the Institute, died in 1903. He + held a professorship in the University of Paris during the later years + of his life, and his special studies had to do largely with the chemical + side of bacteriology. + + (p. 217). Lord Kelvin's estimate as quoted was expressed to the writer + verbally. I do not know whether he has anywhere given a similar written + verdict. +</pre> + <p> + A LIST OF SOURCES I.—PERIOD COVERED BY VOLUME I. + </p> + <p> + An ax agoras. See vol. i., p. 240. + </p> + <p> + Archimedes. See vol. i., p. 196. + </p> + <p> + Many of the works of Archimedes are lost, but the following have come down + to us: (1) On the Sphere and Cylinder; (2) The Measure of the Circle; (3) + Conoids and Spheroids; (4) On Spirals; (5) Equiponderants and Centres of + Gravity; (6) The Quadrature of the Parabola; (7) On Bodies Floating in + Liquids; (8) The Psammites; (9) A Collection of Lemmas. + </p> + <p> + Aristarchus. See vol. i., p. 212. + </p> + <p> + Magnitudes and Distances of the Sun and Moon is the only surviving work. + In the Armarius of Archimedes another work of Aristarchus is quoted—the + one in which he anticipates the discovery of Copernicus. Delambre, in his + Histoire de Vastronomie ancienne, treats fully the discoveries of + Aristarchus. + </p> + <p> + Aristotle. See vol. i., p. 82. + </p> + <p> + An edition of Aristotle was published by Aldus, Venice, 1495-1498, 5 vols. + During the following eighty years seven editions of the Greek text of the + entire works were published, and many Latin translations. + </p> + <p> + Berosus. See vol. i., p. 58. + </p> + <p> + The fragments of Berosus have been trans, by I. P. Cory, and included in + his Ancient Fragments of Phoenician, Chaldean, Egyptian, and Other + Writers, London, 1826; second edition, 1832. + </p> + <p> + Democritus. See vol. i., p. 161. + </p> + <p> + Fragments only of the numerous works ascribed to Democritus have been + preserved. Democriii Abdereo operum fragmenta, Berlin, 1843, edited by F. + G. A. Mullach. Diodorus Siculus. See vol. i., p. 77. + </p> + <p> + The Historical Library. Perhaps the best available editions of Diodorus + are Wesseling's, 2 vols.; Amstel, 1745; and Dindorf's, 5 vols., Leipzig, + 1828-1831. English trans, by Booth, London, 1700. Diogenes Laertius. See + vol. i., p. 121. + </p> + <p> + The Lives and Opinions of Eminent Philosophers (trans. by C. D. Yonge), + London, 1853. + </p> + <p> + Eratosthenes. See vol. i., p. 225. + </p> + <p> + The fragments of his philosophical works were published at Berlin, 1822, + under the title Eratosthenica. His poetical works were published at + Leipzig, 1872. Euclid. See vol. i., p. 193. + </p> + <p> + His Elements of Geometry is still available as an English school + text-book. + </p> + <p> + Galen (Claudius Galenus). See vol. i., p. 272. + </p> + <p> + Galen's preserved works are exceedingly bulky. The best-known edition is + that of C. G. Kuhn, in 21 volumes. + </p> + <p> + Hero. See vol. i., p. 242. + </p> + <p> + The Pneumatics of Hero of Alexandria, from the original Greek. Trans, by + B. Woodcroft, London, 1851. Herodotus. See vol. i.t p. 103. + </p> + <p> + History. English trans, by Beloe, 1791 and 1806. Trans, by Canon + Rawlinson, London, 1858-1860. Hipparchus. See vol. i., p. 233. + </p> + <p> + The only work of Hipparchus which has survived was published first by + Vittorius at Florence, 1567. Hippocrates. See vol. i., p. 170. + </p> + <p> + Numerous editions have been published of the Hippo-cratic writings, + including many works not written by the master himself. One of the best + editions is that of Littré, Paris, 1839, etc. + </p> + <p> + Khamurabi, Codb op. See vol. i., p. 76. + </p> + <p> + This famous inscription is on a block of black diorite nearly eight feet + in height. It was discovered at Susa by the French expedition under M. de + Morgan in December, 1901. + </p> + <p> + Leucippus. See vol. i., p. 161. + </p> + <p> + Pliny (Caius Plinius Secundus). See vol. i., p. 265. + </p> + <p> + His Natural History is available in several English editions and reprints. + Perhaps the best edition of the original text is the one published by + Julius Sillig, 5 vols., Leipzig, 1854-1859. Plutarch. See vol. i., p. 198. + </p> + <p> + Life of Marcellus, in Parallel Lives. In this the mechanical inventions of + Archimedes are described. Polybius. See vol. i., p. 201. + </p> + <p> + In his Histories Polybius describes the mechanical contrivances and + war-engines of Archimedes, and also gives an account of his death. Ptolbmy + (Claudius Ptolemaeus). See vol. i., p. 269. + </p> + <p> + Geographia (or Almagest of the Arabs). The edition published by Nobbe, in + 3 vols., Leipzig, 1842, was one of the best complete editions of the Greek + text. The edition published in Didot's Bibliotheca Classicorum Grocorum, + Paris, 1883, is excellent. Earlier editions contain many errors. + </p> + <p> + Strabo. See vol. i., p. 255. + </p> + <p> + The Geography of Strabo. Trans, by H. C. Hamilton and W. Falconer, 3 + vols., London, 1857. There are several other editions of Strabo's work + available in English. + </p> + <p> + Tertullian. See vol. i., p. 195. + </p> + <p> + Apologeticus. Theophrastus. See vol. i., p. 188. + </p> + <p> + Utpivlaroplas, On the History of Plants. Written in 10 books. This is one + of the earliest works on botany which have come to us. It was largely used + by Pliny. In complete works, Schneider, Leipzig, 1818-1821, 5 vols. On + Plants, edited by Wimmer, Breslau, 247 + </p> + <p> + 1842-1862. On Plants, edited by Slackhouse, Oxford, 1814. atria, On the + Causes of Plants, This was originally in 8 books, of which 6 are now + existant. Bibliog. vid. History of Plants. + </p> + <p> + II.—PERIOD COVERED BY VOLUME II. + </p> + <p> + Albategnius, Mohammed bbn Jabir. See vol. ii., p. 15. + </p> + <p> + The original MS. of his principal work, Zidje Sabt, is in the Vatican. A + Latin translation was first published by Plato Tiburtinus at Nuremberg, in + 1537, under the title De scientia stellarunt. Various reprints of this + have been made. Albertus Magnus. See vol. ii., p. 127. + </p> + <p> + Philosophic* Naturalis Isagoge, Vienna, 1514. Alhazen (full name, Abu Ali + al-Hasan Ibn Alhasan). See vol. ii., p. 18. + </p> + <p> + Only two of his works have been printed, his Treatise on Twilight and his + Thesaurus opticae, these being available in Michael Casiri's Bibliotheca + Arabico-Hispana Escuri-alensis, 2 vols., Madrid, 1760-1770. + </p> + <p> + Bacon, Francis. See vol. ii., p. 192. + </p> + <p> + Novum Organum was published in London, 1620. The Letters and Life of Lard + Bacon, in 7 vols., by James Spedding, appeared in 1862-1874. Bacon, Roger. + See vol. ii., p. 44. + </p> + <p> + Only an approximate estimate of the number of Bacon's works can be given + even now, although an infinite amount of time and labor has been spent in + collecting them. His great work is the Opus ma jus, "the Encyclopaedia and + the Organum of the Thirteenth Century." A partial list of some of his + other works is the following: Speculum alchemio, 1541 (trans, into + English); De mirabili potestate artis et naturo, 1542 (trans, into + English, 1659); Libellus de retardants se-nectutis accidentibus, 1590 + (trans, as "The Cure of Old. Age," 1683); and Sanioris medicino Magistri + d. Rogeri Baconis Anglici de arte chymio scripta, 1603. 248 + </p> + <p> + Boyle, Robert. See vol. ii., p. 205. + </p> + <p> + Philosophical Works, 3 vols., London, 1738. + </p> + <p> + Copernicus, Nicolaus. See vol. ii., p. 54. + </p> + <p> + Ad clar. v. d. Schonerum de libris revolutionism eruditiss. viri et + mathemattci excellentiss. Rev. Doctoris Nicolai Copernici Torunnaei, + Canonici Warmiensis, per quemdam juvenem mathematico studio sum, Narratio + prima, Dantzic, 1540. This was the first published statement of the + doctrine of Copernicus, and was a letter published by Rheticus. Three + years afterwards Copernicus's De orbium colestium revolutionibus, Libri + VI., was published at Nuremberg (1543). + </p> + <p> + Descartes, René. See vol. ii., p. 193. + </p> + <p> + Traité de Vhomme (Cousins's edition, in 11 vols., Paris, 1824). + </p> + <p> + Galilei, Galileo. See vol. ii., p. 91. + </p> + <p> + Dialogo dei due massimi sistemi del mondo, Florence, 1632. Discorsi e + dimostrazioni matematiche intorno a due nuove scienze, Leyden, 1638. + Gilbert, William (1540-1603). See vol. ii., p. 113. + </p> + <p> + De magnete, magneticisque corporibus, et de magno magnete tellure, London, + 1600. De magnete was trans. by P. Fleury Motteley, London, 1893. Guericke, + Otto von (1620-1686). See vol. ii., p. 213. + </p> + <p> + Expérimenta nova, ut vocant, Magdeburgica de vacuo spatio, Amsterdam, + 1672. In the Phil. Trans, of the Royal Society of London, No. 88, for + 1672. + </p> + <p> + Hales, Stephen (1677-1761). See vol. ii., p. 298. + </p> + <p> + Statical Essays, comprising Vegetable Staticks, London, 1727, and + Homostatics, London, 1733. Harvey, William. See vol. ii., p. 169. + </p> + <p> + Exercitatio anatomica de motu cordis et sanguinis, Frankfort-on-Main, + 1628. The Works of, trans, by Robert Willis, London, 1847. Hauksbeb, + Francis. See vol. ii., p. 259. + </p> + <p> + Physico-Mechanical Experiments on Various Subjects, London, 1709. This + contains descriptions of his various discoveries in electricity, many of + which are given in the Phil. Trans. + </p> + <p> + Hooee, Robert. See vol. ii., p. 215. + </p> + <p> + Micrographia, or Some Philosophical Descriptions of Some Minute Bodies, + London, 1665. An Attempt to Prove the Motion of the Earth, London, 1674. + Microscopical Observations, London, 1780. Most of Hooke's important + discoveries were contributed as papers to the Royal Society and are + available in the Phil. Trans. + </p> + <p> + Huygens, Christian (1629-1695). See vol. ii., p. 218. + </p> + <p> + Traite de la lumière, Leyden, 1690. Complete works were published at The + Hague in 1888, under thetit le Ouvres complètes, by the Société + Hollandaise des Sciences. These books have not been translated into + English. Huygens's famous paper on the laws governing the collision of + elastic bodies appeared in the Phil. Trans, of the Royal Society for 1669. + </p> + <p> + Kepler, Johann. See vol. ii., p. 70. + </p> + <p> + Astronomia nova de motibus Stella Mortis, Leipzig, 1609, contains Kepler's + two first laws; and Harmonices mundi, 1619, contains the third law, + Phomomenon singulare, seu Mercurius in sole, Leipzig, 1609. Joannis KepUri + opera omnia, in 8 vols., Frankfort, 1858-1871. + </p> + <p> + Leeuwenhoek, Anthony van. See vol. ii., p. 179. + </p> + <p> + His discoveries are mostly recorded in the Phil. Trans. of the Royal + Society, between the years 1673 and 1723—one hundred and twelve + papers in all. His discovery of bacteria is recorded in Phil. Trans, for + 1683; and that of the discovery of the capillary circulation of the blood + in Phil. Trans, for 1790. + </p> + <p> + LiNNiEus, Carolus (1707-1778). See vol. ii., p. 299. + </p> + <p> + His Systema natures was published in 1735. Tro years later (1737) he + published Genera plantarum, which is generally considered as the + starting-point of modern botany. His published works amount to more than + one hundred and eighty. + </p> + <p> + Mariotte, Edme (died 1684). See vol. ii., p. 210. + </p> + <p> + Essais de physique (four essays), Paris, 1676-1679. 250 + </p> + <p> + His De la nature de l'air, containing his statement of the law connecting + the volume and pressure of a gas, is contained in the second essay. + </p> + <p> + Newton, Sir Isaac. See vol. ii., p. 241. + </p> + <p> + Philosophies naturalis principia mathematica, completed in July of 1687. + The first edition was exhausted in a few months. There are several + translations, among others one by Andrew Motte, New York, 1848. + </p> + <p> + Paracelsus. See vol. ii., p. 159. + </p> + <p> + The Hermetic and Alchemical Writings of Paracelsus, trans, by A. E. Waite, + 2 vols., London, 1894. Pascal, Blaise. See vol. ii., p. 122. + </p> + <p> + Récit de la grande expérience de Vêquilibre de liqueurs, Paris, 1648. + </p> + <p> + Sawtree, John. See vol. ii., p. 124 ff. + </p> + <p> + Of the Philosopher's Stone, London, 1652. Swammerdam, John. See vol. ii., + p. 297. + </p> + <p> + Bibel der Natur, trans, into German, Leipzig, 1752. Sydenham, Thomas. See + vol. ii., p. 189. + </p> + <p> + His first work, Methodus curandi febres, was published in 1666. His last + work, Processus integri, appeared in 1692. His complete works, in Latin, + were published by the Sydenham Society, London, 1844, which published also + an English translation by Pr. R. G. Latham in 1848. There are several + other English translations. + </p> + <p> + Torricelli, Evanoelista. See vol. ii., p. 120. + </p> + <p> + Opera geometrica, Florence, 1644. Tycho Brahe. See vol. ii., p. 65. + </p> + <p> + De mundi aetherei recentioribus phonomenis, Prague, 1603. This has been + trans, into German by M. Bruns, Karlsruhe, 1894. + </p> + <p> + Vinci, Leonardo da. See vol. ii., p. 47. + </p> + <p> + Leonardo da Vinci, Artist, Thinker, and Man of Science, by Eugene Muntz, 2 + vols., New York, 1892, is perhaps the most complete treatment of all + phases of Leonardo's work as a scientist as well as an artist. The older + French work, Essai sur les ouvrages physico-mathématiques de Léonard de + Vinci, by J. B. Venturi, Paris, 1797, is excellent. In German, H. Grothe's + Leonardo da Vinci als Ingénieur und Philosophy Berlin, 1874, is good. + </p> + <p> + III.—MODERN COSMICAL AND TELLURIC SCIENCES + </p> + <p> + Agassiz, L. See vol. iii., p. 147. + </p> + <p> + Etudes sur les glaciers, Neuchâtel, 1840. Arago, François J. D. See vol. + Hi., p. 67. + </p> + <p> + Ouvres (complete), if vols., Paris, 1854-1862. Arago's Meteorological + Essays, trans, into English, London, 1855. This has an introduction by + Humboldt. + </p> + <p> + Boscovich, Roger Joseph. See vol. iii., p. 293. + </p> + <p> + Theoria philosophio naturalis redacta ad unicam legem virium in natura + existentium, Vienna, 1758. Bradley, James. See vol. iii., p. 13. + </p> + <p> + Concerning an Apparent Motion Observed in Sotne of the Fixed Stars, + London, 1748, Phil. Trans., vol. xlv., pp. 8,9. + </p> + <p> + Cuvier,*Baron de. See vol. iv., p. 103. + </p> + <p> + Recherches sur les ossements fossiles de quadrupèdes, 4 vols., Paris, + 1812. (The introduction to this work was translated and published as a + volume bearing title of Theory of the Earth, New York, 1818.) + </p> + <p> + Delambre, Jean Baptiste Joseph. See vol. iii., p. 16. + </p> + <p> + Histoire d'astronomie, Paris, 1817-1821. This work contains not only the + history of the discoveries in astronomy, but is also a complete text-book + of astronomy as understood at this period. + </p> + <p> + Falconer, Hugh. See vol. iii., p. 99. + </p> + <p> + In Paloontological Memoirs, vol. ii., pp. 596-598. 252 + </p> + <p> + Herschbl, William. See vol. iii., p. 20 ff. + </p> + <p> + On the Proper Motion of the Solar System, Phil. Trans., vol. 73, for 1783. + (This paper was read in March, 1783.) The Constitution of the Heavens, + Phil. Trans, for 1785, vol. 75, p. 213. Howard, Luke. See vol. iii., p. + 182. + </p> + <p> + Philosophical Magazine, 1803. Humboldt, Alexander von. See vol. iii., p. + 192. + </p> + <p> + Des lignes isothermes et de la distribution de la chaleur sur le globe, + published in vol. iii., of Mémoires de physique et de chimie de la Société + d'Arcueil, Paris, 1819. Hutton, James. See vol. iii., p. 178. + </p> + <p> + Theory of Rain, in Transactions of the Royal Society of Edinburgh, 1788, + vol. i., pp. 53-56. See vol. iii., p. 121. From Transactions of the Royal + Society of Edinburgh, 1788, vol. i., pp. 214-304. A paper on the "Theory + of the Earth," read before the society in 1781. + </p> + <p> + Kant, Immanuel (i724-1804). See vol. iii., p. 27. + </p> + <p> + Allgemeine Naturgeschichte und Théorie des Himmels, 1755. Cosmogony, ed. + and trans, by W. Hartie, D.D., Glasgow, 1900. + </p> + <p> + Laplace, M. le Marquis de. See vol. iii., p. 32. + </p> + <p> + Exposition du système du monde, Paris, 1796, is available in Ouvres + completes, in 12 vols., Paris, 1825-1833^01. vi., p. 498. Lyell, Charles. + See vol. iii., p. 88. + </p> + <p> + Principles of Geology, 4 vols., London, 1834. + </p> + <p> + Marsh, O. C. See vol. Hi., p. 107. + </p> + <p> + Fossil Horses in America (reprinted from American Naturalist, vol. viii., + May, 1874), pp. 288, 289. + </p> + <p> + Playpair, John. See vol. iii., pp. 131, 165. + </p> + <p> + Illustrations of the Huttonian Theory, 1802. + </p> + <p> + <br />Scrope, G. Poulett. See vol. iii., p. 132. <br /> <br />Consideration + of Volcanoes, London, 1823, pp. 228-234. <br /> <br />Wells, W. C. See vol. + iii., p. 185. Essay on Dew, London, 1818. <br /> + </p> + <p> + IV.—MODERN PHYSICAL AND CHEMICAL SCIENCES + </p> + <p> + Black, Joseph. See vol. iv., p. 12. + </p> + <p> + De acido e cibis orlo, et de magnesia, reprinted at Edinburgh, 1854. In + this he sketched his discovery of carbonic acid. Later this paper was + incorporated in his Experiments on Magnesia, Quicklime, and Other Alkaltne + Substances. + </p> + <p> + Bunsen, William. See vol. iv., p. 69. + </p> + <p> + Cavendish, Henry. See vol. iv., p. 15. + </p> + <p> + "Experiments on Air," in Phil. Trans., 1784, p. 119. This paper contains + Cavendish's discovery of the composition of water and of nitric acid. + </p> + <p> + Daguerre, Louis J. M. See vol. iv., p. 70. + </p> + <p> + Historique et description des procédés du daguerréotype et du diorama, + Paris, 1839. (This was translated into English.) + </p> + <p> + Dalton, John. See vol. iv., p. 40. + </p> + <p> + "On the Absorption of Gases by Water," read before the Literary and + Philosophical Society of Manchester, October 21, 1803. This was published + in 1805, and contains the atomic weight of twenty-one substances, some of + which were probably added, or corrected, between the date of the first + reading and the publication. + </p> + <p> + Davy, Sir Humphry. See vol. iv., pp. 48, 209. + </p> + <p> + "Some Chemical Agencies of Electricity," in Phil. Trans, for 1806, vol. + viii. Researches, Chemical and Philosophical, chiefly concerning Nitrous + Oxide or De-phlogisticated Nitrous Air and its Respiration, London, 1800. + </p> + <p> + Dewar, James. See vol. v., p. 39. + </p> + <p> + "Solid Hydrogen," in Proc. Roy. Inst, for 1900. "The Nadir of Temperature + and Allied Problems " (Bakerian Lecture), Proc. Roy. Soc, 1901. + </p> + <p> + Dufay, Cisternay. See vol. ii., p. 267. + </p> + <p> + Histoire de l'Académie Royale des Sciences, between 1733 and 1737, + contains Dufay's principal papers. + </p> + <p> + Eulbr, Leonard (1707-1783). See vol. iii., p. 17. + </p> + <p> + Lettres a une Princesse d'Allemagne sur quelques sujets de physique et de + philosophie, St. Petersburg, 1768. + </p> + <p> + Faraday, Michael. See vol. iii., p. 241. + </p> + <p> + On the Induction of Electric Currents, in Phil. Trans. of Royal Society + for 1832, pp. 126-128. Explication of Arago's Magnetic Phenomena, by + Michael Faraday, F.R.S., Phil. Trans, of Royal Society for 1832, pp. + 146-149. Franklin, Benjamin. See vol. ii., p. 286. + </p> + <p> + New Experiments and Observations on Electricity, London, 1760. + </p> + <p> + Galvani, Luigi (1737-1798). See vol. iii., p. 229. + </p> + <p> + De viribus electricitatis in motu musculari commentatio, Bologna, 1791. + This discovery of Galvani was first brought to notice by Volta's famous + paper to the Royal Society, entitled "An Account of some Discoveries made + by Mr. Galvani, of Bologna," published in the Phil. Trans, for 1793, pp. + 10-44. + </p> + <p> + Gay-Lussac, Joseph Louis. See vol. iv., p. 41. + </p> + <p> + Mémoire sur la combinaison des substances gazeuses, Mem. Soc. d'Arcueil, + 1809. + </p> + <p> + Halley, Edmund. See vol. iii., p. 7. + </p> + <p> + An Account of Several Extraordinary Meteors or Lights in the Sky, in Phil. + Trans., vol. xxix., pp. 159-162, London, 1714. Helmholtz, H. L. F. See + vol. iii., p. 280. + </p> + <p> + Handbuch der physiologische Optik, Leipzig, 1867. + </p> + <p> + Joule, J. P. See vol. iii., p. 269. + </p> + <p> + On the Calorific Effects of Magneto-Electricity and the Mechanical Value + of Heat, in Report of the British Association for the Advancement of + Science, 1843, vol. xii" p. 33- + </p> + <p> + Kirwan, R. See vol. iv., p. 3 ff. + </p> + <p> + An Essay on Phlogiston and the Constitution of Acids, London, 1789. This + is interesting, written as it was just before Lavoisier's Elements treated + the same subject from the stand-point of the anti-phlogistic chemists. + </p> + <p> + Kleist, Dean von. See vol. ii., p. 280. + </p> + <p> + In the Danzick Memoirs, vol. i. contains the description given by Von + Kleist of his discovery of the Leyden jar. A translation is given also in + Priestley's History of Electricity. + </p> + <p> + Lavoisier, Antoine Laurent. See vol. iv., p. 33. + </p> + <p> + Traité élémentaire de chimie, Paris, 1774, trans, as Elements of + Chemistry, by Robert Kerr, London and Edinburgh, 1790. Lister, Joseph + Jackson. See vol. iv., p. 113. + </p> + <p> + On Some Properties in Achromatic Object Glasses Applicable to the + Improvement of the Microscope, in Phil. Trans, for 1830. + </p> + <p> + Maxwell, James Clerk-. See vol. iii., p. 45. + </p> + <p> + " On the Motions and Collisions of Perfectly Elastic Spheres " in + Philosophical Magazine for January and July, i860. The Scientific Papers + of J. Clerk-Maxwell, edited by W. D. Nevin (2 vols.), vol. i., pp. + 372-374, Cambridge, 1896. This is a reprint of Maxwell's prize paper of + 1859. Mayer, Dr. Julius Robert. See vol. iii., p. 259. + </p> + <p> + The Forces of Inorganic Nature, 1842. This is Mayer's statement of the + conservation of energy. Mendelèepp, Dmitri Ivanovitch. See vol. iv., p. + 68. + </p> + <p> + Principles of Chemistry, 2 vols., London, 1868-1870. (There have been + several subsequent editions.) + </p> + <p> + Oersted, Hans Christian. See vol. iii., p. 236. + </p> + <p> + Experiments with the Effects of the Electric Current on the Magnetic + Needle, published at Berlin, 1816. + </p> + <p> + Priestley, Joseph. See vol. iv., pp. 20, 36. + </p> + <p> + Experiments and Observations on Different Kinds of Air, 3 vols., + Birmingham, 1790. History of Electricity, 256 vol. ii., p. 280, London, + 1775. The Doctrine of Phlogiston Established, 1800. + </p> + <p> + Ramsay and Ravlbigh. See vol. v., p. 86. + </p> + <p> + "On an Anomaly Encountered in Determining the Density of Nitrogen Gas," in + Proc. Roy. Soc, April, 1894. A statement of the properties of argon was + made by the discoverers to the Royal Society, given in Phil. Trans., + clxxxvi., p. 187, January, 1895. + </p> + <p> + ScHBBLB, Karl William. See vol. iv., p. 23. + </p> + <p> + Om Brunsten, eller Magnesia, och dess Egenakaper, Stockholm,1774. This + contains his discovery of chlorine. His book, Chemische Abhandlung von der + Luft und dent Feuer, was published in 1777. + </p> + <p> + Thompson, Benjamin (Count Rumford). See vol. iii., p. 208. Essays + Political, Economical, and Philosophical (2 vols.), vol. ii., pp. 470-493, + London, T. Cadell, Jr., and W. Davies, 1797. Thomson, William (Lord + Kelvin). See vol. iii., p. 276. + </p> + <p> + On a Universal Tendency in Nature to the Dissipation of Mechanical Energy, + in Transactions of the Royal Society of Edinburgh, 1852. + </p> + <p> + Wollaston, William Hyde. See vol. iv., p. 41. + </p> + <p> + Phil. Trans, for 1814, vol. civ., p. i, contains a synoptic scale of + chemical equivalents. This paper was confirmatory of Dalton's theory. + </p> + <p> + Young, Thomas. See vol. iii., p. 218. + </p> + <p> + On the Colors of Thin Plates» I.e. in Phil. Trans, for 1802, pp. 35-37. + </p> + <p> + V.—MODERN BIOLOGICAL SCIENCES + </p> + <p> + Avenbruggbr, Lbopold. See vol. iv., p. 200. + </p> + <p> + Inventum novum ex percussione thoracis humant interni pectoris morbos + detegendi, Vienna, 1761. vot. V.-17 257 + </p> + <p> + Bell, Sir Charles See vol. iv., p. 249. + </p> + <p> + An Exposition of the Natural System of Nerves of the Human Body, being a + Republication of the Papers delivered to the Royal Society on the Subject + of the Nerves in 1811, etc. + </p> + <p> + Bernard, Claude. See vol. iv., p. 137. + </p> + <p> + BOERHAAVB, HERMANN. See Vol. IV., p. 182. + </p> + <p> + Institutions medicos, Leyden, 1708; and De chemie expurgante suos errores, + Lugduni Batavorum, 1718. Brown, Robert. See vol. iv., p. 115. + </p> + <p> + On the Organs and Mode of Fecundation of Orchideo and Asclepiadeo, in + Miscellaneous Botanical Works, London, 1866. + </p> + <p> + Chambers, Robert. See vol. iv., p. 161. + </p> + <p> + Vestiges of the Natural History of Creation, London, 1844 (published + anonymously). His Sequel to Vestiges was published a year later. Charcot, + Jean Martin. See vol. iv., p. 269. + </p> + <p> + Leçons sur Us maladies du système nerveux, Paris, beginning in 1873. + Cuvier, George, Baron de. See vol. iv., p. 159. + </p> + <p> + Histoire naturelle des animaux sans vertèbres, Paris, 1815. Système des + connaissances positives de Vhomme, Paris, 1820. + </p> + <p> + Darwin, Erasmus. See vol. iv., pp. 94, 147. + </p> + <p> + The Botanic Garden, London, 1799. The Temple of Nature, or The Origin of + Society, edition published in London, 1807. Darwin, Charles. See vol. + iii., p. 95, and vol. iv., p. 173. The Origin of Species, London, 1859. + </p> + <p> + Pechner, Gustav. See vol. iv., p. 263. Elemente du Psychophysik, i860. + Flourens, Marie Jean Pierre. See vol. iv., p. 270. + </p> + <p> + Experiences sur le système nerveux, Paris, 1825. Cours sur la génération, + Vovologie, et Vembryologie, Paris, 1836, etc. + </p> + <p> + Gall, Franz Joseph. See vol. iv., p. 248. + </p> + <p> + Recherches sur le système nerveux en général, et sur celui du cerveau en + particulier, Paris, 1809. (This paper was laid before the Institute of + France in March, 1808.) Goethe, Johann Wolfgang. See vol. iv., p. 140. + </p> + <p> + Die Metamorphose der Pflanzen, 1790. Gray, Stephen. See vol. ii.t p. 262. + </p> + <p> + Most of his original papers appeared in the PhU. Trans, between 1720 and + 1737. + </p> + <p> + Haeckel, Ernst Heinrich. See vol. v., p. 144. + </p> + <p> + Naturlich Schopfungsgeschichte, 1866, rewritten in a more popular style + two years later as Natural History of Creation. Some of his more important + monographs are: Radiolaria (1862), Siphonophora (1869), Monera (1870), + Calcarious Sponges (1872), Arabian Corals (1876), another Radiolaria, + enumerating several thousand new species, accompanied by one hundred and + forty plates (1887), and Die Weltrâthsel, trans, in 1900 as The Riddle of + the Universe. Hahnemann, Wilhelm von. See vol. iv., p. 189. + </p> + <p> + Organon der rationellen Heilkunde, Dresden, 1810. Hall, Marshall, M.D., + F.R.S.L. See vol. iv., p. 251. + </p> + <p> + On the Reflex Functions of the Medulla Oblongata and the Medulla Spinalis, + in Phil. Trans, of Royal Society, vol. xxxiii., 1833. Hunter, John. See + vol. iv., p. 92. + </p> + <p> + On the Digestion of the Stomach after Death, first edition, pp. 183-188. + </p> + <p> + Jenner, Edward. See vol. iv., p. 190. + </p> + <p> + An Inquiry into the Causes and Effects of the Variolo Vaccino, London, + 1799. + </p> + <p> + Laénnec, René Théophile Hyacinthe. See vol. iv., p. 201. + </p> + <p> + Traité d'auscultation médiate, Paris, 1819. Lamarck, Jean Baptiste de. See + vol. iv., p. 152. + </p> + <p> + Philosophie zoologique, 8 vols., Paris, 1801. His famous statement of the + supposed origin of species occurs on p. 235 of vol. i., as follows: + "Everything which nature has caused individuals to acquire or lose by the + influence of the circumstance to which their race is long exposed, and + consequently by the influence of the predominant employment of such organ, + or its constant disuse, she preserves by generation to the new individuals + proceeding from them, provided that the changes are common to the two + sexes, or to those which have produced these new individuals." + </p> + <p> + Libbig, Justin. See vol. iv., p. 131. + </p> + <p> + Animal Chemistry, London, 1843. + </p> + <p> + Libbig and Wôhler. See vol. iv., p. 56. + </p> + <p> + The important work of Liebig and Wôhler appeared until 183a mostly in + Poggendorff's Armalen, but after 1832 most of Liebig's work appeared in + his own Annalen. About the earliest as well as one of his most important + separate works is Anleitung zur Analyse organischen, Korper, 1837. + </p> + <p> + Lotze, Hermann. See vol. iv., p. 263. + </p> + <p> + Medizinische Psychologie, oder Physiologie der Seele, Leipzig, 1852. + </p> + <p> + Mohl, Hugo von. See vol. iv., p. 125. + </p> + <p> + Uber der Saftbewegung im Innern d. Zelle, Bot. Zei-tung, 1846. Morgagni, + Giovanni Battista. See vol. iv., p. 76. + </p> + <p> + De sedibus et causis ntorborum, 2 vols., Venice, 1761. + </p> + <p> + Oken, Lorenz. See vol. iv., p. 160. + </p> + <p> + Philosophie der Natur, Zurich, 1802. + </p> + <p> + Pasteur, Louis. See vol. iv., pp. 217, 233. + </p> + <p> + Studies on Fermentation, London, 1879. His famous paper on attenuation and + inoculation was published in the Compte Rendu of the Academy of Science, + Paris, 1881 (vol. xcii.). + </p> + <p> + Saint-Hilaire, Etienne Geoffroy. See vol. iv., p. 160. + </p> + <p> + Philosophie anatomique, vol. i., Paris, 1818. Schwann, Theodor. See vol. + iv., p. 119. + </p> + <p> + Mikroskopische Untersuchungen uber die Ubereinstim-mung in der Structur + und dem Wachsthum der Thiere und Pflanzen, Berlin, 1839. Trans, by + Sydenham Soc., 1847. Spencer, Herbert. See vol. iv., p. 268. + </p> + <p> + Principles of Psychology, London, 1855. 260 + </p> + <p> + Treviranus, Gottfried Reinhold. See vol. iv.t p. 159. Biologie, oder + Philosophie der lebenden Natur, 1802. + </p> + <p> + Weber, E. H. See vol. iv., p. 263. + </p> + <p> + The statement of "Weber's Law*' was first made in articles by Weber + contributed to Wagner's Handwârter-buch der Physiologie, but is again + stated and elaborated in Fechner's Psychophysik. (See Fechner.) Weismann, + August. See vol. iv., p. 179. + </p> + <p> + Studies in the Theories of Descent. Trans, by Professor R. Meldola, + London, 1882. The introduction to this work was written by Darwin. Wohler, + Friedrich. ' (See Liebig and Wôhler.) Wundt, Wilhelm Max. See vol. iv., p. + 268. + </p> + <p> + Grundzuge der physiologischen Psychologie, 1874. Many articles by Wundt + have appeared in the Philosophische Studien, published at Leipzig. + </p> + <p> + V.—ASTRONOMY + </p> + <p> + Astronomische G es disc haft. + </p> + <p> + A quarterly journal of astronomy published in Leipzig. + </p> + <p> + Berry, Arthur. + </p> + <p> + A Short History of Astronomy, New York, 1899. Bertrand, J. L. F. + </p> + <p> + Les fondateurs de Vastronomie modern: Copernic, Tycho Brake, Kepler, + Galileo, et Newton, Paris, 1865. This gives an interesting account of the + lives and works of these philosophers. + </p> + <p> + Flammarion, C. + </p> + <p> + Vie de Copernic, et histoire de la découverte du système du monde, Paris, + 1872. Forster, W. + </p> + <p> + Johann Kepler und die Harmonie der Sphcren, Berlin, 1862. + </p> + <p> + Jensen, P. + </p> + <p> + Die Kosmologie der Babylonier, Strasburg, 1890. 261 + </p> + <p> + Lockyer, Joseph Norman. + </p> + <p> + The Dawn of Astronomy; a Study of the Temple Worship and Mythology of the + Ancient Egyptians, London, 1894. Loom is. + </p> + <p> + History of Astronomy, New York, 1855. + </p> + <p> + Rothmann. + </p> + <p> + History of Astronomy (in the Library of Useful Knowledge), London, 1834. + </p> + <p> + Société Astronomique de France. Monthly bulletin, Paris. + </p> + <p> + Thompson, R. Campbell. + </p> + <p> + Reports of the Magicians and Astrologers of Nineveh and Babylon, p. 19, + London, 1900. + </p> + <p> + Wolf, R. + </p> + <p> + Geschichte der Astronomie, Munich, 1877. + </p> + <p> + VI.—PHYSICS (ELECTRICITY) + </p> + <p> + Annalen der Physik, Leipzig. Edited by Dr. Paul Drude. (Note—Heavy, + scientific, up-to-date. Is apparently under the patronage of all the big + physicists, such as Roentgen, etc.) + </p> + <p> + A tit della Associazione Elethotecnica Italiana (at Rome). A large + bi-monthly magazine, strictly technical, devoted largely to theoretical + problems of electricity and allied subjects. + </p> + <p> + Bulletin International de VElectricitê et Journal de VElectricitê + {réunis). A semi-monthly four-page paper dealing with the technical + application of electricity in its various fields. + </p> + <p> + Die Dissozuerung und Umwandlung chemischer Atome, by Dr. Johannes Stark, + 1903. Price 150 m. "A comprehensive view of the application of the + electron theory to certain phenomena."—Nature, May, 1904. + </p> + <p> + Die Kathodenstrahlen, by G. C. Schmidt, Brunswick, 1904. + </p> + <p> + "A concise and complete account of the properties of the cathode rays."—Nature, + June, 1904. + </p> + <p> + Electrical Engineer. + </p> + <p> + Electrical Magazine. + </p> + <p> + Electricity. A weekly journal, published by the Electricity Newspaper Co., + New York. Devoted largely to questions of the practical application of + electricity, but dealing also with the theoretical side. + </p> + <p> + Elements of Electro-magnetic Theory, by S. J. Barnett, Le-land Stanford, + Junior, University. Macmillan & Co., 1904. + </p> + <p> + ($3.) + </p> + <p> + Handbuch der Physik, by Dr. A. Winkelmann, Leipzig, 1904. "An + indispensable storehouse of expert knowledge."—Nature, July, 1904. + </p> + <p> + Hardin. + </p> + <p> + Rise and Development of the Liquefaction of Gases, New York, 1899. + </p> + <p> + La théorie de Maxwell et les oscillations hertziennes, la Télégraphie sans + flt by H. Poincaré, Paris, 1904 (price 2 fr.). Interesting studies of + light, etc. An interesting brochure.—Revue Scientifique, July, 1904. + </p> + <p> + Le radium et la radioactivité, by Paul Besson, Paris, 1904 (price 2 fr. + 75). A good exposition of the known properties of radium, marred, however, + by an attempt to put in accord science and religion—à propos du + radium! —Revue Scientifique, July, 1904. + </p> + <p> + Lehrbuch der Physik, by Von O. D. Chwolson, St. Petersburg, 1904. 2 vols. + out. First vol. covers general physics and mechanics. Second vol. sound + and radiant energy. "Excellent and quite comprehensive."—Science, + review. + </p> + <p> + Park, Benjamin. + </p> + <p> + The Intellectual Rise in Electricity, New York, 1895. This is a popular + account of the progress in the field of electricity from Gilbert to + Franklin. + </p> + <p> + Radium and all About It, by S. Bottone, London, 1904. Published by + Whittaker & Co. Price is. "An accurate account of the most important + phenomena."—Nature, June, 1904. + </p> + <p> + The Physical Review. A monthly journal of experimental and theoretical + physics. Published for Cornell University by the Macmillan Company. 263 + </p> + <p> + Theory of Heat, by Thomas Preston, F.R.S. Second edition just out. + Macmillan & Co., 185. + </p> + <p> + VII.-CHEMISTRY + </p> + <p> + American Chemical Journal. Edited by Ira Remsen, president of Johns + Hopkins University. Published monthly at Baltimore, Maryland. Price $5 per + annum. A strictly technical journal. + </p> + <p> + Bacon, Roger. + </p> + <p> + Mirror of Alchemy, and Admirable Power of Art and Nature, London, 1597. + </p> + <p> + Berthblot, P. E. M. + </p> + <p> + Introduction a l'étude de la chimie des anciens et du moyen age, Paris, + 1889. + </p> + <p> + Les origines de l'alchimie, Paris, 1885. + </p> + <p> + Bulletin de la Société Chimique de Paris. A monthly technical journal, + treating all phases of the science of chemistry. + </p> + <p> + Food Inspection and Analysis, by Albert E. Leach, S. B. (John Wiley & + Sons, N. Y., $7.50). Note. —This book is designed for the use of + public analysts, health officers, food economists, etc. + </p> + <p> + Hoefer, J. C. F. + </p> + <p> + Histoire de la chimie, Paris, 1866-1869. This gives biographical sketches + of many of the great chemists as well as the history of the development of + chemistry. + </p> + <p> + Jahresbericht uber die Fortschritte der Chemie. A journal of the progress + in chemistry, published irregularly in Brunswick. + </p> + <p> + Kopp, H. + </p> + <p> + Geschichte der Chemie (4 vols.), Brunswick, 1843-1847. This is an + exhaustive history of the development of chemistry. + </p> + <p> + Lehrbuch der Stereochemie, by A. Werner, Jena, 1904, price 10 m. "Should + be in the hands of every organic chemist."—Nature for August, 1904. + </p> + <p> + Lemoine, Y. F. + </p> + <p> + La vitalism et l'aminisme de Stahl, Paris, 1864. This discusses fully + Stahl's famous theories of matter and life. Meyer, E. von. + </p> + <p> + A History of Chemistry from the Earliest Times to the Present Day, London, + 1898. This treats fully the subject of the phlogiston theory and its + influence in the development of chemistry. Muir, M. P. + </p> + <p> + Story of Alchemy and the Beginnings of Chemistry, London and New York, + 1899. A popular account of the development of the phlogiston theory from + alchemy, giving explanations of the curious beliefs and methods of working + of the alchemists. Rodwell, G. F. + </p> + <p> + The Birth of Chemistry, London, 1874. Thompson, C. J. S. + </p> + <p> + The Mystery and Romance of Alchemy and Pharmacy, in the Scientific Press, + London, 1897. This is very interesting and readable. Thompson, T. + </p> + <p> + The History of Chemistry, London, 1830, 1831. Waite, Arthur Edward. + </p> + <p> + Lives of Alchemisttcal Philosophers, London, 1888. A biographical account + of the most noted alchemists. This is very complete. Waite has also + collected a list of the principal works of the alchemists, this list + filling about thirty pages of fine print. + </p> + <p> + VIII.—GEOLOGY. BIOLOGY, PALEONTOLOGY + </p> + <p> + American Geologist. + </p> + <p> + American Museum of Natural History Bulletins, New York. + </p> + <p> + A merican Naturalist. + </p> + <p> + Annales de l'Institut Pasteur (18 fr. per annum). A monthly bulletin of + the Pasteur Institute, containing mostly technical articles, but also + articles of interest to persons interested in problems of immunization and + immune sera. + </p> + <p> + Annales des sciences naturelles: zoologie et paléontologie, Paris. + </p> + <p> + Annals and Magazine of Natural History, including zoology, botany, and + geology. Monthly. London. A technical magazine. Of little interest to the + general reader. + </p> + <p> + Archiv fur Naturgeschichte. A journal of natural history published + bi-monthly at Berlin. + </p> + <p> + Archiv fur Rassen-und—Gesellschaft—Biologie einschliefslich + Rassen—und Gesell.-Hygiene. + </p> + <p> + Archives de biologie (quarterly), Liège. + </p> + <p> + Archives des sciences biologiques. St. Petersburg. Five numbers a year. + </p> + <p> + Archives Italiennes de biologie. Turin. Bi-monthly. + </p> + <p> + Biological Bulletin of the Marine Biological Laboratory, Wood's Holl, + Massachusetts. Published monthly by the laboratory. Managing editor, Prank + R. Lillie. Scientific and technical—very good. + </p> + <p> + Biologie générale des bactéries, by E. Bodin, professor of bacteriology, + University of Rennes, Paris, 1904. Price 2 It. 50. Studies of bacteria in + general treated in a semi-popular manner. Some new ideas prepared to + explain bacterial action in normal life—very good.—Revue + Scientifique, review, August, 1904. + </p> + <p> + Biometrika. A journal for the statistical study of biological problems + (quarterly), 305. per annum. Edited, in consultation with Francis Galton, + by W. F. R. Weldon, Karl Pearson, and C. B. Davenport. A bulky journal, + beautifully illustrated with plates and line cuts. Largely technical, but + containing many articles of interest to general readers on laws of + inheritance, hereditary influences, etc. + </p> + <p> + Bulletin of the Geological Society of America. Published irregularly at + Rochester. + </p> + <p> + Gcologische und Paloontologische Abhandlungen, Jena. + </p> + <p> + Johns Hopkins University, Memoirs from the Biological ^ Laboratory. + </p> + <p> + L'Échange Revue Linnienne, fondée par le Docteur Jacquet. Directeur, M. + Pic. A monthly journal of natural history, devoted largely to entomology—small + and technical. Of interest to entomologists only. + </p> + <p> + Les lois naturelles, par Félix le Danteg, charge du cours d'embryologie + générale à la Sorbonne, Paris, 1904. Price 6 fr. A study in biology. "The + name corresponds exactly with the contents of this admirable work."—Revue + Scientifique, review, September, 1904. + </p> + <p> + Marine Biological Association of the United Kingdom, Plymouth. + </p> + <p> + Société Dauphinoise d'Ethnologie et d'Anthropologie. Quarterly bulletin. + Grenoble. + </p> + <p> + Société Zoologique de France. Monthly bulletin. + </p> + <p> + Text-book of Geology, by Sir Archibald Geikie, a vols. Fourth edition. + $10. Macmillan & Co., 1904. + </p> + <p> + Text-book of Paleontology (Macmillan, 1904, $3), by Carl A. von Zittel, + University of Michigan. + </p> + <p> + The Geological Magazine, or Monthly Journal of Geology, edited by Henry + Woodward, LL.D., F.R.S., etc. London, 15. éd. per copy. A high-class + technical magazine. + </p> + <p> + The American Journal of Psychology, edited by G. Stanley Hall, E. C. + Sanford, and E. B. Titchnener. Published at Worcester, Massachusetts, + monthly. A technical journal devoted to psychological researches. + </p> + <p> + The Naturalist, London. A monthly journal for the north of England. Edited + by J. Sheppard, P.G.S., and T. W. Woodhead, F.L.S. Annual subscription, + 65. 6d. A local journal, but containing general articles of interest. + Semi-popular. + </p> + <p> + The Quarterly Journal of Microscopical Science, edited by E. Ray + Lankester, M.A., LL.D., F.R.S. + </p> + <p> + IX.—MEDICINE + </p> + <p> + American Journal of Insanity. + </p> + <p> + American Journal of the Medical Sciences, Philadelphia. + </p> + <p> + Annales medico-psychologiques, Paris. + </p> + <p> + Arbeiten aus dem leaiserlichen Gesundheitsamte. A journal of hygiene + published irregularly at Berlin. + </p> + <p> + Archiv fur Anatomie und Physiologic. A semi-monthly journal of the + progress in anatomy and physiology, published at Leipzig. + </p> + <p> + Archiv fur die gesammte Physiologie, Bonn. + </p> + <p> + British Medical Journal, London. + </p> + <p> + Immune Sera, by Professor A. Wassermann, M.D., trans, by Charles Bolduan, + M.D., New York and London, 1904. "We confidently commend this little book + to all persons desirous of acquainting themselves with the essential facts + on the subject of immune sera."—Nature, July, 1904. + </p> + <p> + Lancet, London. + </p> + <p> + Leclerc, Lucien. + </p> + <p> + Histoire de la médecine arabe, 2 vols., Paris, 1876. This work is very + complete and well written. + </p> + <p> + Medical Record, New York. + </p> + <p> + Medical Times, New York. + </p> + <p> + Pagel, Julius. + </p> + <p> + Einfuhrung in die Geschichte der Medicin, Berlin, 1898. This is not as + exhaustive as Baas's book, but is written in a much more readable style. + </p> + <p> + Park, Roswell. + </p> + <p> + Epitome of thf History of Medicine, Philadelphia, 1899. + </p> + <p> + Paul of AEgina. + </p> + <p> + The Works of, published by the Sydenham Society, London, 1841, are well + worth reading, as giving a clear understanding of the status of medicine + in the seventh century. + </p> + <p> + Sprengal, K. P. J. + </p> + <p> + Histoire de la médecine depuis son origine jusqu'au dix-neuvième siècle, 8 + vols., Paris, 1815-1820. This is a French translation of the German work, + and is more available than the original volumes. It is, perhaps, the most + exhaustive history of medicine ever attempted. + </p> + <p> + The Journal of Hygiene, edited by George H. F. Nuttall, M.D., Ph.D. A + quarterly journal of hygiene (2 is. per annum), containing many + interesting articles on subjects connected with hygiene and of interest to + general readers. + </p> + <p> + The Journal of Physiology, edited by Sir Michael Foster, K.C.B., M.D., + F.R.S., and J. N. Langley, Sc.D., F.R.S. Issued quarterly. Price Ss. C. J. + Clay & Sons, London. + </p> + <p> + X.—ANTHROPOLOGY AND ARCHAEOLOGY + </p> + <p> + American Anthropologist. F. W. Hodge, editor, Washington, D. C. Published + quarterly for the American Anthropological Association ($4.50 per annum). + Technical (or semi-technical). "A medium of communication between students + of all branches of anthropology." Much space devoted to Indian language, + etc.—;a very good journal. American Journal of Archoology. American + Journal of Sociology. + </p> + <p> + Archivo per V antropologia e V etnologia, Florence. Three numbers a year. + A journal devoted to anthropology and ethnology. Avebury, Lord (Sir John + Lubbock). + </p> + <p> + The Origin of Civilization and the Primitive Condition of Man. Mental and + social condition of modern savages. New York, 1870. Brinton, Daniel + Garrison, M.D. + </p> + <p> + The Basis of Social Relation, a Study in Ethnic Psycliol-ogy, edited by L. + Farrand, New York, 1902. Clodd, Edward. + </p> + <p> + Myths and Dreams, London. 1885. Story of Primitive Man, 3d edition, + London, 1897. The Childhood, of tlte World. A simple account of man in + early times. London, 1893. Dawkins, W. Boyd. + </p> + <p> + Early Man in Britain, London, 1880. Cave Hunting. Researches on the + evidence of caves respecting the early inhabitants of Europe. London, + 1874. Dellenbaugh, Frederick S. + </p> + <p> + The North Americans of Yesterday, New York, 1901. Deniker, Joseph. + </p> + <p> + Races of Man. An outline of anthropology and ethnology. London, 1900. + Grierson, P. J. H. Hamilton. + </p> + <p> + The Silent Trade. A contribution to the early history of human + intercourse. London, 1903. Haeckel, Dr. Ernst Heinrich. + </p> + <p> + Anthropogenic; oder Entwickelungsgeschichtc des Men-schen, 4th edition, 2 + vols., Leipzig, 1891. 269 + </p> + <p> + Müller, Friedrich. + </p> + <p> + Ethnographie; auf Grund des von K. von Scherzer gesammetten Materials. + Vienna, 1868. + </p> + <p> + Murtillbt, Gabriel de. + </p> + <p> + Le préhistorique antiquité de Vhomme. Paris, 1883. + </p> + <p> + Powell, John Wesley. + </p> + <p> + "Relation of Primitive Peoples to Environment." In Smithsonian Institution + Report. Washington, 1896. Reports of American Ethnology, in the annual + reports of the U. S. Bureau of Ethnology since 1877. + </p> + <p> + Quatrepages (A. de Q. de Brun). + </p> + <p> + Histoire générale des races humaines. Paris, 1889. + </p> + <p> + Ratzel, Friedrich. + </p> + <p> + The History of Mankind, 3 vols., trans, by A. J. Bubler, London, + 1896-1898. + </p> + <p> + Revue de l'Ecole d'Anthropologie de Paris. Monthly. Published by the + professors. Treats all phases and branches of anthropology. + </p> + <p> + Science de l'homme et méthode anthropologique, by Alphonse Cels, Paris and + Brussels, 1904. 7 francs. "As a highly abstract and suggestive exposition + of the nature and scope of anthropology, this book deserves a place in the + library of the anthropologist."—Nature, September 24, 1904. + </p> + <p> + Société Académique d'Archéologie, Paris. + </p> + <p> + <br /> <br /> + </p> + <hr /> + <hr /> + <p> + <br /> <br /> + </p> + <h1> + TABLE OF CONTENTS <br /><br /> FOR THE FIVE VOLUMES + </h1> + <p> + <br /> <br /> + </p> + <hr /> + <p> + <br /> <br /> <a + href="http://www.gutenberg.org/files/1705/1705-h/1705-h.htm#2H_4_0002"> <b>BOOK + I</b> </a> + </p> + <table summary="" style="margin-right: auto; margin-left: auto"> + <tr> + <td> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1705/1705-h/1705-h.htm#2H_4_0003"> + I. PREHISTORIC SCIENCE </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1705/1705-h/1705-h.htm#2H_4_0004"> + II. EGYPTIAN SCIENCE </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1705/1705-h/1705-h.htm#2H_4_0005"> + III. SCIENCE OF BABYLONIA AND ASSYRIA </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1705/1705-h/1705-h.htm#2H_4_0006"> + IV. THE DEVELOPMENT OF THE ALPHABET </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1705/1705-h/1705-h.htm#2H_4_0007"> + V. THE BEGINNINGS OF GREEK SCIENCE </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1705/1705-h/1705-h.htm#2H_4_0008"> + VI. THE EARLY GREEK PHILOSOPHERS IN ITALY </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1705/1705-h/1705-h.htm#2H_4_0009"> + VII. GREEK SCIENCE IN THE EARLY ATTIC PERIOD </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1705/1705-h/1705-h.htm#2H_4_0010"> + VIII. POST-SOCRATIC SCIENCE AT ATHENS—PLATO, ARISTOTLE, AND + THEOPHRASTUS </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1705/1705-h/1705-h.htm#2H_4_0011"> + IX. GREEK SCIENCE OF THE ALEXANDRIAN OR HELLENISTIC PERIOD </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1705/1705-h/1705-h.htm#2H_4_0012"> + X. SCIENCE OF THE ROMAN PERIOD </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1705/1705-h/1705-h.htm#2H_4_0013"> + XI. A RETROSPECTIVE GLANCE AT CLASSICAL SCIENCE </a> + </p> + </td> + </tr> + </table> + <p> + <br /> <br /> + </p> + <hr /> + <p> + <br /> <br /> <a + href="http://www.gutenberg.org/files/1706/1706-h/1706-h.htm#2H_4_0002"> <b>BOOK + II. THE BEGINNINGS OF MODERN SCIENCE</b> </a> + </p> + <table summary="" style="margin-right: auto; margin-left: auto"> + <tr> + <td> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1706/1706-h/1706-h.htm#2H_4_0003"> + I. SCIENCE IN THE DARK AGE </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1706/1706-h/1706-h.htm#2H_4_0004"> + II. MEDIAEVAL SCIENCE AMONG THE ARABIANS </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1706/1706-h/1706-h.htm#2H_4_0005"> + III. MEDIAEVAL SCIENCE IN THE WEST </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1706/1706-h/1706-h.htm#2H_4_0006"> + IV. THE NEW COSMOLOGY—COPERNICUS TO KEPLER AND GALILEO </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1706/1706-h/1706-h.htm#2H_4_0007"> + V. GALILEO AND THE NEW PHYSICS </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1706/1706-h/1706-h.htm#2H_4_0008"> + VI. TWO PSEUDO-SCIENCES—ALCHEMY AND ASTROLOGY </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1706/1706-h/1706-h.htm#2H_4_0009"> + VII. FROM PARACELSUS TO HARVEY </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1706/1706-h/1706-h.htm#2H_4_0010"> + VIII. MEDICINE IN THE SIXTEENTH AND SEVENTEENTH CENTURIES </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1706/1706-h/1706-h.htm#2H_4_0011"> + IX. PHILOSOPHER-SCIENTISTS AND NEW INSTITUTIONS OF LEARNING </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1706/1706-h/1706-h.htm#2H_4_0012"> + X. THE SUCCESSORS OF GALILEO IN PHYSICAL SCIENCE </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1706/1706-h/1706-h.htm#2H_4_0013"> + XI. NEWTON AND THE COMPOSITION OF LIGHT </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1706/1706-h/1706-h.htm#2H_4_0014"> + XII. NEWTON AND THE LAW OF GRAVITATION </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1706/1706-h/1706-h.htm#2H_4_0015"> + XIII. INSTRUMENTS OF PRECISION IN THE AGE OF NEWTON </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1706/1706-h/1706-h.htm#2H_4_0016"> + XIV. PROGRESS IN ELECTRICITY FROM GILBERT AND VON GUERICKE TO + FRANKLIN </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1706/1706-h/1706-h.htm#2H_4_0017"> + XV. NATURAL HISTORY TO THE TIME OF LINNAEUS </a> + </p> + </td> + </tr> + </table> + <p> + <br /> <br /> + </p> + <hr /> + <p> + <br /> <br /> <a + href="http://www.gutenberg.org/files/1707/1707-h/1707-h.htm#2H_4_0001"> <b>BOOK + III. MODERN DEVELOPMENT OF THE PHYSICAL SCIENCES</b> </a> + </p> + <table summary="" style="margin-right: auto; margin-left: auto"> + <tr> + <td> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1707/1707-h/1707-h.htm#2H_4_0002"> + I. THE SUCCESSORS OF NEWTON IN ASTRONOMY </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1707/1707-h/1707-h.htm#2H_4_0003"> + II. THE PROGRESS OF MODERN ASTRONOMY </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1707/1707-h/1707-h.htm#2H_4_0004"> + III. THE NEW SCIENCE OF PALEONTOLOGY </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1707/1707-h/1707-h.htm#2H_4_0005"> + IV. THE ORIGIN AND DEVELOPMENT OF MODERN GEOLOGY </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1707/1707-h/1707-h.htm#2H_4_0006"> + V. THE NEW SCIENCE OF METEOROLOGY </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1707/1707-h/1707-h.htm#2H_4_0007"> + VI. MODERN THEORIES OF HEAT AND LIGHT </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1707/1707-h/1707-h.htm#2H_4_0008"> + VII. THE MODERN DEVELOPMENT OF ELECTRICITY AND MAGNETISM </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1707/1707-h/1707-h.htm#2H_4_0009"> + VIII. THE CONSERVATION OF ENERGY </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1707/1707-h/1707-h.htm#2H_4_0010"> + IX. THE ETHER AND PONDERABLE MATTER </a> + </p> + </td> + </tr> + </table> + <p> + <br /> <br /> + </p> + <hr /> + <p> + <br /> <br /> <a + href="http://www.gutenberg.org/files/1708/1708-h/1708-h.htm#2H_4_0001"> <b>BOOK + IV. MODERN DEVELOPMENT OF THE CHEMICAL AND BIOLOGICAL SCIENCES</b> </a> + </p> + <table summary="" style="margin-right: auto; margin-left: auto"> + <tr> + <td> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1708/1708-h/1708-h.htm#2H_4_0002"> + I. THE PHLOGISTON THEORY IN CHEMISTRY </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1708/1708-h/1708-h.htm#2H_4_0003"> + II. THE BEGINNINGS OF MODERN CHEMISTRY </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1708/1708-h/1708-h.htm#2H_4_0004"> + III. CHEMISTRY SINCE THE TIME OF DALTON </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1708/1708-h/1708-h.htm#2H_4_0005"> + IV. ANATOMY AND PHYSIOLOGY IN THE EIGHTEENTH CENTURY </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1708/1708-h/1708-h.htm#2H_4_0006"> + V. ANATOMY AND PHYSIOLOGY IN THE NINETEENTH CENTURY </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1708/1708-h/1708-h.htm#2H_4_0007"> + VI. THEORIES OF ORGANIC EVOLUTION </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1708/1708-h/1708-h.htm#2H_4_0008"> + VII. EIGHTEENTH-CENTURY MEDICINE </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1708/1708-h/1708-h.htm#2H_4_0009"> + VIII. NINETEENTH-CENTURY MEDICINE </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1708/1708-h/1708-h.htm#2H_4_0010"> + IX. THE NEW SCIENCE OF EXPERIMENTAL PSYCHOLOGY </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/1708/1708-h/1708-h.htm#2H_4_0011"> + X. THE NEW SCIENCE OF ORIENTAL ARCHAEOLOGY </a> + </p> + </td> + </tr> + </table> + <p> + <br /> <br /> + </p> + <hr /> + <p> + <br /> <br /> <a + href="http://www.gutenberg.org/files/30495/30495-h/30495-h.htm#2H_4_0001"> + <b>BOOK V. ASPECTS OF RECENT SCIENCE</b> </a><br /> + </p> + <table summary="" style="margin-right: auto; margin-left: auto"> + <tr> + <td> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/30495/30495-h/30495-h.htm#2H_4_0003"> + I. THE BRITISH MUSEUM </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/30495/30495-h/30495-h.htm#2H_4_0004"> + II. THE ROYAL SOCIETY OF LONDON FOR IMPROVING NATURAL KNOWLEDGE </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/30495/30495-h/30495-h.htm#2H_4_0005"> + III. THE ROYAL INSTITUTION AND THE LOW-TEMPERATURE RESEARCHES </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/30495/30495-h/30495-h.htm#2H_4_0006"> + IV. SOME PHYSICAL LABORATORIES AND PHYSICAL PROBLEMS </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/30495/30495-h/30495-h.htm#2H_4_0007"> + V. THE MARINE BIOLOGICAL LABORATORY AT NAPLES </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/30495/30495-h/30495-h.htm#2H_4_0008"> + VI. ERNST HAECKEL AND THE NEW ZOOLOGY </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/30495/30495-h/30495-h.htm#2H_4_0009"> + VII. SOME MEDICAL LABORATORIES AND MEDICAL PROBLEMS </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/30495/30495-h/30495-h.htm#2H_4_0010"> + VII. SOME UNSOLVED SCIENTIFIC PROBLEMS </a> + </p> + <p class="toc"> + <a + href="http://www.gutenberg.org/files/30495/30495-h/30495-h.htm#2H_4_0011"> + IX. RETROSPECT AND PROSPECT </a> + </p> + </td> + </tr> + </table> + <p> + <br /> <br /> + </p> + <hr /> + <p> + <br /> <br /> + </p> +<div>*** END OF THE PROJECT GUTENBERG EBOOK 30495 ***</div> + </body> +</html> |