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+Project Gutenberg (https://www.gutenberg.org) public repository for
+eBook #50565 (https://www.gutenberg.org/ebooks/50565)
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-The Project Gutenberg EBook of The History of Chemistry, Volume 1 (of 2), by 
-Thomas Thomson
-
-This eBook is for the use of anyone anywhere in the United States and most
-other parts of the world at no cost and with almost no restrictions
-whatsoever.  You may copy it, give it away or re-use it under the terms of
-the Project Gutenberg License included with this eBook or online at
-www.gutenberg.org.  If you are not located in the United States, you'll have
-to check the laws of the country where you are located before using this ebook.
-
-Title: The History of Chemistry, Volume 1 (of 2)
-
-Author: Thomas Thomson
-
-Release Date: November 27, 2015 [EBook #50565]
-
-Language: English
-
-Character set encoding: UTF-8
-
-*** START OF THIS PROJECT GUTENBERG EBOOK HISTORY OF CHEMISTRY, VOL 1 ***
-
-
-
-
-Produced by MWS, Wayne Hammond and the Online Distributed
-Proofreading Team at http://www.pgdp.net (This file was
-produced from images generously made available by The
-Internet Archive)
-
-
-
-
-
-
-
-[Illustration:
-
-  _Raeburn. pinx^t._      _Dean, sculp^t._
-
-JOSEPH BLACK, M.D. F.R.S.E.
-
-_London. Published by Henry Colburn & Richard Bentley. 1830._]
-
-
-
-
-  THE
-
-  HISTORY
-
-  OF
-
-  CHEMISTRY.
-
-  BY
-  THOMAS THOMSON, M.D. F.R.S.E.
-  PROFESSOR OF CHEMISTRY IN THE UNIVERSITY OF GLASGOW.
-
-
-  IN TWO VOLUMES.
-
-  VOL. I.
-
-
-  LONDON:
-  HENRY COLBURN, AND RICHARD BENTLEY,
-  NEW BURLINGTON STREET.
-
-  1830.
-
-
-
-
-  C. WHITING, BEAUFORT HOUSE, STRAND.
-
-
-
-
-PREFACE.
-
-
-It may be proper, perhaps, to state here, in a very few words, the
-objects which the author had in view in drawing up the following
-History of Chemistry. Alchymy, or the art of making gold, with which
-the science originated, furnishes too curious a portion of the
-aberrations of the human intellect to be passed over in silence.
-The writings of the alchymists are so voluminous and so mystical,
-that it would have afforded materials for a very long work. But
-I was prevented from extending this part of the subject to any
-greater length than I have done, by considering the small quantity of
-information which could have been gleaned from the reveries of these
-fanatics or impostors; I thought it sufficient to give a general view
-of the nature of their pursuits: but in order to put it in the power of
-those who feel inclined to prosecute such investigations, I have given
-a catalogue of the most eminent of the alchymists and a list of their
-works, so far as I am acquainted with them. This catalogue might have
-been greatly extended. Indeed it would have been possible to have added
-several hundred names. But I think the works which I have quoted are
-more than almost any reasonable man would think it worth his while to
-peruse; and I can state, from experience, that the information gained
-by such a perusal will very seldom repay the trouble.
-
-       *       *       *       *       *
-
-The account of the chemical arts, with which the ancients were
-acquainted, is necessarily imperfect; because all arts and trades were
-held in so much contempt by them that they did not think it worth their
-while to make themselves acquainted with the processes. My chief
-guide has been Pliny, but many of his descriptions are unintelligible,
-obviously from his ignorance of the arts which he attempts to describe.
-Thus circumstanced, I thought it better to be short than to waste a
-great deal of paper, as some have done, on hypothesis and conjecture.
-
-       *       *       *       *       *
-
-The account of the Chemistry of the Arabians is almost entirely limited
-to the works of Geber, which I consider to be the first book on
-Chemistry that ever was published, and to constitute, in every point
-of view, an exceedingly curious performance. I was much struck with
-the vast number of facts with which he was acquainted, and which have
-generally been supposed to have been discovered long after his time.
-I have, therefore, been at some pains in endeavouring to convey a
-notion of Geber’s opinions to the readers of this history; but am not
-sure that I have succeeded. I have generally given his own words, as
-literally as possible, and, wherever it would answer the purpose, have
-employed the English translation of 1678.
-
-Paracelsus gave origin to so great a revolution in medicine and the
-sciences connected with it, that it would have been unpardonable not
-to have attempted to lay his opinions and views before the reader;
-but, after perusing several of his most important treatises, I found
-it almost impossible to form accurate notions on the subject. I
-have, therefore, endeavoured to make use of his own words as much
-as possible, that the want of consistency and the mysticism of his
-opinions may fall upon his own head. Should the reader find any
-difficulty in understanding the philosophy of Paracelsus, he will be
-in no worse a situation than every one has been who has attempted to
-delineate the principles of this prince of quacks and impostors. Van
-Helmont’s merits were of a much higher kind, and I have endeavoured to
-do him justice; though his weaknesses are so visible that it requires
-much candour and patience to discriminate accurately between his
-excellencies and his foibles.
-
-       *       *       *       *       *
-
-The history of Iatro-chemistry forms a branch of our subject scarcely
-less extraordinary than Alchymy itself. It might have been extended
-to a much greater length than I have done. The reason why I did not
-enter into longer details was, that I thought the subject more
-intimately connected with the history of medicine than of chemistry:
-it undoubtedly contributed to the improvement of chemistry; not,
-however, by the opinions or the physiology of the iatro-chemists, but
-by inducing their contemporaries and successors to apply themselves to
-the discovery of chemical medicines.
-
-       *       *       *       *       *
-
-The History of Chemistry, after a theory of combustion had been
-introduced by Beccher and Stahl, becomes much more important. It now
-shook off the trammels of alchymy, and ventured to claim its station
-among the physical sciences. I have found it necessary to treat of its
-progress during the eighteenth century rather succinctly, but I hope
-so as to be easily intelligible. This made it necessary to omit the
-names of many meritorious individuals, who supplied a share of the
-contributions which the science was continually receiving from all
-quarters. I have confined myself to those who made the most prominent
-figure as chemical discoverers. I had no other choice but to follow
-this plan, unless I had doubled the size of this little work, which
-would have rendered it less agreeable and less valuable to the general
-reader.
-
-       *       *       *       *       *
-
-With respect to the History of Chemistry during that portion of the
-nineteenth century which is already past, it was beset with several
-difficulties. Many of the individuals, of whose labours I had occasion
-to speak, are still actively engaged in the prosecution of their
-useful works. Others have but just left the arena, and their friends
-and relations still remain to appreciate their merits. In treating of
-this branch of the science (by far the most important of all) I have
-followed the same plan as in the history of the preceding century. I
-have found it necessary to omit many names that would undoubtedly have
-found a place in a larger work, but which the limited extent to which I
-was obliged to confine myself, necessarily compelled me to pass over. I
-have been anxious not to injure the character of any one, while I have
-rigidly adhered to truth, so far as I was acquainted with it. Should I
-have been so unfortunate as to hurt the feelings of any individual by
-any remarks of mine in the following pages, it will give me great pain;
-and the only alleviation will be the consciousness of the total absence
-on my part of any malignant intention. To gratify the wishes of every
-individual may, perhaps, be impossible; but I can say, with truth,
-that my uniform object has been to do justice to the merits of all, so
-far as my own limited knowledge put it in my power to do.
-
-
-
-
-CONTENTS
-
-OF
-
-THE FIRST VOLUME.
-
-
-                                                                   Page
-
-  Introduction                                                        1
-
-
-  CHAPTER I.
-
-  Of Alchymy                                                          3
-
-
-  CHAPTER II.
-
-  Of the chemical knowledge possessed by the Ancients                49
-
-
-  CHAPTER III.
-
-  Chemistry of the Arabians                                         110
-
-
-  CHAPTER IV.
-
-  Of the progress of Chemistry under Paracelsus and his disciples   140
-
-
-  CHAPTER V.
-
-  Of Van Helmont and the Iatro-Chemists                             179
-
-
-  CHAPTER VI.
-
-  Of Agricola and metallurgy                                        219
-
-
-  CHAPTER VII.
-
-  Of Glauber, Lemery, and some other chemists of the end of the
-  seventeenth century                                               226
-
-
-  CHAPTER VIII.
-
-  Of the attempts to establish a theory in chemistry                246
-
-
-  CHAPTER IX.
-
-  Of the foundation and progress of scientific chemistry in Great
-  Britain                                                           303
-
-
-
-
-
-HISTORY OF CHEMISTRY.
-
-
-
-
-INTRODUCTION.
-
-
-Chemistry, unlike the other sciences, sprang originally from delusion
-and superstition, and was at its commencement exactly on a level
-with magic and astrology. Even after it began to be useful to man,
-by furnishing him with better and more powerful medicines than the
-ancient physicians were acquainted with, it was long before it could
-shake off the trammels of alchymy, which hung upon it like a nightmare,
-cramping and blunting all its energies, and exposing it to the scorn
-and contempt of the enlightened part of mankind. It was not till about
-the middle of the eighteenth century that it was able to free itself
-from these delusions, and to venture abroad in all the native dignity
-of a useful science. It was then that its utility and its importance
-began to attract the attention of the world; that it drew within its
-vortex some of the greatest and most active men in every country; and
-that it advanced towards perfection with an accelerated pace. The field
-which it now presents to our view is vast and imposing. Its paramount
-utility is universally acknowledged. It has become a necessary part of
-education. It has contributed as much to the progress of society, and
-has done as much to augment the comforts and conveniences of life, and
-to increase the power and the resources of mankind, as all the other
-sciences put together.
-
-It is natural to feel a desire to be acquainted with the origin and the
-progress of such a science; and to know something of the history and
-character of those numerous votaries to whom it is indebted for its
-progress and improvement. The object of this little work is to gratify
-these laudable wishes, by taking a rapid view of the progress of
-Chemistry, from its first rude and disgraceful beginnings till it has
-reached its present state of importance and dignity. I shall divide the
-subject into fifteen chapters. In the first I shall treat of Alchymy,
-which may be considered as the inauspicious commencement of the
-science, and which, in fact, consists of little else than an account of
-dupes and impostors; every where so full of fiction and obscurity, that
-it is a hopeless and almost impossible task to reach the truth. In the
-second chapter I shall endeavour to point out the few small chemical
-rills, which were known to the ancients. These I shall follow in their
-progress, in the succeeding chapters, till at last, augmented by an
-infinite number of streams flowing at once from a thousand different
-quarters, they have swelled to the mighty river, which now flows on
-majestically, wafting wealth and information to the civilized world.
-
-
-
-
-CHAPTER I.
-
-OF ALCHYMY.
-
-
-The word _chemistry_ (χημεια, _chemeia_) first occurs in Suidas,
-a Greek writer, who is supposed to have lived in the eleventh
-century, and to have written his lexicon during the reign of Alexius
-Comnenus.[1] Under the word χημεια in his dictionary we find the
-following passage:
-
-“CHEMISTRY, the preparation of silver and gold. The books
-on it were sought out by Dioclesian and burnt, on account of the new
-attempts made by the Egyptians against him. He treated them with
-cruelty and harshness, as he sought out the books written by the
-ancients on the chemistry (Περι χημειας) of gold and silver, and burnt
-them. His object was to prevent the Egyptians from becoming rich by the
-knowledge of this art, lest, emboldened by abundance of wealth, they
-might be induced afterwards to resist the Romans.”[2]
-
-[1] The word χημεια is said to occur in several Greek manuscripts of
-a much earlier date. But of this, as I have never had an opportunity
-of seeing them, I cannot pretend to judge. So much fiction has been
-introduced into the history of Alchymy, and so many ancient names have
-been treacherously dragged into the service, that we may be allowed
-to hesitate when no evidence is presented sufficient to satisfy a
-reasonable man.
-
-[2] Χημεια, ἡ του αργυρου και χρυσου κατασκευη· ἡς τα βιβλια
-διερευνησαμενος ὁ Διοκλητιανος εκαυσε, δια τα νεωτερισθεντα αιγυπτιοις
-Διοκλητιανω· τουτοις ανημερως και φονικως εχρησατο ὁτεδη και τα
-περι χημειας χρυσου και αργυρου τοις παλαιοις γεγραμμενα βιβλια
-διερευνησαμενος εκαυσε, προς το μηκετι πλουτον αιγυπτιοις εκ της
-τοιαυτης προσγινεσθαι τεχνης, μηδε χρηματων αυτοις θαρῥονιτας περιουσια
-του λοιπου ῥωμαιοις ανταιρειν.
-
-Under the word Δερας, _deras_ (_a skin_), in the lexicon, occurs the
-following passage: “Δερας, the golden fleece, which Jason and the
-Argonauts (after a voyage through the Black Sea to Colchis) took,
-together with Medea, daughter of Ætes, the king. But this was not
-what the poets represent, but a treatise written on skins (δερμασι),
-teaching how gold might be prepared by chemistry. Probably, therefore,
-it was called by those who lived at that time, _golden_, on account of
-its great importance.”[3]
-
-[3] Δερας, το χρυσομαλλον δερας, ὁπερ ὁ Ιασων δια της ποντικης
-θαλασσης συν τοις αργοναυταις εις την κολχιδα παραγενομενοι ελαβον,
-και την Μηδειαν την Αιητου του βασιλεως θυγατερα. Τουτο δε ουκ ὡς
-ποιητικως φερεται· αλλα βιβλιον ην εν δερμασι γεγραμενον περισχον ὁπως
-δειγινεσθαι δια χημειας χρυσον· εικοτως ουν ὁι τοτε χρουσουν ωνομαζον
-αυτο δερας δια την ενεργειαν την εξ αυτου.
-
-From these two passages there can be no doubt that the word _chemistry_
-was known to the Greeks in the eleventh century; and that it signified,
-at that time, the art of making gold and silver. It appears, further,
-that in Suidas’s opinion, this art was known to the Egyptians in the
-time of Dioclesian; that Dioclesian was convinced of its reality;
-and that, to put an end to it, he collected and burnt all the
-chemical writings to be found in Egypt. Nay, Suidas affirms that a
-book, describing the art of making gold, existed at the time of the
-Argonauts: and that the object of Jason and his followers was to get
-possession of that invaluable treatise, which the poets disguised under
-the term _golden fleece_.
-
-The first meaning, then, of chemistry, was the _art of making gold_.
-And this art, in the opinion of Suidas, was understood at least as
-early as one thousand two hundred and twenty-five years before
-the Christian era: for that is the period at which the Argonautic
-expedition is commonly fixed by chronologists.
-
-Though the lexicon of Suidas be the first printed book in which the
-word Chemistry occurs, yet it is said to be found in much earlier
-tracts, which still continue in manuscript. Thus Scaliger informs us
-that he perused a Greek manuscript of Zosimus, the Panapolite, written
-in the fifth century, and deposited in the King of France’s library.
-Olaus Borrichius mentions this manuscript; but in such terms that it
-is difficult to know whether he had himself read it; though he seems
-to insinuate as much.[4] The title of this manuscript is said to be
-“A faithful Description of the sacred and divine Art of making Gold
-and Silver, by Zosimus, the Panapolite.”[5] In this treatise, Zosimus
-distinguishes the art by the name χημια, _chemia_. From a passage
-in this manuscript, quoted by Scaliger, and given also by Olaus
-Borrichius, it appears that Zosimus carries the antiquity of the art of
-making gold and silver, much higher than Suidas has ventured to do. The
-following is a literal translation of this curious passage:
-
-[4] De Ortu et Progressu Chemiæ, p. 12.
-
-[5] Σωσιμου του παναπολιτου γνησια γραφη, περι της ἱερας, και θειας
-τεχνης του χρυσου και αργυριου ποιησιος. Παναπολις was a city in Egypt.
-
-“The sacred Scriptures inform us that there exists a tribe of genii,
-who make use of women. Hermes mentions this circumstance in his
-Physics; and almost every writing (λογος), whether sacred (φανερος) or
-apocryphal, states the same thing. The ancient and divine Scriptures
-inform us, that the angels, captivated by women, taught them all the
-operations of nature. Offence being taken at this, they remained out of
-heaven, because they had taught mankind all manner of evil, and things
-which could not be advantageous to their souls. The Scriptures inform
-us that the giants sprang from these embraces. Chema is the first of
-their traditions respecting these arts. The book itself they called
-Chema; hence the art is called _Chemia_.”
-
-Zosimus is not the only Greek writer on Chemistry. Olaus Borrichius has
-given us a list of thirty-eight treatises, which he says exist in the
-libraries of Rome, Venice, and Paris: and Dr. Shaw has increased this
-list to eighty-nine.[6] But among these we find the names of Hermes,
-Isis, Horus, Democritus, Cleopatra, Porphyry, Plato, &c.--names which
-undoubtedly have been affixed to the writings of comparatively modern
-and obscure authors. The style of these authors, as Borrichius informs
-us, is barbarous. They are chiefly the production of ecclesiastics,
-who lived between the fifth and twelfth centuries. In these tracts,
-the art of which they treat is sometimes called _chemistry_ (χημεια);
-sometimes the _chemical art_ (χημευτικα); sometimes the _holy art_; and
-the _philosopher’s stone_.
-
-[6] Shaw’s Translation of Boerhaave’s Chemistry, i. 20.
-
-It is evident from this, that between the fifth century and the taking
-of Constantinople in the fifteenth century, the Greeks believed in the
-possibility of making gold and silver artificially; and that the art
-which professed to teach these processes was called by them Chemistry.
-
-These opinions passed from the Greeks to the Arabians, when, under the
-califs of the family of Abassides, they began to turn their attention
-to science, about the beginning of the ninth century; and when the
-enlightened zeal of the Fatimites in Africa, and the Ommiades in Spain,
-encouraged the cultivation of the sciences. From Spain they gradually
-made their way into the different Christian kingdoms of Europe. From
-the eleventh to the sixteenth century, the art of making gold and
-silver was cultivated in Germany, Italy, France, and England, with
-considerable assiduity. The cultivators of it were called _Alchymists_;
-a name obviously derived from the Greek word _chemia_, but somewhat
-altered by the Arabians. Many alchymistical tracts were written during
-that period. A considerable number of them were collected by Lazarus
-Zetzner, and published at Strasburg in 1602, under the title of
-“Theatrum Chemicum, præcipuos selectorum auctorum tractatus de Chemiæ
-et Lapidis Philosophici Antiquitate, veritate, jure, præstantia, et
-operationibus continens in gratiam veræ Chemiæ et Medicinæ Chemicæ
-Studiosorum (ut qui uberrimam unde optimorum remediorum messem facere
-poterunt) congestum et in quatuor partes seu volumina digestum.” This
-book contains one hundred and five different alchymistical tracts.
-
-In the year 1610 another collection of alchymistical tracts was
-published at Basil, in three volumes, under the title of “Artis
-Auriferæ quam Chemiam vocant volumina tria.” It contains forty-seven
-different tracts.
-
-In the year 1702 Mangetus published at Geneva two very large folio
-volumes, under the name of “Bibliotheca Chemica Curiosa, seu rerum
-ad Alchymiam pertinentium thesaurus instructissimus, quo non tantum
-Artis Auriferæ ac scriptorum in ea nobiliorum Historia traditur;
-lapidis veritas Argumentis et Experimentis innumeris, immo et Juris
-Consultorum Judiciis evincitur; Termini obscuriores explicantur;
-Cautiones contra Impostores et Difficultates in Tinctura Universali
-conficienda occurrentes declarantur: verum etiam Tractatus omnes
-Virorum Celebriorum, qui in Magno sudarunt Elixyre, quique ab ipso
-Hermete, ut dicitur, Trismegisto, ad nostra usque tempora de Chrysopoea
-scripserunt, cum præcipuis suis Commentariis, concinno ordine dispositi
-exhibentur.” This Bibliotheca contains one hundred and twenty-two
-alchymistical treatises, many of them of considerable length.
-
-Two additional volumes of the Theatrum Chemicum were afterwards
-published; but these I have never had an opportunity of seeing.
-
-From these collections, which exhibit a pretty complete view of the
-writings of the alchymists, a tolerably accurate notion may be formed
-of their opinions. But before attempting to lay open the theories and
-notions by which the alchymists were guided, it will be proper to state
-the opinions which were gradually adopted respecting the origin of
-Alchymy, and the contrivances by which these opinions were supported.
-
-Zosimus, the Panapolite, in a passage quoted above informs us, that
-the art of making gold and silver was not a human invention; but was
-communicated to mankind by angels or demons. These angels, he says,
-fell in love with women, and were induced by their charms to abandon
-heaven altogether, and take up their abode upon earth. Among other
-pieces of information which these spiritual beings communicated to
-their paramours, was the sublime art of Chemistry, or the fabrication
-of gold and silver.
-
-It is quite unnecessary to refute this extravagant opinion, obviously
-founded on a misunderstanding of a passage in the sixth chapter of
-Genesis. “And it came to pass, when men began to multiply on the face
-of the earth, and daughters were born unto them, that the sons of God
-saw the daughters of men, that they were fair; and they took them wives
-of all which they chose.--There were giants in the earth in those days;
-and also after that, when the sons of God came in unto the daughters
-of men, and they bare _children_ to them; the same became mighty men,
-which were of old, men of renown.”
-
-There is no mention whatever of angels, or of any information on
-science communicated by them to mankind.
-
-Nor is it necessary to say much about the opinion advanced by some,
-and rather countenanced by Olaus Borrichius, that the art of making
-gold was the invention of Tubal-cain, whom they represent as the same
-as Vulcan. All the information which we have respecting Tubal-cain,
-is simply that he was an instructor of every artificer in brass and
-iron.[7] No allusion whatever is made to gold. And that in these early
-ages of the world there was no occasion for making gold artificially,
-we have the same authority for believing. For in the second chapter
-of Genesis, where the garden of Eden is described, it is said, “And
-a river went out of Eden to water the garden; and from thence it was
-parted, and came into four heads: the name of the first is Pison,
-that is it which encompasseth the whole land of Havilah, where there
-is gold. And the gold of that land is good: there is bdellium and
-onyx-stone.”
-
-[7] Genesis iv. 22.
-
-But the most generally-received opinion is, that alchymy originated in
-Egypt; and the honour of the invention has been unanimously conferred
-upon Hermes Trismegistus. He is by some supposed to be the same person
-with Chanaan, the son of Ham, whose son Mizraim first occupied and
-peopled Egypt. Plutarch informs us, that Egypt was sometimes called
-_Chemia_.[8] This name is supposed to be derived from Chanaan (ןענכ);
-thence it was believed that Chanaan was the true inventor of alchymy,
-to which he affixed his own name. Whether the Hermes (Ἑρμης) of
-the Greeks was the same person with Chanaan or his son Mizraim, it
-is impossible at this distance of time to decide; but to Hermes is
-assigned the invention of alchymy, or the art of making gold, by almost
-the unanimous consent of the adepts.
-
-[8] De Iside and Osiride, c. 5.
-
-Albertus Magnus informs us, that “Alexander the Great discovered the
-sepulchre of Hermes, in one of his journeys, full of all treasures,
-not metallic, but golden, written on a table of _zatadi_, which others
-call emerald.” This passage occurs in a tract of Albertus _de secretis
-chemicis_, which is considered as supposititious. Nothing is said of
-the source whence the information contained in this passage was drawn:
-but, from the quotations produced by Kriegsmann, it would appear that
-the existence of this emerald table was alluded to by Avicenna and
-other Arabian writers. According to them, a woman called Sarah took it
-from the hands of the dead body of Hermes, some ages after the flood,
-in a cave near Hebron. The inscription on it was in the Phœnician
-language. The following is a literal translation of this famous
-inscription, from the Latin version of Kriegsmann:[9]
-
-[9] There are two Latin translations of these tables (unless we are
-rather to consider them as originals, for no Phœnician nor Greek
-original exists). I shall insert them both here.
-
-
-I.--VERBA SECRETORUM HERMETIS TRISMEGISTI.
-
-  1. Verum sine mendacio certum et verissimum.
-
-  2. Quod est inferius, est sicut quod est superius, et quod est
-  superius est sicut quod est inferius ad perpetranda miracula rei
-  unius.
-
-  3. Et sicut omnes res fuerant ab uno meditatione unius: sic
-  omnes res natæ fuerunt ab hac una re adaptatione.
-
-  4. Pater ejus est Sol, mater ejus Luna, portavit illud ventus
-  in ventre suo, nutrix ejus terra est.
-
-  5. Pater omnis thelesmi totius mundi est hic.
-
-  6. Vis ejus integra est, si versa fuerit in terram.
-
-  7. Separabis terram ab igne, subtile a spisso suaviter cum
-  magno ingenio.
-
-  8. Ascendit a terra in cœlum, iterumque descendit in terram,
-  et recipit vim superiorum et inferiorum, sic habebis gloriam
-  totius mundi. Ideo fugiat a te omnis obscuritas.
-
-  9. Hic est totius fortitudinis fortitudo fortis; quia vincit
-  omnem rem subtilem, omnemque solidam penetrabit.
-
-  10. Sic mundus creatus est.
-
-  11. Hinc adaptationes erunt mirabiles, quarum modus est
-  hic.
-
-  12. Itaque vocatus sum Hermes Trismegistus, habens tres
-  partes philosophiæ totius mundi.
-
-  13. Completum est quod dixi de operatione solis.
-
-
-II.--DESCRIPTIO ARCANORUM HERMETIS TRISMEGISTI.
-
-  1. Vere non ficte, certo verissime aio.
-
-  2. Inferiora hæc cum superioribus illis, istaque cum iis vicissim
-  vires sociant, ut producant rem unam omnium mirificissimam.
-
-  3. Ac quemadmodum cuncta educta ex uno fuere verbo Dei
-  unius: sic omnes quoque res perpetuo ex hac una re generantur
-  dispositione Naturæ.
-
-  4. Patrem ea habet Solem, matrem Lunam: ab aëre in utero
-  quasi gestatur, nutritur a terra.
-
-  5. Causa omnis perfectionis rerum ea est per univerum hoc.
-
-  6. Ad summam ipsa perfectionem virium pervenit si redierit
-  in humum.
-
-  7. In partes tribuite humum ignem passam, attenuans densitatem
-  ejus re omnium suavissima.
-
-  8. Summa ascende ingenii sagacitate a terra in cœlum, indeque
-  rursum in terram descende, ac vires superiorum inferiorumque
-  coge in unum: sic potiere gloria totius mundi atque ita abjectæ
-  sortis homo amplius non habere.
-
-  9. Isthæc jam res ipsa fortitudine fortior existet; corpora
-  quippe tam tenuia quam solida penetrando subige.
-
-  10. Atque sic quidem quæcunque mundus continet creata fuere.
-
-  11. Hinc admiranda evadunt opera, quæ ad eundum modum
-  instituantur.
-
-  12. Mihi vero ideo nomen Hermetis Trismegisti impositum
-  fuit, quod trium mundi sapientiæ partium doctor deprehensus
-  sum.
-
-  13. Hæc sunt quæ de chemicæ artis prestantissimo opere
-  consignanda esse duxi.
-
-
-  1. I speak not fictitious things, but what is true and
-  most certain.
-
-  2. What is below is like that which is above, and
-  what is above is similar to that which is below, to accomplish
-  the miracles of one thing.
-
-  3. And as all things were produced by the meditation
-  of one Being, so all things were produced from
-  this one thing by adaptation.
-
-  4. Its father is _Sol_, its mother _Luna_; the wind
-  carried it in its belly, the earth is its nurse.
-
-  5. It is the cause of all perfection throughout the
-  whole world.
-
-  6. Its power is perfect, if it be changed into earth.
-
-  7. Separate the earth from the fire, the subtile
-  from the gross, acting prudently and with judgment.
-
-  8. Ascend with the greatest sagacity from the earth
-  to heaven, and then again descend to the earth, and
-  unite together the powers of things superior and things
-  inferior. Thus you will possess the glory of the whole
-  world; and all obscurity will fly far away from you.
-
-  9. This thing has more fortitude than fortitude itself;
-  because it will overcome every subtile thing, and
-  penetrate every solid thing.
-
-  10. By it this world was formed.
-
-  11. Hence proceed wonderful things, which in this
-  wise were established.
-
-  12. For this reason I am called Hermes Trismegistus,
-  because I possess three parts of the philosophy of
-  the whole world.
-
-  13. What I had to say about the operation of _Sol_
-  is completed.
-
-Such is a literal translation of the celebrated inscription of Hermes
-Trismegistus upon the emerald tablet. It is sufficiently obscure to
-put it in the power of commentators to affix almost any explanation to
-it that they choose. The two individuals who have devoted most time
-to illustrate this tablet, are Kriegsmann and Gerard Dorneus, whose
-commentaries may be seen in the first volume of Mangetus’s Bibliotheca
-Chemica. They both agree that it refers to the _universal medicine_,
-which began to acquire celebrity about the time of Paracelsus, or a
-little earlier.
-
-This exposition, which appears as probable as any other, betrays
-the time when this celebrated inscription seems to have been really
-written. Had it been taken out of the hands of the dead body of Hermes
-by Sarah (obviously intended for the wife of Abraham) as is affirmed
-by Avicenna, it is not possible that Herodotus, and all the writers of
-antiquity, both Pagan and Christian, should have entirely overlooked
-it; or how could Avicenna have learned what was unknown to all those
-who lived nearest the time when the discovery was supposed to have been
-made? Had it been discovered in Egypt by Alexander the Great, would
-it have been unknown to Aristotle, and to all the numerous tribe of
-writers whom the Alexandrian school produced, not one of whom, however,
-make the least allusion to it? In short, it bears all the marks of
-a forgery of the fifteenth century. And even the tract ascribed to
-Albertus Magnus, in which the tablet of Hermes is mentioned, and the
-discovery related, is probably also a forgery; and doubtless a forgery
-of the same individual who fabricated the tablet itself, in order to
-throw a greater air of probability upon a story which he wished to palm
-upon the world as true. His object was in some measure accomplished;
-for the authenticity of the tablet was supported with much zeal by
-Kriegsmann, and afterwards by Olaus Borrichius.
-
-There is another tract of Hermes Trismegistus, entitled “Tractatus
-Aureus de Lapidis Physici Secreto;” on which no less elaborate
-commentaries have been written. It professes to teach the process of
-making the _philosopher’s stone_; and, from the allusions in it, to the
-use of this stone, as a universal medicine, was probably a forgery of
-the same date as the emerald tablet. It would be in vain to attempt to
-extract any thing intelligible out of this Tractatus Aureus: it may be
-worth while to give a single specimen, that the reader may be able to
-form some idea of the nature of the style.
-
-“Take of moisture an ounce and a half; of meridional redness, that is
-the soul of the sun, a fourth part, that is half an ounce; of yellow
-seyr, likewise half an ounce; and of auripigmentum, a half ounce,
-making in all three ounces. Know that the vine of wise men is extracted
-in threes, and its wine at last is completed in thirty.”[10]
-
-[10] “Accipe de humore unciam unam et mediam, et de rubore meridionali,
-id est anima solis, quartam partem, id est, unciam mediam, et de Seyre
-citrino, similiter unciam mediam, et de auripigmenti dimidium, quæ
-sunt octo, id est unciæ tres. Scitote quod vitis sapientum in tribus
-extrahitur, ejusque vinum in fine triginta peragitur.”
-
-Had the opinion, that gold and silver could be artificially formed
-originated with Hermes Trismegistus, or had it prevailed among
-the ancient Egyptians, it would certainly have been alluded to by
-Herodotus, who spent so many years in Egypt, and was instructed by
-the priests in all the science of the Egyptians. Had _chemistry_ been
-the name of a science, real or fictitious, which existed as early as
-the expedition of the Argonauts, and had so many treatises on it, as
-Suidas alleges existed in Egypt before the reign of Dioclesian, it
-could hardly have escaped the notice of Pliny, who was so curious
-and so indefatigable in his researches, and who has collected in his
-natural history a kind of digest of all the knowledge of the ancients
-in every department of practical science. The fact that the term
-chemistry (χημεια) never occurs in any Greek or Roman writer prior to
-Suidas, who wrote so late as the eleventh century, seems to overturn
-all idea of the existence of that pretended science among the ancients,
-notwithstanding the elaborate attempts of Olaus Borrichius to prove the
-contrary.
-
-I am disposed to believe, that chemistry or alchymy, understanding
-by the term the _art of making gold and silver_, originated among
-the Arabians, when they began to turn their attention to medicine,
-after the establishment of the caliphs; or if it had previously been
-cultivated by Greeks (as the writings of Zosimus, the Panapolite,
-if genuine, would lead us to suppose), that it was taken up by the
-Arabians, and reduced by them into regular form and order. If the works
-of Geber be genuine, they leave little doubt on this point. Geber is
-supposed to have been a physician, and to have written in the seventh
-century. He admits, as a first principle, that metals are compounds of
-mercury and sulphur. He talks of the philosopher’s stone; professes
-to give the mode of preparing it; and teaches the way of converting
-the different metals, known in his time, into medicines, on whose
-efficacy he bestows the most ample panegyrics. Thus the principles
-which lie at the bottom of alchymy were implicitly adopted by him.
-Yet I can nowhere find in him any attempt to make gold artificially.
-His chemistry was entirely devoted to the improvement of medicine.
-The subsequent pretensions of the alchymists to convert the baser
-metals into gold are no where avowed by him. I am disposed from this
-to suspect, that the theory of gold-making was started after Geber’s
-time, or at least that it was after the seventh century, before any
-alchymist ventured to affirm that he himself was in possession of the
-secret, and could fabricate gold artificially at pleasure. For there is
-a wide distance between the opinion that gold may be made artificially
-and the affirmation that we are in possession of a method by which this
-transmutation of the baser metals into gold can be accomplished. The
-first may be adopted and defended with much plausibility and perfect
-honesty; but the second would require a degree of skill far exceeding
-that of the most scientific votary of chemistry at present existing.
-
-The opinion of the alchymists was, that all the metals are compounds;
-that the baser metals contain the same constituents as gold,
-contaminated, indeed, with various impurities, but capable, when their
-impurities are removed or remedied, of assuming all the properties and
-characters of gold. The substance possessing this wonderful power they
-distinguish by the name of _lapis philosophorum_, or, philosopher’s
-stone, and they usually describe it as a red powder, having a peculiar
-smell. Few of the alchymists who have left writings behind them boast
-of being possessed of the philosopher’s stone. Paracelsus, indeed,
-affirms, that he was acquainted with the method of making it, and
-gives several processes, which, however, are not intelligible. But
-many affirm that they had seen the philosopher’s stone; that they had
-portions of it in their possession; and that they had seen several of
-the inferior metals, especially lead and quicksilver, converted by
-means of it into gold. Many stories of this kind are upon record, and
-so well authenticated, that we need not be surprised at their having
-been generally credited. It will be sufficient if we state one or two
-of those which depend upon the most unexceptionable evidence. The
-following relation is given by Mangetus, on the authority of M. Gros, a
-clergyman of Geneva, of the most unexceptionable character, and at the
-same time a skilful physician and expert chemist:
-
-“About the year 1650 an unknown Italian came to Geneva, and took
-lodgings at the sign of the _Green Cross_. After remaining there a
-day or two, he requested De Luc, the landlord, to procure him a man
-acquainted with Italian, to accompany him through the town and point
-out those things which deserved to be examined. De Luc was acquainted
-with M. Gros, at that time about twenty years of age, and a student
-in Geneva, and knowing his proficiency in the Italian language,
-requested him to accompany the stranger. To this proposition he
-willingly acceded, and attended the Italian every where for the space
-of a fortnight. The stranger now began to complain of want of money,
-which alarmed M. Gros not a little--for at that time he was very
-poor--and he became apprehensive, from the tenour of the stranger’s
-conversation, that he intended to ask the loan of money from him. But
-instead of this, the Italian asked him if he was acquainted with any
-goldsmith, whose bellows and other utensils they might be permitted
-to use, and who would not refuse to supply them with the different
-articles requisite for a particular process which he wanted to perform.
-M. Gros named a M. Bureau, to whom the Italian immediately repaired.
-He readily furnished crucibles, pure tin, quicksilver, and the other
-things required by the Italian. The goldsmith left his workshop, that
-the Italian might be under the less restraint, leaving M. Gros, with
-one of his own workmen, as an attendant. The Italian put a quantity
-of tin into one crucible, and a quantity of quicksilver into another.
-The tin was melted in the fire and the mercury heated. It was then
-poured into the melted tin, and at the same time a red powder enclosed
-in wax was projected into the amalgam. An agitation took place,
-and a great deal of smoke was exhaled from the crucible; but this
-speedily subsided, and the whole being poured out, formed six heavy
-ingots, having the colour of gold. The goldsmith was called in by the
-Italian, and requested to make a rigid examination of the smallest of
-these ingots. The goldsmith, not content with the touchstone and the
-application of aqua fortis, exposed the metal on the cupel with lead,
-and fused it with antimony, but it sustained no loss. He found it
-possessed of the ductility and specific gravity of gold; and full of
-admiration, he exclaimed that he had never worked before upon gold so
-perfectly pure. The Italian made him a present of the smallest ingot
-as a recompence, and then, accompanied by M. Gros, he repaired to the
-Mint, where he received from M. Bacuet, the mintmaster, a quantity of
-Spanish gold coin, equal in weight to the ingots which he had brought.
-To M. Gros he made a present of twenty pieces, on account of the
-attention that he had paid to him; and, after paying his bill at the
-inn, he added fifteen pieces more, to serve to entertain M. Gros and
-M. Bureau for some days, and in the mean time he ordered a supper,
-that he might, on his return, have the pleasure of supping with these
-two gentlemen. He went out, but never returned, leaving behind him the
-greatest regret and admiration. It is needless to add, that M. Gros and
-M. Bureau continued to enjoy themselves at the inn till the fifteen
-pieces, which the stranger had left, were exhausted.”[11]
-
-[11] Preface to Mangetus’s Bibliotheca Chemica Curiosa.
-
-Mangetus gives also the following relation, which he states upon the
-authority of an English bishop, who communicated it to him in the year
-1685, and at the same time gave him about half an ounce of the gold
-which the alchymist had made:
-
-A stranger, meanly dressed, went to Mr. Boyle, and after conversing
-for some time about chemical processes, requested him to furnish him
-with antimony, and some other common metallic substances, which then
-fortunately happened to be in Mr. Boyle’s laboratory. These were
-put into a crucible, which was then placed in a melting-furnace. As
-soon as these metals were fused, the stranger showed a powder to the
-attendants, which he projected into the crucible, and instantly went
-out, directing the servants to allow the crucible to remain in the
-furnace till the fire went out of its own accord, and promising at the
-same time to return in a few hours. But, as he never fulfilled this
-promise, Boyle ordered the cover to be taken off the crucible, and
-found that it contained a yellow-coloured metal, possessing all the
-properties of pure gold, and only a little lighter than the weight of
-the materials originally put into the crucible.[12]
-
-[12] Ibid.
-
-The following strange story is related by Helvetius, physician to the
-Prince of Orange, in his Vitulus Aureus: Helvetius was a disbeliever of
-the philosopher’s stone, and the universal medicine, and even turned
-Sir Kenelm Digby’s sympathetic powder into ridicule. On the 27th of
-December, 1666, a stranger called upon him, and after conversing for
-some time about a universal medicine, showed a yellow powder, which
-he affirmed to be the philosopher’s stone, and at the same time five
-large plates of gold, which had been made by means of it. Helvetius
-earnestly entreated that he would give him a little of this powder,
-or at least that he would make a trial of its power; but the stranger
-refused, promising however to return in six weeks. He returned
-accordingly, and after much entreaty he gave to Helvetius a piece of
-the stone, not larger than the size of a rape-seed. When Helvetius
-expressed his doubt whether so small a portion would be sufficient to
-convert four grains of lead into gold, the adept broke off one half of
-it, and assured him that what remained was more than sufficient for the
-purpose. Helvetius, during the first conference, had concealed a little
-of the stone below his nail. This he threw into melted lead, but it was
-almost all driven off in smoke, leaving only a vitreous earth. When he
-mentioned this circumstance, the stranger informed him that the powder
-must be enclosed in wax, before it be thrown into the melted lead, lest
-it should be injured by the smoke of the lead. The stranger promised
-to return next day, and show him the method of making the projection;
-but having failed to make his appearance, Helvetius, in the presence
-of his wife and son, put six drachms of lead into a crucible, and as
-soon as it was melted he threw into it the fragment of philosopher’s
-stone in his possession, previously covered over with wax. The crucible
-was now covered with its lid, and left for a quarter of an hour in the
-fire, at the end of which time he found the whole lead converted into
-gold. The colour was at first a deep green; being poured into a conical
-vessel, it assumed a blood-red colour; but when cold, it acquired the
-true tint of gold. Being examined by a goldsmith, he considered it as
-pure gold. He requested Porelius, who had the charge of the Dutch mint,
-to try its value. Two drachms of it being subjected to quartation, and
-solution in aqua fortis, were found to have increased in weight by two
-scruples. This increase was doubtless owing to the silver, which still
-remained enveloped in the gold, after the action of the aqua fortis.
-To endeavour to separate the silver more completely, the gold was again
-fused with seven times its weight of antimony, and treated in the usual
-manner; but no alteration took place in the weight.[13]
-
-[13] Bergmann, Opusc. iv. 121.
-
-It would be easy to relate many other similar narratives; but the
-three which I have given are the best authenticated of any that I am
-acquainted with. The reader will observe, that they are all stated on
-the authority, not of the persons who were the actors, but of others
-to whom they related them; and some of these, as the English bishop,
-perhaps not very familiar with chemical processes, and therefore liable
-to leave out or misstate some essential particulars. The evidence,
-therefore, though the best that can be got, is not sufficient to
-authenticate these wonderful stories. A little latent vanity might
-easily induce the narrators to suppress or alter some particulars,
-which, if known, would have stripped the statements of every thing
-marvellous which they contain, and let us into the secret of the
-origin of the gold, which these alchymists boasted that they had
-fabricated. Whoever will read the statements of Paracelsus, respecting
-his knowledge of the philosopher’s stone, which he applied not to the
-formation of gold but to medicine, or whoever will examine his formulas
-for making the stone, will easily satisfy himself that Paracelsus
-possessed no real knowledge on the subject.[14]
-
-[14] I allude to his _Manuale sive de Lapide Philosophico Medicinali_.
-Opera Paracelsi, ii. 133. Folio edition. Geneva, 1658.
-
-But to convey as precise ideas on this subject as possible, it may
-be worth while to state a few of the methods by which the alchymists
-persuaded themselves that they could convert the baser metals into gold.
-
-In the year 1694 an old gentleman called upon Mr. Wilson, at that time
-a chemist in London, and informed him that at last, after forty years’
-search, he had met with an ample recompence for all his trouble and
-expenses. This he confirmed with some oaths and imprecations; but,
-considering his great weakness and age, he looked upon himself as
-incapable to undergo the fatigues of the process. “I have here,” says
-he, “a piece of sol (_gold_) that I made from silver, about four years
-ago, and I cannot trust any man but you with so rare a secret. We will
-share equally the charges and profit, which will render us wealthy
-enough to command the world.” The nature of the process being stated,
-Mr. Wilson thought it not unreasonable, especially as he aimed at no
-peculiar advantage for himself. He accordingly put it to the trial in
-the following manner:
-
-1. Twelve ounces of Japan copper were beat into thin plates, and laid
-_stratum super stratum_ with three ounces of flowers of sulphur, in a
-crucible. It was exposed in a melting-furnace to a gentle heat, till
-the sulphureous flames expired. When cold, the æs ustum (_sulphuret
-of copper_) was pounded, and stratified again; and this process was
-repeated five times. Mr. Wilson does not inform us whether the powder
-was mixed with flowers of sulphur every time that it was heated; but
-this must have been the case, otherwise the sulphuret would have been
-again converted into metallic copper, which would have melted into a
-mass. By this first process, then, bisulphuret of copper was formed,
-composed of equal weights of sulphur and copper.
-
-2. Six pounds of iron wire were put into a large glass body, and twelve
-pounds of muriatic acid poured upon it. Six days elapsed (during which
-it stood in a gentle heat) before the acid was saturated with the iron.
-The solution was then decanted off, and filtered, and six pounds of new
-muriatic acid poured on the undissolved iron. This acid, after standing
-a sufficient time, was decanted off, and filtered. Both liquids were
-put into a large retort, and distilled by a sand-heat. Towards the
-end, when the drops from the retort became yellow, the receiver was
-changed, and the fire increased to the highest degree, in which the
-retort was kept between four and six hours. When all was cold, the
-receiver was taken off, and a quantity of flowers was found in the neck
-of the retort, variously coloured, like the rainbow. The yellow liquor
-in the receiver weighed ten ounces and a half; the flowers (_chloride
-of iron_), two ounces and three drams. The liquid and flowers were put
-into a clean bottle.
-
-3. Half a pound of sal enixum (_sulphate of potash_) and a pound and a
-half of nitric acid were put into a retort. When the salt had dissolved
-in the acid, ten ounces of mercury (previously distilled through
-quicklime and salt of tartar) were added. The whole being distilled to
-dryness, a fine yellow mass (_pernitrate of mercury_) remained in the
-bottom of the retort. The liquor was returned, with half a pound of
-fresh nitric acid, and the distillation repeated. The distillation was
-repeated a third time, urging this last cohobation with the highest
-degree of fire. When all was cold, a various-coloured mass was found in
-the bottom of the retort: this mass was doubtless a mixture of sulphate
-of potash, and pernitrate of mercury, with some oxide of mercury.
-
-4. Four ounces of fine silver were dissolved in a pound of aqua fortis;
-to the solution was added, of the bisulphuret of copper four ounces;
-of the mixture of sulphate of potash, pernitrate of mercury, and oxide
-of mercury one ounce and a half, and of the solution of perchloride
-of iron two ounces and a half. When these had stood in a retort
-twenty-four hours, the liquor was decanted off, and four ounces of
-nitric acid were poured upon the little matter that was not dissolved.
-Next morning a total dissolution was obtained. The whole of this
-dissolution was put into a retort and distilled almost to dryness. The
-liquid was poured back, and the distillation repeated three times; the
-last time the retort being urged by a very strong fire till no fumes
-appeared, and not a drop fell.
-
-5. The matter left in the bottom of the retort was now put into a
-crucible, all the corrosive fumes were gently evaporated, and the
-residue melted down with a fluxing powder.
-
-This process was expected to yield five ounces of pure gold; but
-on examination the silver was the same (except the loss of half a
-pennyweight) as when dissolved in the aqua fortis: there were indeed
-some grains among the scoria, which appeared like gold, and would not
-dissolve in aqua fortis. No doubt they consisted of peroxide of iron,
-or, perhaps, persulphuret of iron.[15]
-
-[15] Wilson’s Chemistry, p. 375.
-
-Mr. Wilson’s alchymistical friend, not satisfied with this first
-failure, insisted upon a repetition of the process, with some
-alteration in the method and the addition of a certain quantity
-of gold. The whole was accordingly gone through again; but it is
-unnecessary to say that no gold was obtained, or at least, the two
-drams of gold employed had increased in weight by only two scruples and
-thirteen grains; this addition was doubtless owing to a little silver
-from which it had not been freed.[16]
-
-[16] Ibid., p. 379.
-
-I shall now give a process for making the philosopher’s stone, which
-was considered by Mangetus as of great value, and on that account was
-given by him in the preface to his Bibliotheca Chemica.
-
-1. Prepare a quantity of spirit of wine, so free from water that it is
-wholly combustible, and so volatile that when a drop of it is let fall
-it evaporates before it reaches the ground;--this constitutes the first
-menstruum.
-
-2. Take pure mercury, revived in the usual manner from cinnabar, put
-it into a glass vessel with common salt and distilled vinegar; agitate
-violently, and when the vinegar acquires a black colour pour it off and
-add new vinegar; agitate again, and continue these repeated agitations
-and additions till the vinegar ceases to acquire a black colour from
-the mercury: the mercury is now quite pure and very brilliant.
-
-3. Take of this mercury four parts; of sublimed mercury[17] (_mercurii
-meteoresati_), prepared with your own hands, eight parts; triturate
-them together in a wooden mortar with a wooden pestle, till all the
-grains of running mercury disappear. This process is tedious and rather
-difficult.
-
-[17] Probably corrosive sublimate.
-
-4. The mixture thus prepared is to be put into an aludel, or a
-sand-bath, and exposed to a subliming heat, which is to be gradually
-raised till the whole sublimes. Collect the sublimed matter, put it
-again into the aludel, and sublime a second time; this process must be
-repeated five times. Thus a very sweet and crystallized sublimate is
-obtained: it constitutes the salt of wise men (_sal sapientum_), and
-possesses wonderful properties.[18]
-
-[18] Probably calomel.
-
-5. Grind it in a wooden mortar, and reduce it to powder; put it into
-a glass retort, and pour upon it the spirit of wine (No. 1) till it
-stands about three finger-breadths above the powder; seal the retort
-hermetically, and expose it to a very gentle heat for seventy-four
-hours, shaking it several times a-day; then distil with a gentle heat
-and the spirit of wine will pass over, together with spirit of mercury.
-Keep this liquid in a well-stopped bottle, lest it should evaporate.
-More spirit of wine is to be poured upon the residual salt, and after
-digestion it must be distilled off as before; and this process must
-be repeated till the whole salt is dissolved, and distilled over with
-the spirit of wine. You have now performed a great work. The mercury
-is now rendered in some measure volatile, and it will gradually become
-fit to receive the tincture of gold and silver. Now return thanks to
-God, who has hitherto crowned your wonderful work with success; nor
-is this great work involved in Cimmerian darkness, but clearer than
-the sun; though preceding writers have imposed upon us with parables,
-hieroglyphics, fables, and enigmas.
-
-6. Take this mercurial spirit, which contains our magical steel in its
-belly, put it into a glass retort, to which a receiver must be well and
-carefully luted: draw off the spirit by a very gentle heat, there will
-remain in the bottom of the retort the quintessence or soul of mercury;
-this is to be sublimed by applying a stronger heat to the retort that
-it may become volatile, as all the philosophers express themselves--
-
-    Si fixum solvas faciesque volare solutum,
-    Et volucrum figas faciet te vivere tutum.
-
-This is our luna, our fountain, in which the king and queen may bathe.
-Preserve this precious quintessence of mercury, which is very volatile,
-in a well-shut vessel for further use.
-
-8. Let us now proceed to the operation of common gold, which we shall
-communicate clearly and distinctly, without digression or obscurity;
-that from vulgar gold we may obtain our philosophical gold, just
-as from common mercury we obtained, by the preceding processes,
-philosophical mercury.
-
-In the name of God, then, take common gold, purified in the usual
-way by antimony, convert it into small grains, which must be washed
-with salt and vinegar, till it be quite pure. Take one part of this
-gold, and pour on it three parts of the quintessence of mercury; as
-philosophers reckon from seven to ten, so we also reckon our number as
-philosophical, and we begin with three and one; let them be married
-together like husband and wife, to produce children of their own kind,
-and you will see the common gold sink and plainly dissolve. Now the
-marriage is consummated; now two things are converted into one: thus
-the philosophical sulphur is at hand, as the philosophers say, _the
-sulphur being dissolved the stone is at hand_. Take then, in the name
-of God, our philosophical vessel, in which the king and queen embrace
-each other as in a bedchamber, and leave it till the water is converted
-into earth, then peace is concluded between the water and fire, then
-the elements have no longer any thing contrary to each other; because,
-when the elements are converted into earth they no longer oppose each
-other; for in earth all elements are at rest. For the philosophers say,
-“When you shall have seen the water coagulate itself, think that your
-knowledge is true, and that your operations are truly philosophical.”
-The gold is now no longer common, but ours is philosophical, on
-account of our processes: at first exceedingly fixed; then exceedingly
-volatile, and finally exceedingly fixed; and the whole science depends
-upon the change of the elements. The gold at first was a metal, now it
-is a sulphur, capable of converting all metals into its own sulphur.
-Now our tincture is wholly converted into sulphur, which possesses the
-energy of curing all diseases: this is our universal medicine against
-all the most deplorable diseases of the human body; therefore, return
-infinite thanks to Almighty God for all the good things which he has
-bestowed upon us.
-
-9. In this great work of ours, two modes of fermenting and projecting
-are wanting, without which the uninitiated will not easily follow our
-process. The mode of fermenting is as follows: Take of our sulphur
-above described one part, and project it upon three parts of very
-pure gold fused in a furnace; in a moment you will see the gold, by
-the force of the sulphur, converted into a red sulphur of an inferior
-quality to the first sulphur; take one part of this, and project it
-upon three parts of fused gold, the whole will be again converted
-into a sulphur, or a friable mass; mixing one part of this with three
-parts of gold, you will have a malleable and extensible metal. If
-you find it so, well; if not add other sulphur and it will again pass
-into sulphur. Now the sulphur will be sufficiently fermented, or our
-medicine will be brought into a metallic nature.
-
-10. The mode of projecting is this: Take of the fermented sulphur one
-part, and project it upon ten parts of mercury, heated in a crucible,
-and you will have a perfect metal; if its colour is not sufficiently
-deep, fuse it again, and add more fermented sulphur, and thus it will
-acquire colour. If it becomes frangible, add a sufficient quantity of
-mercury and it will be perfect.
-
-Thus, friend, you have a description of the universal medicine, not
-only for curing diseases and prolonging life, but also for transmuting
-all metals into gold. Give therefore thanks to Almighty God, who,
-taking pity on human calamities, has at last revealed this inestimable
-treasure, and made it known for the common benefit of all.[19]
-
-[19] Mangeti Bibliothecæ Chemicæ Præfatio.
-
-Such is the formula (slightly abridged) of Carolus Musitanus, by which
-the philosopher’s stone, according to him, may be formed. Compared with
-the formulas of most of the alchymists, it is sufficiently plain. What
-the _sublimed mercury_ is does not appear; from the process described
-we should be apt to consider it as _corrosive sublimate_; on that
-supposition, the sal sapientum formed in No. 5, would be calomel: the
-only objection to this supposition is the process described in No. 5;
-for calomel is not soluble in alcohol. The philosopher’s stone prepared
-by this elaborate process could hardly have been any thing else than
-an _amalgam of gold_; it could not have contained chloride of gold,
-because such a preparation, instead of acting medicinally, would have
-proved a most virulent poison. There is no doubt that amalgam of gold,
-if projected into melted lead or tin, and afterwards cupellated, would
-leave a portion of gold--all the gold of course that existed previously
-in the amalgam. It might therefore have been employed by impostors to
-persuade the ignorant that it was really the philosopher’s stone; but
-the alchymists who prepared the amalgam could not be ignorant that it
-contained gold.
-
-There is another process given in the same preface of a very different
-nature, but too long to be transcribed here, and the nature of the
-process is not sufficiently intelligible to render an account of it of
-much consequence.[20]
-
-[20] Whoever wishes to enter more particularly into the processes for
-making the philosopher’s stone contrived by the alchymists, will find a
-good deal of information on the subject in Stahl’s Fundamenta Chemiæ,
-vol. i. p. 219, in his chapter _De lapide philosophorum_: and Junker’s
-Conspectus Chemiæ, vol. i. p. 604, in his tabula 28, _De transmutatione
-metallorum universali_: and tabula 29, _De transmutatione metallorum
-particulari_.
-
-The preceding observations will give the reader some notion of the
-nature of the pursuits which occupied the alchymists: their sole
-object was the preparation of a substance to which they gave the name
-of the philosopher’s stone, which possessed the double property of
-converting the baser metals into gold, and of curing all diseases, and
-of preserving human life to an indefinite extent. The experiments of
-Wilson, and the formula of Musitanus, which have been just inserted,
-will give the reader some notion of the way in which they attempted
-to manufacture this most precious substance. Being quite ignorant of
-the properties of bodies, and of their action on each other, their
-processes were guided by no scientific analogies, and one part of the
-labour not unfrequently counteracted another; it would be a waste of
-time, therefore, to attempt to analyze their numerous processes, even
-though such an attempt could be attended with success. But in most
-cases, from the unintelligible terms in which their books are written,
-it is impossible to divine the nature of the processes by which they
-endeavoured to manufacture the philosopher’s stone, or the nature of
-the substances which they obtained.[21]
-
-[21] Kircher, in his Mundus Subterraneus, has an article on the
-philosopher’s stone, in which he examines the processes of the
-alchymists, points out their absurdity, and proves by irrefragable
-arguments that no such substance had ever been obtained. Those who are
-curious about alchymistical processes may consult that work.
-
-In consequence of the universality of the opinion that gold could be
-made by art, there was a set of impostors who went about pretending
-that they were in possession of the philosopher’s stone, and offering
-to communicate the secret of making it for a suitable reward. Nothing
-is more astonishing than that persons should be found credulous enough
-to be the dupes of such impostors. The very circumstance of their
-claiming a reward was a sufficient proof that they were ignorant of
-the secret which they pretended to reveal; for what motive could a
-man have for asking a reward who was in possession of a method of
-creating gold at pleasure? To such a person money could be no object,
-as he could procure it in any quantity. Yet, strange as it may appear,
-they met with abundance of dupes credulous enough to believe their
-asseverations, and to supply them with money to enable them to perform
-the wished-for processes. The object of these impostors was either to
-pocket the money thus furnished, or they made use of it to purchase
-various substances from which they extracted oils, acids, or similar
-products, which they were enabled to sell at a profit. To keep the
-dupes, who thus supplied them with the means of carrying on these
-processes, in good spirits, it was necessary to show them occasionally
-small quantities of the baser metals converted into gold; this they
-performed in various ways. M. Geoffroy, senior, who had an opportunity
-of witnessing many of their performances, has given us an account of a
-number of their tricks. It may be worth while to state a few by way of
-specimen.
-
-Sometimes they made use of crucibles with a false bottom; at the real
-bottom they put a quantity of oxide of gold or silver, this was covered
-with a portion of powdered crucible, glued together by a little gummed
-water or a little wax; the materials being put into this crucible, and
-heat applied, the false bottom disappears, the oxide of gold or silver
-is reduced, and at the end of the process is found at the bottom of the
-crucible, and considered as the product of the operation.
-
-Sometimes they make a hole in a piece of charcoal and fill it with
-oxide of gold or silver, and stop up the mouth with a little wax; or
-they soak charcoal in solutions of these metals; or they stir the
-mixtures in the crucible with hollow rods containing oxide of gold or
-silver within, and the bottom shut with wax: by these means the gold
-or silver wanted is introduced during the process, and considered as a
-product of the operation.
-
-Sometimes they have a solution of silver in nitric acid, or of gold
-in aqua regia, or an amalgam of gold or silver, which being adroitly
-introduced, furnishes the requisite quantity of metal. A common
-exhibition was to dip nails into a liquid, and take them out half
-converted into gold. The nails consisted of one-half gold, neatly
-soldered to the iron, and covered with something to conceal the colour,
-which the liquid removed. Sometimes they had metals one-half gold the
-other half silver, soldered together, and the gold side whitened with
-mercury; the gold half was dipped into the transmuting liquid and then
-the metal heated; the mercury was dissipated, and the gold half of the
-metal appeared.[22]
-
-[22] Mem. Paris, 1722, p. 61.
-
-As the alchymists were assiduous workmen--as they mixed all the metals,
-salts, &c. with which they were acquainted, in various ways with each
-other, and subjected such mixtures to the action of heat in close
-vessels, their labours were occasionally repaid by the discovery of new
-substances, possessed of much greater activity than any with which they
-were previously acquainted. In this way they were led to the discovery
-of sulphuric, nitric, and muriatic acids. These, when known, were made
-to act upon the metals; solutions of the metals were obtained, and
-this gradually led to the knowledge of various metalline salts and
-preparations, which were introduced with considerable advantage into
-medicine. Thus the alchymists, by their absurd pursuits, gradually
-formed a collection of facts, which led ultimately to the establishment
-of scientific chemistry. On this account it will be proper to notice,
-in this place, such of them as appeared in Europe during the darker
-ages, and acquired the highest reputation either on account of their
-skill as physicians, or their celebrity as chemists.[23]
-
-[23] The original author, whom all who have given any account of the
-alchymists have followed, is Olaus Borrichius, in his Conspectus
-Scriptorum Chemicorum Celebriorum. He does not inform us from what
-sources his information was derived.
-
-1. The first alchymist who deserves notice is Albertus Magnus, or
-Albert Groot, a German, who was born, it is supposed, in the year
-1193, at Bollstaedt, and died in the year 1282.[24] When very young
-he is said to have been so remarkable for his dulness, that he became
-the jest of his acquaintances. He studied the sciences at Padua, and
-afterwards taught at Cologne, and finally in Paris. He travelled
-through all Germany as Provincial of the order of Dominican Monks,
-visited Rome, and was made bishop of Ratisbon: but his passion for
-science induced him to give up his bishopric, and return to a cloister
-at Cologne, where he continued till his death.
-
-[24] Sprengel’s History of Medicine, iv. 368.
-
-Albertus was acquainted with all the sciences cultivated in his time.
-He was at once a theologian, a physician, and a man of the world: he
-was an astronomer and an alchymist, and even dipped into magic and
-necromancy. His works are very voluminous. They were collected by Petr.
-Jammy, and published at Leyden in twenty-one folio volumes, in 1651.
-His principal alchymistical tracts are the following:
-
-  1. De Rebus Metallicis et Mineralibus.
-
-  2. De Alchymia.
-
-  3. Secretorum Tractatus.
-
-  4. Breve Compendium de Ortu Metallorum.
-
-  5. Concordantia Philosophorum de Lapide.
-
-  6. Compositum de Compositis.
-
-  7. Liber octo Capitum de Philosophorum Lapide.
-
-Most of these tracts have been inserted in the Theatrum Chemicum. They
-are in general plain and intelligible. In his treatise De Alchymia, for
-example, he gives a distinct account of all the chemical substances
-known in his time, and of the manner of obtaining them. He mentions
-also the apparatus then employed by chemists, and the various processes
-which they had occasion to perform. I may notice the most remarkable
-facts and opinions which I have observed in turning over these
-treatises.
-
-He was of opinion that all metals are composed of sulphur and mercury;
-and endeavoured to account for the diversity of metals partly by
-the difference in the purity, and partly by the difference in the
-proportions of the sulphur and mercury of which they are composed. He
-thought that water existed also as a constituent of all metals.
-
-He was acquainted with the water-bath, employed alembics for
-distillation, and aludels for sublimation; and he was in the habit of
-employing various lutes, the composition of which he describes.
-
-He mentions alum and caustic alkali, and seems to have known the
-alkaline basis of cream of tartar. He knew the method of purifying the
-precious metals by means of lead and of gold, by cementation; and
-likewise the method of trying the purity of gold, and of distinguishing
-pure from impure gold.
-
-He mentions red lead, metallic arsenic, and liver of sulphur. He was
-acquainted with green vitriol and iron pyrites. He knew that arsenic
-renders copper white, and that sulphur attacks all the metals except
-gold.
-
-It is said by some that he was acquainted with gunpowder; but nothing
-indicating any such knowledge occurs in any of his writings that I have
-had an opportunity of perusing.[25]
-
-[25] It is curious that Olaus Borrichius omits Albertus Magnus in the
-list of alchymistical writers that he has given.
-
-2. Albertus is said to have had for a pupil, while he taught in Paris,
-the celebrated Thomas Aquinas, a Dominican, who studied at Bologna,
-Rome, and Naples, and distinguished himself still more in divinity and
-scholastic philosophy than in alchymy. He wrote,
-
-    1. Thesaurum Alchymiæ Secretissimum.
-
-    2. Secreta Alchymiæ Magnalia.
-
-    3. De Esse et Essentia Mineralium; and perhaps some other
-    works, which I have not seen.
-
-These works, so far as I have perused them, are exceedingly obscure,
-and in various places unintelligible. Some of the terms still employed
-by modern chemists occur, for the first time, in the writings of Thomas
-Aquinas. Thus the term _amalgam_, still employed to denote a compound
-of mercury with another metal, occurs in them, and I have not observed
-it in any earlier author.
-
-3. Soon after Albertus Magnus, flourished Roger Bacon, by far the most
-illustrious, the best informed, and the most philosophical of all the
-alchymists. He was born in 1214, in the county of Somerset. After
-studying in Oxford, and afterwards in Paris, he became a cordelier
-friar; and, devoting himself to philosophical investigations, his
-discoveries, notwithstanding the pains which he took to conceal them,
-made such a noise, that he was accused of magic, and his brethren in
-consequence threw him into prison. He died, it is said, in the year
-1284, though Sprengel fixes the year of his death to be 1285.
-
-His writings display a degree of knowledge and extent of thought
-scarcely credible, if we consider the time when he wrote, the darkest
-period of the dark ages. In his small treatise De Mirabili Potestate
-Artis et Naturæ, he begins by pointing out the absurdity of believing
-in magic, necromancy, charms, or any of those similar opinions which
-were at that time universally prevalent. He points out the various
-ways in which mankind are deceived by jugglers, ventriloquists, &c.;
-mentions the advantages which physicians may derive from acting on
-the imaginations of their patients by means of charms, amulets, and
-infallible remedies: he affirms that many of those things which are
-considered as supernatural, are merely so because mankind in general
-are unacquainted with natural philosophy. To illustrate this he
-mentions a great number of natural phenomena, which had been reckoned
-miraculous; and concludes with several secrets of his own, which he
-affirms to be still more extraordinary imitations of some of the most
-singular processes of nature. These he delivers in the enigmatical
-style of the times; induced, as he tells us, partly by the conduct of
-other philosophers, partly by the propriety of the thing, and partly by
-the danger of speaking too plainly.
-
-From an attentive perusal of his works, many of which have been
-printed, it will be seen that Bacon was a great linguist, being
-familiar with Latin, Greek, Hebrew, and Arabic; and that he had perused
-the most important books at that time existing in all these languages.
-He was also a grammarian; he was well versed in the theory and practice
-of perspective; he understood the use of convex and concave glasses,
-and the art of making them. The camera obscura, burning-glasses, and
-the powers of the telescope, were known to him. He was well versed
-in geography and astronomy. He knew the great error in the Julian
-calendar, assigned the cause, and proposed the remedy. He understood
-chronology well; he was a skilful physician, and an able mathematician,
-logician, metaphysician, and theologist; but it is as a chemist that
-he claims our attention here. The following is a list of his chemical
-writings, as given by Gmelin, the whole of which I have never had an
-opportunity of seeing:
-
-  1. Speculum Alchymiæ.[26]
-
-  2. Epistola de Secretis Operibus Artis et Naturæ et
-  de Nullitate Magiæ.
-
-  3. De Mirabili Potestate Artis et Naturæ.
-
-  4. Medulla Alchymiæ.
-
-  5. De Arte Chemiæ.
-
-  6. Breviorium Alchymiæ.
-
-  7. Documenta Alchymiæ.
-
-  8. De Alchymistarum Artibus.
-
-  9. De Secretis.
-
-  10. De Rebus Metallicis.
-
-  11. De Sculpturis Lapidum.
-
-  12. De Philosophorum Lapide.
-
-  13. Opus Majus, _or_ Alchymia Major.
-
-  14. Breviarium de Dono Dei.
-
-  15. Verbum abbreviatum de Leone Viridi.
-
-  16. Secretum Secretorum.
-
-  17. Tractatus Trium Verborum.
-
-  18. Speculum Secretorum.
-
-[26] This tract and the next, which is of considerable length, will be
-found in Mangetus’s Bibliotheca Chemica Curiosa, i. 613.
-
-A number of these were collected together, and published at Frankfort
-in 1603, under the title of “Rogeri Baconis Angli de Arte Chemiæ
-Scripta,” in a small duodecimo volume. The Opus Majus was published in
-London in 1733, by Dr. Jebb, in a folio volume. Several of his tracts
-still continue in manuscript in the Harleian and Bodleian libraries at
-Oxford. He considered the metals as compound of mercury and sulphur.
-Gmelin affirms that he was aware of the peculiar nature of manganese,
-and that he was acquainted with bismuth; but after perusing the whole
-of the Speculum Alchymiæ, the third chapter of which he quotes as
-containing the facts on which he founds his opinion, I cannot find any
-certain allusion either to manganese or bismuth. The term _magnesia_
-indeed occurs, but nothing is said respecting its nature: and long
-after the time of Paracelsus, bismuth (_bisematum_) was considered as
-an impure kind of _lead_. That he was acquainted with the composition
-and properties of _gunpowder_ admits of no doubt. In the sixth chapter
-of his epistle De Secretis Operibus Artis et Naturæ et de Nullitate
-Magiæ, the following passage occurs:
-
-“For sounds like thunder, and coruscations like lightning, may be made
-in the air, and they may be rendered even more horrible than those of
-nature herself. A small quantity of matter, properly manufactured, not
-larger than the human thumb, may be made to produce a horrible noise
-and coruscation. And this may be done many ways, by which a city or an
-army may be destroyed, as was the case when Gideon and his men broke
-their pitchers and exhibited their lamps, fire issuing out of them with
-inestimable noise, destroyed an infinite number of the army of the
-Midianites.” And in the eleventh chapter of the same epistle occurs
-the following passage: “Mix together saltpetre, luru vopo vir con
-utriet, and sulphur, and you will make thunder and lightning, if you
-know the method of mixing them.” Here all the ingredients of gunpowder
-are mentioned except charcoal, which is doubtless concealed under the
-barbarous terms _luru vopo vir con utriet_.
-
-But though Bacon was acquainted with gunpowder, we have no evidence
-that he was the inventor. How far the celebrated Greek fire,
-concerning which so much has been written, was connected with
-gunpowder, it is impossible to say; but there is good evidence to prove
-that gunpowder was known and used in China before the commencement of
-the Christian era; and Lord Bacon is of opinion that the thunder and
-lightning and magic stated by the Macedonians to have been exhibited
-in Oxydrakes, when it was besieged by Alexander the Great, was nothing
-else than gunpowder. Now as there is pretty good evidence that the use
-of gunpowder had been introduced into Spain by the Moors, at least as
-early as the year 1343, and as Roger Bacon was acquainted with Arabic,
-it is by no means unlikely that he might have become acquainted with
-the mode of making the composition, and with its most remarkable
-properties, by perusing some Arabian writer, with whom we are at
-present unacquainted. Barbour, in his life of Bruce, informs us that
-guns were first employed by the English at the battle of Werewater,
-which was fought in 1327, about forty years after the death of Bacon.
-
-    Two novelties that day they saw,
-    That forouth in Scotland had been nene;
-    Timbers for helmes was the ane
-    That they thought then of great beautie,
-    And also wonder for to see.
-    The other _crakys_ were of war
-    That they before heard never air.
-
-In another part of the same book we have the phrase _gynnys for
-crakys_, showing that the term crakys was used to denote a gun or
-musket of some form or other. It is curious that the English would
-seem to have been the first European nation that employed gunpowder
-in war; they used it in the battle of Crecy, fought in 1346, when it
-was unknown to the French, and it is supposed to have contributed
-materially to the brilliant victory which was obtained.
-
-4. Raymond Lully is said to have been a scholar and a friend of
-Roger Bacon. He was a most voluminous writer, and acquired as high a
-reputation as any of the alchymists. According to Mutius he was born
-in Majorca in the year 1235. His father was seneschal to King James
-the First of Arragon. In his younger days he went into the army; but
-afterwards held a situation in the court of his sovereign. Devoting
-himself to science he soon acquired a competent knowledge of Latin and
-Arabic. After studying in Paris he got the degree of doctor conferred
-upon him. He entered into the order of Minorites, and induced King
-James to establish a cloister of that order in Minorca. He afterwards
-travelled through Italy, Germany, England, Portugal, Cyprus, Armenia
-and Palestine. He is said by Mutius to have died in the year 1315, and
-to have been buried in Majorca. The following epitaph is given by Olaus
-Borrichius as engraven on his tomb:
-
-    Raymundus Lulli, cujus pia dogmata nulli
-    Sunt odiosa viro, jacet hic in marmore miro
-    Hic M. et CC. Cum P. cœpit sine sensibus esse.
-
-M C C C in these lines denote 1300, and P which is the 15th letter of
-the alphabet denotes 15, so that if this epitaph be genuine it follows
-that his death took place in the year 1315.
-
-It seems scarcely necessary to notice the story that Raymond Lully
-made a present to Edward, King of England, of six millions of pieces
-of gold, to enable him to make war on the Saracens, which sum that
-monarch employed, contrary to the intentions of the donor, in his
-French wars. This story cannot apply to Edward III., because in 1315,
-at the time of Raymond’s death, that monarch was only three years of
-age. It can scarcely apply to Edward II., who ascended the throne in
-1305: but who had no opportunity of making war, either on the Saracens
-or French, being totally occupied in opposing the intrigues of his
-queen and rebellious subjects, to whom he ultimately fell a sacrifice.
-Edward the First made war both upon the Saracens and the French, and
-lived during the time of Raymond: but his wars with the Saracens were
-finished before he ascended the throne, and during the whole of his
-reign he was too much occupied with his projected conquest of Scotland,
-to pay much serious attention to any French war whatever. The story,
-therefore, cannot apply to any of the three Edwards, and cannot be
-true. Raymond Lully is said to have been stoned to death in Africa for
-preaching Christianity in the year 1315. Others will have it that he
-was alive in England in the year 1332, at which time his age would have
-been 97.
-
-The following table exhibits a list of his numerous writings, most of
-which are to be found in the Theatrum Chemicum, the Artis Auriferæ, or
-the Biblotheca Chemica.
-
-  1. Praxis Universalis Magni Operis.
-
-  2. Clavicula.
-
-  3. Theoria et Practica.
-
-  4. Compendium Animæ Transmutationis Artis Metallorum.
-
-  5. Ultimum Testamentum. Of this work, which
-  professes to give the whole doctrine of alchymy, there
-  is an English translation.
-
-  6. Elucidatio Testamenti.
-
-  7. Potestas Divitiorum cum Expositione Testamenti
-  Hermetis.
-
-  8. Compendium Artis Magicæ, quoad Compositionem
-  Lapidis.
-
-  9. De Lapide et Oleo Philosophorum.
-
-  10. Modus accipiendi Aurum Potabile.
-
-  11. Compendium Alchymiæ et Naturalis Philosophiæ.
-
-  12. Lapidarium.
-
-  13. Lux Mercuriorum.
-
-  14. Experimenta.
-
-  15. Ars Compendiosa vel Vademecum.
-
-  16. De Accurtatione Lapidis.
-
-Several other tracts besides these are named by Gmelin; but I have
-never seen any of them. I have attempted several times to read over
-the works of Raymond Lully, particularly his Last Will and Testament,
-which is considered the most important of them all. But they are all so
-obscure, and filled with such unintelligible jargon, that I have found
-it impossible to understand them. In this respect they form a wonderful
-contrast with the works of Albertus Magnus and Roger Bacon, which are
-comparatively plain and intelligible. For an account, therefore, of
-the chemical substances with which he was acquainted, I am obliged to
-depend on Gmelin; though I put no great confidence in his accuracy.
-
-Like his predecessors, he was of opinion that all the metals are
-compounds of sulphur and mercury. But he seems first to have introduced
-those hieroglyphical figures or symbols, which appear in such profusion
-in the English translation of his Last Will and Testament, and which
-he doubtless intended to illustrate his positions. Though what other
-purpose they could serve, than to induce the reader to consider his
-statements as allegorical, it is not easy to conjecture. Perhaps they
-may have been designed to impose upon his contemporaries by an air of
-something very profound and inexplicable. For that he possessed a good
-deal of charlatanry is pretty evident, from the slightest glance at his
-performances.
-
-He was acquainted with cream of tartar, which he distilled: the
-residue he burnt, and observed that the alkali extracted deliquesced
-when exposed to the air. He was acquainted with nitric acid, which he
-obtained by distilling a mixture of saltpetre and green vitriol. He
-mentions its power of dissolving, not merely mercury, but likewise
-other metals. He could form aqua regia by adding sal ammoniac or
-common salt to nitric acid, and he was aware of the property which it
-had of dissolving gold.
-
-Spirit of wine was well known to him, and distinguished by him by
-the names of aqua vitæ ardens and argentum vivum vegetabile. He knew
-the method of rendering it stronger by an admixture of dry carbonate
-of potash, and of preparing vegetable tinctures by means of it.
-He mentions alum from Rocca, marcasite, white and red mercurial
-precipitate. He knew the volatile alkali and its coagulations by
-means of alcohol. He was acquainted with cupellated silver, and first
-obtained rosemary oil by distilling the plant with water. He employed a
-mixture of flour and white of egg spread upon a linen cloth to cement
-cracked glass vessels, and used other lutes for similar purposes.[27]
-
-[27] Gmelin’s Geschitte der Chemie, i. 74.
-
-5. Arnoldus de Villa Nova is said to have been born at Villeneuve, a
-village of Provence, about the year 1240. Olaus Borrichius assures us,
-that in his time his posterity lived in the neighbourhood of Avignon;
-that he was acquainted with them, and that they were by no means
-destitute of chemical knowledge. He is said to have been educated at
-Barcelona, under John Casamila, a celebrated professor of medicine.
-This place he was obliged to leave, in consequence of foretelling the
-death of Peter of Arragon. He went to Paris, and likewise travelled
-through Italy. He afterwards taught publicly in the University of
-Montpelier. His reputation as a physician became so great, that his
-attendance was solicited in dangerous cases by several kings, and
-even by the pope himself. He was skilled in all the sciences of his
-time, and was besides a proficient in Greek, Hebrew, and Arabic. When
-at Paris he studied astrology, and calculating the age of the world,
-he found that it was to terminate in the year 1335. The theologians
-of Paris exclaimed against this and several other of his opinions,
-and condemned our astrologer as a heretic. This obliged him to leave
-France; but the pope protected him. He died in the year 1313, on his
-way to visit Pope Clement V. who lay sick at Avignon. The following
-table exhibits a pretty full list of his works:
-
-  1. Antidotorium
-
-  2. De Vinis.
-
-  3. De Aquis Laxativis.
-
-  4. Rosarius Philosophorum.
-
-  5. Lumen Novum.
-
-  6. De Sigillis.
-
-  7. Flos Florum.
-
-  8. Epistolæ super Alchymia ad Regem Neapolitanum.
-
-  9. Liber Perfectionis Magisterii.
-
-  10. Succosa Carmina.
-
-  11. Questiones de Arte Transmutationis Metallorum.
-
-  12. Testamentum.
-
-  13. Lumen Luminum.
-
-  14. Practica.
-
-  15. Speculum Alchymiæ.
-
-  16. Carmen.
-
-  17. Questiones ad Bonifacium.
-
-  18. Semita Semitæ.
-
-  19. De Lapide Philosophorum.
-
-  20. De Sanguine Humano.
-
-  21. De Spiritu Vini, Vino Antimonii et Gemmorum Viribus.
-
-Perhaps the most curious of all these works is the _Rosarium_, which
-is intended as a complete compend of all the alchymy of his time.
-The first part of it on the theory of the art is plain enough; but
-the second part on the practice, which is subdivided into thirty-two
-chapters, and which professes to teach the art of making the
-philosopher’s stone, is in many places quite unintelligible to me.
-
-He considered, like his predecessors, mercury as a constituent of
-metals, and he professed a knowledge of the philosopher’s stone,
-which he could increase at pleasure. Gold and gold-water was, in his
-opinion, one of the most precious of medicines. He employed mercury in
-medicine. He seems to designate bismuth under the name _marcasite_. He
-was in the habit of preparing oil of turpentine, oil of rosemary, and
-spirit of rosemary, which afterwards became famous under the name of
-Hungary-water. These distillations were made in a glazed earthen vessel
-with a glass top and helm.
-
-His works were published at Venice in a single folio volume, in the
-year 1505. There were seven subsequent editions, the last of which
-appeared at Strasburg in 1613.
-
-6. John Isaac Hollandus and his countryman of the same name, were
-either two brothers or a father and son; it is uncertain which. For
-very few circumstances respecting these two laborious and meritorious
-men have been handed down to posterity. They were born in the
-village of Stolk in Holland, it is supposed in the 13th century.
-They certainly were after Arnoldus de Villa Nova, because they refer
-to him in their writings. They wrote many treatises on chemistry,
-remarkable, considering the time when they wrote, for clearness and
-precision, describing their processes with accuracy, and even giving
-figures of the instruments which they employed. This makes their books
-intelligible, and they deserve attention because they show that various
-processes, generally supposed of a more modern date were known to them.
-Their treatises are written partly in Latin and partly in German. The
-following list contains the names of most of them:
-
-  1. Opera Vegetabilia ad ejus alia Opera Intelligenda
-  Necessaria.
-
-  2. Opera Mineralia seu de Lapide Philosophico
-  Libri duo.
-
-  3. Tractat vom stein der Weisen.
-
-  4. Fragmenta Quædam Chemica.
-
-  5. De Triplice Ordine Elixiris et Lapidis Theorea.
-
-  6. Tractatus de Salibus et Oleis Metallorum.
-
-  7. Fragmentum de Opere Philosophorum.
-
-  8. Rariores Chemiæ Operationes.
-
-  9. Opus Saturni.
-
-  10. De Spiritu Urinæ.
-
-  11. Hand der Philosopher.
-
-Olaus Borrichius complains that their _opera mineralia_ abound with
-processes; but that they are ambiguous, and such that nothing certain
-can be deduced from them even after much labour. Hence they draw on
-the unwary tyro from labour to labour. I am disposed myself to draw a
-different conclusion, from what I have read of that elaborate work.
-It is true that the processes which profess to make the philosopher’s
-stone, are fallacious, and do not lead to the manufacture of gold,
-as the author intended, and expected: but it is a great deal when
-alchymistical processes are delivered in such intelligible language
-that you know the substances employed. This enables us easily to see
-the results in almost every case, and to know the new compounds which
-were formed during a vain search for the philosopher’s stone. Had the
-other alchymists written as plainly, the absurdity of their researches
-would have been sooner discovered, and thus a useless or pernicious
-investigation would have sooner terminated.
-
-7. Basil Valentine is said to have been born about the year 1394, and
-is, perhaps, the most celebrated of all the alchymists, if we except
-Paracelsus. He was a Benedictine monk, at Erford, in Saxony. If we
-believe Olaus Borrichius, his writings were enclosed in the wall of
-a church at Erford, and were discovered long after his death, in
-consequence of the wall having been driven down by a thunderbolt. But
-this story is not well authenticated, and is utterly improbable. Much
-of his time seems to have been taken up in the preparation of chemical
-medicines. It was he that first introduced antimony into medicine;
-and it is said, though on no good authority, that he first tried the
-effects of antimonial medicines upon the monks of his convent, upon
-whom it acted with such violence that he was induced to distinguish the
-mineral from which these medicines had been extracted, by the name of
-_antimoine_ (hostile to monks). What shows the improbability of this
-story is, that the works of Basil Valentine, and in particular his
-Currus triumphalis Antimonii, were written in the German language. Now
-the German name for antimony is not _antimoine_, but _speissglass_. The
-Currus triumphalis Antimonii was translated into Latin by Kerkringius,
-who published it, with an excellent commentary, at Amsterdam, in 1671.
-
-Basil Valentine writes with almost as much virulence against the
-physicians of his time, as Paracelsus himself did afterwards. As no
-particulars of his life have been handed down to posterity, I shall
-satisfy myself with giving a catalogue of his writings, and then
-pointing out the most striking chemical substances with which he was
-acquainted.
-
-The books which have appeared under the name of Basil Valentine, are
-very numerous; but how many of them were really written by him, and how
-many are supposititious, is extremely doubtful. The following are the
-principal:
-
-  1. Philosophia Occulta.
-
-  2. Tractat von naturlichen und ubernaturlichen
-  Dingen; auch von der ersten tinctur, Wurzel und
-  Geiste der Metallen.
-
-  3. Von dern grossen stein der Uhralten.
-
-  4. Vier tractatlein vom stein der Weisen.
-
-  5. Kurzer anhang und klare repetition oder Wiederholunge
-  vom grosen stein der Uhralten.
-
-  6. De prima Materia Lapidis Philosophici.
-
-  7. Azoth Philosophorum seu Aureliæ occultæ de
-  Materia Lapidis Philosophorum.
-
-  8. Apocalypsis Chemica.
-
-  9. Claves 12 Philosophiæ.
-
-  10. Practica.
-
-  11. Opus præclarum ad utrumque, quod pro Testamento
-  dedit Filio suo adoptivo.
-
-  12. Letztes Testament.
-
-  13. De Microcosmo.
-
-  14. Von der grosen Heimlichkeit der Welt und ihrer
-  Arzney.
-
-  15. Von der Wissenschaft der sieben Planeten.
-
-  16. Offenbahrung der verborgenen Handgriffe.
-
-  17. Conclusiones or Schlussreden.
-
-  18. Dialogus Fratris Alberti cum Spiritu.
-
-  19. De Sulphure et fermento Philosophorum.
-
-  20. Haliographia.
-
-  21. Triumph wagen Antimonii.
-
-  22. Einiger Weg zur Wahrheit.
-
-  23. Licht der Natur.
-
-The only one of these works that I have read with care, is
-Kerkringius’s translation and commentary on the Currus triumphalis
-Antimonii. It is an excellent book, written with clearness and
-precision, and contains every thing respecting antimony that was known
-before the commencement of the 19th century. How much of this is owing
-to Kerkringius I cannot say, as I have never had an opportunity of
-seeing a copy of the original German work of Basil Valentine.
-
-Basil Valentine, like Isaac Hollandus, was of opinion that the metals
-are compounds of salt, sulphur, and mercury. The philosopher’s stone
-was composed of the same ingredients. He affirmed, that there exists
-a great similarity between the mode of purifying gold and curing the
-diseases of men, and that antimony answers best for both. He was
-acquainted with arsenic, knew many of its properties, and mentions the
-red compound which it forms with sulphur. Zinc seems to have been known
-to him, and he mentions bismuth, both under its own name, and under
-that of _marcasite_. He was aware that manganese was employed to render
-glass colourless. He mentions nitrate of mercury, alludes to corrosive
-sublimate, and seems to have known the red oxide of mercury. It would
-be needless to specify the preparations of antimony with which he was
-acquainted; scarcely one was unknown to him which, even at present,
-exists in the European Pharmacopœias. Many of the preparations of lead
-were also familiar to him. He was aware that lead gives a sweet taste
-to vinegar. He knew sugar of lead, litharge, yellow oxide of lead,
-white carbonate of lead; and mentions that this last preparation was
-often adulterated in his time. He knew the method of making green
-vitriol, and the double chloride of iron and ammonia. He was aware
-that iron could be precipitated from its solution by potash, and that
-iron has the property of throwing down copper. He was aware that tin
-sometimes contains iron, and ascribed the brittleness of Hungarian
-iron to copper. He knew that oxides of copper gave a green colour to
-glass; that Hungarian silver contained gold; that gold is precipitated
-from aqua regia by mercury, in the state of an amalgam. He mentions
-fulminating gold. But the important facts contained in his works are
-so numerous, while we are so uncertain about the genuineness of the
-writings themselves, that it will scarcely be worth while to proceed
-further with the catalogue.
-
-Thus I have brought the history of alchymy to the time of Paracelsus,
-when it was doomed to undergo a new and important change. It will be
-better, therefore, not to pursue the history of alchymy further, but
-to take up the history of true chemistry; and in the first place to
-endeavour to determine what chemical facts were known to the Ancients,
-and how far the science had proceeded to develop itself before the time
-of Paracelsus.
-
-
-
-
-CHAPTER II.
-
-OF THE CHEMICAL KNOWLEDGE POSSESSED BY THE ANCIENTS.
-
-
-Notwithstanding the assertions of Olaus Borrichius, and various other
-writers who followed him on the same side, nothing is more certain
-than that the ancients have left no chemical writings behind them,
-and that no evidence whatever exists to prove that the science of
-chemistry was known to them. Scientific chemistry, on the contrary,
-took its origin from the collection and comparison of the chemical
-facts, made known by the practice and improvement of those branches
-of manufactures which can only be conducted by chemical processes.
-Thus the smelting of ores, and the reduction of the metals which
-they contain, is a chemical process; because it requires, for its
-success, the separation of certain bodies which exist in the ore
-chemically combined with the metals; and it cannot be done, except
-by the application or mixture of a new substance, having an affinity
-for these substances, and capable, in consequence, of separating them
-from the metal, and thus reducing the metal to a state of purity. The
-manufacture of glass, of soap, of leather, are all chemical, because
-they consist of processes, by means of which bodies, having an affinity
-for each other, are made to unite in chemical combination. Now I shall
-in this chapter point out the principal chemical manufactures that
-were known to the ancients, that we may see how much they contributed
-towards laying the foundation of the science. The chief sources of our
-information on this subject are the writings of the Greeks and Romans.
-Unfortunately the arts and manufactures stood in a very different
-degree of estimation among the ancients from what they do among the
-moderns. Their artists and manufacturers were chiefly slaves. The
-citizens of Greece and Rome devoted themselves to politics or war. Such
-of them as turned their attention to learning confined themselves to
-_oratory_, which was the most fashionable and the most important study,
-or to history, or poetry. The only scientific pursuits which ever
-engaged their attention, were politics, ethics, and mathematics. For,
-unless Archimedes is to be considered as an exception, scarcely any
-of the numerous branches of physics and mechanical philosophy, which
-constitute so great a portion of modern science, even attracted the
-attention of the ancients.
-
-In consequence of the contemptible light in which all mechanical
-employments were viewed by the ancients, we look in vain in any of
-their writings for accurate details respecting the processes which
-they followed. The only exception to this general neglect and contempt
-for all the arts and trades, is Pliny the Elder, whose object, in
-his natural history, was to collect into one focus, every thing that
-was known at the period when he lived. His work displays prodigious
-reading, and a vast fund of erudition. It is to him that we are chiefly
-indebted for the knowledge of the chemical arts which were practised
-by the ancients. But the low estimation in which these arts were held,
-appears evident from the wonderful want of information which Pliny so
-frequently displays, and the erroneous statements which he has recorded
-respecting these processes. Still a great deal may be drawn from the
-information which has been collected and transmitted to us by this
-indefatigable natural historian.
-
-I.--The ancients were acquainted with SEVEN METALS;
-namely, gold, silver, mercury, copper, iron, tin, and lead. They knew
-and employed various preparations of zinc, and antimony, and arsenic;
-though we have no evidence that these bodies were known to them in the
-metallic state.
-
-1. Gold is spoken of in the second chapter of Genesis as existing and
-familiarly known before the flood.
-
-“The name of the first is Pison; that is it which encompasseth the
-whole land of Havilah, where there is gold. And the gold of that
-land is good: there is bdellium and the onyx-stone.” The Hebrew word
-for gold, בהז (_zahav_) signifies to be clear, to shine; alluding,
-doubtless, to the brilliancy of that metal. The term _gold_ occurs
-frequently in the writings of Moses, and the metal must have been in
-common use among the Egyptians, when that legislator led the children
-of Israel out of Egypt.[28] Gold is found in the earth almost always in
-a native state. There can be no doubt that it was much more abundant
-on the surface of the earth, and in the beds of rivers in the early
-periods of society, than it is at present: indeed this is obvious,
-from the account which Pliny gives of the numerous places in Asia and
-Greece, and other European countries, where gold was found in his time.
-
-[28] Exodus xi. 2--xxv. 11, 12, 13, 17, 18, 24, 25, 26--xxviii.
-8--xxxii. 2, &c.
-
-Gold, therefore, could hardly fail to attract the attention of the
-very first inhabitants of the globe; its beauty, its malleability, its
-indestructibility, would give it value: accident would soon discover
-the possibility of melting it by heat, and thus of reducing the grains
-or small pieces of it found on the surface of the earth into one large
-mass. It would be speedily made into ornaments and utensils of various
-kinds, and thus gradually would come into common use. This we find
-to have occurred in America, when it was discovered by Columbus.
-The inhabitants of the tropical parts of that vast continent were
-familiarly acquainted with gold; and in Mexico and Peru it existed in
-great abundance; indeed the natives of these countries seem to have
-been acquainted with no other metal, or at least no other metal was
-brought into such general use, except silver, which in Peru was, it is
-true, still more common than gold.
-
-Gold, then, was probably the first metal with which man became
-acquainted; and that knowledge must have preceded the commencement of
-history, since it is mentioned as a common and familiar substance in
-the Book of Genesis, the oldest book in existence, of the authenticity
-of which we possess sufficient evidence. The period of leading the
-children of Israel out of Egypt by Moses, is generally fixed to
-have been one thousand six hundred and forty-eight years before the
-commencement of the Christian era. So early, then, we are certain,
-that not only gold, but the other six malleable metals known to the
-ancients, were familiar to the inhabitants of Egypt. The Greeks ascribe
-the discovery of gold to the earliest of their heroes. According to
-Pliny, it was discovered on Mount Pangæus by Cadmus, the Phœnician:
-but Cadmus’s voyage into Greece was nearly coeval with the exit of
-the Israelites out of Egypt, at which time we learn from Moses that
-gold was in common use in Egypt. All that can be meant, then, is, that
-Cadmus first discovered gold in Greece; not that he made mankind first
-acquainted with it. Others say that Thoas and Eaclis, or Sol, the son
-of Oceanus, first found gold in Panchaia. Thoas was a contemporary
-of the heroes of the Trojan war, or at least was posterior to the
-Argonautic expedition, and consequently long posterior to Moses and the
-departure of the children of Israel from Egypt.
-
-2. Silver also was not only familiarly known to the Egyptians in
-the time of Moses, but, as we learn from Genesis, was coined into
-money before Joseph was set over the land of Egypt by Pharaoh, which
-happened one thousand eight hundred and seventy-two years before the
-commencement of the Christian era, and consequently two hundred and
-twenty-four years before the departure of the children of Israel out of
-Egypt.
-
-“And Joseph gathered up all the money that was found in the land of
-Egypt, and in the land of Canaan, for the corn which they bought; and
-Joseph brought the money into Pharaoh’s house.”[29] The Hebrew word ףםכ
-(_keseph_), translated _money_, signifies silver, and was so called
-from its pale colour. Silver occurs in many other passages of the
-writings of Moses.[30] The Greeks inform us, that Erichthonius the
-Athenian, or Ceacus, were the discoverers of silver; but both of these
-individuals were long posterior to the time of Joseph.
-
-[29] Genesis xlvii. 14.
-
-[30] For example, Exodus xi. 2--xxvi. 19, 21--xxvii. 10, 11, 17, &c.
-
-Silver, like gold, occurs very frequently in the metallic state. This,
-no doubt, was a still more frequent occurrence in the early ages of the
-world; it would therefore attract the attention of mankind as early as
-gold, and for the same reason. It is very ductile, very beautiful, and
-much more easily fused than gold: it would be therefore more easily
-reduced into masses, and formed into different utensils and ornaments
-than even gold itself. The ores of it which occur in the earth are
-heavy, and would therefore draw the attention of even rude men to them:
-they have, most of them at least, the appearance of being metallic, and
-the most common of them may be reduced to the state of metallic silver,
-simply by keeping them a sufficient time in fusion. Accordingly we find
-that the Peruvians, before they were overrun by the Spaniards, had made
-themselves acquainted with the mode of digging out and smelting the
-ores of silver which occur in their country, and that many of their
-most common utensils were made of that metal.
-
-Silver and gold approached each other nearer in value among the
-ancients than at present: an ounce of fine gold was worth from ten
-to twelve ounces of fine silver, the variation depending upon the
-accidental relation of the supply of both metals. But after the
-discovery of America, the quantity of silver found in that continent,
-especially in Mexico, was so great, compared with that of the gold
-found, that silver became considerably cheaper; so that an ounce of
-fine gold came to be equivalent to about fourteen ounces and a half
-of fine silver. Of course these relative values have fluctuated a
-little according to the abundance of the supply of silver. Though the
-revolution in the Spanish American colonies has considerably diminished
-the supply of silver from the mines, that deficiency seems to have been
-supplied by other ways, and thus the relative proportion between the
-value of gold and silver has continued nearly unaltered.
-
-3. That copper must have been known in the earliest ages of society,
-is sufficiently evident. It occurs frequently native, and could not
-fail to attract the attention of mankind, from its colour, weight, and
-malleability. It would not be difficult to fuse it even in the rudest
-ages: and when melted into masses, as it is malleable and ductile, it
-would not require much skill to convert it into useful and ornamental
-utensils. The Hebrew word תשחנ (_nechooshat_) translated _brass_,
-obviously means _copper_. We have the authority of the Book of Genesis
-to satisfy us that copper was known before the flood, and probably as
-early as either silver or gold.
-
-“And Zillah, she also bore Tubal-cain, an instructor of every artificer
-in brass (_copper_) and iron.”[31]
-
-[31] Genesis iv. 22.
-
-The word _copper_ occurs in many other passages of the writings of
-Moses.[32] That the Hebrew word translated _brass_ must have meant
-copper is obvious, from the following passage: “Out of whose hills
-thou mayest dig brass.”[33] Brass does not exist in the earth, nor any
-ore of it, it is always made artificially; it must therefore have been
-copper, or an ore of copper, that was alluded to by Moses.
-
-[32] For example, Exodus xxvii. 2, 3, 4, 6, 10, 11, 17, 18, 19--xxx.
-18, &c. Numbers xxi. 9.
-
-[33] Deut. viii. 9.
-
-Copper must have been discovered and brought into common use long
-before iron or steel; for Homer represents his heroes of the Trojan war
-as armed with swords, &c. of copper. Copper itself is too soft to be
-made into cutting instruments; but the addition of a little tin gives
-it the requisite hardness. Now we learn from the analyses of Klaproth,
-that the copper swords of the ancients were actually hardened by the
-addition of tin.[34]
-
-[34] Beitrage, vi. 81.
-
-Copper was the metal in common use in the early part of the Roman
-commonwealth. Romulus coined copper money alone. Numa established a
-college of workers in copper (_ærariorum fabrum_).[35]
-
-[35] Plinii Hist. Nat. xxxiv. 1.
-
-The Latin word _æs_ sometimes signifies copper, and sometimes brass.
-It is plain from what Pliny says on the subject, that he did not know
-the difference between copper and brass; he says, that an ore of _æs_
-occurs in Cyprus, called _chalcitis_, where _æs_ was first discovered.
-Here _æs_ obviously means copper. In another place he says, that _æs_
-is obtained from a mineral called _cadmia_. Now from the account of
-cadmia by Pliny and Dioscorides, there cannot be a doubt that it is
-the ore to which the moderns have given the name of _calamine_, by
-means of which brass is made. It is sometimes a silicate and sometimes
-a carbonate of zinc; for both of these ores are confounded together
-under the name of cadmia, and both are employed in the manufacture of
-brass.
-
-Solinus says, that _æs_ was first made at Chalcis, a town in Eubœa.
-Hence the Greek name, χαλκος (_chalkos_), by which copper was
-distinguished.
-
-The proper name for brass, by which is meant an alloy of copper and
-zinc, was _aurichalcum_, or golden, or yellow copper. Pliny says,
-that long before his time, the ore of aurichalcum was exhausted, so
-that no more of that beautiful alloy was made. Are we to conclude
-from this, that there once existed an ore consisting of calamine and
-ore of copper, mixed or united together? After the exhaustion of the
-aurichalcum mine, the _salustianum_ became the most famous; but it soon
-gave place to the _livianum_, a copper-mine in Gaul, named after Livia,
-the wife of Augustus. Both these mines were exhausted in the time of
-Pliny. The _æs marianum_, or copper of Cordova, was the most celebrated
-in his time. This last _æs_, he says, absorbs most cadmia, and acquires
-the greatest resemblance to aurichalcum. We see from this, that in
-Pliny’s time brass was made artificially, and by a process similar to
-that still followed by the moderns.
-
-The most celebrated alloy of copper among the ancients, was the _æs
-corinthium_, or Corinthian copper, formed accidentally, as Pliny
-informs us, during the burning of Corinth by Mummius in the year 608,
-after the building of Rome, or one hundred and forty-five years before
-the commencement of the Christian era. There were four kinds of it,
-of which Pliny gives the following description; not, however, very
-intelligible:
-
-  1. White. It resembled silver much in its lustre,
-  and contained an excess of that metal.
-
-  2. Red. In this kind there is an excess of gold.
-
-  3. In the third kind, gold, silver, and copper are
-  mixed in equal proportions.
-
-  4. The fourth kind is called _hepatizon_, from its
-  having a liver colour. It is this colour which gives it
-  its value.[36]
-
-[36] Plinii Hist. Nat. xxxiv. 2.
-
-Copper was put by the ancients to almost all the uses to which it is
-put by the moderns. One of the great sources of consumption was bronze
-statues, which were first introduced into Rome after the conquest of
-Asia Minor. Before that time, the statues of the Romans were made of
-wood or stoneware. Pliny gives various formulas for making bronze for
-statues. Of these it may be worth while to put down the most material.
-
-1. To new copper add a third part of old copper. To every hundred
-pounds of this mixture, twelve pounds and a half of tin[37] are added,
-and the whole melted together.
-
-[37] Pliny’s phrase is _plumbum argentorium_. But that the addition was
-tin, and consequently that plumbum argentorium meant tin, we have the
-evidence of Klaproth, who analyzed several of these bronze statues, and
-found them composed of copper, lead, and tin.
-
-2. Another kind of bronze for statues was formed, by melting together
-
-  100lbs. copper,
-   10lbs. lead,
-    5lbs. tin.
-
-3. Their copper-pots for boiling consisted of 100lbs. of copper, melted
-with three or four pounds of tin.
-
-The four celebrated statues of horses which, during the reign of
-Theodosius II. were transported from Chio to Constantinople; and, when
-Constantinople was taken and plundered by the Crusaders and Venetians
-in 1204, were sent by Martin Zeno and set up by the doge, Peter Ziani,
-in the portal of St. Mark; were in 1798, transported by the French
-to Paris; and finally, after the overthrow of Buonaparte, and the
-restoration of the Bourbons in 1815, returned to Venice and placed
-upon their ancient pedestals. The metal of which these horses had been
-made was examined by Klaproth, and found by him composed of
-
-  Copper,      993
-  Tin,           7
-              ----
-              1000[38]
-
-[38] Beitrage, vi. 89.
-
-Klaproth also analyzed an ancient bronze statue in one of the German
-cabinets, and found it composed of
-
-  Copper,      916
-  Tin,          75
-  Lead,          9
-              ----
-              1000[39]
-
-[39] Beitrage, vi. 118. The statue in question was known by the name of
-“The Statue of Püstrichs,” at Sondershausen.
-
-Several other old brass and bronze pieces of metal, very ancient, but
-found in Germany, were also analyzed by Klaproth. The result of his
-analyses was as follows:
-
-The metal of which the altar of Krodo was made consisted of
-
-  Copper,       69
-  Zinc,         18
-  Lead,         13
-              ----
-               100[40]
-
-[40] Ibid., p. 127.
-
-The emperor’s chair, which had in the eleventh century been transported
-from Harzburg to Goslar, where it still remains, was found to be
-composed of
-
-  Copper,       92·5
-  Tin,           5
-  Lead,          2·5
-               ----
-                100[41]
-
-[41] Ibid., p. 132.
-
-Another piece of metal, which enclosed the high altar in a church in
-Germany, was composed of
-
-  Copper,      75
-  Tin,         12·5
-  Lead,        12·5
-              ----
-              100[42]
-
-[42] Ibid., p. 134.
-
-These analyses, though none of them corresponds exactly with the
-proportions given by Pliny, confirms sufficiently his general
-statement, that the bronze of the ancients employed for statues was
-copper, alloyed with lead and tin.
-
-Some of the bronze statues cast by the ancients were of enormous
-dimensions, and show decisively the great progress which had been made
-by them in the art of working and casting metals. The addition of the
-lead and tin would not only add greatly to the hardness of the alloy,
-but would at the same time render it more easily fusible. The bronze
-statue of Apollo, placed in the capitol at the time of Pliny, was
-forty-five feet high, and cost 500 talents, equivalent to about £50,000
-of our money. It was brought from Apollonia, in Pontus, by Lucullus.
-The famous statue of the sun at Rhodes was the work of Chares, a
-disciple of Lysippus; it was ninety feet high, was twelve years in
-making, and cost 300 talents (about £30,000). It was made out of the
-engines of war left by Demetrius when he raised the siege of Rhodes.
-After standing fifty-six years, it was overthrown by an earthquake.
-It lay on the ground 900 years, and was sold by Mauvia, king of the
-Saracens, to a merchant, who loaded 900 camels with the fragments of it.
-
-Copper was introduced into medicine at rather an early period of
-society, and various medicinal preparations of it are described by
-Dioscorides and Pliny. It remains for us to notice the most remarkable
-of these. Pliny mentions an institution, to which he gives the name
-of _Seplasia_; the object of which was, to prepare medicines for the
-use of medical men. It seems, therefore, to have been similar to our
-apothecaries’ shops of the present day. Pliny reprobates the conduct of
-the persons who had the charge of these Seplasiæ in his time. They were
-in the habit of adulterating medicines to such a degree, that nothing
-good or genuine could be procured from them.[43]
-
-[43] Plinii Hist. Nat. xxxiv. 11.
-
-Both the oxides of copper were known to the ancients, though they were
-not very accurately distinguished from each other: they were known by
-the names _flos æris_ and _scoria æris_, or _squama æris_. They were
-obtained by heating bars of copper red-hot and letting them cool,
-exposed to the air. What fell off during the cooling was the _flos_,
-what was driven off by blows of a hammer was the _squama_ or _scoria
-æris_. It is obvious, that all these substances were nearly of the same
-nature, and that they were in reality mixtures of the black and red
-oxides of copper.
-
-_Stomoma_ seems also to have been an oxide of copper, which was
-gradually formed upon the surface of the metal, when it was kept in a
-state of fusion.
-
-These oxides of copper were used as external applications in cases of
-polypi of the nose, diseases of the anus, ear, mouth, &c., seemingly as
-escharotics.
-
-_Ærugo_, verdigris, was a subacetate of copper, doubtless often mixed
-with subacetate of zinc, as not only copper but brass also was used for
-preparing it. The mode of preparing this substance was similar to the
-process still followed. Whether verdigris was employed as a paint by
-the ancients does not appear; for Pliny takes no notice of any such use
-of it.
-
-_Chalcantum_, called also _atramentum sutorium_, was probably a mixture
-of sulphate of copper and sulphate of iron. Pliny’s account of the
-mode of procuring it is too imperfect to enable us to form precise
-ideas concerning it; but it was crystallized on strings, which were
-extended for the purpose in the solution: its colour was blue, and it
-was transparent like glass. This description might apply to sulphate of
-copper; but as the substance was used for blackening leather, and on
-that account was called _atramentum sutorium_, it is obvious that it
-must have contained also _sulphate of iron_.
-
-_Chalcitis_ was the name for an ore of copper. The account given of it
-by Pliny agrees best with copper pyrites, which is now known to be a
-_sulphur salt_, composed of one atom of sulphide of copper (the acid)
-united to one atom of sulphide of iron (the base). Pliny informs us,
-that it is a mixture of _copper_, _misy_, and _sory_: its colour is
-that of honey. By age, he says, it changes into sory. I think it most
-probable that native sory, of which Pliny speaks, was sulphuret of
-copper, and artificial sory sulphate of copper. The native sory is said
-to constitute black veins in chalcitis. Pliny’s description of misy
-(μισυ) best agrees with copper pyrites. Dioscorides describes it as
-hard, as having the colour of gold, and as shining like a star.[44] All
-this agrees pretty well with copper pyrites.
-
-[44] Lib. v. c. 117.
-
-_Scoleca_ (so called because it assumed the shape of a worm) was formed
-by triturating alumen, carbonate of soda, and white vinegar, till the
-matter became green. It was probably a mixture of sulphate of soda,
-acetate of soda, acetate of alumina, and acetate of copper, probably
-with more or less oxide of copper, &c., depending upon the proportions
-of the respective constituents employed.
-
-Such are the preparations of copper, employed by the ancients. They
-were only used as external applications, partly as escharotics, and
-partly to induce ulcers to put on a healthy appearance. It does not
-appear that copper was ever used by the ancients as an internal remedy.
-
-4. Though _zinc_ in the metallic state was unknown to the ancients,
-yet as they knew some of its ores, and employed preparations of it
-in medicine, and were in the habit of alloying copper with it, and
-converting it into brass, it will be proper to state here what was
-known to them concerning it.
-
-Pliny nowhere makes us acquainted with the process by which copper was
-converted into brass, nor does he seem to have been acquainted with it;
-but from several facts incidentally mentioned by him, it is obvious
-that their process was similar to that which is followed at present
-by modern brass-makers. The copper in grains is mixed with a certain
-quantity of calamine (cadmia) and charcoal, and exposed for some time
-to a moderate heat in a covered crucible. The calamine is reduced to
-the metallic state, and imbibed by the copper grains. When the copper
-is thus converted into brass, the temperature is raised sufficiently
-high to melt the whole: it is then poured out and cast into a slab or
-ingot.
-
-The cadmia employed by the ancients in medicine was not calamine,
-but oxide of zinc, which sublimed during the fusion of brass in an
-open vessel. It was distinguished by a variety of names, according to
-the state in which it was obtained: the lighter portion was called
-_capnitis_. _Botryitis_ was the name of the portion in the interior of
-the chimney: the name was derived from some resemblance which it was
-supposed to have to a bunch of grapes. It had two colours, ash and red.
-The red variety was reckoned best. This red colour it might derive from
-some copper mixed with it, but more probably from iron; for a small
-quantity of oxide of iron is sufficient to give oxide of zinc a rather
-beautiful red colour. The portion collected on the sides of the furnace
-was called _placitis_: it constituted a crust, and was distinguished by
-different names, according to its colour; _onychitis_ when it was blue
-externally, but spotted internally: _ostracitis_, when it was black
-and dirty-looking. This last variety was considered as an excellent
-application to wounds. The best cadmia in Pliny’s time was furnished
-by the furnaces of the Isle of Cyprus: it was used as an external
-application in ulcers, inflammations, eruptions, &c., so that its
-use in medicine was pretty much the same as at present. Sulphate and
-acetate of zinc were unknown to the ancients. No attempt seems to have
-been made by them to introduce any preparations of zinc as internal
-medicines.
-
-_Pompholyx_ was the name given to oxide of zinc, sublimed by the
-combustion of the zinc which exists in brass. _Spodos_ seems to have
-been a mixture of oxides of zinc and copper. There were different
-varieties of it distinguished by various names.[45]
-
-[45] See Plinii Hist. Nat. xxxiv. 13.
-
-5. Iron exists very rarely in the earth in a metallic state, but most
-commonly in the state of an oxide; and the processes necessary to
-extract metallic iron from these ores are much more complicated, and
-require much greater skill, than the reduction of gold, silver, or
-copper from their respective ores. This would lead us to expect that
-iron would have been much longer in being discovered than the three
-metals whose names have been just given. But we learn from the Book of
-Genesis that iron, like copper and gold, was known before the flood,
-Tubal-cain being represented as an artificer in copper and iron.[46]
-The Hebrew word for iron, לזרב (_barzel_), is said to be derived from
-רב (_bar_), bright, לזנ (_nazal_), to melt; and would lead one to the
-suspicion, that it referred to _cast_ iron rather than _malleable_
-iron. It is possible that in these early times native iron may have
-existed as well as native gold, silver, and copper; and in this way
-Tubal-cain may have become acquainted with the existence and properties
-of this metal. In the time of Moses, who was learned in all the wisdom
-of the Egyptians, iron must have been in common use in Egypt: for
-he mentions furnaces for working iron;[47] ores from which it was
-extracted;[48] and tells us that swords,[49] knives,[50] axes,[51]
-and tools for cutting stones,[52] were then made of that metal. Now
-iron in its pure metallic state is too soft to be applied to these
-uses: it is obvious, therefore, that in Moses’s time, not only iron
-but steel also must have been in common use in Egypt. From this we see
-how much further advanced the Egyptians were than the Greeks in the
-knowledge of the manufacture of this most important metal: for during
-the Trojan war, which was several centuries after the time of Moses,
-Homer represents his heroes as armed with swords of copper, hardened
-by tin, and as never using any weapons of iron whatever. Nay, in
-such estimation was it held, that Achilles, when he celebrated games
-in honour of Patrocles, proposes a ball of iron as one of his most
-valuable prizes.[53]
-
-[46] Genesis iv. 22.
-
-[47] Deut. iv. 20.
-
-[48] Deut. viii. 9.
-
-[49] Numbers xxxv. 16.
-
-[50] Levit. i. 17.
-
-[51] Deut. xviii. 5.
-
-[52] Deut. xxvii. 5.
-
-[53] Iliad, lib. xxiii. l. 826.
-
-    “Then hurl’d the hero, thundering on the ground,
-    A mass of iron (an enormous round),
-    Whose weight and size the circling Greeks admire,
-    Rude from the furnace and but shaped by fire.
-    This mighty quoit Ætion wont to rear,
-    And from his whirling arm dismiss’d in air;
-    The giant by Achilles slain, he stow’d
-    Among his spoils this memorable load.
-    For this he bids those nervous artists vie
-    That teach the disk to sound along the sky.
-    Let him whose might can hurl this bowl, arise;
-    Who farthest hurls it, takes it as his prize:
-    If he be one enrich’d with large domain
-    Of downs for flocks and arable for grain,
-    Small stock of iron needs that man provide,
-    His hinds and swains whole years shall be supplied
-    From hence: nor ask the neighbouring city’s aid
-    For ploughshares, wheels, and all the rural trade.”
-
-The mass of iron was large enough to supply a shepherd or a ploughman
-with iron for five years. This circumstance is a sufficient proof of
-the high estimation in which iron was held during the time of Homer.
-Were a modern poet to represent his hero as holding out a large lump
-of iron as a prize, and were he to represent this prize as eagerly
-contended for by kings and princes, it would appear to us perfectly
-ridiculous.
-
-Hesiod informs us, that the knowledge of iron was brought over from
-Phrygia to Greece by the Dactyli, who settled in Crete during the reign
-of Minos I., about 1431 years before the commencement of the Christian
-era, and consequently about sixty years before the departure of the
-children of Israel from Egypt: and it does not appear, that in Homer’s
-time, which was about five hundred years later, the art of smelting
-iron had been so much improved, as to enable men to apply it to the
-common purposes of life, as had long before been done by the Egyptians.
-The general opinion of the ancients was, that the method of smelting
-iron ore had been brought to perfection by the Chalybes, a small
-nation situated near the Black Sea,[54] and that the name _chalybs_,
-occasionally used for steel, was derived from that people.
-
-[54] Xenophon’s Anabasis, v. 5.
-
-Pliny informs us, that the ores of iron are scattered very profusely
-almost every where: that they exist in Elba; that there was a mountain
-in Cantabria composed entirely of iron ore; and that the earth in
-Cappadocia, when watered from a certain river, is converted into
-iron.[55] He gives no account of the mode of smelting iron ores; nor
-does he appear to have been acquainted with the processes; for he says
-that iron is reduced from its ore precisely in the same way as copper
-is. Now we know, that the processes for smelting copper and iron are
-quite different, and founded upon different principles. He says,
-that in his time many different kinds of iron existed, and they were
-_stricturæ_, in Latin _a stringenda acie_.
-
-[55] Plinii Hist. Nat. xxxiv. 14.
-
-That steel was well known and in common use when Pliny wrote is obvious
-from many considerations; but he seems to have had no notion of what
-constituted the difference between iron and steel, or of the method
-employed to convert iron into steel. In his opinion it depended upon
-the nature of the water, and consisted in heating iron red-hot, and
-plunging it, while in that state, into certain waters. The waters at
-Bilbilis and Turiasso, in Spain, and at Comum, in Italy, possessed this
-extraordinary virtue. The best steel in Pliny’s time came from China;
-the next best, in point of quality, was manufactured in Parthia.
-
-It would appear, that at Noricum steel was manufactured directly from
-the ore of iron. This process was perfectly practicable, and it is said
-still to be practised in certain cases.
-
-The ancients were acquainted with the method of rendering iron, or
-rather steel, magnetic; as appears from a passage in the fourteenth
-chapter of the thirty-fourth book of Pliny. Magnetic iron was
-distinguished by the name of _ferrum vivum_.
-
-When iron is dabbed over with alumen and vinegar it becomes like
-copper, according to Pliny. Cerussa, gypsum, and liquid pitch, keep it
-from rusting. Pliny was of opinion that a method of preventing iron
-from rusting had been once known, but had been lost before his time.
-The iron chains of an old bridge over the Euphrates had not rusted in
-Pliny’s time; but a few new links, which had been added to supply the
-place of some that had decayed, were become rusty.
-
-It would appear from Pliny, that the ancients made use of something
-very like _tractors_; for he says that pain in the side is relieved by
-holding near it the point of a dagger that has wounded a man. Water in
-which red-hot iron had been plunged was recommended as a cure for the
-dysentery; and the actual cautery with red-hot iron, Pliny informs us,
-prevents hydrophobia, when a person has been bitten by a mad dog.
-
-Rust of iron and scales of iron were used by the ancients as astringent
-medicines.
-
-6. Tin, also, must have been in common use in the time of Moses; for it
-is mentioned without any observation as one of the common metals.[56]
-And from the way in which it is spoken of by Isaiah and Ezekiel, it is
-obvious that it was considered as of far inferior value to silver and
-gold. Now tin, though the ores of it where it does occur are usually
-abundant, is rather a scarce metal: that is to say, there are but few
-spots on the face of the earth where it is known to exist. Cornwall,
-Spain, in the mountains of Gallicia, and the mountains which separate
-Saxony and Bohemia, are the only countries in Europe where tin occurs
-abundantly. The last of these localities has not been known for five
-centuries. It was from Spain and from Britain that the ancients were
-supplied with tin; for no mines of tin exist, or have ever been known
-to exist, in Africa or Asia, except in the East Indies. The Phœnicians
-were the first nation which carried on a great trade by sea. There
-is evidence that at a very early period they traded with Spain and
-with Britain, and that from these countries they drew their supplies
-of tin. It was doubtless the Phœnicians that supplied the Egyptians
-with this metal. They had imbibed strongly a spirit of monopoly; and
-to secure the whole trade of tin they carefully concealed the source
-from which they drew that metal. Hence, doubtless, the reason why the
-Grecian geographers, who derived their information from the Phœnicians,
-represented the Insulæ Cassiterides, or tin islands, as a set of
-islands lying off the north coast of Spain. We know that in fact the
-Scilly islands, in these early ages, yielded tin, though doubtless the
-great supply was drawn from the neighbouring province of Cornwall.
-It was probably from these islands that the Greek name for _tin_ was
-derived (κασσιτερος). Even Pliny informs us, that in his time tin was
-obtained from the Cassiterides, and from Lusitania and Gallicia. It
-occurs, he says, in grains in alluvial soil, from which it is obtained
-by washing. It is in black grains, the metallic nature of which is only
-recognisable by the great weight. This is a pretty accurate description
-of _stream tin_, which we know formerly constituted the only ore of
-that metal wrought in Cornwall. He says that the ore occurs also along
-with grains of gold; that it is separated from the soil by washing
-along with the grains of gold, and afterwards smelted separately.
-
-[56] Numbers xxxi. 22.
-
-Pliny gives no particulars about the mode of reducing the ore of tin to
-the metallic state; nor is it at all likely that he was acquainted with
-the process.
-
-The Latin term for tin was _plumbum album_. _Stannum_ is also used by
-Pliny; but it is impossible to understand the account which he gives
-of it. There is, he says, an ore consisting of lead, united to silver.
-When this ore is smelted, the first metal that flows out is _stannum_.
-What flows next is _silver_. What remains in the furnace is _galena_.
-This being smelted, yields _lead_.
-
-Were we to admit the existence of an ore composed of lead and silver,
-it is obvious that no such products could be obtained by simply
-smelting it.
-
-Cassiteros, or tin, is mentioned by Homer; and, from the way in which
-the metal is said by him to have been used, it is obvious that in his
-time it bore a much higher price, and, consequently, was more valued
-than at present. In his description of the breastplate of Agamemnon, he
-says that it contained ten bands of steel, twelve of gold, and twenty
-of tin (κασσιτεροιο).[57] And in the twenty-third book of the Iliad
-(line 561), Achilles describes a copper breastplate surrounded with
-shining tin (φαεινου κασσιτεροιο). Pliny informs us, that in his time
-tin was adulterated by adding to it about one-third of white copper. A
-pound of tin, when Pliny lived, cost ten denarii. Now, if we reckon a
-denarius at 7¾_d._, with Dr. Arbuthnot, this would make a Roman pound
-of tin to cost 6_s._ 5½_d._ But, as the Roman pound was only equal to
-three-fourths of our avoirdupois pound, it is plain that in the time
-of Pliny an avoirdupois pound of tin was worth 8_s._ 7¼_d._, which is
-almost seven times the price of tin in the present day.
-
-[57] Iliad xi. 25.
-
-Tin, in the time of Pliny, was used for covering the inside of copper
-vessels, as it is at this day. And, no doubt, the process still
-followed is of the same nature as the process used by the ancients for
-tinning copper. Pliny remarks, with surprise, that copper thus tinned
-does not increase in weight. Now Bayen ascertained that a copper pan,
-nine inches in diameter, and three inches three lines in depth, when
-tinned, only acquired an additional weight of twenty-one grains. These
-measures and weights are French. When we convert them into English, we
-have a copper pan 9·59 inches in diameter, and 3·46 inches deep, which,
-when tinned, increased in weight 17·23 troy grains. Now the surface
-of the copper pan, thus tinned, was 176·468 square inches. Hence it
-follows, that a square inch of copper, when tinned, increases in weight
-only 0·097 grains. This increase is so small, that we may excuse Pliny,
-who probably had never seen the increase of weight determined, except
-by means of a rude Roman statera, for concluding that there was no
-increase of weight whatever.
-
-Tin was employed by the ancients for mirrors: but mirrors of silver
-were gradually substituted; and these in Pliny’s time had become so
-common, that they were even employed by female servants or slaves.
-
-That Pliny’s knowledge of the properties of tin was very limited, and
-far from accurate, is obvious from his assertion that _tin_ is less
-fusible than silver.[58] It is true that the ancients had no measure
-to determine the different degrees of heat; but as tin melts at a heat
-under redness, while silver requires a bright red heat to bring it into
-fusion, a single comparative trial would have shown him which was most
-fusible. This trial, it is obvious, had never been made by him.
-
-[58] Lib. xxxiv. c. 17.
-
-The ancients seem to have been ignorant of the method of tinning iron.
-At least, no reference to _tin plate_ is made by Pliny, or by any other
-ancient author, that I have had an opportunity of consulting.
-
-It would appear from Pliny, that both copper and brass were tinned by
-the Gauls at an early period. Tinned brass was called _æra coctilia_,
-and was so beautiful that it almost passed for silver. _Plating_ (or
-covering the metal with plates of silver), was gradually substituted
-for tinning; and finally _gilding_ took the place of plating. The
-trappings of horses, chariots, &c., were thus ornamented. Pliny nowhere
-gives a description of the process of plating; but there can be little
-doubt that it was similar to that at present practised. Gilding was
-accomplished by laying an amalgam of gold on the copper or brass, as at
-present.
-
-7. Lead appears also to have been in common use among the Egyptians,
-at the time of Moses.[59] It was distinguished among the Romans by
-the name of _plumbum nigrum_. In Pliny’s time the lead-mines existed
-chiefly in Spain and Britain. In Britain lead was so abundant, that it
-was prohibited to extract above a certain quantity in a year. The mines
-lay on the surface of the earth. Derbyshire was the county in which
-lead ores were chiefly wrought by the Romans. The rich mines in the
-north of England seem to have been unknown to them.
-
-[59] Numbers xxxi. 22.
-
-Pliny was of opinion that if a lead-mine, after being exhausted, be
-shut up for some time, the ore will be again renewed.
-
-In the time of Pliny leaden pipes were commonly used for conveying
-water. The vulgar notion that the ancients did not know that water will
-always rise in pipes as high as the source from which it proceeds, and
-that it was this ignorance which led to the formation of aqueducts,
-is quite unfounded. Nobody can read Pliny without seeing that this
-important fact was well known in his time.
-
-Sheet lead was also used in the time of Pliny, and applied to the same
-purposes as at present. But lead was much higher priced among the
-ancients than it is at present. Pliny informs us that its price was to
-that of tin as 7 to 10. Hence it must have sold at the rate of 6_s._
-0¼_d._ per pound. The present price of lead does not much exceed three
-halfpence the pound. It is therefore only 1-48th part of the price
-which it bore in the time of Pliny. This difference must be chiefly
-owing to the improvements made by the moderns in working the mines and
-smelting the ores of lead.
-
-Tin, in Pliny’s time, was used as a solder for lead. For this purpose
-it is well adapted, as it is so much easier smelted than lead. But when
-he says that lead is used also as a solder for tin, his meaning is not
-so clear. Probably he means an alloy of lead and tin, which, fusing at
-a lower point than tin, may be used to solder that metal. The addition
-of some bismuth reduces the fusing point materially; but that metal was
-unknown to the ancients.
-
-_Argentarium_ is an alloy of equal parts of lead and tin. _Tertiarium_,
-of two parts lead and one part tin. It was used as a solder.
-
-Some preparations of lead were used by the ancients in medicine, as we
-know from the description of them given us by Dioscorides and Pliny.
-These preparations consisted chiefly of protoxide of lead and lead
-reduced to powder, and partially oxidized by triturating it with water
-in a mortar. They were applied to ulcers, and employed externally as
-astringents.
-
-_Molybdena_ was also employed in medicine. Pliny says it was the same
-as galena. From his description it is obvious that it was _litharge_;
-for it was in scales, and was more valued the nearer its colour
-approached to that of gold. It was employed, as it still is, for making
-plasters. Pliny gives us the process for making the plaster employed by
-the Roman surgeons. It was made by heating together
-
-  3 lbs. molybdena or litharge,
-  1 lb. wax,
-  3 heminæ, or 1½ pint, of olive oil.
-
-This process is very nearly the same as the one at present followed by
-apothecaries for making adhesive plaster.
-
-_Psimmythium_, or _cerussa_, was the same as our _white lead_. It was
-made by exposing lead in sheets to the fumes of vinegar. It would seem
-probable from Pliny’s account, though it is confused and inaccurate,
-that the ancients were in the habit of dissolving cerussa in vinegar,
-and thus making an impure acetate of lead.
-
-Cerussa was used in medicine. It constituted also a common white paint.
-At one time, Pliny says, it was found native; but in his time all that
-was used was prepared artificially.
-
-_Cerussa usta_ seems to have been nearly the same as our _red lead_. It
-was formed accidentally from cerussa during the burning of the Pyræus.
-The colour was purple. It was imitated at Rome by burning _silis_
-_marmarosus_, which was probably a variety of some of our ochres.
-
-8. Besides the metals above enumerated, the ancients were also
-acquainted with quicksilver. Nothing is known about the first discovery
-of this metal; though it obviously precedes the commencement of
-history. I am not aware that the term occurs in the writings of Moses.
-We have therefore no evidence that it was known to the Egyptians at
-that early period; nor do I find any allusion to it in the works of
-Herodotus. But this is not surprising, as that author confines himself
-chiefly to subjects connected with history. Dioscorides and Pliny both
-mention it as common in their time. Dioscorides gives a method of
-obtaining it by sublimation from cinnabar. It is remarkable, because
-it constitutes the first example of a process which ultimately led to
-distillation.[60]
-
-[60] Dioscorides, lib. v. c. 110.
-
-Cinnabar is also described by Theophrastus. The term _minium_ was
-applied to it also, till in consequence of the adulteration of cinnabar
-with _red lead_, the term minium came at last to be restricted to
-that preparation of lead. Theophrastus describes an artificial
-cinnabar, which came from the country above Ephesus. It was a shining
-red-coloured sand, which was collected and reduced to a fine powder
-by pounding it in vessels of stone. We do not know what it was. The
-native cinnabar was found in Spain, and was used chiefly as a paint.
-Dioscorides employs _minium_ as the name for what we at present call
-cinnabar, or bisulphuret of mercury. His cinnabar was a red paint from
-Africa, produced in such small quantity that painters could scarcely
-procure enough of it to answer their purposes.
-
-Mercury is described by Pliny as existing native in the mines of Spain,
-and Dioscorides gives the process for extracting it from cinnabar. It
-was employed in gilding precisely as it is by the moderns. Pliny was
-aware of its great specific gravity, and of the readiness with which
-it dissolves gold. The amalgam was squeezed through leather, which
-separated most of the quicksilver. When the solid amalgam remaining was
-heated, the mercury was driven off and pure gold remained.
-
-It is obvious from what Dioscorides says, that the properties of
-mercury were very imperfectly known to him. He says that it may be
-kept in vessels of glass, or of lead, or of tin, or of silver.[61] Now
-it is well known that it dissolves lead, tin, and silver with so much
-rapidity, that vessels of these metals, were mercury put into them,
-would be speedily destroyed. Pliny’s account of quicksilver is rather
-obscure. It seems doubtful whether he was aware that native _argentum
-vivum_ and the _hydrargyrum_ extracted from cinnabar were the same.
-
-[61] Lib. v. c. 110.
-
-Cinnabar was occasionally used as an external medicine; but Pliny
-disapproves of it, assuring his readers that quicksilver and all its
-preparations are virulent poisons. No other mercurial preparations
-except cinnabar and the amalgam of mercury seem to have been known to
-the ancients.[62]
-
-[62] The ancients were in the habit of extracting mercury from
-cinnabar, by a kind of imperfect distillation. The native mercury they
-called _argentum vivum_, that from cinnabar _hydrargyrus_. See Plinii
-Hist. Nat. xxxiii. 8.
-
-9. The ancients were unacquainted with the metal to which we at present
-give the name of _antimony_; but several of the ores of that metal, and
-of the products of these ores were not altogether unknown to them. From
-the account of stimmi and stibium, by Dioscorides[63] and Pliny,[64]
-there can be little doubt that these names were applied to the mineral
-now called _sulphuret of antimony_ or crude antimony. It is found most
-commonly, Pliny says, among the ores of silver, and consists of two
-kinds, the male and the female; the latter of which is most valued.
-
-[63] Lib. v. c. 99.
-
-[64] Lib. xxxiii. c. 6.
-
-This pigment was known at a very early period, and employed by the
-Asiatic ladies in painting their eyelashes, or rather the insides of
-their eyelashes, black. Thus it is said of Jezebel, that when Jehu came
-to Jezreel she painted her face. The original is, _she put her eyes in
-sulphuret of antimony_.[65] A similar expression occurs in Ezekiel,
-“For whom thou didst wash thyself, paintedst thy eyes”--literally,
-put thy eyes in sulphuret of antimony.[66] This custom of painting
-the eyes black with antimony was transferred from Asia to Greece, and
-while the Moors occupied Spain it was employed by the Spanish ladies
-also. It is curious that the term _alcohol_, at present confined to
-_spirit of wine_, was originally applied to the powder of sulphuret of
-antimony.[67] The ancients were in the habit of roasting sulphuret of
-antimony, and thus converting it into an impure oxide. This preparation
-was also called stimmi and stibium. It was employed in medicine as
-an external application, and was conceived to act chiefly as an
-astringent; Dioscorides describes the method of preparing it. We see,
-from Pliny’s account of stibium, that he did not distinguish between
-sulphuret of antimony and oxide of antimony.[68]
-
-[65] 2 Kings ix. 30.
-
-[66] Chap. 23. v. 40, the Vulgate has it εστιβιζω τους οφθαλμους σουo.
-
-[67] Hartmanni Praxis Chemiatrica, p. 598.
-
-[68] Plinii Hist. Nat. xxxiii. 6.
-
-9. Some of the compounds of arsenic were also known to the ancients;
-though they were neither acquainted with this substance in the metallic
-state, nor with its oxide; the nature of which is so violent that had
-it been known to them it could not have been omitted by Dioscorides and
-Pliny.
-
-The word σανδαραχη (_sandarache_) occurs in Aristotle, and the
-term αρῥενιχον (_arrhenichon_) in Theophrastus.[69] Dioscorides
-uses likewise the same name with Aristotle. It was applied to a
-scarlet-coloured mineral, which occurs native, and is now known by the
-name of _realgar_. It is a compound of arsenic and sulphur. It was
-employed in medicine both externally and internally, and is recommended
-by Dioscorides, as an excellent remedy for an inveterate cough.
-
-[69] Περι των λιθων, c. 71.
-
-_Auripigmentum_ and _arsenicum_ were names given to the native yellow
-sulphuret of arsenic. It was used in the same way, and considered by
-Dioscorides and Pliny as of the same nature with realgar. But there
-is no reason for supposing that the ancients were acquainted with the
-compositions of either of these bodies; far less that they had any
-suspicion of the existence of the metal to which we at present give the
-name of arsenic.
-
-Such is a sketch of the facts known to the ancients respecting metals.
-They knew the six malleable metals which are still in common use, and
-applied them to most of the purposes to which the moderns apply them.
-Scarcely any information has been left us of the methods employed by
-them to reduce these metals from their ores. But unless the ores were
-of a much simpler nature than the modern ores of these metals, of which
-we have no evidence, the smelting processes with which the ancients
-were familiar, could scarcely have been contrived without a knowledge
-of the substances united with the different metals in their ores, and
-of the means by which these foreign bodies could be separated, and the
-metals isolated from all impurities. This doubtless implied a certain
-quantity of chemical knowledge, which having been handed down to the
-moderns, served as a foundation upon which the modern science of
-chemistry was gradually reared: at the same time it will be admitted
-that this foundation was very slender, and would of itself have led to
-little. Most of the oxides, sulphurets, &c., and almost all the salts
-into which these metallic bodies enter, were unknown to the ancients.
-
-Besides the working in metals there were some other branches of
-industry practised by the ancients, so intimately connected with
-chemical science, that it would be improper to pass them over in
-silence. The most important of these are the following:
-
-
-II.--COLOURS USED BY PAINTERS.
-
-It is well known that the ancient Grecian artists carried the art of
-painting to the highest degree of perfection, and that their paintings
-were admired and sought after by the most eminent and accomplished
-men of antiquity; and Pliny gives us a catalogue of a great number of
-first-rate pictures, and a historical account of a vast many celebrated
-painters of antiquity. In his own time, he says, the art of painting
-had lost its importance, statues and tablets having came in place of
-pictures.
-
-Two kinds of colours were employed by the ancients; namely, the florid
-and the austere. The florid colours, as enumerated by Pliny, were
-_minium_, _armenium_, _cinnaberis_, _chrysocolla_, _purpurissum_, and
-_indicum purpurissum_.
-
-The word _minium_ as used by Pliny means _red lead_; though Dioscorides
-employs it for bisulphuret of mercury or cinnabar.
-
-_Armenium_ was obviously an ochre, probably of a yellow or orange
-colour.
-
-_Cinnaberis_ was bisulphuret of mercury, which is known to have a
-scarlet colour. Dioscorides employs it to denote a vegetable red
-colour, probably similar to the resin at present called _dragon’s
-blood_.
-
-_Chrysocolla_ was a green-coloured paint, and from Pliny’s description
-of it, could have been nothing else than carbonate of copper or
-malachite.
-
-_Purpurissum_ was a _lake_, as is obvious from the account of its
-formation given by Pliny. The colouring matter is not specified, but
-from the term used there can be little doubt that it was the liquor
-from the shellfish that yielded the celebrated purple dye of the
-Tyrians.
-
-_Indicum purpurissum_ was probably _indigo_. This might be implied from
-the account of it given by Pliny.
-
-The austere colours used by the ancient painters were of two kinds,
-native and artificial. The native were _sinopis_, _rubrica_,
-_parætonium_, _melinum_, _eretria_, _auripigmentum_. The artificial
-were, _ochra_, _cerussa usta_, _sandaracha_, _sandyx_, _syricum_,
-_atramentum_.
-
-_Sinopis_ is the red substance now known by the name of reddle, and
-used for marking. On that account it is sometimes called _red chalk_.
-It was found in Pontus, in the Balearian islands, and in Egypt. The
-price was three denarii, or 1_s._ 11¼_d._ the pound weight. The most
-famous variety of _sinopis_ was from the isle of Lemnos; it was sold
-sealed and stamped: hence it was called _sphragis_. It was employed to
-adulterate minium. In medicine it was used to appease inflammation, and
-as an antidote to poison.
-
-_Ochre_ is merely sinopis heated in a covered vessel. The higher the
-temperature to which it has been exposed the better it is.
-
-_Leucophorum_ is a compound of
-
-   6 lbs. sinopis of Pontus,
-  10 lbs. siris,
-   2 lbs. melinum,
-
-triturated together for thirty days. It was used to make gold adhere to
-wood.
-
-_Rubrica_ from the name, was probably a red ochre.
-
-_Parætonium_ was a white colour, so called from a place in Egypt,
-where it was found. It was obtained also in the island of Crete, and
-in Cyrene. It was said to be a combination of the froth of the sea
-consolidated with mud. It consisted probably of carbonate of lime. Six
-pounds of it cost only one denarius.
-
-_Melinum_ was also a white-coloured powder found in Melos and Samos in
-veins. It was most probably a carbonate of lime.
-
-_Eretria_ was named from the place where it was found. Pliny gives
-its medical properties, but does not inform us of its colour. It is
-impossible to say what it was.
-
-_Auripigmentum_ was yellow sulphuret of arsenic. It was probably but
-little used as a pigment by the ancient painters.
-
-_Cerussa usta_ was red lead.
-
-_Sandaracha_ was red sulphuret of arsenic. The pound of sandaracha cost
-5 as.: it was imitated by red lead. Both it and _ochra_ were found in
-the island Topazos in the Red Sea.
-
-_Sandyx_ was made by torrefying equal parts of true sandaracha and
-sinopis. It cost half the price of sandaracha. Virgil mistook this
-pigment for a plant, as is obvious from the following line:
-
-    Sponte sua sandix, pascentes vestiet agnos.[70]
-
-[70] Bucol. iv. 1. 45.
-
-_Siricum_ is made by mixing sinopis and sandyx.
-
-_Atramentum_ was obviously from Pliny’s account of it _lamp-black_.
-He mentions ivory-black as an invention of Apelles: it was called
-_elephantinum_. There was a native atramentum, which had the colour of
-sulphur, and got a black colour artificially. It is not unlikely that
-it contained sulphate of iron, and that it got its black colour from
-the admixture of some astringent substance.
-
-The ink of the ancients was lamp-black mixed with water, containing
-gum or glue dissolved in it. _Atramentum indicum_ was the same as our
-_China ink_.
-
-The _purpurissum_ was a high-priced pigment. It was made by putting
-_creta argentaria_ (a species of white clay) into the caldrons
-containing the ingredients for dying purple. The creta imbibed the
-purple colour and became _purpurissum_. The first portion of _creta_
-put in constituted the finest and highest-priced pigment. The portions
-put in afterwards became successively worse, and were, of consequence
-lower priced. We see, from this description, that it was a lake similar
-to our modern cochineal lakes.[71]
-
-[71] Plinii Hist. Nat. xxxv. 6.
-
-That the purpurissum indicum was indigo is obvious from the statement
-of Pliny, that when thrown upon hot coals it gives out a beautiful
-purple flame. This constitutes the character of indigo. Its price in
-Pliny’s time was ten denarii, or six shillings and five-pence halfpenny
-the Roman pound; which is equivalent to 8_s._ 7⅓_d._ the avoirdupois.
-
-Though few or none of the ancient pictures have been preserved, yet
-several specimens of the colours used by them still remain in Rome and
-in the ruins of Herculaneum. Among others the fresco paintings, in
-the baths of Titus, still remain; and as these were made for a Roman
-emperor, we might expect to find the most beautiful and costly colours
-employed in them. These paints, and some others, were examined by Sir
-Humphrey Davy, in 1813, while he was in Rome. From his researches we
-derive some pretty accurate information respecting the colours employed
-by the painters of Greece and Rome.
-
-1. _Red paints._ Three different kinds of red were found in a chamber
-opened in 1811, in the baths of Titus, namely, a bright orange red,
-a dull red, and a brown red. The bright orange red was _minium_, or
-_red lead_; the other two were merely two varieties of iron ochres.
-Another still brighter red was observed on the walls; it proved, on
-examination, to be _vermilion_ or _cinnabar_.
-
-2. _Yellow paints._ All the _yellows_ examined by Davy proved to be
-_iron ochres_, sometimes mixed with a little _red lead_. Orpiment
-was undoubtedly employed, as is obvious from what Pliny says on the
-subject: but Davy found no traces of it among the yellow colours which
-he examined. A very deep yellow, approaching orange, which covered a
-piece of stucco in the ruins near the monument of Caius Cestius, proved
-to be protoxide of lead, or massicot, mixed with some red lead. The
-yellows in the Aldobrandini pictures were all ochres, and so were those
-in the pictures on the walls of the houses at Pompeii.
-
-3. _Blue paints._ Different shades of blues are used in the different
-apartments of the baths of Titus, which are darker or lighter, as they
-contain more or less carbonate of lime with which the blue pigment
-had been mixed by the painter. This blue pigment turned out, on
-examination, to be a frit composed of alkali and silica, fused together
-with a certain quantity of oxide of copper. This was the colour
-called χυανος (_kyanos_) by the Greeks, and _cæruleum_ by the Romans.
-Vitruvius gives the method of preparing it by heating strongly together
-sand, carbonate of soda, and filings of copper. Davy found that
-fifteen parts by weight of anhydrous carbonate of soda, twenty parts
-of powdered opaque flints, and three parts of copper filings, strongly
-heated together for two hours, gave a substance exactly similar to
-the blue pigment of the ancients, and which, when powdered, produced
-a fine deep blue colour. This cæruleum has the advantage of remaining
-unaltered even when the painting is exposed to the actions of the air
-and sun.
-
-There is reason to suspect, from what Vitruvius and Pliny say, that
-glass rendered blue by means of cobalt constituted the basis of some
-of the blue pigments of the ancients; but all those examined by Davy
-consisted of glass tinged blue by copper, without any trace of cobalt
-whatever.
-
-4. _Green paints._ All the green paints examined by Davy proved to be
-carbonates of copper, more or less mixed with carbonate of lime. I have
-already mentioned that verdigris was known to the ancients. It was no
-doubt employed by them as a pigment, though it is not probable that the
-acetic acid would be able to withstand the action of the atmosphere for
-a couple of thousand years.
-
-5. _Purple paints._ Davy ascertained that the colouring matter of
-the ancient purple was combustible. It did not give out the smell of
-ammonia, at least perceptibly. There is little doubt that it was the
-_purpurissum_ of the ancients, or a clay coloured by means of the
-purple of the buccinum employed by the Syrians in the celebrated purple
-dye.
-
-6. _Black and brown paints._ The black paints were lamp-black: the
-browns were some of them ochres and some of them oxides of manganese.
-
-7. _White paints._ All the ancient white paints examined by Davy were
-carbonates of lime.[72] We know from Pliny that white lead was employed
-by the ancients as a pigment; but it might probably become altered in
-its nature by long-continued exposure to the weather.
-
-[72] Phil. Trans. 1814, p. 97.
-
-
-III.--GLASS.
-
-It is admitted by some that the word which in our English Bible is
-translated crystal, means glass, in the following passage of Job: “The
-gold and the crystal cannot equal it.”[73] Now although the exact time
-when Job was written is not known, it is admitted on all hands to be
-one of the oldest of the books contained in the Old Testament. There
-are strong reasons for believing that it existed before the time of
-Moses; and some go so far as to affirm that there are several allusions
-to it in the writings of Moses. If therefore glass were known when
-the Book of Job was written, it is obvious that the discovery of it
-preceded the commencement of history. But even though the word used
-in Job should not refer to glass, there can be no doubt that it was
-known at a very early period; for glass beads are frequently found
-on the Egyptian mummies, and they are known to have been embalmed at
-a very remote period. The first Greek author who uses the word glass
-(ὑαλος, _hyalos_) is Aristophanes. In his comedy of The Clouds, act ii.
-scene 1, in the ridiculous dialogue between Socrates and Strepsiades,
-the latter announces a method which had occurred to him to pay his
-debts. “You know,” says he, “the beautiful transparent stone used for
-kindling fire.” “Do you mean glass (τον ὕαλον, _ton hyalon_)?” replied
-Socrates. “I do,” was the answer. He then describes how he would
-destroy the writings by means of it, and thus defraud his creditors.
-Now this comedy was acted about four hundred and twenty-three years
-before the beginning of the Christian era. The story related by Pliny,
-respecting the discovery of this beautiful and important substance, is
-well known. Some Phœnician merchants, in a ship loaded with carbonate
-of soda from Egypt, stopped, and went ashore on the banks of the river
-Belus: having nothing to support their kettles while they were dressing
-their food, they employed lumps of carbonate of soda for that purpose.
-The fire was strong enough to fuse some of this soda, and to unite it
-with the fine sand of the river Belus: the consequence of this was
-the formation of glass.[74] Whether this story be entitled to credit
-or not, it is clear that the discovery must have originated in some
-such accident. Pliny’s account of the manufacture of glass, like his
-account of every other manufacture, is very imperfect: but we see from
-it that in his time they were in the habit of making coloured glasses;
-that colourless glasses were most highly prized, and that glass was
-rendered colourless then as it is at present, by the addition of a
-certain quantity of oxide of manganese. Colourless glass was very
-high priced in Pliny’s time. He relates, that for two moderate-sized
-colourless drinking-glasses the Emperor Nero paid 6000 sistertii, which
-is equivalent to 25_l._ of our money.
-
-[73] Job xxviii. 17.
-
-[74] Plinii Hist. Nat. xxxvi. 26.
-
-Pliny relates the story of the man who brought a vessel of malleable
-glass to the Emperor Tiberius, and who, after dimpling it by dashing
-it against the floor, restored it to its original shape and beauty by
-means of a hammer; Tiberius, as a reward for this important discovery,
-ordered the artist to be executed, in order, as he alleged, to prevent
-gold and silver from becoming useless. But though Pliny relates this
-story, it is evident that he does not give credit to it; nor does it
-deserve credit. We can assign no reason why malleable substances may
-not be transparent; but all of them hitherto known are opaque. Chloride
-of silver, chloride of lead and iron constitute no exception, for
-they are not malleable, though by peculiar contrivances they may be
-extended; and their transparency is very imperfect.
-
-Many specimens of the coloured glasses made by the ancients still
-remain, particularly the beads employed as ornaments to the Egyptian
-mummies. Of these ancient glasses several have been examined chemically
-by Klaproth, Hatchett, and some other individuals, in order to
-ascertain the substances employed to give colour to the glass. The
-following are the facts that have been ascertained:
-
-1. _Red glass._ This glass was opaque, and of a lively copper-red
-colour. It was probably the kind of red glass to which Pliny gave the
-name of hæmatinon. Klaproth analyzed it, and obtained from 100 grains
-of it the following constituents:
-
-  Silica               71
-  Oxide of lead        10
-  Oxide of copper       7·5
-  Oxide of iron         1
-  Alumina               2·5
-  Lime                  1·5
-                      -----
-                       93·5[75]
-
-[75] Beitrage, vi. 140.
-
-No doubt the deficiency was owing to the presence of an alkali. From
-this analysis we see that the colouring matter of this glass was _red
-oxide of copper_.
-
-2. _Green glass._ The colour was light verdigris-green, and the glass,
-like the preceding, was opaque. The constituents from 100 grains were,
-
-  Silica                     65
-  Black oxide of copper      10
-  Oxide of lead               7·5
-  Oxide of iron               3·5
-  Lime                        6·5
-  Alumina                     5·5
-                            -----
-                             98·0[76]
-
-[76] Ibid., p. 142.
-
-Thus it appears that both the red and green glass are composed of the
-same ingredients, though in different proportions. Both owe their
-colour to copper. The red glass is coloured by the red oxide of that
-metal; the green by the black oxide, which forms green-coloured
-compounds, with various acids, particularly with carbonic acid and with
-silica.
-
-3. _Blue glass._ The variety analyzed by Klaproth had a sapphire-blue
-colour, and was only translucent on the edges. The constituents from
-100 grains of it were,
-
-  Silica              81·5
-  Oxide of iron        9·5
-  Alumina              1·5
-  Oxide of copper      0·5
-  Lime                 0·25
-                      -----
-                      93·25[77]
-
-[77] Beitrage, p. 144.
-
-From this analysis it appears that the colouring matter of this glass
-was oxide of iron: it was therefore analogous to the lapis lazuli, or
-ultramarine, in its nature.
-
-Davy, as has been formerly noticed, found another blue glass, or frit,
-coloured by means of copper; and he showed that the blue paint of the
-ancients was often made from this glass, simply by grinding it to
-powder.
-
-Klaproth could find no cobalt in the blue glass which he examined; but
-Davy found the transparent blue glass vessels, which are along with
-the vases, in the tombs of Magna Græcia, tinged with cobalt; and he
-found cobalt in all the transparent ancient blue glasses with which
-Mr. Millingen supplied him. The mere fusion of these glasses with
-alkali, and subsequent digestion of the product with muriatic acid, was
-sufficient to produce a sympathetic ink from them.[78] The transparent
-blue beads which occasionally adorn the Egyptian mummies have also been
-examined, and found coloured by cobalt. The opaque glass beads are all
-tinged by means of oxide of copper. It is probable from this that all
-the transparent blue glasses of the ancients were coloured by cobalt;
-yet we find no allusion to cobalt in any of the ancient authors.
-Theophrastus says that copper (χαλκος, _chalcos_) was used to give
-glass a fine colour. Is it not likely that the impure oxide of cobalt,
-in the state in which they used it, was confounded by them with χαλκος
-(_chalcos_)?
-
-[78] Phil. Trans. 1815, p. 108.
-
-
-IV.--VASA MURRHINA.
-
-The Romans obtained from the east, and particularly from Egypt, a set
-of vessels which they distinguished by the name of _vasa murrhina_,
-and which were held by them in very high estimation. They were never
-larger than to be capable of containing from about thirty-six to forty
-cubic inches. One of the largest size cost, in the time of Pliny, about
-7000_l._ Nero actually gave for one 3000_l._ They began to be known in
-Rome about the latter days of the republic. The first six ever seen in
-Rome were sent by Pompey from the treasures of Mithridates. They were
-deposited in the temple of Jupiter in the capitol. Augustus, after
-the battle of Actium, brought one of these vessels from Egypt, and
-dedicated it also to the gods. In Nero’s time they began to be used by
-private persons; and were so much coveted that Petronius, the favourite
-of that tyrant, being ordered for execution, and conceiving that his
-death was owing to a wish of Nero to get possession of a vessel of this
-kind which he had, broke the vessel in pieces in order to prevent Nero
-from gaining his object.
-
-There appear to have been two kinds of these vasa murrhina; those that
-came from Asia, and those that were made in Egypt. The latter were much
-more common, and much lower priced than the former, as appears from
-various passages in Martial and Propertius.
-
-Many attempts have been made, and much learning displayed by the
-moderns to determine the nature of these celebrated vessels; but in
-general these attempts were made by individuals too little acquainted
-with chemistry and with natural history in general to qualify them
-for researches of so difficult a nature. Some will have it that they
-consisted of a kind of gum; others that they were made of glass;
-others, of a particular kind of shell. Cardan and Scaliger assure
-us that they were _porcelain_ vessels; and this opinion was adopted
-likewise by Whitaker, who supported it with his usual violence and
-arrogance. Many conceive them to have been made of some precious stone,
-some that they were of _obsidian_; Count de Veltheim thinks that
-they were made of the Chinese _agalmatolite_, or _figure stone_; and
-Dr. Hager conceives that they were made from the Chinese stone _yu_.
-Bruckmann was of opinion that these vessels were made of sardonyx, and
-the Abbé Winckelmann joins him in the same conclusion.
-
-Pliny informs us that these vasa murrhina were formed from a species
-of stone dug out of the earth in Parthia, and especially in Carimania,
-and also in other places but little known.[79] They must have been very
-abundant at Rome in the time of Nero; for Pliny informs us that a man
-of consular rank, famous for his collection of vasa murrhina, having
-died, Nero forcibly deprived his children of these vessels, and they
-were so numerous that they filled the whole inside of a theatre, which
-Nero hoped to have seen filled with Romans when he came to it to sing
-in public.
-
-[79] Plinii Hist. Nat. xxxvii. 2.
-
-It is clear that the value of these vessels depended on their size.
-Small vessels bore but a small price, while that of large vessels was
-very high; this shows us that it must have been difficult to procure a
-block of the stone out of which they were cut, of a size sufficiently
-great to make a large vessel.
-
-These vessels were so soft that an impression might be made upon them
-with the teeth; for Pliny relates the story of a man of consular rank,
-who drank out of one, and was so enamoured with it that he bit pieces
-out of the lip of the cup: “Potavit ex eo ante hos annos consularis, ob
-amorem abraso ejus margine.” And what is singular, the value of the
-cup, so far from being injured by this abrasure, was augmented: “ut
-tamen injuria ilia pretium augeret; neque est hodie murrhini alterius
-præstantior indicatura.”[80] It is clear from this that the matter of
-these vessels was neither rock crystal, agate, nor any precious stone
-whatever, all of which are too hard to admit of an impression from the
-teeth of a man.
-
-[80] Plinii Hist. Nat. xxxvii. 2.
-
-The lustre was vitreous to such a degree that the name _vitrum
-murrhinum_ was given to the artificial fabric, in Egypt.
-
-The splendour was not very great, for Pliny observes, “Splendor his
-sine viribus nitorque verius quam splendor.”
-
-The colours, from their depth and richness, were what gave these
-vessels their value and excited admiration. The principal colours were
-purple and white, disposed in undulating bands, and usually separated
-by a third band, in which the two colours being mixed, assumed the tint
-of flame: “Sed in pretio varietas colorum, subinde circumagentibus se
-maculis in purpuram candoremque, et tertium ex utroque ignescentem,
-velut per transitum coloris, purpura rubescente, aut lacte candescente.”
-
-Perfect transparency was considered as a defect, they were merely
-translucent; this we learn not merely from Pliny, but from the
-following epigram of Martial:
-
-    Nos bibimus vitro, tu murra, Pontice: quare?
-    Prodat perspicuus ne duo vina calix.
-
-Some specimens, and they were the most valued, exhibited a play of
-colour like the rainbow: Pliny says they were very commonly spotted
-with “sales, verrucæque non eminentes, sed ut in corpore etiam
-plerumque sessiles.” This, no doubt, refers to foreign bodies, such as
-grains of pyrites, antimony, galena, &c., which were often scattered
-through the substances of which the vessels were made.
-
-Such are all the facts respecting the vasa murrhina to be found in the
-writings of the ancients; they all apply to fluor spar, and to nothing
-else; but to it they apply so accurately as to leave little doubt that
-they were in reality vessels of fluor spar, similar to those at present
-made in Derbyshire.[81]
-
-[81] This opinion was first formed by Baron Born, and stated in
-his Catalogue of Minerals in M. E. Raab’s collection, i. 356. But
-the evidences in favour of it have been brought forward with great
-clearness and force by M. Roziere. See Jour. de Min. xxxvi. 193.
-
-The artificial vasa murrhina made at Thebes, in Egypt, were doubtless
-of glass, coloured to imitate fluor spar as much as possible, and
-having the semi-transparency which distinguishes that mineral. The
-imitations being imperfect, these factitious vessels were not much
-prized nor sought after by the Romans, they were rather distributed
-among the Arabians and Ethiopians, who were supplied with glass from
-Egypt.
-
-Rock crystal is compared by Pliny with the stone from which the vasa
-murrhina were made; the former, in his opinion, had been coagulated
-by cold, the latter by heat. Though the ancients, as we have seen,
-were acquainted with the method of colouring glass, yet they prized
-colourless glass highest on account of its resemblance to rock crystal;
-cups of it, in Pliny’s time, had supplanted those of silver and gold;
-Nero gave for a crystal cup 150,000 sistertii, or 625_l._
-
-
-V.--DYEING AND CALICO-PRINTING.
-
-Very little has been handed down by the ancients respecting the
-processes of dyeing. It is evident, from Pliny, that they were
-acquainted with madder, and that preparations of iron were used in
-the black dyes. The most celebrated dye of all, the _purple_, was
-discovered by the Tyrians about fifteen centuries before the Christian
-era. This colour was given by various kinds of shellfish which inhabit
-the Mediterranean. Pliny divides them into two genera; the first,
-comprehending the smaller species, he called _buccinum_, from their
-resemblance to a hunting-horn; the second, included those called
-_purpura_: Fabius Columna thinks that these were distinguished also by
-the name of _murex_.
-
-These shellfish yielded liquor of different shades of colour; they
-were often mixed in various proportions to produce particular shades
-of colour. One, or at most two drops of this liquor were obtained from
-each fish, by extracting and opening a little reservoir placed in the
-throat. To avoid this trouble, the smaller species were generally
-bruised whole, in a mortar; this was also frequently done with the
-large, though the other liquids of the fish must have in some degree
-injured the colour. The liquor, when extracted, was mixed with a
-considerable quantity of salt to keep it from putrifying; it was then
-diluted with five or six times as much water, and kept moderately hot
-in leaden or tin vessels, for eight or ten days, during which the
-liquor was often skimmed to separate all the impurities. After this,
-the wool to be dyed, being first well washed, was immersed and kept
-therein for five hours; then taken out, cooled, and again immersed, and
-continued in the liquor till all the colour was exhausted.[82]
-
-[82] Plinii Hist. Nat. ix. 38.
-
-To produce particular shades of colour, carbonate of soda, urine,
-and a marine plant called _fucus_, were occasionally added: one of
-these colours was a very dark reddish violet--“Nigrantis rosæ colore
-sublucens.”[83] But the most esteemed, and that in which the Tyrians
-particularly excelled, resembled coagulated blood--“laus ei summa
-in colore sanguinis concreti, nigricans aspectu, idemque suspectu
-refulgens.”[84]
-
-[83] Ibid., ix. 36.
-
-[84] Plinii Hist. Nat. ix. c. 38.
-
-Pliny says that the Tyrians first dyed their wool in the liquor of the
-purpura, and afterwards in that of the buccinum; and it is obvious from
-Moses that this purple was known to the Egyptians in his time.[85]
-Wool which had received this double Tyrian dye (_dia bapha_) was so
-very costly that, in the reign of Augustus, it sold for about 36_l._
-the pound. But lest this should not be sufficient to exclude all from
-the use of it but those invested with the very highest dignities
-of the state, laws were made inflicting severe penalties, and even
-death, upon all who should presume to wear it under the dignity
-of an emperor. The art of dyeing this colour came at length to be
-practised by a few individuals only, appointed by the emperors, and
-having been interrupted about the beginning of the twelfth century all
-knowledge of it died away, and during several ages this celebrated
-dye was considered and lamented as an irrecoverable loss.[86] How it
-was afterwards recovered and made known by Mr. Cole, of Bristol, M.
-Jussieu, M. Reaumur, and M. Duhamel, would lead us too far from our
-present object, were we to relate it: those who are interested in the
-subject will find an historical detail in Bancroft’s work on Permanent
-Colours, just referred to.
-
-[85] Exodus xxv. 4.
-
-[86] See Bancroft on Permanent Colours, i. 79.
-
-There is reason to suspect that the Hebrew word translated _fine linen_
-in the Old Testament, and so celebrated as a production of Egypt, was
-in reality _cotton_, and not linen. From a curious passage in Pliny,
-there is reason to believe that the Egyptians in his time, and probably
-long before, were acquainted with the method of calico-printing, such
-as is still practised in India and the east. The following is a
-literal translation of the passage in question:
-
-“There exists in Egypt a wonderful method of dyeing. The white cloth
-is stained in various places, not with dye stuffs, but with substances
-which have the property of absorbing (_fixing_) colours, these
-applications are not visible upon the cloth; but when they are dipped
-into a hot caldron of the dye they are drawn out an instant after dyed.
-The remarkable circumstance is, that though there be only one dye in
-the vat, yet different colours appear upon the cloth; nor can the
-colour be afterwards removed.”[87]
-
-[87] Plinii Hist. Nat. xxxv. 11.
-
-It is evident enough that these substances applied were different
-mordants which served to fix the dye upon the cloth; the nature of
-these mordants cannot be discovered, as nothing specific seems to have
-been known to Pliny. The modern mordants are solutions of alumina; of
-the oxide of tin, oxide of iron, oxide of lead, &c.: and doubtless
-these, or something equivalent to these, were the substances employed
-by the ancients. The purple dye required no mordant, it fixed itself to
-the cloth in consequence of the chemical affinity which existed between
-them. Whether indigo was used by the ancients as a dye does not appear,
-but there can be no doubt, at least, that its use was known to the
-Indians at a very remote period.
-
-From these facts, few as they are, there can be little doubt that
-dyeing, and even calico-printing, had made considerable progress
-among the ancients; and this could not have taken place without a
-considerable knowledge of colouring matters, and of the mordants by
-which these colouring matters were fixed. These facts, however, were
-probably but imperfectly understood, and could not be the means of
-furnishing the ancients with any accurate chemical knowledge.
-
-
-VI.--SOAP.
-
-Soap, which constitutes so important and indispensable an article in
-the domestic economy of the moderns, was quite unknown to the ancient
-inhabitants of Asia, and even of Greece. No allusion to it occurs in
-the Old Testament. In Homer, we find Nausicaa, the daughter of the King
-of the Phæacians, using nothing but water to wash her nuptial garments:
-
-    They seek the cisterns where Phæacian dames
-    Wash their fair garments in the limped streams;
-    Where gathering into depth from falling rills,
-    The lucid wave a spacious bason fills.
-    The mules unharness’d range beside the main,
-    Or crop the verdant herbage of the plain.
-    Then emulous the royal robes they lave,
-    And plunge the vestures in the cleansing wave.
-    _Odyssey_, vi. 1. 99.
-
-We find, in some of the comic poets, that the Greeks were in the habit
-of adding wood-ashes to water to make it a better detergent. Wood-ashes
-contain a certain portion of carbonate of potash, which of course would
-answer as a detergent; though, from its caustic qualities, it would be
-injurious to the hands of the washerwomen. There is no evidence that
-carbonate of soda, the _nitrum_ of the ancients, was ever used as a
-detergent; this is the more surprising, because we know from Pliny that
-it was employed in dyeing, and one cannot see how a solution of it
-could be employed by the dyers in their processes without discovering
-that it acted powerfully as a detergent.
-
-The word _soap_ (_sapo_) occurs first in Pliny. He informs us that it
-was an invention of the Gauls, who employed it to render their hair
-shining; that it was a compound of wood-ashes and tallow, that there
-were two kinds of it, _hard_ and _soft_ (_spissus et liquidus_); and
-that the best kind was made of the ashes of the beech and the fat of
-goats. Among the Germans it was more employed by the men than the
-women.[88] It is curious that no allusion whatever is made by Pliny to
-the use of soap as a detergent; shall we conclude from this that the
-most important of all the uses of soap was unknown to the ancients?
-
-[88] Plinii Hist. Nat. xxviii. 12. The passage of Pliny is as follows:
-“Prodest et sapo; Gallorum hoc inventum rutilandis capillis ex sevo et
-cinere. Optimus fagino et caprino, duobus modis, spissus et liquidus:
-uterque apud Germanos majore in usu viris quam feminis.”
-
-It was employed by the ancients as a pomatum; and, during the early
-part of the government of the emperors, it was imported into Rome from
-Germany, as a pomatum for the young Roman beaus. Beckmann is of opinion
-that the Latin word _sapo_ is derived from the old German word _sepe_,
-a word still employed by the common people of Scotland.[89]
-
-[89] Hist. of Inventions, iii. 239.
-
-It is well known that the state of soap depends upon the alkali
-employed in making it. _Soda_ constitutes a _hard_ soap, and _potash_ a
-_soft_ soap. The ancients being ignorant of the difference between the
-two alkalies, and using wood-ashes in the preparation of it, doubtless
-formed soft soap. The addition of some common salt, during the boiling
-of the soap, would convert the soft into hard soap. As Pliny informs us
-that the ancients were acquainted both with hard and soft soap, it is
-clear that they must have followed some such process.
-
-
-VII.--STARCH.
-
-The manufacture of starch was known to the ancients. Pliny informs us
-that it was made from wheat and from _siligo_, which was probably a
-variety or sub-species of wheat. The invention of starch is ascribed
-by Pliny to the inhabitants of the island of Chio, where in his time
-the best starch was still made. Pliny’s description of the method
-employed by the ancients of making starch is tolerably exact. Next to
-the China starch that of Crete was most celebrated; and next to it was
-the Egyptian. The qualities of starch were judged of by the weight; the
-lightest being always reckoned the best.
-
-
-VIII.--BEER.
-
-That the ancients were acquainted with wine is universally known. This
-knowledge must have been nearly coeval with the origin of society;
-for we are informed in Genesis that Noah, after the flood, planted a
-vineyard, and made wine, and got intoxicated by drinking the liquid
-which he had manufactured.[90] Beer also is a very old manufacture.
-It was in common use among the Egyptians in the time of Herodotus,
-who informs us that they made use of a kind of wine made from barley,
-because no vines grew in their country.[91] Tacitus informs us, that
-in his time it was the drink of the Germans.[92] Pliny informs us that
-it was made by the Gauls, and by other nations. He gives it the name
-of _cerevisia_ or _cervisia_; the name obviously alluding to the grain
-from which it was made.
-
-[90] Genesis ix. 20.
-
-[91] “Oinô d’ ek kritheôn pepoiêmenô diachreontai; ou gar sphi eisi en
-tê chôrê ampeloi.” Euterpe chap. 77.
-
-[92] De Moribus Germanorum, c. 23. “Potui humor ex hordeo aut frumento
-in quandam similitudinem vini corruptus.”
-
-But though the ancients seem acquainted with both wine and beer,
-there is no evidence of their having ever subjected these liquids
-to distillation, and of having collected the products. This would
-have furnished them with ardent spirits or alcohol, of which there
-is every reason to believe they were entirely ignorant. Indeed, the
-method employed by Dioscorides to obtain mercury from cinnabar, is a
-sufficient proof that the true process of distillation was unknown to
-them. He mixed cinnabar with iron filings, put the mixture into a pot,
-to the top of which a cover of stoneware was luted. Heat was applied
-to the pot, and when the process was at an end, the mercury was found
-adhering to the inside of the cover. Had they been aware of the method
-of distilling the quicksilver ore into a receiver, this imperfect mode
-of collecting only a small portion of the quicksilver, separated from
-the cinnabar, would never have been practised. Besides, there is not
-the smallest allusion to ardent spirits, either in the writings of the
-poets, historians, naturalists, or medical men of ancient Greece; a
-circumstance not to be accounted for had ardent spirits been known,
-and applied even to one-tenth of the uses to which they are put by the
-moderns.
-
-
-IX.--STONEWARE.
-
-The manufacture of stoneware vessels was known at a very early period
-of society. Frequent allusions to the potter’s wheel occur in the Old
-Testament, showing that the manufacture must have been familiar to
-the Jewish nation. The porcelain of the Chinese boasts of a very high
-antiquity indeed. We cannot doubt that the processes of the ancients
-were similar to those of the moderns, though I am not aware of any
-tolerably accurate account of them in any ancient author whatever.
-
-Moulds of plaster of Paris were used by the ancients to take casts
-precisely as at present.[93]
-
-[93] Plinii Hist. Nat. xxxv. 12.
-
-The sand of Puzzoli was used by the Romans, as it is by the moderns, to
-form a mortar capable of hardening under water.
-
-Pliny gives us some idea of the Roman bricks, which are known to have
-been of an excellent quality. There were three sizes of bricks used by
-the Romans.
-
-1. Lydian, which were 1½ foot long and 1 foot broad.
-
-2. Tetradoron, which was a square of 16 inches each side.
-
-3. Pentadoron, which was a square, each side of which was 20 inches
-long.
-
-Doron signifies the palm of the hand: of course it was equivalent to 4
-inches.
-
-
-X.--PRECIOUS STONES AND MINERALS.
-
-Pliny has given a pretty detailed description of the precious stones
-of the ancients; but it is not very easy to determine the specific
-minerals to which he alludes.
-
-1. The description of the diamond is tolerably precise. It was found in
-Ethiopia, India, Arabia, and Macedonia. But the Macedonian diamond, as
-well as the adamas cyprius and siderites, were obviously not diamonds,
-but soft stones.
-
-2. The _emerald_ of the ancients (_smaragdus_) must have varied in its
-nature. It was a green, transparent, hard stone; and, as colour was
-the criterion by which the ancients distinguished minerals and divided
-them into species, it is obvious that very different minerals must
-have been confounded together, under the name of emerald. Sapphire,
-beryl, doubtless fluor spar when green, and probably even serpentine,
-nephrite, and some ores of copper, seem to have occasionally got the
-same name. There is no reason to believe that the _emerald_ of the
-moderns was known before the discovery of America. At least it has been
-only found in modern times in America. Some of the emeralds described
-by Pliny as losing their colour by exposure to the sun, must have been
-fluor spars. There is a remarkably deep and beautiful green fluor spar,
-met with some years ago in the county of Durham, in one of the Weredale
-mines that possesses this property. The emeralds of the ancients were
-of such a size (13½ feet, large enough to be cut into a pillar), that
-we can consider them in no other light than as a species of rock.
-
-3. Topaz of the ancients had a green colour, which is never the case
-with the modern topaz. It was found in the island Topazios, in the
-Red Sea.[94] It is generally supposed to have been the _chrysolite_
-of the moderns. But Pliny mentions a statue of it six feet long. Now
-chrysolite never occurs in such large masses. Bruce mentions a green
-substance in an emerald island in the Red Sea, not harder than glass.
-Might not this be the emerald of the ancients?
-
-[94] The word topazo is said by Pliny to signify, in the language of
-the Troglodytes, _to seek_.
-
-4. _Calais_, from the locality and colour was probably the Persian
-turquoise, as it is generally supposed to be.
-
-5. Whether the _prasius_ and _chrysoprasius_ of Pliny were the modern
-stones to which these names are given, we have no means of determining.
-It is generally supposed that they are, and we have no evidence to the
-contrary.
-
-6. The _chrysolite_ of Pliny is supposed to be our _topaz_: but we have
-no other evidence of this than the opinion of M. Du Tems.
-
-7. _Asteria_ of Pliny is supposed by Saussure to be our sapphire. The
-lustre described by Pliny agrees with this opinion. The stone is said
-to have been very hard and colourless.
-
-8. _Opalus_ seems to have been our _opal_. It is called, Pliny says,
-_pæderos_ by many, on account of its beauty. The Indians called it
-_sangenon_.
-
-9. _Obsidian_ was the same as the mineral to which we give that name.
-It was so called because a Roman named Obsidianus first brought it from
-Egypt. I have a piece of obsidian, which the late Mr. Salt brought from
-the locality specified by Pliny, and which possesses all the characters
-of that mineral in its purest state.
-
-10. _Sarda_ was the name of _carnelian_, so called because it was first
-found near Sardis. The _sardonyx_ was also another name for _carnelian_.
-
-11. Onyx was a name sometimes given to a rock, _gypsum_; sometimes it
-was a light-coloured _chalcedony_. The Latin name for chalcedony was
-_carchedonius_, so called because Carthage was the place where this
-mineral was exposed to sale. The Greek name for Carthage was Καρχηδων
-(_carchedon_).
-
-12. _Carbunculus_ was the garnet; and _anthrax_ was a name for another
-variety of the same mineral.
-
-13. The _oriental amethyst_ of Pliny was probably a sapphire. The
-fourth species of amethyst described by Pliny, seems to have been our
-amethyst. Pliny derives the name from α (_a_) and μυθη (_mythe_),
-_wine_, because it has not quite the colour of wine. But the common
-derivation is from α and μυθυω, _to intoxicate_, because it was used as
-an amulet to prevent intoxication.
-
-14. The _sapphire_ is described by Pliny as always opaque, and as unfit
-for engraving on. We do not know what it was.
-
-15. The _hyacinth_ of Pliny is equally unknown. From its name it was
-obviously of a blue colour. Our hyacinth has a reddish-brown colour,
-and a great deal of hardness and lustre.
-
-16. The _cyanus_ of Pliny may have been our _cyanite_.
-
-17. _Astrios_ agrees very well, as far as the description of Pliny
-goes, with the variety of felspar called _adularia_.
-
-18. _Belioculus_ seems to have been our _catseye_.
-
-19. _Lychnites_ was a violet-coloured stone, which became electric by
-heat. Unless it was a _blue tourmalin_, I do not know what it could be.
-
-20. The _jasper_ of the ancients was probably the same as ours.
-
-21. _Molochites_ may have been our _malachite_. The name comes from the
-Greek word μολοχη, _mallow_, or _marshmallow_.
-
-22. Pliny considers _amber_ as the juice of a tree concreted into a
-solid form. The largest piece of it that he had ever seen weighed 13
-lbs. Roman weight, which is nearly equivalent to 9¾ lbs. avoirdupois.
-_Indian amber_, of which he speaks, was probably _copal_, or some
-transparent resin. It may be dyed, he says, by means of _anchusa_ and
-the _fat of kids_.
-
-23. _Lapis specularis_ was foliated sulphate of lime, or selenite.
-
-24. _Pyrites_ had the same meaning among the ancients that it has among
-the moderns; at least as far as iron pyrites or bisulphuret of iron is
-concerned. Pliny describes two kind of pyrites; namely, the _white_
-(_arsenical pyrites_), and the _yellow_ (iron pyrites). It was used for
-striking fire with steel, in order to kindle tinder. Hence the name
-_pyrites_ or _firestone_.
-
-25. _Gagates_, from the account given of it by Pliny, was obviously
-pit-coal or jet.
-
-26. _Marble_ had the same meaning among the ancients that it has among
-the moderns. It was sawed by the ancients into slabs, and the action of
-the saw was facilitated by a sand brought for the purpose from Ethiopia
-and the isle of Naxos. It is obvious that this sand was powdered
-corundum, or emery.
-
-27. _Creta_ was a name applied by the ancients not only to chalk, but
-to _white clay_.
-
-28. _Melinum_ was an _oxide of iron_. Pliny gives a list of one hundred
-and fifty-one species of stones in the order of the alphabet. Very few
-of the minerals contained in this list can be made out. He gives also
-a list of fifty-two species of stones, whose names are derived from a
-fancied resemblance which the stones are supposed to bear to certain
-parts of animals. Of these, also, very few can be made out.
-
-
-XI.--MISCELLANEOUS OBSERVATIONS.
-
-The ancients seem to have been ignorant of the nature and properties
-of air, and of all gaseous bodies. Pliny’s account of air consists
-of a single sentence: “Aër densatur nubibus; furit procellis.” “Air
-is condensed in clouds, it rages in storms.” Nor is his description
-of water much more complete, since it consists only of the following
-phrases: “Aquæ subeunt in imbres, rigescunt in grandines, tumescunt
-in fluctus, præcipitantur in torrentes.”[95] “Water falls in showers,
-congeals in hail, swells in waves, and rushes down in torrents.” In
-the thirty-eighth chapter of the second book, indeed, he professes
-to treat of _air_; but the chapter contains merely an enumeration of
-meteorological phenomena, without once touching upon the nature and
-properties of air.
-
-[95] Plinii Hist. Nat. ii. 63.
-
-Pliny, with all the philosophers of antiquity, admitted the existence
-of the four elements, fire, air, water, and earth; but though he
-enumerates these in the fifth chapter of his first book, he never
-attempts to explain their nature or properties. Earth, among the
-ancients, had two meanings, namely, the planet on which we live, and
-the soil upon which vegetables grow. These two meanings still exist in
-common language. The meaning afterwards given to the _term_, earth,
-by the chemists, did not exist in the days of Pliny, or, at least,
-was unknown to him; a sufficient proof that chemistry, in his time,
-had made no progress as a science; for some notions respecting the
-properties and constituents of those supposed four elements must have
-constituted the very foundation of scientific chemistry.
-
-The ancients were acquainted with none of the acids which at present
-constitute so numerous a tribe, except _vinegar_, or _acetic acid_;
-and even this acid was not known to them in a state of purity. They
-knew none of the saline bases, except lime, soda, and potash, and these
-very imperfectly. Of course the whole tribe of salts was unknown to
-them, except a very few, which they found ready formed in the earth,
-or which they succeeded in forming by the action of vinegar on lead
-and copper. Hence all that extensive and most important branch of
-chemistry, consisting of the combinations of the acids and bases, on
-which scientific chemistry mainly depends, must have been unknown to
-them.
-
-Sulphur occurring native in large quantities, and being remarkable for
-its easy combustibility, and its disagreeable smell when burning, was
-known in the very earliest ages. Pliny describes four kinds of sulphur,
-differing from each other, probably, merely in their purity. These were
-
-1. Sulphur vivum, or apyron. It was dug out of the earth solid, and was
-doubtless pure, or nearly so. It alone was used in medicine.
-
-2. Gleba--used only by fullers.
-
-3. Egula--used also by fullers.
-
-Pliny says, it renders woollen stuffs white and soft. It is obvious
-from this, that the ancients knew the method of bleaching flannel by
-the fumes of sulphur, as practised by the moderns.
-
-4. The fourth kind was used only for sulphuring matches.
-
-Sulphur, in Pliny’s time, was found native in the Æolian islands, and
-in Campania. It is curious that he never mentions Sicily, whence the
-great supply is drawn for modern manufacture.
-
-In medicine, it seems to have been only used externally by the
-ancients. It was considered as excellent for removing eruptions. It was
-used also for fumigating.
-
-The word _alumen_, which we translate _alum_, occurs often in Pliny;
-and is the same substance which the Greeks distinguished by the
-name of στυπτηρια (_stypteria_). It is described pretty minutely by
-Dioscorides, and also by Pliny. It was obviously a natural production,
-dug out of the earth, and consequently quite different from our alum,
-with which the ancients were unacquainted. Dioscorides says that it
-was found abundantly in Egypt; that it was of various kinds, but that
-the slaty variety was the best. He mentions also many other localities.
-He says that, for medical purposes, the most valued of all the
-varieties of alumen were the _slaty_, the _round_, and the _liquid_.
-The slaty alumen is very white, has an exceedingly astringent taste, a
-strong smell, is free from stony concretions, and gradually cracks and
-emits long capillary crystals from these rifts; on which account it is
-sometimes called _trichites_. This description obviously applies to a
-kind of slate-clay, which probably contained pyrites mixed with it of
-the decomposing kind. The capillary crystals were probably similar to
-those crystals at present called _hair-salt_ by mineralogists, which
-exude pretty abundantly from the shale of the coal-beds, when it has
-been long exposed to the air. _Hair-salt_ differs very much in its
-nature. Klaproth ascertained by analysis, that the _hair-salt_ from the
-quicksilver-mines in Idria is sulphate of magnesia, mixed with a small
-quantity of sulphate of iron.[96] The _hair-salt_ from the abandoned
-coal-pits in the neighbourhood of Glasgow is a double salt, composed of
-sulphate of alumina, and sulphate of iron, in definite proportions; the
-composition being
-
-[96] Beitrage, iii. 104.
-
-   1 atom protosulphate of iron,
-   1½ atom sulphate of alumina,
-  15 atoms water.
-
-I suspect strongly that the capillary crystals from the schistose
-alumen of Dioscorides were nearly of the same nature.
-
-From Pliny’s account of the uses to which alumen was applied, it is
-quite obvious that it must have varied very much in its nature. _Alumen
-nigrum_ was used to strike a black colour, and must therefore have
-contained iron. It was doubtless an impure native sulphate of iron,
-similar to many native productions of the same nature still met with
-in various parts of the world, but not employed; their use having been
-superseded by various artificial salts, more definite in their nature,
-and consequently more certain in their application, and at the same
-time cheaper and more abundant than the native.
-
-The alumen employed as a mordant by the dyers, must have been a
-sulphate of alumina more or less pure; at least it must have been free
-from all sulphate of iron, which would have affected the colour of the
-cloth, and prevented the dyer from accomplishing his object.[97]
-
-[97] “Quoniam inficiendis claro colore lanis candidum liquidumque
-utilissimum est, contraque fuscis et obscuris nigrum.”--_Plinii_, xxxv.
-15.
-
-What the _alumen rotundum_ was, is not easily conjectured. Dioscorides
-says, that it was sometimes made artificially; but that the artificial
-alumen rotundum was not much valued. The best, he says, was full of
-air-bubbles, nearly white, and of a very astringent taste. It had a
-slaty appearance, and was found in Egypt or the Island of Melos.
-
-The _liquid alumen_ was limpid, milky, of an equal colour, free from
-hard concretions, and having a fiery shade of colour.[98] In its
-nature, it was similar to the alumen candidum; it must therefore have
-consisted chiefly, at least, of sulphate of alumina.
-
-[98] See Dioscorides, lib. v. c. 123. Plinii Hist. Nat. xxxv. 18.
-
-Bitumen and naphtha were known to the ancients, and used by them
-to give light instead of oil; they were employed also as external
-applications in cases of disease, and were considered as having
-the same virtues as sulphur. It is said, that the word translated
-_salt_ in the New Testament--“Ye are the salt of the earth: but if
-the salt have lost his savour, wherewith shall it be salted? It is
-henceforth good for nothing, but to be cast out, and to be trodden
-under foot of men”[99]--it is said, that the word salt in this passage
-refers to asphalt, or bitumen, which was used by the Jews in their
-sacrifices, and called _salt_ by them. But I have not been able to find
-satisfactory evidence of the truth of this opinion. It is obvious from
-the context, that the word translated _salt_ could not have had that
-meaning among the Jews; because salt never can be supposed to lose its
-savour. Bitumen, while liquid, has a strong taste and smell, which it
-loses gradually by exposure to the air, as it approaches more and more
-to a solid form.
-
-[99] Matthew v. 13.--“Ὑμεις εστε το ἁλας της γης· εαν δε το ἁλας
-μωρανθη, εν τινι ἁλισθησεται· εις ουδεν ισχωει ετι ει μη βληθηναι εξω,
-και καταπατεισθαι ὑπο των ανθρωπων.”
-
-Asphalt was one of the great constituents of the Greek fire. A great
-bed of it still existing in Albania, supplied the Greeks with this
-substance. Concerning the nature of the Greek fire, it is clear that
-many exaggerated and even fabulous statements have been published.
-The obvious intention of the Greeks being, probably, to make their
-invention as much dreaded as possible by their enemies. Nitre was
-undoubtedly one of the most important of its constituents; though
-no allusion whatever is ever made. We do not know when _nitrate of
-potash_, the nitre of the moderns, became known in Europe. It was
-discovered in the east; and was undoubtedly known in China and India
-before the commencement of the Christian era. The property of nitre,
-as a supporter of combustion, could not have remained long unknown
-after the discovery of the salt. The first person who threw a piece of
-it upon a red-hot coal would observe it. Accordingly we find that its
-use in fireworks was known very early in China and India; though its
-prodigious expansive power, by which it propels bullets with so great
-and destructive velocity, is a European invention, posterior to the
-time of Roger Bacon.
-
-The word _nitre_ (רתנ) had been applied by the ancients to _carbonate
-of soda_, a production of Egypt, where it is still formed from
-sea-water, by some unknown process of nature in the marshes near
-Alexandria. This is evident, not merely from the account given of it
-by Dioscorides and Pliny; for the following passage, from the Old
-Testament, shows that it had the same meaning among the Jews: “As he
-that taketh away a garment in cold weather, is as vinegar upon nitre:
-so is he that singeth songs to a heavy heart.”[100] Vinegar poured upon
-saltpetre produces no sensible effect whatever, but when poured upon
-carbonate of soda, it occasions an _effervescence_. When saltpetre
-came to be imported to Europe, it was natural to give it the same
-name as that applied to carbonate of soda, to which both in taste and
-appearance it bore some faint resemblance. Saltpetre possessing much
-more striking properties than carbonate of soda much more attention
-was drawn to it, and it gradually fixed upon itself the term _nitre_,
-at first applied to a different salt. When this change of nomenclature
-took place does not appear; but it was completed before the time of
-Roger Bacon, who always applies the term _nitrum_ to our nitrate of
-potash and never to carbonate of soda.
-
-[100] Proverbs xxv. 20.
-
-In the preceding history of the chemical facts known to the ancients,
-I have taken no notice of a well-known story related of Cleopatra.
-This magnificent and profligate queen boasted to Antony that she would
-herself consume a million of sistertii at a supper. Antony smiled at
-the proposal, and doubted the possibility of her performing it. Next
-evening a magnificent entertainment was provided, at which Antony, as
-usual, was present, and expressed his opinion that the cost of the
-feast, magnificent as it was, fell far short of the sum specified by
-the queen. She requested him to defer computing till the dessert
-was finished. A vessel filled with vinegar was placed before her, in
-which she threw two pearls, the finest in the world, and which were
-valued at ten millions of sistertii; these pearls were dissolved by
-the vinegar,[101] and the liquid was immediately drunk by the queen.
-Thus she made good her boast, and destroyed the two finest pearls in
-the world.[102] This story, supposing it true, shows that Cleopatra
-was aware that vinegar has the property of dissolving pearls. But not
-that she knew the nature of these beautiful productions of nature. We
-now know that pearls consist essentially of carbonate of lime, and that
-the beauty is owing to the thin concentric laminæ, of which they are
-composed.
-
-[101] “Cujus asperitas visque in tabem margeritas resolvit.”
-
-[102] Plinii Hist. Nat. ix. 35.
-
-Nor have I taken any notice of lime with which the ancients were well
-acquainted, and which they applied to most of the uses to which the
-moderns put it. Thus it constituted the base of the Roman mortar, which
-is known to have been excellent. They employed it also as a manure
-for the fields, as the moderns do. It was known to have a corrosive
-nature when taken internally; but was much employed by the ancients
-externally, and in various ways as an application to ulcers. Whether
-they knew its solubility in water does not appear; though, from the
-circumstance of its being used for making mortar, this fact could
-hardly escape them. These facts, though of great importance, could
-scarcely be applied to the rearing of a chemical structure, as the
-ancients could have no notion of the action of acids upon lime, or of
-the numerous salts which it is capable of forming. Phenomena which
-must have remained unknown till the discovery of the acids enabled
-experimenters to try their effects upon limestone and quicklime. Not
-even a conjecture appears in any ancient writer that I have looked
-into, about the difference between quicklime and limestone. This
-difference is so great that it must have been remarked by them, yet
-nobody seems ever to have thought of attempting to account for it. Even
-the method of burning or calcining lime is not described by Pliny;
-though there can be no doubt that the ancients were acquainted with it.
-
-Nor have I taken any notice of leather or the method of tanning it.
-There are so many allusions to leather and its uses by the ancient
-poets and historians, that the acquaintance of the ancients with it is
-put out of doubt. But so far as I know, there is no description of the
-process of tanning in any ancient author whatever.
-
-
-
-
-CHAPTER III.
-
-CHEMISTRY OF THE ARABIANS.
-
-
-Hitherto I have spoken of Alchymy, or of the chemical manufactures
-of the ancients. The people to whom scientific chemistry owes its
-origin are the Arabians. Not that they prosecuted scientific chemistry
-themselves; but they were the first persons who attempted to form
-chemical medicines. This they did by mixing various bodies with each
-other, and applying heat to the mixture in various ways. This led to
-the discovery of some of the mineral acids. These they applied to
-the metals, &c., and ascertained the effects produced upon that most
-important class of bodies. Thus the Arabians began those researches
-which led gradually to the formation of scientific chemistry. We must
-therefore endeavour to ascertain the chemical facts for which we are
-indebted to the Arabians.
-
-When Mahomet first delivered his dogmas to his countrymen they were not
-altogether barbarous. Possessed of a copious and expressive language,
-and inhabiting a burning climate, their imaginations were lively and
-their passions violent. Poetry and fiction were cultivated by them
-with ardour, and with considerable success. But science and inductive
-philosophy, had made little or no progress among them. The fatalism
-introduced by Mahomet, and the blind enthusiasm which he inculcated,
-rendered them furious bigots and determined enemies to every kind of
-intellectual improvement. The rapidity with which they overran Asia,
-Africa, and even a portion of Europe, is universally known. At that
-period the western world, was sunk into extreme barbarism, and the
-Greeks, with whom the remains of civilization still lingered, were
-sadly degenerated from those sages who graced the classic ages. Bent
-to the earth under the most grinding but turbulent despotism that
-ever disgraced mankind, and having their understandings sealed up by
-the most subtle and absurd, and uncompromising superstition, all the
-energy of mind, all the powers of invention, all the industry and
-talent, which distinguished their ancestors, had completely forsaken
-them. Their writers aimed at nothing new or great, and were satisfied
-with repeating the scientific facts determined by their ancestors. The
-lamp of science fluttered in its socket, and was on the eve of being
-extinguished.
-
-Nothing good or great could be expected from such a state of society.
-It was, therefore, wisely determined by Providence that the Mussulman
-conquerors, should overrun the earth, sweep out those miserable
-governors, and free the wretched inhabitants from the trammels of
-despotism and superstition. As a despotism not less severe, and a
-superstition still more gloomy and uncompromising, was substituted in
-their place, it may seem at first sight, that the conquests of the
-Mahometans brought things into a worse state than they found them. But
-the listless inactivity, the almost deathlike torpor which had frozen
-the minds of mankind, were effectually roused. The Mussulmans displayed
-a degree of energy and activity which have few parallels in the history
-of the world: and after the conquests of the Mahometans were completed,
-and the Califs quietly seated upon the greatest and most powerful
-throne that the world had ever seen; after Almanzor, about the middle
-of the eighth century, had founded the city of Bagdad, and settled a
-permanent and flourishing peace, the arts and sciences, which usually
-accompany such a state of society, began to make their appearance.
-
-That calif founded an academy at Bagdad, which acquired much celebrity,
-and gradually raised itself above all the other academies in his
-dominions. A medical college was established there with powers to
-examine all those persons who intended to devote themselves to the
-medical profession. So many professors and pupils flocked to this
-celebrated college, from all parts of the world, that at one time their
-number amounted to no fewer than six thousand. Public hospitals and
-laboratories were established to facilitate a knowledge of diseases,
-and to make the students acquainted with the method of preparing
-medicines. It was this last establishment which originated with the
-califs that gave a first beginning to the science of chemistry.
-
-In the thirteenth century the calif Mostanser re-established the
-academy and the medical college at Bagdad: for both had fallen
-into decay, and had been replaced by an infinite number of Jewish
-seminaries. Mostanser gave large salaries to the professors, collected
-a magnificent library, and established a new school of pharmacy. He was
-himself often present at the public lectures.
-
-The successor of Mostanser was the calif Haroun-Al-Raschid, the
-perpetual hero of the Arabian tales. He not only carried his love for
-the sciences further than his predecessors, but displayed a liberality
-and a tolerance for religious opinions, which was not quite consistent
-with Mahometan bigotry and superstition. He drew round him the
-Syrian Christians, who translated the Greek classics, rewarded them
-liberally, and appointed them instructors of his Mahometan subjects,
-especially in medicine and pharmacy. He protected the Christian school
-of Dschondisabour, founded by the Nestorian Christians, before the
-time of Mahomet, and still continuing in a flourishing state: always
-surrounded by literary men, he frequently condescended to take a part
-in their discussions, and not unfrequently, as might have been expected
-from his rank, came off victorious.
-
-The most enlightened of all the califs was Almamon, who has rendered
-his name immortal by his exertions in favour of the sciences. It
-was during his reign that the Arabian schools came to be thoroughly
-acquainted with Greek science; he procured the translation of a great
-number of important works. This conduct inflamed the religious zeal
-of the faithful, who devoted him to destruction, and to the divine
-wrath, for favouring philosophy, and in that way diminishing the
-authority of the Koran. Almamon purchased the ancient classics, from
-all quarters, and recommended the care of doing so in a particular
-manner to his ambassadors at the court of the Greek emperors. To Leo,
-the philosopher, he made the most advantageous offers, to induce
-him to come to Bagdad; but that philosopher would not listen to his
-invitation. It was under the auspices of this enlightened prince, that
-the celebrated attempt was made to determine the size of the earth by
-measuring a degree of the meridian. The result of this attempt it does
-not belong to this work to relate.
-
-Almotassem and Motawakkel, who succeeded Almamon, followed his example,
-favoured the sciences, and extended their protection to men of science
-who were Christians. Motawakkel re-established the celebrated academy
-and library of Alexandria. But he acted with more severity than his
-predecessors with regard to the Christians, who may perhaps have abused
-the tolerance which they enjoyed.
-
-The other vicars of the prophet, in the different Mahometan states,
-followed the fine example set them by Almamon. Already in the eighth
-century the sovereigns of Mogreb and the western provinces of
-Africa showed themselves the zealous friends of the sciences. One of
-them called Abdallah-Ebn-Ibadschab rendered commerce and industry
-flourishing at Tunis. He himself cultivated poetry and drew numerous
-artists and men of science into his state. At Fez and in Morocco the
-sciences flourished, especially during the reign of the Edrisites,
-the last of whom, Jahiah, a prince possessed of genius, sweetness,
-and goodness, changed his court into an academy, and paid attention
-to those only who had distinguished themselves by their scientific
-knowledge.
-
-But Spain was the most fortunate of all the Mahometan states, and had
-arrived at such a degree of prosperity both in commerce, manufactures,
-population, and wealth, as is hardly to be credited. The three
-Abdalrahmans and Alhakem carried, from the eighth to the tenth century,
-the country subject to the Calif of Cordova to the highest degree of
-splendour. They protected the sciences, and governed with so much
-mildness, that Spain was probably never so happy under the dominion
-of any Christian prince. Alhakem established at Cordova an academy,
-which for several ages was the most celebrated in the whole world. All
-the Christians of Western Europe repaired to this academy in search of
-information. It contained, in the tenth century, a library of 280,000
-volumes. The catalogue of this library filled no less than forty-four
-volumes. Seville, Toledo, and Murcia, had likewise their schools of
-science and their libraries, which retained their celebrity as long as
-the dominion of the Moors lasted. In the twelfth century there were
-seventy public libraries in that part of Spain which belonged to the
-Mahometans. Cordova had produced one hundred and fifty authors, Almeria
-fifty-two, and Murcia sixty-two.
-
-The Mahometan states of the east continued also to favour the sciences.
-An emir of Irak, Adad-El-Daula by name, distinguished himself towards
-the end of the tenth century by the protection which he afforded
-to men of science. To him almost all the philosophers of the age
-dedicated their works. Another emir of Irak, Saif-Ed-Daula, established
-schools at Kufa and at Bussora, which soon acquired great celebrity.
-Abou-Mansor-Baharam, established a public library at Firuzabad in
-Curdistan, which at its very commencement contained 7000 volumes. In
-the thirteenth century there existed a celebrated school of medicine in
-Damascus. The calif Malek-Adel endowed it richly, and was often present
-at the lectures with a book under his arm.
-
-Had the progress of the sciences among the Arabians been proportional
-to the number of those who cultivated them, we might hail the Saracens
-as the saviours of literature during the dark and benighted ages of
-Christianity; but we must acknowledge with regret, that notwithstanding
-the enlightened views of the califs, notwithstanding the multiplicity
-of academies and libraries, and the prodigious number of writers, the
-sciences received but little improvement from the Arabians. There are
-very few Arabian writers in whose works we find either philosophical
-ideas, successful researches, new facts, or great and new and important
-truths. How, indeed, could such things be expected from a people
-naturally hostile to mental exertion; professing a religion which
-stigmatizes all exercise of the judgment as a crime, and weighed down
-by the heavy yoke of despotism? It was the religion of the Arabians,
-and the despotism of their princes, that opposed the greatest obstacles
-to the progress of the sciences, even during the most flourishing
-period of their civilization.[103] Fortunately chemistry was the
-branch of science least obnoxious to the religious prejudices of the
-Mahometans. It was in it, therefore, that the greatest improvements
-were made: of these improvements it will be requisite now to endeavour
-to give the reader some idea. Astrology and alchymy, they both derived
-from the Greeks: neither of them were inconsistent with the taste of
-the nation--neither of them were anathematized by the Mahometan creed,
-though Islamism prohibited magic and all the arts of divination.
-Alchymy may have suggested the chemical processes--but the Arabians
-applied them to the preparation of medicines, and thus opened a new and
-most copious source of investigation.
-
-[103] For a fuller account of the progress of science among the
-Arabians than would be consistent with this work, the reader is
-referred to Mortucla’s Hist. des Mathématiques, i. 351; Sprengel’s
-Hist. de la Médecine, ii. 246.
-
-The chemical writings of the Arabians which I have had an opportunity
-of seeing and perusing in a Latin dress, being ignorant of the original
-language in which they were written, are those of Geber and Avicenna.
-
-Geber, whose real name was Abou-Moussah-Dschafar-Al-Soli, was a Sabean
-of Harran, in Mesopotamia, and lived during the eighth century. Very
-little is known respecting the history of this writer, who must be
-considered as the patriarch of chemistry. Golius, professor of the
-oriental languages in the University of Leyden, made a present of
-Geber’s work in manuscript to the public library. He translated
-it into Latin, and published it in the same city in folio, and
-afterwards in quarto, under the title of “Lapis Philosophorum.”[104]
-It was translated into English by Richard Russel in 1678, under the
-title of, “The Works of Geber, the most famous Arabian Prince and
-Philosopher.”[105] The works of Geber, so far as they appeared in
-Latin or English, consist of four tracts. The first is entitled, “Of
-the Investigation or Search of Perfection.” The second is entitled, “Of
-the Sum of Perfection, or of the perfect Magistery.” The third, “Of the
-Invention of Verity or Perfection.” And the last, “Of Furnaces, &c.;
-with a Recapitulation of the Author’s Experiments.”
-
-[104] Boerhaave’s Chemistry (Shaw’s translation), i. 26. _Note._
-
-[105] Golius was not, however, the first translator of Geber. A
-translation of the longest and most important of his tracts into Latin
-appeared in Strasburg, in 1529. There was another translation published
-in Italy, from a manuscript in the Vatican. There probably might be
-other translations. I have compared four different copies of Geber’s
-works, and found some differences, though not very material. I have
-followed Russel’s English translation most commonly, as upon the whole
-the most accurate that I have seen.
-
-The object of Geber’s work is to teach the method of making the
-philosopher’s stone, which he distinguishes usually by the name of
-_medicine of the third class_. The whole is in general written with so
-much plainness, that we can understand the nature of the substances
-which he employed, the processes which he followed, and the greater
-number of the products which he obtained. It is, therefore, a book
-of some importance, because it is the oldest chemical treatise in
-existence,[106] and because it makes us acquainted with the processes
-followed by the Arabians, and the progress which they had made in
-chemical investigations. I shall therefore lay before the reader the
-most important facts contained in Geber’s work.
-
-[106] Of course I exclude the writings of the Greek ecclesiastics
-mentioned in a previous part of this work, which still continue in
-manuscript; because, I am ignorant of what they contain.
-
-1. He considered all the metals as compounds of mercury and sulphur:
-this opinion did not originate with him. It is evident from what he
-says, that the same notion had been adopted by his predecessors--men
-whom he speaks of under the title of the _ancients_.
-
-2. The metals with which he was acquainted were _gold_, _silver_,
-_copper_, _iron_, _tin_, and _lead_. These are usually distinguished
-by him under the names of _Sol_, _Luna_, _Venus_, _Mars_, _Jupiter_,
-and _Saturn_. Whether these names of the planets were applied to the
-metals by Geber, or only by his translators, I cannot say; but they
-were always employed by the alchymists, who never designated the metals
-by any other appellations.
-
-3. Gold and silver he considered as perfect metals; but the other four
-were imperfect metals. The difference between them depends, in his
-opinion, partly upon the proportions of mercury and sulphur in each,
-and partly upon the purity or impurity of the mercury and sulphur which
-enters into the composition of each.
-
-Gold, according to him, is created of the most subtile substance of
-mercury and of most clear fixture, and of a small substance of sulphur,
-clean and of pure redness, fixed, clear, and changed from its own
-nature, tinging that; and because there happens a diversity in the
-colours of that sulphur, the yellowness of gold must needs have a like
-diversity.[107] His evidence that gold consisted chiefly of mercury, is
-the great ease with which mercury dissolves gold. For mercury, in his
-opinion, dissolves nothing that is not of its own nature. The lustre
-and splendour of gold is another proof of the great proportion of
-mercury which it contains. That it is a fixed substance, void of all
-burning sulphur, he thinks evident by every operation in the fire, for
-it is neither diminished nor inflamed. His other reasons are not so
-intelligible.[108]
-
-[107] Sum of Perfection, book ii. part i. chap. 5.
-
-[108] Ibid.
-
-Silver, like gold, is composed of much mercury and a little sulphur;
-but in the gold the sulphur is red; whereas the sulphur that goes to
-the formation of silver is white. The sulphur in silver is also clean,
-fixed, and clear. Silver has a purity short of that of gold, and a
-more gross inspissation. The proof of this is, that its parts are not
-so condensed, nor is it so fixed as gold; for it may be diminished by
-fire, which is not the case with gold.[109]
-
-[109] Ibid., chap. 6.
-
-Iron is composed of earthy mercury and earthy sulphur, highly fixed,
-the latter in by far the greatest quantity. Sulphur, by the work of
-fixation, more easily destroys the easiness of liquefaction than
-mercury. Hence the reason why iron is not fusible, as is the case with
-the other metals.[110]
-
-[110] Sum of Perfection, book ii. part i. chap. 7.
-
-Sulphur not fixed melts sooner than mercury; but fixed sulphur opposes
-fusion. What contains more fixed sulphur, more slowly admits of fusion
-than what partakes of burning sulphur, which more easily and sooner
-flows.[111]
-
-[111] Ibid.
-
-Copper is composed of sulphur unclean, gross and fixed as to its
-greater part; but as to its lesser part not fixed, red, and livid,
-in relation to the whole not overcoming nor overcome and of gross
-mercury.[112]
-
-[112] Ibid., chap. 8.
-
-When copper is exposed to ignition, you may discern a sulphureous flame
-to arise from it, which is a sign of sulphur not fixed; and the loss
-of the quantity of it by exhalation through the frequent combustion
-of it, shows that it has fixed sulphur. This last being in abundance,
-occasions the slowness of its fusion and the hardness of its substance.
-That copper contains red and unclean sulphur, united to unclean
-mercury, is, he thinks, evident, from its sensible qualities.[113]
-
-[113] Ibid.
-
-Tin consists of sulphur of small fixation, white with a whiteness not
-pure, not overcoming but overcome, mixed with mercury partly fixed and
-partly not fixed, white and impure.[114] That this is the constitution
-of tin he thinks evident; for when calcined, it emits a sulphureous
-stench, which is a sign of sulphur not fixed: it yields no flame, not
-because the sulphur is fixed, but because it contains a great portion
-of mercury. In tin there is a twofold sulphur and also a twofold
-mercury. One sulphur is less fixed, because in calcining it gives out
-a stench as sulphur. The fixed sulphur continues in the tin after it
-is calcined. He thinks that the twofold mercury in tin is evident, from
-this, that before calcination it makes a crashing noise when bent, but
-after it has been thrice calcined, that crashing noise can no longer
-be perceived.[115] Geber says, that if lead be washed with mercury,
-and after its washing melted in a fire not exceeding the fire of its
-fusion, a portion of the mercury will remain combined with the lead,
-and will give it the crashing noise and all the qualities of tin. On
-the other hand, you may convert tin into lead. By manifold repetition
-of its calcination, and the administration of fire convenient for its
-reduction, it is turned into lead.[116]
-
-[114] Ibid., chap. 9.
-
-[115] Sum of Perfection, book ii. part i. chap. 9.
-
-[116] Ibid.
-
-Lead, in Geber’s opinion, differs from tin only in having a more
-unclean substance commixed of the two more gross substances, sulphur
-and mercury. The sulphur in it is burning and more adhesive to the
-substance of its own mercury, and it has more of the substance of fixed
-sulphur in its composition than tin has.[117]
-
-[117] Ibid., chap. 10.
-
-Such are the opinions which Geber entertained respecting the
-composition of the metals. I have been induced to state them as nearly
-in his own words as possible, and to give the reasons which he has
-assigned for them, even when his facts were not quite correct, because
-I thought that this was the most likely way of conveying to the reader
-an accurate notion of the sentiments of this father of the alchymists,
-upon the very foundation of the whole doctrine of the transmutation
-of metals. He was of opinion that all the imperfect metals might be
-transformed into gold and silver, by altering the proportions of the
-mercury and sulphur of which they are composed, and by changing the
-nature of the mercury and sulphur so as to make them the same with the
-mercury and sulphur which constitute gold and silver. The substance
-capable of producing these important changes he calls sometimes the
-_philosopher’s stone_, but generally the _medicine_. He gives the
-method of preparing this important _magistery_, as he calls it. But it
-is not worth while to state his process, because he leaves out several
-particulars, in order to prevent the foolish from reaping any benefit
-from his writings, while at the same time those readers who possess the
-proper degree of sagacity will be able, by studying the different parts
-of his writings, to divine the nature of the steps which he omits, and
-thus profit by his researches and explanations. But it will be worth
-while to notice the most important of his processes, because this will
-enable us to judge of the state of chemistry in his time.
-
-4. In his book on furnaces, he gives a description of a furnace proper
-for calcining metals, and from the fourteenth chapter of the fourth
-part of the first book of his Sum of Perfection, it is obvious that the
-method of calcining or oxidizing iron, copper, tin, and lead, and also
-mercury and arsenic were familiarly known to him.
-
-He gives a description of a furnace for distilling, and a pretty minute
-account of the glass or stoneware, or metallic aludel and alembic,
-by means of which the process was conducted. He was in the habit of
-distilling by surrounding his aludel with hot ashes, to prevent it
-from being broken. He was acquainted also with the water-bath. These
-processes were familiar to him. The description of the distillation of
-many bodies occurs in his work; but there is not the least evidence
-that he was acquainted with ardent spirits. The term _spirit_ occurs
-frequently in his writings, but it was applied to volatile bodies in
-general, and in particular to sulphur and white arsenic, which he
-considered as substances very similar in their properties. Mercury also
-he considered as a spirit.
-
-The method of distilling _per descensum_, as is practised in the
-smelting of zinc, was also known to him. He describes an apparatus for
-the purpose, and gives several examples of such distillations in his
-writings.
-
-He gives also a description of a furnace for melting metals, and
-mentions the vessels in which such processes were conducted. He was
-acquainted with crucibles; and even describes the mode of making
-cupels, nearly similar to those used at present. The process of
-cupellating gold and silver, and purifying them by means of lead, is
-given by him pretty minutely and accurately: he calls it _cineritium_,
-or at least that is the term used by his Latin translator.
-
-He was in the habit of dissolving salts in water and acetic acid, and
-even the metals in different menstrua. Of these menstrua he nowhere
-gives any account; but from our knowledge of the properties of the
-different metals, and from some processes which he notices, it is easy
-to perceive what his solvents must have been; namely, the mineral acids
-which were known to him, and to which there is no allusion whatever
-in any preceding writer that I have had an opportunity of consulting.
-Whether Geber was the discoverer of these acids cannot be known, as
-he nowhere claims the discovery: indeed his object was to slur over
-these acids, as much as possible, that their existence, or at least
-their remarkable properties, might not be suspected by the uninitiated.
-It was this affectation of secrecy and mystery that has deprived the
-earliest chemists of that credit and reputation to which they would
-have been justly entitled, had their discoveries been made known to the
-public in a plain and intelligible manner.
-
-The mode of purifying liquids by filtration, and of separating
-precipitates from liquids by the same means, was known to Geber. He
-called the process _distillation through a filter_.
-
-Thus the greater number of chemical processes, such as they were
-practised almost to the end of the eighteenth century, were known to
-Geber. If we compare his works with those of Dioscorides and Pliny, we
-shall perceive the great progress which chemistry or rather pharmacy
-had made. It is more than probable that these improvements were made
-by the Arabian physicians, or at least by the physicians who filled
-the chairs in the medical schools, which were under the protection of
-the califs: for as no notice is taken of these processes by any of the
-Greek or Roman writers that have come down to us, and as we find them
-minutely described by the earliest chemical writers among the Arabians,
-we have no other alternative than to admit that they originated in the
-east.
-
-I shall now state the different chemical substances or preparations
-which were known to Geber, or which he describes the method of
-preparing in his works.
-
-1. Common salt. This substance occurring in such abundance in the
-earth, and being indispensable as a seasoner of food, was known from
-the earliest ages. But Geber describes the method which he adopted to
-free it from impurities. It was exposed to a red heat, then dissolved
-in water, filtered, crystallized by evaporation, and the crystals being
-exposed to a red heat, were put into a close vessel, and kept for
-use.[118] Whether the identity of sal-gem (_native salt_) and common
-salt was known to Geber is nowhere said. Probably not, as he gives
-separate directions for purifying each.
-
-[118] Investigation and Search of Perfection, chap. 3.
-
-2. Geber gives an account of the two fixed alkalies, _potash_ and
-_soda_, and gives processes for obtaining them. Potash was obtained by
-burning cream of tartar in a crucible, dissolving the residue in water,
-filtering the solution, and evaporating to dryness.[119] This would
-yield a pure carbonate of potash.
-
-[119] Invention of Verity, chap. 4.
-
-Carbonate of soda he calls _sagimen vitri_, and salt of soda. He
-mentions plants which yield it when burnt, points out the method of
-purifying it, and even describes the method of rendering it caustic by
-means of quicklime.[120]
-
-[120] Search of Perfection, chap. 3.
-
-3. Saltpetre, or nitrate of potash, was known to him; and Geber is the
-first writer in whom we find an account of this salt. Nothing is said
-respecting its origin; but there can be little doubt that it came from
-India, where it was collected, and known long before Europeans were
-acquainted with it. The knowledge of this salt was probably one great
-cause of the superiority of the Arabians over Europeans in chemical
-knowledge; for it enabled them to procure _nitric acid_, by means of
-which they dissolved all the metals known in their time, and thus
-acquired a knowledge of various important saline compounds, which were
-of considerable importance.
-
-There is a process for preparing saltpetre artificially, in several of
-the Latin copies of Geber, though it does not appear in our English
-translation. The method was to dissolve sagimen vitri, or carbonate of
-soda, in aqua fortis, to filter and crystallize by evaporation.[121]
-If this process be genuine, it is obvious that Geber must have been
-acquainted with nitrate of soda; but I have some doubts about the
-genuineness of the passage, because the term _aqua fortis_ occurs in
-it. Now this term occurs nowhere else in Geber’s work: even when he
-gives the process for procuring nitric acid, he calls it simply water;
-but observes, that it is a water possessed of much virtue, and that it
-constitutes a precious instrument in the hands of the man who possesses
-sagacity to use it aright.
-
-[121] De Investigatione Perfect. chap. 4.
-
-4. Sal ammoniac was known to Geber, and seems to have been quite common
-in his time. There is no evidence that it was known to the Greeks or
-Romans, as neither Dioscorides nor Pliny make any allusion to it.
-The word in old books is sometimes _sal armoniac_, sometimes _sal
-ammoniac_. It is supposed to have been brought originally from the
-neighbourhood of the temple of Jupiter Ammon: but had this been the
-case, and had it occurred native, it could scarcely have been unknown
-to the Romans, under whose dominions that part of Africa fell. In
-the writings of the alchymists, sal ammoniac is mentioned under the
-following whimsical names:
-
-    Anima sensibilis,
-    Aqua duorum fratrum ex sorore,
-    Aquila,
-    Lapis aquilinis,
-    Cancer,
-    Lapis angeli conjungentis,
-    Sal lapidum,
-    Sal alocoph.
-
-Geber not only knew sal ammoniac, but he was aware of its volatility;
-and gives various processes for subliming it, and uses it frequently
-to promote the sublimation of other bodies, as of oxides of iron
-and copper. He gives also a method of procuring it from urine, a
-liquid which, when allowed to run into putrefaction, is known to
-yield it in abundance. Sal ammoniac was much used by Geber, in his
-various processes to bring the inferior metals to a state of greater
-perfection. By adding it or common salt to aqua fortis, he was enabled
-to dissolve gold, which certainly could not be accomplished in the
-time of Dioscorides or Pliny. The description, indeed, of Geber’s
-process for dissolving gold is left on purpose in a defective state;
-but an attentive reader will find no great difficulty in supplying the
-defects, and thus understanding the whole of the process.
-
-5. Alum, precisely the same as the alum of the moderns, was familiarly
-known to Geber, and employed by him in his processes. The manufacture
-of this salt, therefore, had been discovered between the time when
-Pliny composed his Natural History and the eighth century, when Geber
-wrote; unless we admit that the mode of making it had been known to
-the Tyrian dyers, but that they had kept the secret so well, that no
-suspicion of its existence was entertained by the Greeks and Romans.
-That they employed _alumina_ as a mordant in some of their dyes, is
-evident; but there is no proof whatever that _alum_, in the modern
-sense of the word, was known to them.
-
-Geber mentions three alums which he was in the habit of using; namely,
-icy alum, or Rocca alum; Jamenous alum, or alum of Jameni, and feather
-alum. _Rocca_, or _Edessa_, in Syria, is admitted to have been the
-place where the first manufactory of alum was established; but at what
-time, or by whom, is quite unknown: we know only that it must have
-been posterior to the commencement of the Christian era, and prior to
-the eighth century, when Geber wrote. Jameni must have been another
-locality where, at the time of Geber, a manufactory of alum existed.
-_Feather alum_ was undoubtedly one of the native impure varieties of
-_alum_, known to the Greeks and Romans. Geber was in the habit of
-distilling alum by a strong heat, and of preserving the water which
-came over as a valuable menstruum. If alum be exposed to a red heat
-in glass vessels, it will give out a portion of sulphuric acid: hence
-water distilled from alum by Geber was probably a weak solution of
-sulphuric acid, which would undoubtedly act powerfully as a solvent of
-iron, and of the alkaline carbonates. It was probably in this way that
-he used it.
-
-6. Sulphate of iron or copperas, as it is called (_cuperosa_), in the
-state of a crystalline salt, was well known to Geber, and appears in
-his time to have been manufactured.
-
-7. Baurach, or borax, is mentioned by him, but without any description
-by which we can know whether or not it was our borax: the probability
-is that it was. Both glass and borax were used by him when the oxides
-of metals were reduced by him to the metallic state.
-
-8. Vinegar was purified by him by distilling it over, and it was used
-as a solvent in many of his processes.
-
-9. Nitric acid was known to him by the name of _dissolving water_. He
-prepared it by putting into an alembic one pound of sulphate of iron of
-Cyprus, half a pound of saltpetre, and a quarter of a pound of alum of
-Jameni: this mixture was distilled till every thing liquid was driven
-over. He mentions the red fumes which make their appearance in the
-alembic during the process.[122] This process, though not an economical
-one, would certainly yield nitric acid; and it is remarkable, because
-it is here that we find the first hint of the knowledge of chemists of
-this most important acid, without which many chemical processes of the
-utmost importance could not be performed at all.
-
-[122] Invention of Verity, chap. 23.
-
-10. This acid, thus prepared, he made use of to dissolve silver: the
-solution was concentrated till the nitrate of silver was obtained by
-him in a crystallized state. This process is thus described by him:
-“Dissolve silver calcined in solutive water (_nitric acid_), as before;
-which being done, coct it in a phial with a long neck, the orifice of
-which must be left unstopped, for one day only, until a third part of
-the water be consumed. This being effected, set it with its vessel in
-a cold place, and then it is converted into small fusible stones, like
-crystal.”[123]
-
-[123] Ibid., chap. 21.
-
-11. He was in the habit also of dissolving sal ammoniac in this nitric
-acid, and employing the solution, which was the aqua regia of the old
-chemists, to dissolve gold.[124] He assures us that this aqua regia
-would dissolve likewise sulphur and silver. The latter assertion is
-erroneous. But sulphur is easily converted into sulphuric acid by the
-action of aqua regia, and of course it disappears or dissolves.
-
-[124] Ibid., chap. 23.
-
-12. Corrosive sublimate is likewise described by Geber in a very
-intelligible manner. His method of preparing it was as follows: “Take
-of mercury one pound, of dried sulphate of iron two pounds, of alum
-calcined one pound, of common salt half a pound, and of saltpetre a
-quarter of a pound: incorporate altogether by trituration and sublime;
-gather the white, dense, and ponderous portions which shall be found
-about the sides of the vessel. If in the first sublimation you find it
-turbid or unclean (which may happen by reason of your own negligence),
-sublime a second time with the same fuses.”[125] Still more minute
-directions are given in other parts of the work: we have even some
-imperfect account of the properties of corrosive sublimate.
-
-[125] Invention of Verity, chap. 8.
-
-13. Corrosive sublimate is not the only preparation of mercury
-mentioned by Geber. He informs us that when mercury is combined
-with sulphur it assumes a red colour, and becomes cinnabar.[126] He
-describes the affinities of mercury for the different metals. It
-adheres easily to three metals; namely, lead, tin, and gold; to silver
-with more difficulty. To copper with still more difficulty than to
-silver; but to iron it unites in nowise unless by artifice.[127] This
-is a tolerably accurate account of the matter. He says, that mercury is
-the heaviest body in nature except gold, which is the only metal that
-will sink in it.[128] Now this was true, applied to all the substances
-known when Geber lived.
-
-[126] Sum of Perfection, book i. part iii. chap. 4.
-
-[127] Ibid., chap. 6.
-
-[128] Ibid.
-
-He gives an account of the method of forming the peroxide of mercury
-by heat; that variety of it formerly distinguished by the name of _red
-precipitati per se_. “Mercury,” he says, “is also coagulated by long
-and constant retention in fire, in a glass vessel with a very long
-neck and round belly; the orifice of the neck being kept open, that
-the humidity may vanish thereby.”[129] He gives another process for
-preparing this oxide, possible, perhaps, though certainly requiring
-very cautious regulation of the fire. “Take,” says he, “of mercury
-one pound, of vitriol (sulphate of iron) rubified two pounds, and of
-saltpetre one pound. Mortify the mercury with these, and then sublime
-it from rock alum and saltpetre in equal weights.”[130]
-
-[129] Sum of Perfection, book i. part iv. chap. 16.
-
-[130] Invention of Verity, chap. 10.
-
-14. Geber was acquainted with several of the compounds of metals with
-sulphur. He remarks that sulphur when fused with metals increases their
-weight.[131] Copper combined with sulphur becomes yellow, and mercury
-red.[132] He knew the method of dissolving sulphur in caustic potash,
-and again precipitating it by the addition of an acid. His process is
-as follows: “Grind clear and gummose sulphur to a most subtile powder,
-which boil in a lixivium made of ashes of _heartsease_ and quicklime,
-gathering from off the surface its oleaginous combustibility, until it
-be discerned to be clear. This being done, stir the whole with a stick,
-and then warily take off that which passeth out with the lixivium,
-leaving the more gross parts in the bottom. Permit that extract to
-cool a little, and upon it pour a fourth part of its own quantity of
-distilled vinegar, and then will the whole suddenly be congealed as
-milk. Remove as much of the clear lixivium as you can; but dry the
-residue with a gentle fire and keep it.”[133]
-
-[131] Sum of Perfection, book i. part iii. chap. 4.
-
-[132] Ibid.
-
-[133] Invention of Verity, chap. 6.
-
-15. It would appear from various passages in Geber’s works that he was
-acquainted with arsenic in the metallic state. He frequently mentions
-its combustibility, and considers it as the _compeer_ of sulphur.
-And in his book on _Furnaces_, chapter 25 (or 28 in some copies), he
-expressly mentions _metallic arsenic_ (_arsenicum metallinum_), in a
-preparation not very intelligible, but which he considered of great
-importance. The white oxide of arsenic or arsenious acid, was obviously
-well known to him. He gives more than one process for obtaining it by
-sublimation.[134] He observes in his Sum of Perfection, book i. part
-iv. chap. 2, which treats of sublimation, “Arsenic, which before its
-sublimation was evil and prone to adustion, after its sublimation,
-suffers not itself to be inflamed; but only resides without
-inflammation.”
-
-[134] Invention of Verity, chap. 7.
-
-Geber states the fact, that when arsenic is heated with copper that
-metal becomes white.[135] He gives also a process by which the white
-arseniate of iron is obviously made. “Grind one pound of iron filings
-with half a pound of sublimed arsenic (arsenious acid). Imbibe the
-mixture with the water of saltpetre, and salt-alkali, repeating this
-imbibation thrice. Then make it flow with a violent fire, and you will
-have your iron white. Repeat this labour till it flow sufficiently with
-peculiar dealbation.”[136]
-
-[135] Sum of Perfection, book ii. part. ii. chap. 11.
-
-[136] Invention of Verity, chap. 14.
-
-16. He mentions oxide of copper under the name of _æs ustum_, the red
-oxide of iron under the name of _crocus_ of iron. He mentions also
-litharge and red lead.[137] But as all these substances were known to
-the Greeks and Romans, it is needless to enter into any particular
-details.
-
-[137] Ibid., chap. 4 and 12.
-
-17. I am not sure what substance Geber understood by the word
-_marchasite_. It was a substance which must have been abundant, and in
-common use, for he refers to it frequently, and uses it in many of his
-processes; but he nowhere informs us what it is. I suspect it may have
-been sulphuret of antimony, which was certainly in common use in Asia
-long before the time of Geber. But he also makes mention of antimony
-by name, or at least the Latin translator has made use of the word
-_antimonium_. When speaking of the reduction of metals after heating
-them with sulphur, he says, “The reduction of tin is converted into
-clear antimony; but of lead, into a dark-coloured antimony, as we have
-found by proper experience.”[138] It is not easy to conjecture what
-meaning the word antimony is intended to convey in this passage. In
-another passage he says, “Antimony is calcined, dissolved, clarified,
-congealed, and ground to powder, so it is prepared.”[139]
-
-[138] Sum of Perfection, book ii. part iii. chap. 10.
-
-[139] Invention of Verity, chap. 4.
-
-18. Geber’s description of the metals is tolerably accurate,
-considering the time when he wrote. As an example I shall subjoin his
-account of gold. “Gold is a metallic body, yellow, ponderous, mute,
-fulged, equally digested in the bowels of the earth, and very long
-washed with mineral water; under the hammer extensible, fusible, and
-sustaining the trial of the cupel and cementation.”[140] He gives an
-example of copper being changed into gold. “In copper-mines,” he says,
-“we see a certain water which flows out, and carries with it thin
-scales of copper, which (by a continual and long-continued course) it
-washes and cleanses. But after such water ceases to flow, we find these
-thin scales with the dry sand, in three years time to be digested with
-the heat of the sun; and among these scales the purest gold is found:
-therefore we judge those scales were cleansed by the benefit of the
-water, but were equally digested by heat of the sun, in the dryness of
-the sand, and so brought to equality.”[141] Here we have an example of
-plausible reasoning from defective premises. The gold grains doubtless
-existed in the sand before, while the scales of copper in the course of
-three years would be oxidized and converted into powder, and disappear,
-or at least lose all their metallic lustre.
-
-[140] Sum of Perfection, book i. part iii. chap. 8.
-
-[141] Ibid., book i. part iii. chap. 8.
-
-Such are the most remarkable chemical facts which I have observed in
-the works of Geber. They are so numerous and important, as to entitle
-him with some justice to the appellation of the father and founder of
-chemistry. Besides the metals, sulphur and salt, with which the Greeks
-and Romans were acquainted, he knew the method of preparing sulphuric
-acid, nitric acid, and aqua regia. He knew the method of dissolving
-the metals by means of these acids, and actually prepared nitrate of
-silver and corrosive sublimate. He was acquainted with potash and
-soda, both in the state of carbonates and caustic. He was aware that
-these alkalies dissolve sulphur, and he employed the process to obtain
-sulphur in a state of purity.
-
-But notwithstanding the experimental merit of Geber, his spirit of
-philosophy did not much exceed that of his countrymen. He satisfied
-himself with accounting for phenomena by occult causes, as was the
-universal custom of the Arabians; a practice quite inconsistent with
-real scientific progress. That this was the case will appear from the
-following passage, in which Geber attempts to give an explanation
-of the properties of the _great elixir_ or _philosopher’s stone_:
-“Therefore, let him attend to the properties and ways of action of
-the composition of the greater elixir. For we endeavour to make one
-substance, yet compounded and composed of many, so permanently fixed,
-that being put upon the fire, the fire cannot injure; and that it may
-be mixed with metals in flux and flow with them, and enter with that
-which in them is of an ingressible substance, and be fermented with
-that which in them is of a permixable substance; and be consolidated
-with that which in them is of a consolidable substance; and be
-fixed with that which in them is of a fixable substance; and not be
-burnt by those things which burn not gold and silver; and take away
-consolidation and weights with due ignition.”[142]
-
-[142] Investigation of Perfections, chap. 11.
-
-The next Arabian whose name I shall introduce into this history, is
-Al-Hassain-Abou-Ali-Ben-Abdallah-Ebn-Sina, surnamed Scheik Reyes, or
-prince of physicians, vulgarly known by the name of _Avicenna_. Next to
-Aristotle and Galen, his reputation was the highest, and his authority
-the greatest of all medical practitioners; and he reigned paramount, or
-at least shared the medical sceptre till he was hurled from his throne
-by the rude hands of Paracelsus.
-
-Avicenna was born in the year 978, at Bokhara, to which place his
-father had retired during the emirate of the calif Nuhh, one of the
-sons of the celebrated Almansor. Ali, his father, had dwelt in Balkh,
-in the Chorazan. After the birth of Avicenna he went to Asschena in
-Bucharia, where he continued to live till his son had reached his
-fifteenth year. No labour nor expense was spared on the education of
-Avicenna, whose abilities were so extraordinary that he is said to
-have been able to repeat the whole Koran by heart at the age of ten
-years. Ali gave him for a master Abou-Abdallah-Annatholi, who taught
-him grammar, dialectics, the geometry of Euclid, and the astronomy of
-Ptolemy. But Avicenna quitted his tuition because he could not give him
-the solution of a problem in logic. He attached himself to a merchant,
-who taught him arithmetic, and made him acquainted with the Indian
-numerals from which our own are derived. He then undertook a journey
-to Bagdad, where he studied philosophy under the great Peripatician,
-Abou-Nasr-Alfarabi, a disciple of Mesue the elder. At the same time
-he applied himself to medicine, under the tuition of the Nestorian,
-Abou-Sahel-Masichi. He informs us himself that he applied with an
-extraordinary ardour to the study of the sciences. He was in the habit
-of drinking great quantities of liquids during the night, to prevent
-him from sleeping; and he often obtained in a dream a solution of those
-problems at which he had laboured in vain while he was awake. When the
-difficulties to be surmounted appeared to him too great, he prayed to
-God to communicate to him a share of his wisdom; and these prayers, he
-assures us, were never offered in vain. The metaphysics of Aristotle
-was the only book which he could not comprehend, and after reading them
-over forty times, he threw them aside with great anger at himself.
-
-Already, at the age of sixteen, he was a physician of eminence; and at
-eighteen he performed a brilliant cure on the calif Nuhh, which gave
-him such celebrity that Mohammed, Calif of Chorazan, invited him to his
-palace; but Avicenna rather chose to reside at Dschordschan, where he
-cured the nephew of the calif Kabus of a grievous distemper.
-
-Afterwards he went to Ray, where he was appointed physician to Prince
-Magd-Oddaula. Here he composed a dictionary of the sciences. Sometime
-after this he was raised to the dignity of vizier at Hamdan; but he
-was speedily deprived of his office and thrown into prison for having
-favoured a sedition. While incarcerated he wrote many works on medicine
-and philosophy. By-and-by he was set at liberty, and restored to his
-dignity; but after the death of his protector, Schems-Oddaula, being
-afraid of a new attempt to deprive him of his liberty, he took refuge
-in the house of an apothecary, where he remained long concealed and
-completely occupied with his literary labours. Being at last discovered
-he was thrown into the castle of Berdawa, where he was confined for
-four months. At the end of that time a fortunate accident enabled
-him to make his escape, in the disguise of a monk. He repaired to
-Ispahan, where he lived much respected at the court of the calif
-Ola-Oddaula. He did not live to a great age, because he had worn out
-his constitution by too free an indulgence of women and wine. Having
-been attacked by a violent colic, he caused eight injections, prepared
-from long pepper, to be thrown up in one day. This excessive use of so
-irritating a remedy, occasioned an excoriation of the intestines, which
-was followed by an attack of epilepsy. A journey to Hamdan, in company
-with the calif, and the use of mithridate, into which his servant by
-mistake had put too much opium, contributed still further to put an end
-to his life. He had scarcely arrived at the town when he died in the
-fifty-eighth year of his age, in the year 1036.
-
-Avicenna was the author of the immense work entitled “Canon,” which
-was translated into Latin, and for five centuries constituted the
-great standard, the infallible guide, the confession of faith of the
-medical world. All medical knowledge was contained in it; and nothing
-except what was contained in it was considered by medical men as of any
-importance. When we take a view of the Canon, and compare it with the
-writings of the Greeks, and even of the Arabians, that preceded it, we
-shall find some difficulty in accounting for the unbounded authority
-which he acquired over the medical world, and for the length of time
-during which that authority continued.
-
-But it must be remembered, that Avicenna’s reign occupies the darkest
-and most dreary period of the history of the human mind. The human
-race seems to have been asleep, and the mental faculties in a state
-of complete torpor. Mankind, accustomed in their religious opinions
-to obey blindly the infallible decisions of the church, and to think
-precisely as the church enjoined them to think, would naturally
-look for some means to save them the trouble of thinking on medical
-subjects; and this means they found fortunately in the canons of
-Avicenna. These canons, in their opinion, were equally infallible with
-the decisions of the holy father, and required to be as implicitly
-obeyed. The whole science of medicine was reduced to a simple perusal
-of Avicenna’s Canon, and an implicit adherence to his rules and
-directions.
-
-When we compare this celebrated work with the medical writings of the
-Greeks, and even of the Arabians, the predecessors of Avicenna, we
-shall be surprised that it contains little or nothing which can be
-considered as original; the whole is borrowed from the writings of
-Galen, or Ætius, or Rhazes: scarcely ever does he venture to trust his
-own wings, but rests entirely on the sagacity of his Greek and Arabian
-predecessors. Galen is his great guide; or, if he ever forsake him, it
-is to place himself under the direction of Aristotle.
-
-The Canon contains a collection of most of the valuable information
-contained in the writings of the ancient Greek physicians, arranged,
-it must be allowed, with great clearness. The Hhawi of Razes is almost
-as complete; but it wants the _lucidus ordo_ which distinguishes the
-Canon of Avicenna. I conceive that the high reputation which Avicenna
-acquired, was owing to the care which he bestowed upon his arrangement.
-He was undoubtedly a man of abilities, but not of inventive genius.
-There is little original matter in the Canon. But the physicians in the
-west, while Avicenna occupied the medical sceptre, had no opportunity
-of judging of the originality of their oracle, because they were
-unacquainted with the Greek language, and could not therefore consult
-the writings of Galen or Ætius, except through the corrupt medium of an
-Arabian version.
-
-But it is not the medical reputation of Avicenna that induced me to
-mention his name here. Like all the Arabian physicians, he was also a
-chemist; and his chemical tracts having been translated into Latin, and
-published in Western Europe, we are enabled to judge of their merit,
-and to estimate the effect which they may have had upon the progress
-of chemistry. The first Latin translation of the chemical writings of
-Avicenna was published at Basil in 1572; they consist of two separate
-books; the first, under the name of “Porta Elementorum,” consists of a
-dialogue between a master and his pupil, respecting the mysteries of
-Alchymy. He gives an account of the four elements, fire, air, water,
-earth, and gives them their usual qualities of dry, moist, hot, and
-cold. He then treats of air, which, he says, is the food of fire, of
-water, of honey, of the mutual conversion of the elements into each
-other; of milk and cheese, of the mixture of fire and water, and that
-all things are composed of the four elements. There is nothing in
-this tract which has any pretension to novelty; he merely retails the
-opinions of the Greek philosophers.
-
-The other treatise is much larger, and professes to teach the whole
-art of alchymy; it is divided into ten parts, entitled “Dictiones.”
-The first diction treats of the philosopher’s stone in general; the
-second diction treats of the method of converting light things into
-heavy, hard things into soft; of the mutation of the elements; and of
-some other particulars of a nature not very intelligible. The third
-diction treats of the formation of the elixir; and the same subject is
-continued in the fourth.
-
-The fifth diction is one of the most important in the whole treatise;
-it is in general intelligible, which is more than can be said of those
-that precede it. This diction is divided into twenty-eight chapters:
-the first chapter treats of copper, which, he says, is of three kinds;
-permenian copper, natural copper, and Navarre copper. But of these
-three varieties he gives no account whatever; though he enlarges a good
-deal on the qualities of copper--not its properties, but its supposed
-medicinal action. It is hot and dry, he says, but in the calx of it
-there is humidity. His account of the composition of copper is the same
-with that of Geber.
-
-The second chapter treats of lead, the third of tin, and in the
-remaining chapters he treats successively of brass, iron, gold, silver,
-marcasite, sulphuret of antimony, which is distinguished by the name of
-alcohol; of soda, which he says is the juice of a plant called _sosa_.
-And he gives an unintelligible process by which it is extracted from
-that plant, without mentioning a syllable about the combustion to which
-it is obvious that it must have been subjected.
-
-In the twelfth chapter he treats of saltpetre, which, he says, is
-brought from Sicily, from India, from Egypt, and from Herminia. He
-describes several varieties of it, but mentions nothing about its
-characteristic property of deflagrating upon burning coals. He then
-treats successively of common salt, of sal-gem, of vitriol, of sulphur,
-of orpiment, and of sal ammoniac, which, he says, comes from Egypt,
-from India, and from Forperia. In the nineteenth and subsequent
-chapters he treats of aurum vivum, of hair, of urine, of eggs, of
-blood, of glass, of white linen, of horse-dung, and of vinegar.
-
-The sixth diction, in thirty-three chapters, treats of the calcination
-of the metals, of sublimation, and of some other processes. I think it
-unnecessary to be more particular, because I cannot perceive any thing
-in it that had not been previously treated of by Geber.
-
-The seventh diction treats of the preparation of blood and eggs, and
-the method of dividing them into their four elements. It treats also
-of the elixir of silver, and the elixir of gold; but it contains no
-chemical fact of any importance.
-
-The eighth diction treats of the preparation of the ferment of silver,
-and of gold. The ninth diction treats of the whole magistery, and of
-the nuptials of the sun and moon; that is, of gold and silver. The
-tenth diction treats of weights.
-
-The chemical writings of Avicenna are of little value, and apply
-chemistry rather to the supposed medical qualities of the different
-substances treated of, than to the advancement of the science. All
-the chemical knowledge which he possesses is obviously drawn from
-Geber. Geber, then, may be looked upon as the only chemist among the
-Arabians to whom we are indebted for any real improvements and new
-facts. It is true that the Arabian physicians improved considerably the
-materia medica of the Greeks, and introduced many valuable medicines
-into common use which were unknown before their time. It is enough
-to mention corrosive sublimate, manna, opium, asafœtida. It would
-be difficult to make out many of the vegetable substances used by
-the Arabian chemists; because the plants which they designated by
-particular names, can very seldom be identified. Botany at that time
-had made so little progress, that no method was known of describing
-plants so as to enable other persons to determine what they were.
-
-
-
-
-CHAPTER IV
-
-OF THE PROGRESS OF CHEMISTRY UNDER PARACELSUS AND HIS DISCIPLES.
-
-
-Hitherto we have witnessed only the first rude beginnings, or, as
-it were, the early dawn of the chemical day. It is from the time of
-Paracelsus that the true commencement of chemical investigations is to
-be dated. Not that Paracelsus or his followers understood the nature
-of the science, or undertook any regular or successful investigation.
-But Paracelsus shook the medical throne of Galen and Avicenna to its
-very foundation; he roused the latent energies of the human mind, which
-had for so long a period lain torpid; he freed medical men from those
-trammels, and put an end to that despotism which had existed for five
-centuries. He pointed out the importance of chemical medicines, and
-of chemical investigations, to the physician. This led many laborious
-men to turn their attention to the subject. Those metals which were
-considered as likely to afford useful medicines, mercury for example,
-and antimony, were exposed to the action of an infinite number of
-reagents, and a prodigious collection of new products obtained and
-introduced into medicine. Some of these were better, and some worse,
-than the preparations formerly employed; but all of them led to an
-increase of the stock of chemical knowledge, which now began to
-accumulate with considerable rapidity. It will be proper, therefore,
-to give a somewhat particular account of the life and opinions
-of Paracelsus, so far as they can be made out from his writings,
-because, though he was not himself a scientific chemist, he may be
-truly considered as the man through whose means the stock of chemical
-knowledge was accumulated, which was afterwards, by the ingenuity of
-Beccher, and Stahl, moulded into a scientific form.
-
-Philippus Aureolus Theophrastus Paracelsus Bombast ab Hohenheim (as
-he denominates himself) was born at Einsideln, two German miles from
-Zurich. His father was called William Bombast von Hohenheim. He was
-a very near relation of George Bombast von Hohenheim, who became
-afterwards grand master of the order of Johannites. William Bombast
-von Hohenheim practised medicine at Einsideln.[143] After receiving
-the first rudiments of his education in his native city, he became
-a wandering scholastic, as was then the custom with poor scholars.
-He wandered from province to province, predicting the future by the
-position of the stars, and the lines on the hand, and exhibiting
-all the chemical processes which he had learned from founders and
-alchymists. For his initiation in alchymy, astrology, and medicine,
-he was indebted to his father, who was much devoted to these three
-sciences. Paracelsus mentions also the names of several ecclesiastics
-from whom he received chemical information; among others, Tritheimius,
-abbot of Spanheim; Bishop Scheit, of Stettbach; Bishop Erhart, of
-Laventall; Bishop Nicolas, of Hippon; and Bishop Matthew Schacht.
-He seems also to have served some years as an army surgeon, for he
-mentions many cures which he performed in the Low Countries, in the
-States of the Church, in the kingdom of Naples, and during the wars
-against the Venetians, the Danes, and the Dutch.
-
-[143] See Testamentum Paracelsi, passim.
-
-There is some uncertainty whether he received a regular college
-education, as was then the practice with all medical men. He
-acknowledges himself that his medical antagonists reproached him with
-never having frequented their schools; and he is perpetually affirming,
-that a physician should receive all his knowledge from God, and not
-from man. But if we can trust his own assertions, there can be no doubt
-that he took a regular medical degree, which implies a regular college
-education. He tells us, in his preface to his Chirurgia Magna, that he
-visited the universities of Germany, France, and Italy. He assures his
-readers, that he was the ornament of the schools where he studied. He
-even speaks of the oath which he was obliged to take when he received
-his medical degree; but where he studied, or where and when he received
-his medical degree, are questions which neither Paracelsus nor his
-disciples, nor his biographers, have enabled us to solve. If he ever
-attended a university, he must have neglected his studies, otherwise he
-could not have been ignorant, as he confessedly was, of the very first
-elements of the most common kinds of knowledge. But if he neglected the
-universities, he laboured long and assiduously with the rich Sigismond
-Fuggerus, of Schwartz, in order to learn the true secret of forming the
-philosopher’s stone.
-
-He gives us some details of the numerous journeys that he made, as
-was customary with the alchymists of the time, into the mountains of
-Bohemia, the East, and Sweden, to inspect the mines, to get himself
-initiated into the mysteries of the eastern adepts, to inspect the
-wonders of nature, and to view the celebrated diamond mountain, the
-position of which, however, he unfortunately forgets to specify.
-
-In the preface to his Chirurgia Magna, he informs us that he traversed
-Spain, Portugal, England, Prussia, Poland, and Transylvania; where he
-not only profited by the information of the medical men with whom he
-became acquainted, but that he drew much precious information from
-old women, gipsies, conjurors, and chemists.[144] He spent several
-years in Hungary; and informs us that at Weissenburg, in Croatia, and
-in Stockholm, he was taught by several old women to prepare drinks
-capable of curing ulcers. He is said also to have made a voyage into
-Egypt, and even into Tartary; and he accompanied the son of the Kan
-of the Tartars to Constantinople, in order to learn the secret of the
-philosopher’s stone from Trismogin, who inhabited that capital. This
-prodigious activity, this constant motion from place to place, left
-him but little leisure for reading: accordingly he informs us himself,
-that during the space of ten years he never opened a book, and that his
-whole library consisted only of six sheets. The inventory of his books,
-drawn up after his death, confirms this recital; for they consisted
-only of the Bible, the Concordance to the Bible, the New Testament, and
-the Commentaries of St. Jerome on the Evangelists.
-
-[144] “Hispania, Portugallia, Anglia, Borussia, Lithuania, Polonia,
-Pannonia, Valachia, Transylvania, Croatia, Illyrico, immo omnibus
-totius Europæ nationibus peragratis, undeque non solum apud medicos,
-sed et chirurgos, tonsores, aniculas, magos, chymistas, nobiles ac
-ignobiles, optima, selectiora ac secretiora, quæ uspiam extarent
-remedia, inquisivi acriter.”--_Præfatio Chirurgiæ Magnæ._ Opera
-Paracelsi, tom. iii.
-
-We know not at what period he returned back to Germany; but at the
-age of thirty-three the great number of fortunate cures which he had
-performed rendered him an object of admiration to the people, and
-of jealousy to the rival physicians of the time. He assures us that
-he cured eighteen princes whose diseases had been aggravated by the
-practitioners devoted to the system of Galen. Among others he cured
-Philip, Margrave of Baden, of a dysentery, who promised him a great
-reward, but did not keep his promise, and even treated him in a way
-unworthy of that prince. This cure, however, and others of a similar
-nature, added greatly to his celebrity; and in order to raise his
-reputation to the highest possible pitch, he announced publicly that he
-was able to cure all the diseases hitherto reckoned incurable; and that
-he had discovered an elixir, by means of which the life of man might be
-prolonged at pleasure to any extent whatever. He began the practice,
-which has since been so successfully followed in this country, of
-dispensing medicines gratuitously to the poor, in order to induce the
-rich to apply to him for assistance when they were overtaken with
-diseases.
-
-In the year 1526 Paracelsus was appointed professor of physic and
-surgery in the University of Basil. This appointment was given him,
-it is said, by the recommendation of Œcolampadius. He introduced the
-custom of lecturing in the common language of the country, as is at
-present the universal practice: but during the time of Paracelsus, and
-long after indeed, all lectures were delivered in Latin. The new method
-which he followed in explaining the theory and practice of the art;
-the numerous fortunate cures which he stated in confirmation of his
-method of treatment; the emphasis with which he spoke of his secrets
-for prolonging life, and for curing every kind of disease without
-distinction, but still more his lecturing in a language which was
-understood by the whole population, drew to Bâle an immense crowd of
-idle, enthusiastic, and credulous hearers.
-
-The lectures which he delivered on Practical Medicine still remain,
-written in a confused mixture of German and barbarous Latin, and
-containing little or nothing except a farrago of empirical remedies,
-advanced with the greatest confidence. They have a much greater
-resemblance to a collection of quack advertisements than to the sober
-lectures of a professor in a university. In the month of November,
-1526, he wrote to Christopher Clauser, a physician in Zurich, that
-as Hippocrates was the first physician among the Greeks, Avicenna
-among the Arabians, Galen among the Pergamenians, and Marsilius among
-the Italians, so he was beyond dispute the greatest physician among
-the Germans. Every country produces an illustrious physician, whose
-medicines are adapted to the climate in which he lived, but not suited
-to other countries. The remedies of Hippocrates were good to the
-Greeks, but not suitable to the Germans; thus it was necessary that
-an inspired physician should spring up in every country, and that he
-was the person destined to teach the Germans the art of curing all
-diseases.[145]
-
-[145] See the dedication to his treatise _De Gradibus et
-Compositionibus Receptorum et Naturalium_. Opera Paracelsi, vol. ii.
-p. 144. I always refer to the folio edition of Paracelsus’s works, in
-three volumes, published at Geneva in 1658, by M. de Tournes, which is
-the edition in my possession.
-
-Paracelsus began his professorial career by burning publicly, in his
-class-room, and in the presence of his pupils, the works of Galen
-and Avicenna, assuring his hearers that the strings of his shoes
-possessed more knowledge than those two celebrated physicians. All the
-universities united had not, he assured them, as much knowledge as was
-contained in his own beard, and the hairs upon his neck were better
-informed than all the writers that ever existed put together. To give
-the reader an idea of the arrogant absurdity of his pretensions, I
-shall translate a few sentences of the preface to his tract, entitled
-“Paragranum,” where he indulges in his usual strain of rodomontade:
-“Me, me you shall follow, you Avicenna, you Galen, you Rhazes, you
-Montagnana, you Mesue. I shall not follow you, but you shall follow me.
-You, I say, you inhabitants of Paris, you inhabitants of Montpelier,
-you Suevi, you Misnians, you inhabitants of Cologne, you inhabitants of
-Vienna; all you whom the Rhine and the Danube nourish, you who inhabit
-the islands of the sea; you also Italy, you Dalmatia, you Athens, you
-Greek, you Arabian, you Israelite--I shall not follow you, but you
-shall follow me. Nor shall any one lurk in the darkest and most remote
-corner whom the dogs shall not piss upon. I shall be the monarch, the
-monarchy shall be mine. If I administer, and I bind up your loins, is
-he with whom you are at present delighted a Cacophrastus? This ordure
-must be eaten by you.”
-
-“What will your opinion be when you see your Cacophrastus constituted
-the chief of the monarchy? What will you think when you see the sect
-of Theophrastus leading on a solemn triumph, if I make you pass under
-the yoke of my philosophy? your Pliny will you call Cacopliny, and your
-Aristotle, Cacoaristotle? If I plunge them together with your Porphyry,
-Albertus, &c., and the whole of their compatriots into my _necessary_.”
-But the terms become now so coarse and indelicate, that I cannot bring
-myself to proceed further with the translation. Enough has been given
-to show the extreme arrogance and folly of Paracelsus.
-
-So far, however, was this impudence and grossness from injuring the
-interest of Paracelsus, that we are assured by Ramus and Urstisius
-that it contributed still further to increase it. The coarseness
-of his language was well suited to the vulgarity of the age; and
-his arrogance and boasting were considered, as usual, as a proof of
-superior merit. The cure which he performed on Frobenius, drew the
-attention of Erasmus himself, who consulted him about the diseases
-with which he was afflicted; and the letters that passed between them
-are still preserved. The epistle of Paracelsus is short, enigmatical,
-and unintelligible; that of Erasmus is distinguished by that clearness
-and elegance which characterize his writings.[146] But Frobenius died
-in the month of October, 1527, and the antagonists of Paracelsus
-attributed his death (and probably with justice) to the violent
-remedies which had been administered to a man whose constitution had
-been destroyed by the gout.
-
-[146] Opera Paracelsi, i. 485.
-
-His death contributed not a little to tarnish the glory of Paracelsus:
-but he suffered the greatest injury from the habits of intoxication
-in which he indulged, and from the vulgarity of the way in which he
-spent his time. He hardly ever went into his class-room to deliver
-a lecture till he was half intoxicated, and scarcely ever dictated
-to his secretaries till he had lost the use of his reason by a too
-liberal indulgence in wine. If he was summoned to visit a patient, he
-scarcely ever went but in a state of intoxication. Not unfrequently he
-passed the whole night in the alehouse, in the company of peasants,
-and when morning came, was quite incapable of performing the duties
-of his station. On one occasion, after a debauch, which lasted the
-whole night, he was called next morning to visit a patient; on
-entering the room, he inquired if the sick person had taken any thing:
-“Nothing,” was the answer, “except the body of our Lord.” “Since you
-have already,” says he, “provided yourself with another physician, my
-presence here is unnecessary,” and he left the apartment instantly.
-When Albertus Basa, physician to the king of Poland, visited Paracelsus
-in the city of Basel, he carried him to see a patient whose strength
-was completely exhausted, and which, in his opinion, it was impossible
-to restore; but Paracelsus, wishing to make a parade of his skill,
-administered to him three drops of his laudanum, and invited him to
-dine with him next day.[147] The invitation was accepted, and the sick
-man dined next day with his physician.
-
-[147] There were two laudanums of Paracelsus; one was _red oxide of
-mercury_, the other consisted of the following substances: Chloride
-of antimony, 1 ounce; hepatic aloes, 1 ounce; rose-water, ½ ounce;
-saffron, 3 ounces; ambergris, 2 drams. All these well mixed.
-
-Towards the end of the year 1527 a disgraceful dispute into which he
-entered brought his career, as a professor, to a sudden termination.
-The canon Cornelius, of Lichtenfels, who had been long a martyr to
-the gout, employed him as his physician, and promised him one hundred
-florins if he could cure him. Paracelsus made him take three pills of
-laudanum, and having thus freed him from pain, demanded the sum agreed
-upon; but Lichtenfels refused to pay him the whole of it. Paracelsus
-summoned him before the court, and the magistrate of Basle decided
-that the canon was bound to pay only the regular price of the medicine
-administered. Irritated at this decision, our intoxicated professor
-uttered a most violent invective against the magistrate, who threatened
-to punish him for his outrageous conduct. His friends advised him to
-save himself by flight. He took their advice, and thus abdicated his
-professorship. But, by this time, his celebrity as a teacher had been
-so completely destroyed by his foolish and immoral conduct, that he
-had lost all his hearers. In consequence of this state of things, his
-flight from Basle produced no sensation whatever in that university.
-
-Paracelsus betook himself, in the first place, to Alsace, and sent
-for his faithful follower, the bookseller, Operinus, together with
-the whole of his chemical apparatus. In 1528 we find him at Colmar,
-where he recommenced his ambulating life of a theosophist, which he
-had led during his youth. His book upon syphilis, known at that time
-by the name of Morbus Gallicus, was dedicated at Colmar, to the chief
-magistrate of Colmar, Hieronymus Bonerus.[148] In 1531 he was at
-Saint-Gallen; in 1535, at Pfeffersbade, and in 1536, at Augsburg, where
-he dedicated his Chirurgia Magna to Malhausen. At the request of John
-de Leippa, Marshal of Bohemia, he undertook a journey into Moravia;
-as that nobleman, having been informed that Paracelsus understood
-the method of curing the gout radically, was anxious to put himself
-under his care. Paracelsus lived for a long time at Kroman, and its
-environs. John de Leippa, instead of receiving any benefit from the
-medicines administered to him, became daily worse, and at last died.
-This was the fate also of the lady of Zerotin, in whom the remedies of
-Paracelsus produced no fewer than twenty-four epileptic fits in one
-day. Paracelsus, instead of waiting the disgrace with which the death
-of this lady would have overwhelmed him, announced his intention of
-going to Vienna, that he might see how they would treat him in that
-capital.
-
-[148] Opera Paracelsi, iii, 101.
-
-It is said, that from Vienna he went into Hungary; but in 1538, we find
-him in Villach, where he dedicated his Chronica et Origo Carinthiæ
-to the states of Carinthia.[149] His book, De Natura Rerum, had
-been dedicated to Winkelstein, and the dedication is dated also at
-Villach, in the year 1537.[150] In 1540 he was at Mindelheim, and in
-1541, at Strasburg, where he died, in St. Stephen’s hospital, in the
-forty-eighth year of his age.
-
-[149] Opera Paracelsi, i. 243.
-
-[150] Ibid., ii. 84.
-
-To form an accurate idea of this most extraordinary man, we must attend
-to his habits, and to the situation in which he was placed. He had
-acquired such a habit of moving about, that he assures us himself he
-found it impossible for him to continue for any length of time in one
-place. He was always surrounded by a number of followers, whom neither
-his habits of intoxication, nor the foolish and immoral conduct in
-which he was accustomed to indulge, could induce to forsake him. The
-most celebrated of these was Operinus, a printer at Basle, on whom
-Paracelsus lavishes the most excessive praises, in his book De Morbo
-Gallico. But Operinus loaded his master with obloquy, being provoked
-at him because he had not made him acquainted with the secret of the
-philosopher’s stone, as he had promised to do. We must therefore be
-cautious in believing the stories that he relates to the discredit of
-his master. We know the names of two others of his followers; Francis,
-who assures us that Paracelsus was devoted to the transmutation of
-metals; and George Vetter, who considered him as a magician; as was the
-opinion also of Operinus. Paracelsus himself, speaks of Dr. Cornelius,
-whom he calls his secretary, and in honour of whom he wrote several
-of his libels. Other libels are dedicated to Doctors Peter, Andrew,
-and Ursinus, to the licentiate Pancrace, and to Mr. Raphael. On this
-occasion he complains bitterly of the infidelity of his servants, who,
-he says, had succeeded in stealing from him several of his secrets;
-and had by this means been enabled to establish their reputation. He
-accuses equally the barbers and bathers that followed him, and is no
-less severe upon the physicians of every country through which he
-travelled.
-
-When we attempt to form an accurate conception of the medical and
-philosophical opinions of this singular man, we find ourselves beset
-with almost insurmountable difficulties. His statements are so much
-at variance with each other, in his different pieces, and so much
-confusion reigns with respect to the order of publication, that we know
-not what to fix on as his last and maturest opinions. His style is
-execrable; filled with new words of his own coining, and of mysticisms
-either introduced to excite the admiration of the ignorant, or from
-the fanaticism and credulity of the writer, who was undoubtedly, to a
-considerable extent, the dupe of his own impostures. That he was in
-possession of the philosopher’s stone, or of a medicine capable of
-prolonging life to an indefinite length, as he all along asserted, he
-could not himself believe; but he had boasted so long and so loudly of
-his wonderful cures, and of the efficacy of his medicines, that there
-can be no doubt that he ultimately placed implicit faith in them. The
-blunders of the transcribers whom he employed to copy his works, may
-perhaps account for some of the contradictions which they contain.
-But how can we look for a regular system of opinions from a man who
-generally dictated his works when in a state of intoxication, and thus
-laboured under an almost constant deprivation of reason.
-
-His obscurity was partly the effect of design, and no doubt was
-intended to exalt the notions entertained of his profundity. He uses
-common words in new significations, without giving any indication
-of the change which he introduced. Thus _anatomy_, in the writings
-of Paracelsus, signifies not the dissection of dead animals to
-determine their structure, but it means the nature, force, and
-magical designation of a thing. And as, according to the Platonic and
-Cabalistic theory, every earthly body is formed after the model of a
-heavenly body, Paracelsus calls _anatomy_ the knowledge of that model,
-of that ideal, or of that paradigm after which all things are created.
-He terms the fundamental force of a thing _a star_, and defines alchymy
-the art of drawing out the stars of metals. The star is the source of
-all knowledge. When we eat, we introduce into our bodies _the star_,
-which is then modified, and favours nutrition.
-
-It is probable that many of his obscure and unintelligible expressions
-are the fruit of ignorance. Thus he uses the term _pagoyus_, instead
-of _paganus_. He gives the name of _pagoyæ_ to the four _entities_,
-or causes of diseases, founded on the influence of the stars, to the
-elementary qualities; to the occult qualities, and to the influence
-of spirits; because these had been already admitted by the _Pagans_.
-But the fifth _entity_, or cause of disease, which has God immediately
-for its author, is _non pagoya_. The _undimia_ of Paracelsus is our
-_œdema_; only he applies the name to every kind of dropsy. The Latin
-word _tonitru_, we find is declined by Paracelsus. Thus he says, _lapis
-tonitrui_. The well-known line of Ovid,
-
-    Tollere nodosam nescit medicina podagram,
-
-He travestied into
-
-    Nescit tartaream Roades curare podagram.[151]
-
-[151] Opera Paracelsi, i. 328.
-
-_Roades_, he says, means medicines for horses; and if any person wishes
-a more elegant verse, he may make it for himself.[152] He employs,
-also, a great number of words to which no meaning whatever can be
-attached; and to which, in all probability, he himself had affixed none.
-
-[152] “Qui elegantiorem optat, ille eum condat.”--_Ibid._
-
-As is the case with all fanatics, he treated with contempt every
-kind of knowledge acquired by labour and application; and boasted
-that his wisdom was communicated to him directly by God Almighty.
-The theosophist who is worthy of partaking of the divine light, has
-no occasion for adopting a positive religion, nor of subjecting
-himself to any kind of religious ceremony. The divine light within,
-which assimilates him to the Deity, more than compensates for all
-these vulgar usages, and raises the illuminated votary far above the
-beggarly elements of external worship. Accordingly, Paracelsus has been
-accused of treating the public worship of the Deity with contempt. Not
-satisfied with the plain sense of the book, he attempted to explain
-in a mystical manner the words and syllables of the Bible. He accused
-Luther of not going far enough. “Luther,” says he, “is not worthy of
-untying the strings of my shoes: should I undertake a reformation,
-I would begin by sending the pope and the reformers themselves to
-school.” God, says Paracelsus, is the first and most excellent of
-writers. The Holy Scripture conducts us to all truth, and teaches us
-all things. But medicine, philosophy, and astronomy, are among the
-number of things. Therefore, when we want to know what magical medicine
-is, we must consult the Apocalypse. The Bible, with its paraphrases,
-is the key to the theory of diseases. It puts it in our power to
-understand St. John, who, like Daniel, Ezekiel, Moses, &c., was a
-magician, a cabalist, a diviner. The first duty of a physician is to
-study the Cabala, without which he must every moment commit a thousand
-blunders. “Learn,” says he, “the cabalistic art, which includes under
-it all the others.” “Man invents nothing, the devil invents nothing;
-it is God alone who unveils to us the light of nature.” “God honoured
-at first with his illumination the blind pagans, Apollo, Æsculapius,
-Machaon, Podalirius, and Hippocrates, and imparted to them the genius
-of medicine; their successors were the sophists.” One would suppose,
-from this passage, that Paracelsus had read and studied Hippocrates,
-and that he held him in high estimation. But the commentaries which
-he has left on some of the aphorisms, show evidently that he did not
-even understand the Greek physician. “The compassion of God,” says he,
-“is the only foundation of medical science, and not a knowledge of the
-great masters, or of the writings which they have left in Greek and
-Latin.” “God often acts in dreams by the light of nature, and points
-out to man the manner of curing diseases.” “This knowledge renders
-all those objects visible which would otherwise escape the sight;
-and when faith is joined with it, nothing is then impossible to the
-theosophist, who may transport the ocean to the top of Mount Ætna, and
-Olympus into the Red Sea.” Paracelsus predicts that by the year 1590
-Christian theosophy would be generally spread over the world, and that
-the Galenical schools would be almost or entirely overthrown.
-
-We find in Paracelsus some traces of the opinions of the Gnostics and
-Arians, who considered Christ as the first emanation of the Deity. He
-calls the first man _parens hominis_; and makes all spirits emanate
-from him. He is the _limbus minor_, or the last creature, into whom
-enters the great _limbus_, or the seed of all the creatures, the
-infinite being. All the sciences, and all the arts of man, are derived
-from this great _limbus_; and he who can sink himself in the little
-_limbus_, that is to say, in Adam, and who can communicate by faith
-with Jesus Christ, may invoke all _spirits_. Those who owe their
-science to this _limbus_, are the best informed; those who derive it
-from the stars, occupy the last rank; and those who owe it to the light
-of nature, are intermediate between the preceding. Jesus Christ, in his
-capacity of _limbus minor_ and first man, being always an emanation of
-the Divinity; and, consequently, a subordinate personage. These ideas
-explain to us why Paracelsus passed for an Arian, and was supposed not
-to believe in the Divinity of Jesus Christ. He was of opinion that the
-faithful performed miracles, and operated magical cures by their simple
-confidence in God the Father, and not by their faith in Christ; but he
-adds, however, that we ought to pray to Jesus, in order to obtain his
-intercession.
-
-From the preceding attempt to explain the opinions of Paracelsus, it
-will be evident to the reader that he was both a fanatic and impostor,
-and that his theory (if such a name can be given to the reveries of
-a drunkard), consisted in uniting medicine with the doctrines of the
-Cabala. A few more observations will be necessary to develop his dogmas
-still further.
-
-Every body, in his opinion, and man in particular, is double,
-consisting of a material and spiritual substance.[153] The
-spiritual, which may be called the _sideric_, results from the
-celestial influences; and we may trace after it a figure capable of
-producing all kinds of magical effects. When we can act upon the
-body itself, we act at the same time upon the spiritual form by
-characters and conjurations.[154] Yet, in another passage, he blames
-all magical ceremonies, and ascribes them to want of faith. The
-celestial intelligences impress upon material bodies certain signs,
-which manifest their influence. The perfection of art consists in
-understanding the meaning of these signs, and in determining from them
-the nature, qualities, and essence of a body. Adam, the first man, had
-a perfect knowledge of the Cabala; he could interpret the signatures
-of all things. It was this which enabled him to assign to the animals
-names which suited them best. A man who renounces all sensuality, and
-is blindly obedient to the will of God, is capable of taking a share
-in the actions which celestial intelligences perform; and consequently
-is possessed of the philosopher’s stone. Never does he want any thing;
-all creatures in earth and in heaven are obedient to him; he can cure
-all diseases, and prolong his life as long as he pleases; because he
-possesses the tincture which Adam and the patriarch’s before the flood
-employed to prolong the term of their existence.[155] Beelzebub, the
-chief of the demons, is also subject to the power of magic: and who can
-blame the theosophist for believing in the devil? He ought, however,
-to take care to prevent this malignant spirit from commanding him.
-Paracelsus was often wont to say, “If God does not aid me, the devil
-will help me.”
-
-[153] Archidoxorum, lib. i. Opera Paracelsi, ii. 4.
-
-[154] De longa Vita. Opera Paracelsi, ii. 46.
-
-[155] Archidoxorum, lib. viii. Opera Paracelsi, ii. 29. In this book
-he gives the method of preparing the elixir of life. It seems to have
-been nothing else than a solution of _common salt_ in water; for the
-quintessence of gold, with which this solution was to be mixed, was
-doubtless an imaginary substance.
-
-Pantheism was one of the principal dogmas of the Cabala; and Paracelsus
-adopts it in all its grossness. He affirms perpetually that every thing
-is animated in the universe; that every thing which exists, eats,
-drinks, and voids excrements: even minerals and liquids take food and
-void the digested remains of their nourishment.[156] This opinion
-leads necessarily to the admission of a great number of spiritual
-substances, intermediate between material and immaterial in every part
-of the sublunary world, in water, air, earth, and fire; who, as well
-as man, eat, drink, converse, beget children; but which approach pure
-spirits in this, that they are more transparent, and infinitely more
-agile than all other animal bodies. Man possesses a soul, of which
-these pure spirits are destitute. Hence it happens that these spiritual
-substances are at once body and spirit without a soul. When they die
-(for like the human race they are subject to death), no soul remains.
-Like us they are exposed to diseases. Their names vary according to the
-places that they occupy. When they inhabit the air, they are called
-_sylphs_; when the water, _nymphs_; when the earth, _pigmies_; when the
-fire, _salamanders_.[157] The inhabitants of the waters are also called
-_undinæ_, and those of the fire _vulcani_. The sylphs approach nearest
-to our nature, as they live in the air like us. The sylphs, nymphs,
-and pigmies, sometimes obtain permission from God to make themselves
-visible, to converse with men, to indulge in carnal pleasures, and
-to produce children. But the salamanders have no relation to man.
-These spiritual beings are acquainted with the future, and capable of
-revealing it to man. They appear under the form of _ignes fatui_. We
-have also the history of the fairies and the giants; and are told how
-these spiritual beings are the guardians of concealed treasures; and
-how these sylphs, nymphs, pigmies, and salamanders, may be charmed, and
-their treasures taken from them.
-
-[156] Modus Pharmacandi. Opera Paracelsi, i. 811.
-
-[157] Liber de Nymphis, Sylphis, Pygmæis, et Salamandris, et de ceteris
-Spiritibus. Opera Paracelsi, ii. 388. If the reader can understand this
-singular book, his sagacity will be greater than mine.
-
-This division of man into body and spirit, and of the things of nature
-into visible and invisible, has in all ages of the world, been adopted
-by fanatics, because it enabled them to explain the history of ghosts,
-and a thousand similar prejudices. Hence the distinction between soul
-and spirit, which is so very ancient; and hence the three following
-harmonies to which the successors of Paracelsus paid a particular
-attention:
-
-  _Soul_,     _Spirit_,   _Body_,
-  _Mercury_,  _Sulphur_,  _Salt_,
-  _Water_,    _Air_,      _Earth_.
-
-The will and the imagination of man acts principally by means of the
-spirit. Hence the reason of the efficacy of sorcery and magic. The
-_nævi materni_ are the impressions of these _vice-men_, and Paracelsus
-calls them _cocomica signa_. The _sideric_ body of man draws to him,
-by imagination, all that surrounds him, and particularly the stars,
-on which it acts like a magnet. In this manner, women with child, and
-during the regular period of monthly evacuation, having a diseased
-imagination, are not only capable of poisoning a mirror by their
-breath, but of injuring the infants in their wombs, and even also of
-poisoning the moon. But it seems needless to continue this disagreeable
-detail of the absurd and ridiculous opinions which Paracelsus has
-consigned to us in his different tracts.
-
-The Physiology of Paracelsus (if such a name can be applied to his
-reveries) is nothing else than an application of the laws of the
-Cabala to the explanation of the functions of the body. There exists,
-he assures us, an intimate connexion between the sun and the heart,
-the moon and the brain, Jupiter and the liver, Saturn and the spleen,
-Mercury and the lungs, Mars and the bile, Venus and the kidneys. In
-another part of his works, he informs us that the sun acts on the
-umbilicus and the middle parts of the abdomen, the moon on the spine,
-Mercury on the bowels, Venus on the organs of generation, Mars on the
-face, Jupiter on the head, and Saturn on the extremities. The pulse is
-nothing else than the measure of the temperature of the body, according
-to the space of the six places which are in relation to the planets.
-Two pulses under the sole of the feet belong to Saturn and Jupiter,
-two at the elbow to Mars and Venus, two in the temples to the moon and
-mercury. The pulse of the sun is found under the heart. The _macrocosm_
-has also seven pulses, which are the revolutions of the seven planets,
-and the irregularity or intermittence of these pulses, is represented
-by the eclipses. The moon and Saturn are charged in the macrocosm with
-thickening the water, which causes it to congeal. In like manner the
-moon of the microcosm, that is to say the brain, coagulates the blood.
-Hence _melancholy persons_, whom Paracelsus calls _lunatics_, have a
-thick blood. We ought not to say of a man that he has such and such
-a complexion; but that it is Mars, Venus, &c., so that a physician
-ought to know the planets of the microcosm, the arctic and antarctic
-pole, the meridian, the zodiac, the east and the west, before trying
-to explain the functions or cure the diseases.[158] This knowledge is
-acquired by a continual comparison of the macrocosm with the microcosm.
-What must have been the state of medicine at the time when Paracelsus
-wrote, when the propagator of such opinions could be reckoned one of
-the greatest of its reformers?
-
-[158] Paragrani Alterius, tract. ii. Opera Paracelsi, i. 235. The
-reader who has the curiosity to consult this tract, will find abundance
-of similar stuff, which I did not think worth translating.
-
-The system of Galen had for its principal basis the doctrine of
-the four elements, _fire_, _air_, _water_, and _earth_. Paracelsus
-neglected these elements, and multiplied the substances of the
-disease itself. He admits, strictly speaking, three or four elements;
-namely, the _star_, the _root_, the _element_, the _sperm_, which
-he distinguishes by the name of the _true seed_. All these elements
-were originally confounded together in the _chaos_ or _yliados_. The
-_star_ is the active force which gives form to matter. The _stars_
-are reasonable beings addicted to sodomy and adultery, like other
-creatures. Each of them draws at pleasure out of the _chaos_, the
-plant and the metal to which it has an affinity, and gives a _sideric_
-form to their _root_. There are two kinds of _seed_; the _sperm_
-is the vehicle of the true seed. It is engendered by speculation,
-by imagination, by the power of the _star_. The occult, invisible,
-_sideric_ body produces the _true seed_, and the Adamic man secretes
-only the visible envelope of it. Putrefaction cannot give birth to
-a new body: the seed must pre-exist, and it is developed during
-putrefaction by the power of the stars. The generation of animals is
-produced by the concourse of the infinite number of seeds which detach
-themselves from all parts of the body. Thus the seed of the nose
-reproduces a nose, that of the eye the eye, and so on.
-
-With respect to the elements themselves, Paracelsus admits occasionally
-their influence on the functions of the body, and the theory of
-diseases; but he deduces the faculties which they possess from the
-_stars_. It was he that first shook the doctrine of the four elements,
-originally contrived by Empedocles. Alchymy had introduced another set
-of elements, and the alchymists maintained that salt, sulphur, and
-mercury, were the true elements of things. Paracelsus endeavoured to
-reconcile these chemical elements with his cabalistic ideas, and to
-show more clearly their utility in the theory of medicine. He invented
-a _sideric salt_, which can only be perceived by the exquisite senses
-of a theosophist, elevated by the abnegation of all gross sensuality
-to a level with pure and spiritual demons. This _salt_ is the cause of
-the consistence of bodies, and it is it which gives them the faculty of
-being reproduced from their ashes.
-
-Paracelsus imagined also a _sideric sulphur_, which being vivified
-by the influence of the stars, gives bodies the property of growing,
-and of being combustible. He admits also a _sideric mercury_, the
-foundation of fluidity and volatilization. The concourse of these three
-substances forms the body. In different parts of his works, Paracelsus
-says, that the _elements_ are composed of these three principles.
-In plants he calls the salt _balsam_, the sulphur _resin_ and the
-mercury _gotaronium_. In other passages he opposes the assertion of
-the Galenists, that _fire_ is _dry_ and _hot_, _air cold_ and _moist_,
-_earth dry_ and _cold_, _water moist_ and _cold_. Each of these
-elements, he says, is capable of admitting all qualities, so that in
-reality there exists a _dry water_, a _cold fire_, &c.
-
-I must not omit another remarkable physiological doctrine of
-Paracelsus, namely, that there exists in the stomach a demon called
-_Archæus_, who presides over the chemical operations which take place
-in it, separating the poisonous from the nutritive part of food, and
-furnishing the alimentary substances with the tincture, in consequence
-of which they become capable of being assimilated. This _ruler of the
-stomach_, who changes bread into blood, is the type of the physician,
-who ought to keep up a good understanding with him, and lend him his
-assistance. To produce a change in the humours ought never to be the
-object of the true physician, he should endeavour to concentrate all
-his operations on the stomach and the ruler who reigns in it. This
-Archæus to whom the name of _Nature_ may also be given, produces all
-the changes by his own power. It is he alone who cures diseases. He has
-a _head_ and _hands_, and is nothing else than the _spirit of life_,
-the _sideric body_ of man, and no other spirit besides exists in the
-body. Each part of the body has also a peculiar stomach in which the
-secretions are elaborated.
-
-There are, he informs us, five different causes of diseases. The first
-is the _ens astrorum_. The constellations do not immediately induce
-diseases, but they alter and infect the air. This is what, properly
-speaking constitutes the _entity of the stars_. Some constellations
-_sulphurize_ the atmosphere, others communicate to it _arsenical_,
-_saline_, or _mercurial_ qualities. The arsenical astral entities
-injure the blood, the mercurial the head, the saline the bones and
-the vessels. Orpiment occasions tumours and dropsies, and the _bitter
-stars_ induce fever.
-
-The second morbific cause is the _ens veneni_, which proceeds from
-alimentary substances: when the archeus is languid putrefaction
-ensues, either _localiter_ or _emuncturaliter_. This last takes place
-when those evacuations, which ought to be expelled by the nose, the
-intestines, or the bladder, are retained in the body. Dissolved mercury
-escapes through the pores of the skin, white sulphur by the nose,
-arsenic by the ears, sulphur diluted with water by the eyes, salt in
-solution by the urine, and sulphur deliquesced by the intestines.
-
-The third morbific cause of disease is the _ens naturale_; but
-Paracelsus subjects to the ens astrorum the principles which the
-schools are in the habit of arranging among the number of natural
-causes. The _ens spirituale_ forms the fourth species and the _ens
-deale_ or _Christian entity_ the fifth. This last class comprehends all
-the immediate effects of divine predestination.
-
-It would lead us too far if I were to point out the strange methods
-which he takes to discover the cause of diseases. But his doctrine
-concerning _tartar_ is too important, and does our fanatic too much
-credit to be omitted. It is without doubt the most useful of all the
-innovations which he introduced. _Tartar_ according to him, is the
-principle of all the maladies proceeding from the thickening of the
-humours, the rigidity of the solids, or the accumulation of earthy
-matter. Paracelsus thought the term _stone_ not suitable to indicate
-that matter, because it applies only to one species of it. Frequently
-the principle proceeds from mucilage, and mucilage is tartar. He calls
-this principle _tartar_ (_tartarus_) because it burns like hellfire,
-and occasions the most dreadful diseases. As _tartar_ (_bitartrate of
-potash_) is deposited at the bottom of the wine-cask, in the same way
-_tartar_ in the living body is deposited on the surface of the teeth.
-It is deposited on the internal parts of the body when the archæus acts
-with too great impetuosity and in an irregular manner, and when it
-separates the nutritive principle with too much impetuosity. Then the
-saline spirit unites itself to it and coagulates the earthy principle,
-which is always present, but often in the state of _materia prima_
-without being coagulated.
-
-In this manner tartar, in the state of _materia prima_, may be
-transmitted from father to son. But it is not hereditary and
-transmittable when it has already assumed the form of gout, of renal
-calculus, or of obstruction. The saline spirit which gives it its form,
-and causes its coagulation, is seldom pure and free from mixture;
-usually it contains alum, vitriol, or common salt; and this mixture
-contributes also to modify the tartarous diseases. The tartar may be
-likewise distinguished according as it comes from the blood itself,
-or from foreign matters accumulated in the humours. The great number
-of calculi which have been found in every part of the body, and the
-obstructions, confirm the generality of this morbific cause, to which
-are due most of the diseases of the liver. When the tartarous matter
-is increased by certain articles of food, renal calculi are engendered,
-a calculous paroxysm is induced, and violent pain is occasioned. It
-acts as an emetic, and may even give occasion to death, when the saline
-spirit becomes corrosive; and when the tartar coagulated by it becomes
-too irritating.
-
-Tartar, then, is always an excrementitious substance, which in many
-cases results from the too great activity of the digestive forces. It
-may make its appearance in all parts of the body, from the irregularity
-and the activity, too energetic or too indolent, of the archeus;
-and then it occasions particular accidents relative to each of the
-functions. Paracelsus enumerates a great number of diseases of the
-organs, which may be explained by that one cause; and affirms, that the
-profession of medicine would be infinitely more useful, if medical men
-would endeavour to discover the tartar before they tried to explain the
-affections.
-
-Paracelsus points out, also, the means by which we can distinguish
-the presence of tartar in urine. For this it is necessary, not merely
-to inspect the urine, but to subject it to a chemical analysis. He
-declaims violently against the ordinary ouroscopy. He divides urine
-into internal and external; the internal comes from the blood, and the
-external announces the nature of the food and drink which has been
-employed. To the sediment of urine he gives the new name of _alcola_,
-and admits three species of it, namely, _hypostasis_, _divulsio_, and
-_sedimen_. The first is connected with the stomach, the second with the
-liver, and the third with the kidneys; and tartar predominates in all
-the three.
-
-The Cabala constantly directs Paracelsus in his therapeutics and
-materia medica. As all terrestrial things have their image in the
-region of the stars, and as diseases depend also on the influence of
-the stars, we have nothing more to do, in order to obtain a certain
-cure for these diseases, than to discover, by means of the Cabala,
-the harmony of the constellations. _Gold_ is a specific against all
-diseases of the _heart_, because, in the mystic scale, it is in
-harmony with that viscus. The _liquor of the moon_ and crystal cure
-the diseases of the _brain_. The liquor _alkahest_ and _cheiri_ are
-efficacious against those of the _liver_. When we employ vegetable
-substances, we must consider their harmony with the constellations,
-and their magical harmony with the parts of the body and the diseases,
-each star drawing, by a sort of magical virtue, the plant for which it
-has an affinity, and imparting to it its activity. So that plants are
-a kind of sublunary stars. To discover the virtues of plants, we must
-study their anatomy and cheiromancy; for the leaves are their hands,
-and the lines observable on them enable us to appreciate the virtues
-which they possess. Thus the anatomy of the _chelidonium_ shows us that
-it is a remedy for jaundice. These are the celebrated _signatures_ by
-means of which we deduce the virtues of vegetables, and the medicines
-of analogy which they present in relation to their form. Medicines,
-like women, are known by the forms which they affect. He who calls
-in question this principle, accuses the Divinity of falsehood, the
-infinite wisdom of whom has contrived these external characters to
-bring the study of them more upon a level with the weakness of the
-human understanding. On the corolla of the euphrasia there is a black
-dot; from this we may conclude that it furnishes an excellent remedy
-against all diseases of the eye. The lizard has the colour of malignant
-ulcers, and of the carbuncle; this points out the efficacy which that
-animal possesses as a remedy.
-
-These signatures were exceedingly convenient for the fanatics, since
-they saved them the trouble of studying the medical virtues of plants,
-but enabled them to decide the subject _à priori_. Paracelsus acted
-very considerately, when he ascribed these virtues principally to the
-stars, and affirmed that the observation of favourable constellations
-is an indispensable condition in the employment of these medicines.
-“The remedies are subjected to the will of the stars, and directed by
-them; you ought therefore to wait till heaven is favourable, before
-ordering a medicine.”
-
-Paracelsus considered all the effects of plants as specifics, and the
-use of them as secrets. The same notions explain the eulogy which he
-bestowed on the _elixir of long life_, and upon all the means which
-he employed to prolong the term of existence. He believed that these
-methods, which contained the _materia prima_, served to repair the
-constant waste of that matter in the human body. He was acquainted,
-he says, with four of these arcana, to which he applied the mystic
-terms, _mercury of life_, _philosopher’s stone_, &c. The _polygonum
-persicaria_ was an infallible specific against all the effects of
-magic. The method of using it is, to apply it to the suffering part,
-and then to bury it in the earth. It draws out the malignant spirits
-like a magnet, and it is buried to prevent these malignant spirits from
-making their escape.
-
-The reformation of Paracelsus had the great advantage of representing
-_chemistry_ as an indispensable art in the preparation of medicines.
-The disgusting decoctions and useless syrups gave place to _tinctures_,
-_essences_, and _extracts_. Paracelsus says, expressly, that the true
-use of chemistry is to prepare medicines, and not to make gold. He
-takes that opportunity of declaiming against cooks and innkeepers, who
-drown medicines in soup, and thus destroy all their properties. He
-blames medical men for prescribing simples, or mixtures of simples, and
-affirms that the object should always be to extract the quintessence
-of each substance; and he describes at length the method of extracting
-this quintessence. But he was very little scrupulous about the
-substances from which this quintessence was to be extracted. The
-heart of a hare, the bones of a hare, the bone of the heart of a stag,
-mother-of-pearl, coral, and various other bodies may, he says, be used
-indiscriminately to furnish a quintessence capable of curing some of
-the most grievous diseases.
-
-Paracelsus combats with peculiar energy the method of cure employed
-by the disciples of Galen, directed solely against the predominating
-humours, and the elementary qualities. He blames them for attempting
-to correct the action of their medicines, by the addition of useless
-ingredients. Fire and chemistry, he affirmed, are the sole correctives.
-It was Paracelsus that first introduced _tin_ as a remedy for worms,
-though his mode of employing it was not good.
-
-I have been thus particular in pointing out the philosophical and
-medical opinions of Paracelsus, because they were productive of such
-important consequences, by setting medical men free from the slavish
-deference which they had been accustomed to pay to the dogmas of Galen
-and Avicenna. But it was the high rank to which he raised chemistry,
-by making a knowledge of it indispensable to all medical men; and by
-insisting that the great importance of chemistry did not consist in the
-formation of gold, but in the preparation of medicines, that rendered
-the era of Paracelsus so important in the history of chemistry; for
-after his time the art of chemistry was cultivated by medical men in
-general--it became a necessary part of their education, and began to
-be taught in colleges and medical schools. The object of chemistry
-came to be, not to discover the philosopher’s stone, but to prepare
-medicines; and a great number of new medicines, both from the mineral
-and vegetable kingdom--some of more, some of less, consequence, soon
-issued from the laboratories of the chemical physicians.
-
-There can be little doubt that many chemical preparations were either
-first introduced into medicine by Paracelsus, or at least were first
-openly prescribed by him: though from the nature of his writings, and
-the secrecy in which he endeavoured to keep his most valuable remedies,
-it is not easy to point out what these remedies were. Mercury is said
-to have been employed in medicine by Basil Valentine; but it was
-Paracelsus who first used it openly as a cure for the venereal disease,
-and who drew general attention to it by his encomiums on its medical
-virtues, and by the eclat of the cures which he performed by means of
-it, after all the Galenical prescriptions of the schools had been tried
-in vain.
-
-He ascertained that alum contains, united to an acid, not a metallic
-oxide, but an earth. He mentions metallic arsenic; but there is some
-reason for believing that this metal was known to Geber and the
-Arabian physicians. Zinc is mentioned by him, and likewise bismuth,
-as substances not truly metallic, but approaching to metals in their
-properties: for malleability and ductility were considered by him as
-essential to the metals.[159] I cannot be sure of any other chemical
-fact which appears in Paracelsus, and which was not known before his
-time. The use of sal ammoniac in subliming several metallic calces,
-was familiar to him, but it had long ago been explained by Geber. It
-is clear also that Geber was acquainted with aqua regia, and that he
-employed it to dissolve gold. Paracelsus’s reputation as a chemist,
-therefore, depends not upon any discoveries which he actually made,
-but upon the great importance which he attached to the knowledge of
-it, and to his making an acquaintance with chemistry an indispensable
-requisite of a medical education.
-
-[159] Philosophiæ, tract. iv. De Mineralibus. Opera Paracelsi, ii.
-282. “Quando ergo hoc modo metalla fiunt et producuntur, dum scilicet
-verus metallicus fluxus et ductilitas aufertur et in septem metalla
-distribuitur; residentia quædam manet in Ares, instar fœtûm trium
-primorum. Ex hac nescitur zinetum, quod et metallum est et non est.
-Sic et bisemutum et huic similia alia partim fluida, partim ductilia
-sunt--Zinetum maxima ex parte spuria soboles est ex cupro et bisemutum
-de stanno. Ex hisce duobus omnium plurimæ fæces et remanentiæ in Ares
-fiunt.”
-
-Paracelsus, as the founder of a new system of medicine, the object
-of which was to draw chemistry out of that state of obscurity and
-degradation into which it had been plunged, and to give it the charge
-of the preparation of medicine, and presiding over the whole healing
-art, deserved a particular notice; and I have even endeavoured, at
-some length, to lay his system of opinions, absurd as it is, before
-the reader. But the same attention is not due to the herd of followers
-who adopted his absurdities, and even carried them, if possible,
-still further than their master: at the same time there are one or
-two particulars connected with the Paracelsian sect which it would be
-improper to omit.
-
-The most celebrated of his followers was Leonhard
-Thurneysser-zum-Thurn, who was born in 1530, at Basle, where his father
-was a goldsmith. His life, like that of his master, was checkered with
-very extraordinary vicissitudes. In 1560 he was sent to Scotland to
-examine the lead-mines in that country. In 1558 he commenced miner and
-sulphur extractor at Tarenz on the Inn, and was so successful, that he
-acquired a great reputation. He had turned his attention to medicine
-on the Paracelsian plan, and in 1568 made himself distinguished by
-several important cures which he performed. In 1570 he published his
-Quinta Essentia, with wooden cuts, in Munster; from thence he went to
-Frankfort on the Oder, and published his Piso, a work which treats of
-_waters_, _rivers_, and _springs_. John George, Elector of Brandenburg,
-was at that time in Frankfort, and was informed that the treatise
-of Thurneysser pointed out the existence of a great deal of riches
-in the March of Brandenburg, till that time unknown. His courtiers,
-who were anxious to establish mines in their possessions, united in
-recommending the author. He was consulted about a disease under which
-the wife of the elector was labouring, and having performed a cure, he
-was immediately named physician to this prince.
-
-He turned this situation to the best account. He sold Spanish white,
-and other cosmetics, to the ladies of the court; and instead of the
-disgusting decoctions of the Galenists, he administered the remedies of
-Paracelsus under the pompous titles of _tincture of gold_, _magistery
-of the sun_, _potable gold_, &c. By these methods he succeeded in
-amassing a prodigious fortune, but was not fortunate enough to be able
-to keep it. Gaspard Hoffmann, professor at Frankfort, a well-informed
-and enlightened man, published a treatise, the object of which was
-to expose the extravagant pretensions and ridiculous ignorance of
-Thurneysser. This book drew the attention of the courtiers, and opened
-the eyes of the elector. Thurneysser lost much of his reputation; and
-the methods by which he attempted to bolster himself up, served only
-to sink him still lower in the estimation of men of sense. Among other
-things, he gave out that he was the possessor of a devil, which he
-carried about with him in a bottle. This pretended devil was nothing
-else than a scorpion, preserved in a phial of oil. The trick was
-discovered, and the usual consequences followed. He lost a process with
-his wife, from whom he was separated; this deprived him of the greatest
-part of his fortune. In 1584 he fled to Italy, where he occupied
-himself with the transmutation of metals, and he died at Cologne in
-1595.
-
-Thurneysser extols Paracelsus as the only true physician that ever
-existed. His Quintessence is written in verse. In the first book
-_The Secret_ is the speaker. He is represented with a padlock in his
-mouth, a key in his hand, and seated on a coffer in a chamber, the
-windows of which are shut. This personage teaches that all things
-are composed of salt, sulphur, and mercury, or of earth, air, and
-water; and consequently that _fire_ is excluded from the number of the
-elements. We must search for the secret in the _Bible_, and then in
-the _stars_ and the _spirits_. In the second book, _Alchymy_ is the
-speaker. She points out the mode of performing the processes; and says
-that to endeavour to fix volatile substances, is the same thing as to
-endeavour to trace white letters on a wall with a piece of charcoal.
-She prohibits all long processes, because God created the world in six
-days.
-
-His method of judging of the diseases from the urine of the patient
-deserves to be mentioned. He distilled the urine, and fixed to the
-receiver a tube furnished with a scale, the degrees of which consisted
-of all the parts of the body. The phenomena which he observed during
-the distillation of the urine, enabled him to draw inferences
-respecting the state of all these different organs.
-
-I pass over Bodenstein, Taxites, and Dorn, who distinguished themselves
-as partisans of Paracelsus. Dorn derived the whole of chemistry from
-the first chapter of Genesis, the words of which he explained in an
-alchymistical sense. These words in particular, “And God made the
-firmament, and divided the waters which were under the firmament
-from the waters which were above the firmament,” appeared to him to
-be an account of the _great work_. Severinus, physician to the King
-of Denmark, and canon of Roskild, was also a celebrated partisan of
-Paracelsus; but his writings do not show either that knowledge or
-stretch of thought which would enable us to account for the reputation
-which he acquired and enjoyed.
-
-There were very few partisans of Paracelsus out of Germany. The most
-celebrated of his followers among the French, was Joseph du Chesne,
-better known by the name of Quercitanus, who was physician to Henry
-IV. He was a native of Gascony, and drew many enemies upon himself by
-his arrogant and overbearing conduct. He pretended to be acquainted
-with the method of making gold. He was a thorough-going Paracelsian.
-He affirmed that diseases, like plants, spring from seeds. The word
-alchymy, according to him, is composed of the two Greek words ἁλς
-(salt) and χημεια, because the _great secret_ is concealed in salt. All
-bodies are composed of three principles, as God is of three substances.
-These principles are contained in saltpetre, the salts of sulphur solid
-and volatile, and the volatile mercurial salt. He who possesses _sal
-generalis_ may easily produce philosophical gold, and draw potable
-gold from the three kingdoms of nature. To prove the possibility of
-this transmutation, he cites an experiment very often repeated after
-him, and which some theologians have even employed as analogous to the
-resurrection of the dead; namely, the faculty which plants have of
-being produced from their ashes. His materia medica is founded on the
-_signatures_ of plants, which he carries so far as to assert that male
-plants are more suitable to men, and female plants to women. Sulphuric
-acid, he says, has a magnetic virtue, in consequence of which it is
-capable of curing the epilepsy. He recommends the _magisterium cranii
-humani_ as an excellent medicine, and boasts much of the virtues of
-antimony.
-
-Du Chesne was opposed by Riolanus, who attacked chemical remedies with
-much bitterness. The medical faculty of Paris took up the cause of the
-Galenists with much zeal, and prohibited their fellows and licentiates
-from using any chemical medicines whatever. He had to sustain a
-dispute with Aubert relative to the origin and the transmutation of
-metals. Fenot came to the assistance of Aubert, and affirmed that gold
-possesses no medical properties whatever, that _crabs’ eyes_ are of
-no use when administered in intermittents, and that the laudanum of
-Paracelsus (being an opiate) is in reality hurtful instead of being
-beneficial.
-
-The decree of the medical faculty of Paris which placed antimony among
-the poisons, and which occasioned that of the Parliament of Paris, was
-composed by Simon Pietre, the elder, a man of great erudition and the
-most unimpeachable probity. Had it been literally obeyed it would have
-occasioned very violent proceedings; because chemical remedies, as they
-act more promptly and with greater energy, were getting daily into
-more general use. In 1603 the celebrated Theodore Turquet de Mayenne
-was prosecuted, because, in spite of the prohibition, he had sold
-antimonial preparations. The decree of the faculty against him exhibits
-a remarkable proof of the bigotry and intolerance of the times.[160]
-However Turquet does not seem to have been molested notwithstanding
-this decree. He ceased indeed to be professor of chemistry, but
-continued to practise medicine as formerly; and two members of the
-faculty, Seguin and Akakia, even wrote an apology for him. At last he
-went to England, whither he had been invited, to accept an honourable
-appointment.
-
-[160] It was as follows: “Collegium medicorum in Academia Parisiensi
-legitime congregatum, audita renunciatione sensorum, quibus demandata
-erat provincia examinandi apologiam sub nomine Mayerni Turqueti editam,
-ipsam unanimi consensu damnat, tanquam famosum libellum, mendacibus
-conviciis et impudentibus calumniis refertum, quæ nonnisi ab homine
-imperito, impudenti, temulento et furioso profiteri potuerunt. Ipsum
-Turquetum indignum judicat, qui usquam medicinam faciat, propter
-temeritatem, impudentiam et veræ medicinæ ignorantiam. Omnes vero
-medicos, qui ubique gentium et locorum medicinam exercent, hortatur
-ut ipsum Turquetum similiaque hominum et opinionum portenta, a se
-suisque finibus arceant et in Hippocratis ac Galeni doctrina constantes
-permaneant: et prohibuit ne quis ex hoc medicorum Parisiensium ordine
-cum Turqueto eique similibus medica consilia ineat. Qui secus fecerit,
-scholæ ornamentis et academiæ privilegiis privabitur, et de regentium
-numero expungetur.--Datum Lutetiæ in scholis superioribus, die 5
-Decembris, anno salutis, 1603.”
-
-The mystical doctrines of Paracelsus are supposed to have given
-origin to the sect of Rosecrucians, concerning which so much has been
-written and so little certain is known. It is not at all unlikely
-that the greatest part, if not the whole that has been stated about
-the antiquity, and extent, and importance of this sect, is mere
-fiction, and that the origin of the whole was nothing else than a
-ludicrous performance of Valentine Andreæ, an ecclesiastic of Calwe,
-in the country of Wirtemburg, a man of much learning, genius, and
-philanthropy. From his life, written by himself, and preserved in
-the library of Wolfenbuttel, we learn that in the year 1603 he drew
-up the celebrated Noce Chimique of Christian Rosenkreuz, in order to
-counteract the alchymistical and the theosophistical dogmas so common
-at that period. He was unable to restrain his risible faculties when
-he saw this _ludibrium juvenilis ingenii_ adopted as a true history,
-while he meant it merely as a satire. It is believed that the Fama
-Fraternitatis is a production of this ecclesiastic, and that he
-published it in order to correct the chemists and enthusiasts of the
-time. He himself was called Andreæ, Knight of the Rose-cross (_rosæ
-crucis_) because he had engraven on his seal a cross with four roses.
-
-It is true that Andreæ instituted, in 1620, a _fraternitas christiana_,
-but with quite other views than those which are supposed to have
-actuated the Rosecrucians. His object was to correct the religious
-opinions of the times, and to separate Christian theology from
-scholastic controversies, with which it had been unhappily intermixed.
-He himself, in different parts of his writings, distinguishes carefully
-between the Rosecrucians and his own society, and amuses himself with
-the credulity of the German theosophists, who adopted so readily his
-fiction for a series of truths. It would appear, therefore, that this
-secret order of Rosecrucians, notwithstanding the brilliant origin
-assigned to it, really owes its birth to the pleasantry of a clergyman
-of Wirtemburg, who endeavoured by that means to set bounds to the
-chimeras of theosophy, but who unfortunately only increased still more
-the adherents of this absurd science.
-
-A crowd of enthusiasts found it too advantageous to propagate the
-principles of the _rosa crux_ not to endeavour to unite them into
-a sect. Valentine Weigel, a fanatical preacher at Tschoppau, near
-Chemnitz, left at his death a prodigious number of followers, who
-were already Rosecrucians, without bearing the name. Egidius Gutmann,
-of Suabia, was equally a Rosecrucian, without bearing the name; he
-condemned all pagan medicines, and affirmed that he possessed the
-universal remedy which ennobles man, cures all diseases, and gives man
-the power of fabricating gold. “To fly in the air, to transmute metals,
-and to know all the sciences,” says he, “nothing more is requisite than
-faith.”
-
-Oswald Crollius, of Hesse, must also take his station in this
-honourable fraternity of enthusiasts. He was physician to the Prince
-of Anhalt, and afterwards a counsellor of the Emperor Rodolphus II.
-The introduction to his Basilica Chymica, contains a short but exact
-epitome of the opinions of Paracelsus. It is not worth while to give
-the reader a notion of his own opinions, which are quite as absurd
-and unintelligible as those of Paracelsus and his followers. As a
-preparer of chemical medicines he deserves more credit; _antimonium
-diaphoreticum_ was a favourite preparation of his, and so was sulphate
-of potash, which was known at the time by the name of _specificum
-purgans Paracelsi_: he knew chloride of silver well, and first gave it
-the name of _luna cornea_, or _horn silver_: fulminating gold was known
-to him, and called by him _aurum volatile_.
-
-This is the place to mention Andrew Libavius, of Halle, in Saxony,
-where he was a physician, and a professor in the gymnasium of
-Coburg, who was one of the most successful opponents of the school
-of Paracelsus, and whose writings do him much credit. As a chemist,
-he deserves perhaps to occupy a higher rank than any of his
-contemporaries: he was, it is true, a believer in the possibility of
-transmuting metals, and boasted of the wonderful powers of _aurum
-potabile_; but he always distinguishes between rational alchymy and
-the _mental_ alchymy of Paracelsus. He separated, with great care,
-_chemistry_ from the reveries of the theosophists, and stands at
-the head of those who opposed most successfully the progress of
-superstition and fanaticism, which was making such an overwhelming
-progress in his time. His writings are very numerous and various, and
-were collected and published at Frankfort, in 1615, in three folio
-volumes, under the title of “Opera omnia Medico-chymica.” Libavius
-himself died in 1616. It would occupy more space than we have room
-for, to attempt an abstract of his very multifarious works. A few
-observations will be sufficient: he wrote no fewer than five different
-tracts to expose the quackery of George Amwald, who had boasted that
-he was in possession of a panacea, by means of which he was enabled
-to perform the most wonderful cures, and which he was in the habit of
-selling to his patients at an enormous price; Libavius showed that
-this boasted panacea was nothing else than _cinnabar_, which neither
-possessed the virtues ascribed to it by Amwald, nor deserved to be
-purchased at so high a price. He entered also into a controversy
-with Crollius, and exposed his fanatical and absurd opinions. He
-engaged likewise in a dispute with Henning Scheunemann, a physician in
-Bamberg, who was a Rosecrucian, and, like the rest of his brethren,
-profoundly ignorant not merely of all science, but even of philology.
-The expressions of Scheunemann are so obscure, that we learn more of
-his opinions from Libavius than from his own writings. He divides the
-internal nature of man into seven different degrees, from the seven
-changes it undergoes: these are, combustion, sublimation, dissolution,
-putrefaction, distillation, coagulation, and tincture. He gives us
-likewise an account of ten modifications which the three elements
-undergo; but as they are quite unintelligible, it is not worth while to
-state them. Libavius had the patience to analyze and expose all these
-gallimatias.
-
-Libavius’s system of chemistry, entitled “Alchymia è dispersis passim
-optimorum auctorum, veterum et recentiorum exemplis potissimum, tum
-etiam preceptis quibusdam operose collecta, adhibitisque ratione
-et experientia quanta potuit esse methodo accurate explicata et in
-integrum corpus redacta. Accesserunt tractati nonnulli physici chymici
-item methodistici.” Frankfort, 1595, folio, 1597, 4to.--is really an
-excellent book, considering the period in which it was written, and
-deserves the attention of every person who is interested in the history
-of chemistry. I shall notice some of the most remarkable chemical facts
-which occur in Libavius, and which I have not observed in any preceding
-writer; who the actual discoverer of these facts really was, it is
-impossible to say, in consequence of the secrecy which at that time was
-affected, and the obscure terms in which chemical facts are in general
-stated.
-
-He was aware that the fumes of sulphur have the property of blackening
-white lead. He was in the habit of purifying cinnabar by means of
-arsenic and oxide of lead. He knew the method of giving glass a red
-colour by means of gold or its oxide, and was aware of the method
-of making artificial gems, such as ruby, topaz, hyacinth, garnet,
-balass, by tinging glass by means of metallic oxides. He points out
-fluor spar as an excellent flux for various metals and their oxides.
-He knew that when metals were fused along with alkaline bodies, a
-certain portion of them was converted into slags, and this portion
-he endeavoured to recover by the addition of iron filings. He was
-aware of the mode of acidifying sulphur by means of nitric acid. He
-knew that camphor is soluble in nitric acid, and forms with it a kind
-of oil. Of the perchloride of tin he was undoubtedly the discoverer,
-as it has continued ever since his time to pass by his name; namely,
-_fuming liquor of Libavius_. He was aware, that alcohol or spirits
-could be obtained by distilling the fermented juice of a great variety
-of sweet fruits. He procured sulphuric acid by the distillation of alum
-and sulphate of iron, as Geber had done long before his time; but he
-determined the nature of the acid with more care than had been done,
-and showed, that it was the same as that obtained by the combustion of
-sulphur along with saltpetre. To him, therefore, in some measure, are
-we indebted for the process of preparing sulphuric acid which is at
-present practised by manufacturers.
-
-Libavius found a successor in Angelus Sala, of Vicenza, physician to
-the Duke of Mecklenburg-Schwerin, worthy of his enlightened views and
-indefatigable exertions to oppose the torrent of fanaticism which
-threatened to overwhelm all Europe. Sala was still more addicted to
-chemical remedies than Libavius himself; but he had abjured a multitude
-of prejudices which had distinguished the school of Paracelsus. He
-discarded _aurum potabile_, and considered fulminating gold as the
-only remedy of that metal that deserved to be prescribed by medical
-men. He treated the notion of the existence of a universal remedy with
-contempt. He described sulphuret of gold and glass of antimony with a
-good deal of precision. He recommended sulphuric acid as an excellent
-remedy, and showed that it might be formed indifferently from sulphur,
-or by distilling blue vitriol or green vitriol. He affirmed, that the
-essential salts obtained from plants had not the same virtues as the
-plants from which they are obtained. He showed that sal ammoniac is
-a compound of muriatic acid and ammonia. To him, therefore, we are
-indebted for the first accurate mention of ammonia. It could not but
-have been noticed before by chemists, as it is procured with so much
-ease by the distillation of animal substances; but Sala is the first
-person who seems to have examined it with attention, and to have
-recognised its peculiar properties, and the readiness with which it
-saturates the different acids. He showed that iron has the property
-of precipitating copper from acid solutions: he pointed out also
-various precipitations of metals by other metals. He seems to have
-been acquainted with calomel, and to have been aware of at least some
-of its medical properties. He says, that fulminating gold loses its
-fulminating property when mixed with its own weight of sulphur, and
-the sulphur is burnt off it. Many other curious chemical facts occur
-in his writings, which it would be too tedious to particularize here.
-His works were collected and published in a quarto volume at Frankfort,
-in 1647, under the title of “Opera Medico-chymica, quæ extant omnia.”
-There was another edition in the same place in 1682, and an edition was
-published at Rome in 1650.
-
-
-
-
-CHAPTER V.
-
-OF VAN HELMONT AND THE IATRO-CHEMISTS.
-
-
-Paracelsus first raised the dignity of chemistry, by pointing out the
-necessity of it for medical men, and by showing the superiority of
-chemical medicines over the disgusting decoctions of the Galenists.
-Libavius and Angelus Sala had carefully separated chemistry from the
-fanatical opinions of the followers of Paracelsus and the Rosecrucians.
-But matters were not doomed to remain in this state. Chemistry
-underwent a new revolution at this period, which shook the Spagirical
-system to its foundation; substituted other principles, and gave to
-medicine an aspect entirely new. This revolution was in a great measure
-due to the labours of Van Helmont.
-
-John Baptist Van Helmont was a gentleman of Brabant, and Lord of
-Merode, of Royenboch, of Oorschot, and of Pellines. He was born in
-Brussels in 1577, and studied scholastic philosophy in Louvain till
-the age of seventeen. After having finished his _humanity_ (as it was
-termed), he ought, according to the usage of the place, to have taken
-his degree of master of arts; but, having reflected on the futility of
-these ceremonies, he resolved never to solicit any academical honour.
-He next associated himself to the Jesuits, who then delivered courses
-of philosophy at Louvain, to the great displeasure of the professors
-of that city. One of the most celebrated of the Jesuits, Martin del
-Rio, even taught him magic. But Van Helmont was disappointed in his
-expectations: instead of that true wisdom which he hoped to acquire,
-he met with nothing but scholastic dialectics, with all its usual
-subtilties. He was no better satisfied with the doctrines of the
-Stoics, who taught him his own weakness and misery.
-
-At last the works of Thomas à Kempis, and John Taulerus fell into
-his hands. These sacred books of mysticism attracted his attention:
-he thought that he perceived that wisdom is the gift of the Supreme
-Being; that it must be obtained by prayer; and that we must renounce
-our own will, if we wish to participate in the influence of the divine
-grace. From this moment he imitated Jesus Christ, in his humility. He
-abandoned all his property to his sister, renouncing the privileges
-of his birth, and laying aside the rank which he had hitherto
-occupied in society. It was not long before he reaped the fruit of
-these abnegations. A genius appeared to him in all the important
-circumstances of his life. In the year 1633 his own soul appeared to
-him under the figure of a resplendent crystal.
-
-The desire which he had of imitating in every respect the conduct of
-Christ, suggested to him the idea of practising medicine as a work of
-charity and benevolence. He began, as was then the custom of the time,
-by studying the art of healing in the writings of the ancients. He
-read the works of Hippocrates and Galen with avidity; and made himself
-so well acquainted with their opinions, that he astonished all the
-medical men by the profundity of his knowledge. But as his taste for
-mysticism was insatiable, he soon became disgusted with the writings
-of the Greeks; an accident led him to abandon them for ever. Happening
-to take up the glove of a young girl afflicted with the _itch_, he
-caught that disagreeable disease. The Galenists whom he consulted,
-attributed it to the combustion of the bile, and the saline state of
-the phlegm. They prescribed a course of purgatives which weakened him
-considerably, without effecting a cure. This circumstance disgusted him
-with the system of the humorists, and led him to form the resolution of
-reforming medicine, as Paracelsus had done. The works of this reformer,
-which he read with attention, awakened in him a spirit of reformation,
-but did not satisfy him; because his knowledge, being much greater
-than that of Paracelsus, he could not avoid despising the disgusting
-egotism, and the ridiculous ignorance of that fanatic. Though he had
-already refused a canonicate, he took the degree of doctor of medicine,
-in 1599, and afterwards travelled through the greatest part of France
-and Italy; and he assures us, that during his travels, he performed
-a great number of cures. On his return, he married a rich Brabantine
-lady, by whom he had several children; among others a son, afterwards
-celebrated under the name of Francis Mercurius, who edited his father’s
-works, and who went a good deal further than his father had done, in
-all the branches of theosophy. Van Helmont passed the rest of his
-life on his estate at Vilvorde, almost constantly occupied with the
-processes of his laboratory. He died in the year 1644, on the 13th of
-December, at six o’clock in the evening, after having nearly reached
-the age of sixty-seven years.
-
-The system of Van Helmont has for its basis the opinions of the
-spiritualists. He arranged even the influence of evil genii, the
-efforts of sorcerers, and the power of magicians among the causes which
-produce diseases. The archeus of Paracelsus constituted one of the
-capital points of his theory; but he ascribed to it a more substantial
-nature than Paracelsus had done. This archeus is independent of
-the elements; it has no form; for form constitutes the object of
-generation, or of production. These ideas are obviously borrowed
-from the ancients. The _form_ of Aristotle is not the μορφη, but the
-ενεργεια (_the power of acting_) which matter does not possess.
-
-The archeus draws all the corpuscles of matter to the aid of
-_fermentation_. There are, properly speaking, only two causes of
-things; the cause _ex qua_, and the cause _per quam_. The first of
-these causes is _water_. Van Helmont considered water as the true
-principle of every thing which exists; and he brought forward very
-specious arguments in favour of his opinion, drawn both from the
-animal and vegetable kingdom. The reader will find his arguments on
-the subject, in his treatise entitled “Complexionum atque Mistionum
-elementalium Figmentum.”[161] The only one of his experiments that,
-in the present state of our knowledge, possesses much plausibility,
-is the following: He took a large earthen vessel, and put into it 200
-lbs. of earth, previously dried in an oven. This earth he moistened
-with rain-water, and planted in it a willow which weighed five pounds.
-After an interval of five years, he pulled up his willow and found
-that its weight amounted to 169 pounds, and about three ounces. During
-these five years, the earth in the pot was duly watered with rain
-or distilled water. To prevent the earth in which the willow grew
-from being mixed with new earth blown upon it by the winds, the pot
-was covered with tin plate, pierced with a great number of holes to
-admit the air freely. The leaves which fell every autumn during the
-vegetation of the willow in the pot, were not reckoned in the 169 lbs.
-3 oz. The earth in the pot being again dried in the oven, was found to
-have lost about two ounces of its original weight. Thus 164 lbs. of
-wood, bark, roots, &c., were produced from water alone.[162] This,
-and several other experiments which it is needless to state, satisfied
-him that all vegetable substances are produced from water alone. He
-takes it for granted that fish live (ultimately at least) on water
-alone; but they contain almost all the peculiar animal substances that
-exist in the animal kingdom. Hence he concludes that animal substances
-are derived also from pure water.[163] His reasoning with respect
-to sulphur, glass, stone, metals, &c., all of which he thinks may
-ultimately be resolved into water, is not so satisfactory.
-
-[161] J. B. Van Helmont, Opera Omnia, p. 100. The edition which I quote
-from was printed at Frankfort, in 1682, at the expense of John Justus
-Erythropilus, in a very thick quarto volume.
-
-[162] Van Helmont, Opera Omnia, p. 104.
-
-[163] Ibid., p. 105.
-
-Water produces elementary earth, or pure quartz; but this elementary
-earth does not enter into the composition of organic bodies. Van
-Helmont excludes _fire_ from the number of elements, because it is not
-a substance, nor even the essential form of a substance. The matter of
-fire is compound, and differs entirely from the matter of light. Water
-gives origin also to the three chemical principles, salt, sulphur, and
-mercury, which cannot be considered as elements or active principles. I
-do not see clearly how he gets rid of _air_; for he says, that though
-water may be elevated in the form of vapour, yet that these vapours are
-no more air than the dust of marble is water.
-
-According to Van Helmont, a particular disposition of matter, or a
-particular mixture of that matter is not necessary for the formation of
-a body. The archeus, by its sole power, draws all bodies from water,
-when the _ferment_ exists. This _ferment_, in its quality of a mean
-which determines the action of the archeus, is not a formal being; it
-can neither be called a _substance_, nor an _accident_. It pre-exists
-in the seed which is developed by it, and which contains in itself
-a second ferment of the seed, the product of the first. The ferment
-exhales an odour, which attracts the generating spirit of the archeus.
-This spirit consists in an _aura vitalis_, and it creates the bodies
-of nature in its own image, after its own _idea_. It is the true
-foundation of life, and of all the functions of organized bodies; it
-disappears only at the instant of death to produce a new creation of
-the body, which enters then, for the second time, into fermentation.
-The seed, then, is not indispensable to enable an animal to propagate
-its species; it is merely necessary that the archeus should act upon
-a suitable ferment. Animals produced in this manner are as perfect as
-those which spring from eggs.
-
-When water, as an element, ferments, it develops a vapour, to which Van
-Helmont gave the name of _gas_, and which he endeavours to distinguish
-from _air_. This gas contains the chemical principles of the body from
-which it escapes in an aerial form by the impulse of the archeus. It
-is a substance intermediate between spirit and matter, the principle
-of action of life, and of generation of all bodies; for its production
-is the first result of the action of the vital spirit on the torpid
-ferment, and it may be compared to the _chaos_ of the ancients.
-
-The term _gas_, now in common use among chemists, and applied by them
-to all elastic fluids which differ in their properties from common air,
-was first employed by Van Helmont: and it is evident, from different
-parts of his writings, that he was aware that different species of gas
-exist. His _gas sylvestre_ was evidently our _carbonic acid gas_, for
-he says, that it is evolved during the fermentation of wine and beer;
-that it is formed when charcoal is burnt in air; and that it exists
-in the Grotto del Cane. He was aware that this gas extinguishes a
-lighted candle. But he says that the gases from dung, and those formed
-in the large intestines, when passed through a candle, catch fire,
-and exhibit a variety of colours, like the rainbow.[164] To these
-combustible gases he gave the names of _gas pingue_, _gas siccum_, _gas
-fuliginosum_, or _endimicum_.
-
-[164] De Flatibus, sect. 49. Opera Van Helmont, p. 405.
-
-Sal ammoniac, he says, may be distilled alone, without danger, and so
-may aqua fortis (_aqua chrysulca_), but if they be mixed together so
-much gas sylvestre is produced, that the vessels employed, however
-strong, will burst asunder, unless an opening be left for the escape
-of this gas.[165] In the same way cream of tartar cannot be distilled
-in close vessels without breaking them in pieces, an opening must be
-left for the escape of the _gas sylvestre_, which is generated in
-such abundance.[166] He says, also, that when carbonate of lime is
-dissolved in distilled vinegar, or silver in nitric acid, abundance
-of gas sylvestre is extricated. From these, and many other passages
-which might be quoted, it is evident that Van Helmont was aware of the
-evolution of gas during the solution of carbonates and metals in acids,
-and during the distillation of various animal and vegetable substances,
-that he had anticipated the experiments made so many years after by
-Dr. Hales, and for which that philosopher got so much credit. But it
-would be going too far to say, as some have done, that Van Helmont
-knew accurately the differences which characterize the different gases
-which he produced, or indeed that he distinguished accurately between
-them. For it is evident, from the passages quoted and from many others
-which occur in his treatise, De Flatibus, that carbonic acid, protoxide
-of azote, and deutoxide of azote, and probably also muriatic acid gas
-were all considered by him as constituting one and the same gas. How,
-indeed, could he distinguish between different gases when he was not
-acquainted with the method of collecting them, or of determining their
-properties? These observations of Van Helmont, then, though they do him
-much credit, and show how far his chemical knowledge was superior to
-that of the age in which he lived, take nothing from the merit or the
-credit of those illustrious chemists who, in the latter half of the
-eighteenth century, devoted themselves to the investigation of this
-part of chemistry, at that time attended with much difficulty, but
-intimately connected with the subsequent progress which the science has
-made.
-
-[165] Ibid., p. 408.
-
-[166] Ibid., p. 409.
-
-Van Helmont was aware, also, that the bulk of air is diminished when
-bodies are burnt in it. He considered respiration to be necessary in
-this way: the air was drawn into the blood by the pulmonary arteries
-and veins, and occasioned a fermentation in it requisite for the
-continuance of life.
-
-Gas, according to Van Helmont, has an affinity with the principle of
-the movement of the stars, to which he gave the name of _blas_. It had,
-he supposed, much influence on all sublunary bodies. He admitted in
-the ferment which gives birth to plants, a substance which, after the
-example of Paracelsus, he called _pessas_, and to the metallic ferment
-he gave the name of _bur_.[167]
-
-[167] In his Magnum Oportet, sect. 39, p. 151, he gives an account
-of the origin of metals in the earth, and in that section there is a
-description of _bur_, which those who are anxious to understand the
-ideas of the author on this subject may consult.
-
-The archeus of Van Helmont, like that of Paracelsus, has its seat in
-the stomach. It is the same thing as the sentient soul. This notion
-of the nature and seat of the archeus was founded on the following
-experiment: He swallowed a quantity of _aconitum_ (_henbane_). In two
-hours he experienced the most disagreeable sensation in his stomach.
-His feeling and understanding seemed to be concentrated in that
-organ, for he had no longer the free use of his mental faculties.
-This feeling induced him to place the seat of understanding in the
-stomach, of volition in the heart, and of memory in the brain. The
-faculty of desire, to which the ancients had assigned the liver as its
-organ, he placed in the spleen. What confirmed him still more in the
-idea that the stomach is the seat of the soul, is the fact, that life
-sometimes continues after the destruction of the brain, but never, he
-alleges, after that of the stomach. The sentient soul acts constantly
-by means of the _vital spirits_, which are of a resplendent nature,
-and the nerves serve merely to moisten these spirits which constitute
-the mediums of sensation. By virtue of the archeus man is much nearer
-to the realm of spirits and the father of all the genii, than to the
-world. He thinks that Paracelsus’s constant comparison of the human
-body with the world is absurd. Yet Van Helmont, at least in his
-youth, was a believer in magnetism, which he employed as a method of
-explaining the effect of sympathy.
-
-The archeus exercises the greatest influence on digestion, and he
-has chiefly the stomach and spleen under his superintendence. These
-two organs form a duumvirate in the body; for the stomach cannot
-act alone and without the concurrence of the spleen. Digestion is
-produced by means of an acid liquor, which dissolves the food, under
-the superintendence of the archeus. Van Helmont assures us that he
-had himself tasted this acid liquor in the stomach of birds. Heat,
-strictly speaking, does not favour digestion; for we see no increase of
-the digestive powers during the most ardent fever. Nor are the powers
-of digestion wanting in fishes, although they want the animal heat
-which is requisite for mammiferous animals. Certain birds even digest
-fragments of glass, which, certainly, simple heat would not enable them
-to do. The pylorus is, in some measure, the director of digestion. It
-acts by a peculiar and immaterial power, in virtue of a _blas_, and not
-as a muscle. It opens and shuts the stomach according to the orders of
-the archeus. It is in it, therefore, that the causes of derangement of
-digestion must be sought for.
-
-The duumvirate just spoken of is the cause of natural sleep, which does
-not belong to the soul, as far as it resides in the stomach. Sleep is
-a natural action, and one of the first vital actions. Hence the reason
-why the embryo sleeps without ceasing. At any rate it is not true that
-sleep is owing to vapours which mount to the brain. During sleep the
-soul is naturally occupied, and it is then that the deity approaches
-most intimately to man. Accordingly, Van Helmont informs us, that he
-received in dreams the revelation of several secrets, which he could
-not have learnt otherwise.
-
-The duumvirate operates the _first_ digestion, of which, Van Helmont
-enumerates six different species. When the acid, which is prepared for
-digestion, passes into the duodenum it is neutralized by the bile of
-the gall-bladder. This constitutes the second digestion. To the bile of
-the gall-bladder, Van Helmont gave the name of _fel_, and he carefully
-distinguished it from the biliary principle in the mass of the blood.
-This last he called _bile_. The _fel_ is not an excrementitious matter,
-but a humour necessary to life, a true vital balsam. Van Helmont
-endeavoured to show by various experiments that it is not _bitter_.
-
-The _third_ digestion takes place in the vessels of the mesentery,
-into which the gall-bladder sends the prepared fluid. The _fourth_
-digestion is operated in the heart, where the red blood becomes more
-yellow and more volatile by the addition of the vital spirits. This
-is owing to the passage of the vital spirit from the posterior to the
-anterior ventricle, through the pores of the septum. At the same time
-the pulse is produced, which of itself develops heat; but does not
-regulate it in any manner, as the ancients pretended that it did. The
-_fifth_ digestion consists in the conversion of the arterial blood
-into vital spirit. It takes place principally in the brain, but is
-produced also throughout all the body. The _sixth_ digestion consists
-in the elaboration of the nutritive principle in each member, where the
-archeus prepares its own nourishment by means of the vital spirits.
-Thus, there are six digestions: the number seven has been chosen by
-nature for a state of repose.
-
-From the preceding sketch of the physiology of Van Helmont, it is
-evident that he paid little or no regard to the structure of the parts
-in explaining the functions. In his pathology we find the same passion
-for spiritualism. He admitted, indeed, the importance of anatomy, but
-he regretted that the pathological part of that science had been so
-little cultivated. As the archeus is the foundation of life and of all
-the functions, it is plain that the diseases can neither be derived
-from the four cardinal humours, nor from the disposition or the action
-of opposite things; the proximate cause of diseases must be sought for
-in the sufferings, the anger, the fear, and the other affections of the
-archeus, and their remote cause may be considered as the ideal seed
-of the archeus. Disease, in his opinion, is not a negative state or a
-mere absence of health, it is a substantial and active thing as well
-as a state of health. Most of the diseases which attack certain parts
-or members of the body result from an error in the archeus, who sends
-his ferment from the stomach in which he resides into the other parts
-of the body. Van Helmont explained in this way not only the epilepsy
-and madness, but likewise the _gout_, which does not proceed from a
-flux, and has not its seat in the limb in which the pain resides, but
-is always owing to an error in the vital spirit. It is true that the
-character of the gout acts upon the semen in which the vital spirit
-principally manifests its action, and that in this way diseases are
-propagated in the act of generation; but if, during life instead of
-altering the semen it is carried to the liquid of the articulations,
-this is a proof of the prudence of nature, which lavishes all her
-cares on the preservation of the species, and loves better to alter
-the humours of the articulations than the semen itself. The gout
-acidifies the liquors of the articulations, which is then coagulated
-by the acids. The duumvirate is the cause of apoplexy, vertigo, and
-particularly of a species of asthma, which Van Helmont calls _caducus
-pulmonalis_. Pleurisy is produced in a similar way. The archeus, in a
-movement of rage, sends acrid acids to the lungs, which occasion an
-inflammation. Dropsy is also owing to the anger of the archeus, who
-prevents the secretions of the kidneys from going on in the usual way.
-
-Of all the diseases, fever appeared to him most conformable to his
-notions of the unlimited power of the archeus. The causes of fever are
-all much more proper to offend the archeus, than to alter the structure
-of parts and the mixture of humours. The cold fit is owing to a state
-of fear and consternation, into which the archeus is thrown, and the
-hot stage results from his disordered movements. All fevers have their
-peculiar seat in the duumvirate.
-
-Van Helmont was in general much more successful in refuting the
-scholastic opinions by which the practice of medicine was regulated in
-his time, than in establishing his own. We are struck with the force
-of his arguments against the Galenical doctrine of fever, and against
-the influence of the cardinal humours on the different kinds of fever.
-He refuted no less vehemently the idea of the putridity of the blood,
-while that liquid circulates in the vessels. Perhaps he carried the
-opposite doctrine too far; but his opinions have had a good effect upon
-subsequent medical theory, and medical men learned from them to make
-less use of the term putridity. The phrase _mixture of humours_, not
-more intelligible, however, came to be substituted for it.
-
-Van Helmont’s theory of urinary calculi deserves peculiar attention,
-because it exhibits the germ of a more rational explanation of these
-concretions than had been previously attempted by physiologists. Van
-Helmont was aware that Paracelsus, who ascribed these concretions to
-tartar, had formed an idea of their nature, which a careful chemical
-analysis would immediately refute. He satisfied himself that urinary
-calculi differ completely from common stones, and that they do not
-exist in the food or drink which the calculous person had taken.
-Tartar, he says, precipitates from wine, not as an earth, but as
-a crystallized salt. In like manner, the natural salt of urine
-precipitates from that liquid, and gives origin to calculi. We may
-imitate this natural process by mixing spirit of urine with rectified
-alcohol. Immediately an _offa alba_ is precipitated.
-
-It is needless to observe that Van Helmont was mistaken, in supposing
-that this _offa_ was the matter of calculus. Spirit of urine was a
-strong solution of carbonate of ammonia. The alcohol precipitated
-this salt; so that his _offa_ was merely _carbonate of ammonia_. Nor
-is there the shadow of evidence that alcohol, as Van Helmont thought
-it did, ever makes its way into the mass of humours; yet his notion
-of the origin of calculi is not less accurate, though of course he
-was ignorant of the chemical nature of the various substances which
-constitute these calculi. From this reasoning Van Helmont was induced
-to reject the term _tartar_, employed by Paracelsus. To avoid all false
-interpretations he substitutes the word _duelech_, to denote the state
-in which the spirit of urine precipitates and gives origin to these
-calculous concretions.
-
-As all diseases proceeded in his opinion from the archeus, the object
-of his treatment was to calm the archeus, to stimulate it, and to
-regulate its movements. To accomplish these objects he relied upon
-dietetics, and upon acting on the imaginations of his patients. He
-considered _certain words_ as very efficacious in curing the diseases
-of the archeus. He admitted the existence of the universal medicine,
-to which he gave the names of _liquor alkahest_, _ens primum salium_,
-_primus metallus_. Mercurials, antimonials, opium, and wine, are
-particularly agreeable to the archeus, when in a state of delirium from
-fever.
-
-Among the mercurial preparations, he praises what he calls _mercurius
-diaphoreticus_ as the best. He gives no account of the mode of
-preparing it; but from some circumstances I think it must have been
-_calomel_. He considers it as a sovereign remedy in fevers, dropsies,
-diseases of the liver, and ulcers of the lungs. He employed the red
-oxide of mercury as an external application to ulcers. The principal
-antimonial preparations which he employed were the hydrosulphuret, or
-_golden sulphur_, and the deutoxide, or _antimonium diaphoreticum_.
-This last medicine was used in scruple doses--a proof of its great
-inertness compared with the protoxide of antimony.
-
-Opium he considered as a fortifying and calming medicine. It contains
-an acrid salt and a bitter oil, which give it the virtue of putting a
-stop to the errors of the archeus, when it was sending its acid ferment
-into other acid parts of the body. Van Helmont assures us that he
-wrought many important cures by the employment of wine.
-
-Such is a very short statement of the opinions of a man, who,
-notwithstanding his attachment to the fanatical opinions which
-distinguished the time in which he lived, had the merit of overturning
-a vast number of errors, both theoretical and practical; and of
-laying down many principles, which, for want of erudition, have been
-frequently assigned to modern writers. Van Helmont has been frequently
-placed on the same level with Paracelsus, and treated like him with
-contempt. But his claims upon the medical world are much higher, and
-his merits infinitely greater. His notions, it is true, were fanatical;
-but his erudition was great, his understanding excellent, and his
-industry indefatigable. His writings did not become known till rather a
-late period; for, with the exception of a single tract, they were not
-published till 1648, by his son, after his death.
-
-The decided preference given to chemical medicines by Van Helmont, and
-the uses to which he applies chemical theory, had a natural tendency
-to raise chemistry to a higher rank in the eyes of medical men than
-it had yet reached. But the man to whom the credit of founding the
-iatro-chemical sect is due, is Francis de le Boé Sylvius, who was
-born in the year 1614. While a practitioner of medicine at Amsterdam,
-he studied with profound attention the system of Van Helmont, and
-the rival and much more popular theory of Descartes: upon these he
-founded his own theory, which, in reality, contains little entitled to
-the name of original, notwithstanding the tone in which he speaks of
-it, and his repeated declarations that he had borrowed from no one.
-He was appointed professor of the theory and practice of medicine in
-the University of Leyden, where he taught with such eclat, and drew
-after him so great a number of pupils, that Boerhaave alone surpassed
-him in this respect. It was he that first introduced the practice of
-giving clinical lectures in the hospitals, on the cases treated in the
-presence of the pupils. This admirable innovation has been productive
-of much benefit to medicine. He greatly promoted anatomical studies,
-and inspected, himself, a vast number of dead bodies. This is the more
-remarkable, because his own system, like that of Van Helmont, from whom
-it was borrowed, was quite independent of the structure of the parts.
-
-Every thing was explained by him according to the principles of
-chemistry, as they were then understood. The celebrity of the
-university in which he taught, and the vast number of his pupils,
-contributed to spread this theory into every part of the world, and to
-give it an eclat which is really surprising, when we consider it with
-attention. But he possessed the talents just suited for securing the
-reception of his opinions by his pupils as infallible oracles, and of
-being the idol of the university. Yet it is melancholy to be obliged to
-add, that few persons ever more abused the favours of nature, or the
-advantages of situation and elocution.
-
-To form a clear idea of the principles of this founder of
-iatro-chemistry, we have only to call to mind the ferments of Van
-Helmont, which constitute the foundation-stone of the whole system.
-We cannot, says he, conceive a single change in the mixture of the
-humours, which is not the consequence of fermentation; and yet he
-assigns to this fermentation conditions which are scarcely to be
-found united in the living body. Digestion, in his opinion, is a
-true fermentation produced by the application of a ferment. Like Van
-Helmont, he admits a _triumvirate_; but places it in the humours; the
-effervescence or fermentation of which enabled him to explain most of
-the functions of the body. Digestion is the result of the mixture of
-the saliva with the pancreatic juice and the bile, and the fermentation
-of these humours. The saliva, as well as the pancreatic juice, contains
-an acidulous salt easily recognised by the taste. Here Sylvius derives
-advantage from the experiments of Regnier de Graaf on the pancreatic
-juice, which he had constantly found acid.
-
-Sylvius, who affirmed that the bile contained an alkali, united with
-an oil and a volatile spirit, supposes an effervescence from the union
-of the alkali of the bile with the acid of the pancreatic juice, and
-this _fermentation_ he considered as the cause of digestion. By this
-fermentation the _chyle_ is produced, which is nothing else than the
-_volatile spirit_ of the food accompanied by an _oil_ and an alkali,
-neutralized by a weak acid. The blood is more than completed (_plus
-quam perficitur_) in the spleen. It acquires its highest perfection by
-the addition of a certain quantity of vital spirits. The _bile_ is not
-drawn from the blood in the liver, but pre-exists in the circulating
-fluid. It mixes with that fluid anew to be carried to the heart
-together with the _lymph_, equally mixed with the blood, and there it
-gives origin to a vital fermentation. In this way the blood becomes
-the centre of reunion of all the humours of the secretions, which mix
-together or separate, without the solids taking the smallest share in
-the operations. Indeed, so completely are the solids banished from
-the system of Sylvius that he attends to nothing whatever except the
-humours.
-
-The formation and motion of the blood is explained by the fermentation
-of the oily volatile salt of the bile, and the dulcified acid of the
-lymph, which develops the vital heat, by which the blood is attenuated
-and becomes capable of circulating. This vital fire, quite different
-from ordinary fire is kept up in its turn by the uniform mixture of the
-blood. It attenuates the humours, not because it is _heat_ but because
-it is composed of _pyramids_. This last notion is obviously borrowed
-from Descartes, just as the fermentation in the heart, as the cause of
-the motion of the blood, reminds us of the opinions of Van Helmont.
-
-Sylvius explains the preparation of the vital spirits in the encephalos
-by distillation, and he finds a great resemblance between their
-properties and those of spirit of wine. The nerves conduct these
-spirits to the different parts, and they spread themselves in the
-substance of the organs to render them sensible. When they insinuate
-themselves into the glands the addition of the acid of the blood
-produces a liquid analogous to naphtha, which constitutes the _lymph_.
-Lymph, then, is a compound of the vital spirit and the acid of the
-blood. _Milk_ is formed in the mammæ by the afflux of a very mild acid,
-which gives a white colour to the red humour of the blood.
-
-The theory of the natural functions was no less chemical. Even the
-diseases themselves were explained upon chemical principles. Sylvius
-first introduced the word _acridity_ to denote a predominance of the
-chemical elements of the humours, and he looked upon these _acridities_
-as the proximate cause of all diseases. But as every thing acrid may be
-referred to one or other of two classes, acids and alkalies, there are
-only two great classes of diseases; namely, those proceeding from an
-_acid acridity_, and those proceeding from an _alkaline_.
-
-Sylvius was not altogether ignorant of the constituent parts of the
-animal humours; but it is obvious, from the account of his opinions
-just given, that this knowledge was very incomplete; indeed the whole
-of his chemical science resolves itself into a comparison of the
-humours of the living body with chemical liquids. Perhaps his notions
-respecting such of the _gases_, as he had occasion to observe, were
-somewhat clearer than those of Van Helmont. He called them _halitus_,
-and takes some notice of their different chemical properties, and
-states the influence which he supposes them to exert in certain
-diseases.
-
-In the human body he saw nothing but a magna of humours continually in
-fermentation, distillation, effervescence, or precipitation; and the
-physician was degraded by him to the rank of a distiller or a brewer.
-
-Bile acquires different acridities, when bad food, altered air,
-or other similar causes act apon the body. It becomes _acid_ or
-_alkaline_. In the former case it thickens and occasions obstructions;
-in the latter it excites febrile heat; and the viscid vapours elevated
-from it are the cause of the cold fit with which fever commences. All
-acute and continued fevers have their origin in this acridity of the
-bile. The vicious mixture of the bile with the blood, or its specific
-acridity, produces _jaundice_, which is far from being always owing to
-obstructions in the liver. The vicious effervescence of the bile with
-the pancreatic juice produces almost all other diseases. But all these
-assertions of Sylvius are unsupported by evidence.
-
-The acid acridity of the pancreatic juice, and the obstruction of the
-pancreatic ducts, which are produced by it, are considered by him as
-the cause of intermittent fevers. When the acid of the pancreatic
-juice acquires still more acridity, hypochondriasis and hysteria are
-the consequences of it. If, during the morbid effervescence of the
-pancreatic juice with the bile an acid and viscid humour arise, the
-vital spirits of the heart are overwhelmed during a certain time.
-This occasions syncope, palpitation of the heart, and other nervous
-affections.
-
-When the acid acridity of the pancreatic juice or of the lymph (for
-both are similar) is deposited on the nerves, the consequence is spasms
-or convulsions; epilepsy in particular depends upon the acrid vapours
-produced by the morbid effervescence of the pancreatic juice with acrid
-bile. Gout has the same origin as intermittent fevers, for we must look
-for it in the obstruction of the pancreas and the lymphatic glands,
-accompanied with an acid acridity of the lymph. Rheumatism is owing to
-the acrid acid, deprived of the oil which dulcifies it. The smallpox is
-occasioned by an acid acridity in the lymph, which gives origin to the
-pustules. Indeed all suppuration in general is owing to a coagulating
-acid in the lymph. Syphilis results from a caustic acid in the lymph.
-The itch is produced by an acid acridity of the lymph. Dropsies are
-produced by the same acid acridity of the lymph. Urinary calculi are
-the consequences of a coagulating acid existing in the lymph and the
-pancreatic juice. Corrosive acids, and the loss of volatile spirits,
-occasion leucorrhœa.
-
-From the preceding statement it would appear that almost all diseases
-proceed from acids. However, Sylvius informs us that malignant fevers
-are owing to a superabundance of volatile salts and to a too great
-tenuity of the blood. The vital spirits themselves give occasion to
-diseases. They are sometimes too aqueous, sometimes they effervesce too
-violently, and sometimes not at all. Hence all the nervous diseases,
-which Sylvius never considers as existing by themselves; but as always
-derived from the acid, acrid, or alkaline vapours which trouble the
-vital spirits.
-
-The method of cure which Sylvius deduced from these absurd and
-contemptible hypotheses, was worthy of the hypotheses themselves;
-and certainly constitute the most detestable mode of treatment that
-ever has disgraced medical science. To diseases produced by the
-effervescence of the bile he opposed purgatives; because in his
-opinion emetics produced injurious effects. The reason was, that the
-emetics which he employed were too violent, consisting of antimonial
-preparations, particularly _powder of Algerotti_, or an impure
-protoxide of antimony. For though _emetic tartar_ had been discovered
-in 1630, it does not seem to have come into use till a much later
-period. We do not find any notice of it in the _praxis chymiatrica_ of
-Hartmann published in 1647, at Geneva.
-
-He endeavoured to moderate the acridity of the bile by opiates and
-other narcotics. It will scarcely be believed, though it was a natural
-consequence of his opinions, when we state that he recommended
-ammoniacal preparations, particularly his oleaginous volatile salt, and
-spirit of hartshorn, &c., as cures for almost all diseases. Sometimes
-they were employed to correct the acidity of the lymph, sometimes
-to destroy the acid acridity of the pancreatic juice, sometimes to
-correct the inertness of the vital spirits, sometimes to promote the
-secretions, and to induce a flow of the menses. Volatile spirit of
-amber and opium were prescribed by him in intermittent fevers; and
-volatile salts in almost all acute diseases. He united them with
-antivenomous potions, angelica, contrayerva, bezoard, crabs’ eyes, and
-other similar substances. These absorbents seemed to him very necessary
-to correct the acidity of the pancreatic juice, and the acridity of the
-bile. In administering them he paid no attention to the regular course
-which acute diseases usually run; he neither inquired into the remote
-nor proximate causes of disease, nor to the symptoms: every thing was
-neglected connected with induction, and his whole proceedings regulated
-by wild speculations and absurd theories, quite inconsistent with the
-phenomena of nature.
-
-To attempt to refute these wild notions of Sylvius would be loss of
-time. It is extraordinary, and almost incredible, that he could have
-regulated his practice by them: and it is a still more incredible
-thing, and exhibits a very humiliating view of human nature, that these
-crudities and absurdities were swallowed with avidity by crowds of
-students, who placed a blind reliance on the dogmas of their master,
-and were initiated by him into a method of treating their patients,
-better calculated than any other that could easily have been devised,
-to aggravate all their diseases, and put an end to their lives. If any
-of the patients of the iatro-chemists ever recovered their health, well
-might it be said that their recovery was not the consequence of the
-prescriptions of their physicians, but that it took place in spite of
-them.[168]
-
-[168] As an example of the prescriptions of Sylvius, we give the
-following for malignant fever:
-
-  _R._ Theriac. veter. ᴣij
-       Antim. diaphor. ᴣj
-       Syrup. Card. Benedic. ℥ij
-       Aq. prophylact. ℥j
-       -- Cinnam. ℥ss
-       -- Scabios. ℥ij
-  M. D.
-
-
-It is a very remarkable circumstance, and shows clearly that mankind
-in general had become disgusted with the dogmas of the Galenists,
-that iatro-chemistry was adopted more or less completely by almost
-all physicians. There were, indeed, a few individuals who raised
-their voices against it; but, what is curious and inexplicable, they
-never attempted to start objections against the principles of the
-iatro-chemists, or to point out the futility of their hypothesis, and
-their inconsistency with fact. They combated them by arguments not more
-solid than those of their antagonists.
-
-During the presidency of Riolan over the Medical College of Paris,
-that learned body set itself against all innovations. Guy Patin, who
-was a medical professor in the University of Paris, and a man of great
-celebrity, opposed the chemical system of medicine with much zeal. In
-his Martyrologium Antimonii he collects all the cases in which the use
-of antimony, as a medicine, had proved injurious to the patient. But
-in the year 1666, the dispute relative to antimony, and particularly
-relative to tartar emetic, became so violent, that all the doctors of
-the faculty of Paris were assembled by an order of the parliament,
-under the presidency of Dean Vignon, and after a long deliberation,
-it was concluded by a majority of ninety-two votes, that tartar
-emetic, and other antimonials, should not only be permitted, but even
-recommended. Patin after this decision pretended no longer to combat
-chemical medicine; but he did not remain inactive. One of his friends,
-Francis Blondel, demanded the resolution to be cancelled; but his
-exertions were unsuccessful; nor were the writings of Guillemeau and
-Menjot, who were also keen partisans of the views of Patin, attended
-with better success.
-
-In England iatro-chemistry assumed a direction quite peculiar. It was
-embraced by a set of men who had cultivated anatomy with the most
-marked success, and who were quite familiar with the experimental
-method of investigating nature. The most eminent of all the English
-supporters of iatro-chemistry was Thomas Willis, who was a contemporary
-of Sylvius.
-
-Dr. Willis was born at Great Bodmin, in Wiltshire, in 1621. He was
-a student at Christchurch College, in Oxford, when that city was
-garrisoned for King Charles I. Like the other students, he bore arms
-for his Majesty, and devoted his leisure hours to the study of physic.
-After the surrender of Oxford to the parliament, he devoted himself to
-the practice of medicine, and soon acquired reputation. He appropriated
-a room as an oratory for divine service, according to the forms of
-the church of England, to which most of the loyalists of Oxford daily
-resorted. In 1660, he became Sedleian professor of natural philosophy,
-and the same year he took the degree of doctor of physic. He settled
-ultimately in London, and soon acquired a higher reputation, and a more
-extensive practice, than any of his contemporaries. He died in 1675,
-and was buried in Westminster Abbey. He was a first-rate anatomist. To
-him we are indebted for the first accurate description of the brain and
-nerves.
-
-But it is as an iatro-chemist that he claims a place in this work. His
-notions approach nearer to those of Paracelsus than to the hypotheses
-of Van Helmont and Sylvius. He admits the three chemical elements of
-Paracelsus, salt, sulphur, and mercury, in all the bodies in nature,
-and employs them to explain their properties and changes; but he gives
-the name of _spirit_ to the _mercury_ of Paracelsus. He ascribes to it
-the virtue of volatilizing all the constituent parts of bodies: salt,
-on the other hand, is the cause of fixity in bodies; _sulphur_ produces
-colour and heat, and unites the _spirit_ to the _salt_. In the stomach
-there occurs an acid ferment, which forms the chyle with the sulphur
-of the aliments: this chyle enters into effervescence in the heart,
-because the salt and sulphur take fire together. From this results
-the vital flame, which penetrates every thing. The vital spirits are
-secreted in the brain by a real distillation. The vessels of the testes
-draw an elixir from the constituent parts of the blood; but the spleen
-retains the earthy part, and communicates a new igneous ferment to the
-circulating fluid. On this account the blood must be considered as a
-humour, constantly disposed to fermentation, and in this respect it may
-be compared to wine. Every humour in which salt, sulphur, and spirit
-predominates in a certain manner, may be converted into a _ferment_.
-All diseases proceed from a morbid state or action of this ferment; and
-a physician may be compared to a wine-merchant; for, like him, he has
-nothing to do but to watch that the necessary fermentations take place
-with regularity, and that no foreign substance come to derange the
-operation.
-
-At this period the mania of explaining every thing had proceeded to
-such a length, that no distinction was made between dead and living
-bodies. The chemical facts which were at that time known, were applied
-without hesitation to explain all the functions and all the diseases
-of the living body. According to Willis, fever is the simple result
-of a violent and preternatural effervescence of the blood and the
-other humours of the body, either produced by external causes, or by
-internal ferments, into which the chyle is converted when it mixes
-with the blood. The effervescence of the vital spirits is the source
-of quotidians; that of salt and sulphur produces continued fever; and
-external ferments of a malignant nature produce malignant fevers. Thus
-the smallpox is owing to the seeds of fermentation set in activity by
-an external principle of contagion. Spasms and convulsions are produced
-by an explosion of the salt and sulphur with the animal spirits.
-Hypochondriacal affections and hysteria depend originally on the morbid
-putrifaction of the blood in the spleen, or on a bad fermentescible
-principle, loaded with salt and sulphur, which unites with the vital
-spirits and deranges them. Scurvy is owing to an alteration of the
-blood, which may then be compared to vapid or stale wine. The gout is
-merely the coagulation of the nutritive juices altered by the acidified
-animal spirits; just as sulphuric acid forms a coagulum with carbonate
-of potash.
-
-The action of medicines is easily explained by the effects which they
-produce on the nourishing principles. Sudorifics are considered as
-cordials, because they augment the sulphur of the blood, which is the
-true food of the vital flame. Cordials purify the animal spirits,
-and fix the too volatile blood. Willis disagrees with the other
-iatro-chemists of his time in one thing: he recommends bleeding in
-the greater number of diseases, as an excellent method of diminishing
-unnatural fermentation.
-
-Dr. Croone, a celebrated Fellow of the Royal Society, was another
-English iatro-chemist, who attempted to explain muscular motion by the
-effervescence of the nervous fluid, or animal spirits.
-
-It is not worth while to notice the host of writers--English, French,
-Italian, Dutch, and German, who exerted themselves to maintain,
-improve, and defend, the chemical doctrines of medicine. The first
-person who attempted to overturn these absurd doctrines, and to
-introduce something more satisfactory in their place, was Mr. Boyle, at
-that time in the height of his celebrity.
-
-Robert Boyle was born at Youghall, in the province of Munster, on the
-25th of January, 1627. He was the seventh son, and the fourteenth
-child of Richard, Earl of Cork. He was partly educated at home, and
-partly at Eton, where he was under the tuition of Sir Henry Wotton. At
-the age of eleven, he travelled with his brother and a French tutor
-through France to Geneva, where he pursued his studies for twenty-one
-months, and then went to Italy. During this period, he acquired the
-French and Italian languages; and, indeed, talked in the former with
-so much fluency and correctness, that he passed, when he thought
-proper, for a Frenchman. In 1642, his father’s finances were deranged,
-by the breaking out of the great Irish rebellion. His tutor, who was
-a Genevese, was obliged to borrow, on his own credit, a sum of money
-sufficient to carry him home. On his arrival, he found his father dead;
-and, though two estates had been left to him, such was the state of the
-times, that several years elapsed before he could command the requisite
-sum of money to supply his exigencies. He retired to an estate at
-Stalbridge, in Dorsetshire.
-
-In 1654 he went to Oxford, where he associated himself with a number of
-eminent men (Dr. Willis among others), who had constituted themselves
-into a combination for experimental investigations, distinguished by
-the name of the _Philosophical College_. This society was transferred
-to London; and, in 1663, was incorporated by Charles II. under the
-name of the _Royal Society_. In 1668 Mr. Boyle took up his residence
-in London, where he continued till the last day of December, 1691,
-assiduously occupied in experimental investigations, on which day he
-died, in the sixty-fifth year of his age.
-
-We are indebted to Mr. Boyle for the first introduction of the air-pump
-and the thermometer into Britain, and for contributing so much, by
-means of Dr. Hooke, to the improvement of both. His hydrostatical and
-pneumatical investigations and experiments constitute the foundation
-of these two sciences. The thermometer was first made an accurate
-instrument of investigation by Sir Isaac Newton, in 1701. This he
-did by selecting as two fixed points the temperatures at which water
-freezes and boils; marking these upon the stem of the thermometer,
-and dividing the interval between them into a certain number of
-degrees. All thermometers made in this way will stand at the same
-point when plunged into bodies of the same temperature. The number of
-divisions between the freezing and boiling points constitute the cause
-of the differences between different thermometers. In Fahrenheit’s
-thermometer, which is used in Great Britain, the number of degrees,
-between the freezing and boiling points of water, is 180; in Reaumur’s
-it is 80; in Celsius’s, or the centigrade, it is 100; and in De Lisle’s
-it is 150.
-
-But my reason for mentioning Mr. Boyle here was, the attempt which he
-made in 1661, by the publication of his Sceptical Chemist, to overturn
-the absurd opinions of the iatro-chemists. He raises doubts, not only
-respecting the existence of the elements of the Peripatetics, but even
-of those of the chemists. The first elements of bodies, in his opinion,
-are _atoms_, of different shapes and sizes; the union of which gives
-origin to what we vulgarly call _elements_. We cannot restrain the
-number of these to four, as the Peripatetics do; nor to three, with the
-chemists: neither are they immutable, but convertible into each other.
-Fire is not the means that ought to be employed to obtain them; for
-the _salt_ and _sulphur_ are formed during its action by the union of
-different simple bodies.
-
-Boyle shows, besides, that the chemical theory of qualities is
-exceedingly inaccurate and uncertain; because it takes for granted
-things which are very doubtful, and in many cases directly contrary
-to the phenomena of nature. He endeavours to prove the truth of these
-ideas, and particularly the production of the chemical principles, by a
-great number of convincing and conclusive experiments.
-
-In another treatise, entitled “The Imperfections of the Chemical
-Doctrine of Qualities,”[169] he points out, in the second section, the
-insufficiency of the hypotheses of Sylvius relative to the generality
-of acids and alkalies. He shows that the offices ascribed to them
-are arbitrary, and the notions respecting them unsettled; that the
-hypotheses respecting them are needless, and insufficient, and afford
-but an unsatisfactory solution of the phenomena.
-
-[169] Shaw’s Boyle, iii, 424.
-
-These arguments of Boyle did not immediately shake the credit of the
-chemical system. In the year 1691, a chemical academy was founded
-at Paris by Nicolas de Blegny, the express object of which was to
-examine these objections of Boyle, which by this time had attracted
-great attention. Boyle’s experiments were repeated and confirmed; but
-the academicians, notwithstanding, came to the conclusion, that it is
-unnecessary to have recourse to the true elements of bodies; and that
-the phenomena which occur in the animal economy may be explained by the
-predominance of acids or alkalies. Various other publications appeared,
-all on the same side.
-
-In Germany, Hermann Conringius, the most skilful physician of his time,
-opposed the chemical theory; and his opinions were impugned by Olaus
-Borrichius, who defended not only alchymy, but the chemical theory of
-medicine, with equal erudition and zeal.[170]
-
-[170] De Ortu et Progressu Chemiæ. _Hafniæ_, 1674.
-
-Towards the end of the sixteenth century, the chemists thought of
-examining the liquids of the living body, to ascertain whether they
-really contained the acids and alkalies which had been assigned them,
-and considered as the cause of all diseases. But at that time chemistry
-had made so little progress, and such was the want of skill of those
-who undertook these investigations, that they readily obtained every
-thing that was wanted to confirm their previous notions. John Viridet,
-a physician of Geneva, announced that he had found an acid in the
-saliva and the pancreatic juice, and an alkali in the gastric juice
-and the bile. But the most celebrated experiments of that period were
-those of Raimond Vieussens, undertaken in 1698, in order to discover
-the presence of an acid spirit in the blood. His method was, to mix
-blood with a species of clay, called _bole_, and to subject the mixture
-to distillation. He found that the liquid distilled over was acid.
-Charmed with this discovery, which he considered as of first-rate
-importance, he announced it by letter to the different academies and
-colleges in Europe. Some doubts being raised about the accuracy of
-his experiment, it having been alleged that the acid came from the
-clay which he had mixed with the blood, and not from the blood itself,
-Vieussens purified the _bole_ from all the acid which it could contain,
-and repeated his experiment again. The result was the same--the acrid
-salt of the fluid yielded an acid spirit.
-
-It would be needless in the present state of our knowledge to point
-out the inaccuracy of such an experiment, or how little it contributed
-to prove that blood contains a free acid. It is now well known to
-chemists, that blood is remarkably free from acids; and, that if we
-except a little common salt, which exists in all the liquids of the
-human body, there is neither any acid nor salt whatever in that liquid.
-
-Michael Ettmuller, at Leipsic, who was a chemist of some eminence in
-his day, and published a small treatise on the science, which was much
-sought after, was also a zealous iatro-chemist; but his opinions were
-obviously regulated by the researches of Boyle. He denies the existence
-of acids and alkalies in certain bodies, and distinguishes carefully
-between acid and putrid fermentation.
-
-One of the most formidable antagonists to the iatro-chemical doctrines
-was Dr. Archibald Pitcairne, first a professor of medicine in the
-University of Leyden, and afterwards of Edinburgh, and one of the most
-eminent physicians of his time. He was born in Edinburgh, on the 25th
-of December, 1652. After finishing his school education in Dalkeith,
-he went to the University of Edinburgh, where he improved himself in
-classical learning, and completed a regular course of philosophy. He
-turned his attention to the law, and prosecuted his studies with so
-much ardour and intensity that his health began to suffer. He was
-advised to travel, and set out accordingly for the South of France: by
-the time he reached Paris he was so far recovered that he determined
-to renew his studies; but as there was no eminent professor of law in
-that city, and as several gentlemen of his acquaintance were engaged in
-the study of medicine, he went with them to the lectures and hospitals,
-and employed himself in this way for several months, till his affairs
-called him home.
-
-On his return he applied himself chiefly to mathematics, in which,
-under the auspices of his friend, the celebrated Dr. David Gregory, he
-made uncommon progress. Struck with the charms of this science, and
-hoping by the application of it to medicine to reduce the healing art
-under the rigid rules of mathematical demonstration, he formed the
-resolution of devoting himself to the study of medicine. There was at
-that time no medical school in Edinburgh, and no hospital at which he
-could improve himself; he therefore repaired to Paris, and devoted
-himself to his studies with a degree of ardour that ensured an almost
-unparalleled success. In 1680 he received from the faculty of Rheims
-the degree of doctor of medicine, a degree also conferred on him in
-1699 by the University of Aberdeen.
-
-In the year 1691 his reputation was so high that the University of
-Leyden solicited him to fill the medical chair, at that time vacant;
-he accepted the invitation, and delivered a course of lectures at
-Leyden, which was greatly admired by all his auditors, among whom
-were Boerhaave and Mead. At the close of the session he set out for
-Scotland, to marry the daughter of Sir Archibald Stevenson: his friends
-in his own country would not consent to part with him, and thus he was
-reluctantly obliged to resign his chair in the University of Leyden.
-
-He settled as a physician in Edinburgh, where he was appointed titular
-professor of medicine. His practice extended beyond example, and he was
-more consulted by foreigners than any Edinburgh physician either before
-or after his time. He died in October, 1713, admired and regretted by
-the whole country. He was a zealous supporter of iatro-mathematics, and
-as such a professed antagonist of the iatro-chemists. He refuted their
-opinions with much strength of reasoning, while his high reputation
-gave his opinions an uncommon effect; so that he contributed perhaps as
-much as any one, to put a period to the most disgraceful, as well as
-dangerous, set of opinions that ever overspread the medical horizon.
-
-Into the merits of the iatro-mathematicians it is not the business of
-this work to enter; they at least display science, and labour, and
-erudition, and in all these respects are far before the iatro-chemists.
-Perhaps their own opinions were not more agreeable to the real
-structure of the human body, nor their practice more conformable to
-reason, or more successful than those of the chemists. Probably the
-most valuable of all Dr. Pitcairne’s writings, is his vindication of
-the claims of Hervey to the great discovery of the circulation.
-
-Boerhaave, the pupil of Pitcairne, and afterwards a professor
-in Leyden, was a no less zealous or successful opponent of the
-iatro-chemists.
-
-Herman Boerhaave, perhaps the most celebrated physician that ever
-existed, if we except Hippocrates, was born at Voorhout, a village near
-Leyden, in 1668, where his father was the parish clergyman. At the age
-of sixteen he was left without parents, protection, advice, or fortune.
-He had already studied theology, and the other branches of knowledge
-that are considered as requisite for a clergyman, to which situation he
-aspired; and while occupied with these studies he supported himself at
-Leyden by teaching mathematics to the students--a branch of knowledge
-to which he had devoted himself with considerable ardour while living
-in his father’s house. But, a report being raised that he was attached
-to the doctrines of Spinoza, the clamour against him was so loud
-that he thought it requisite to renounce his intention of going into
-_orders_.[171] He turned his studies to medicine, and the branches of
-science connected with that pursuit, and these delightful subjects soon
-engrossed the whole of his attention. In 1693 he was created doctor of
-medicine, and began to practise. He continued to teach mathematics for
-some time, till his practice increased sufficiently to enable him to
-live by his fees. His spare money was chiefly laid out upon books; he
-also erected a chemical laboratory, and though he had no garden he paid
-great attention to the study of plants. His reputation increased with
-considerable rapidity; but his fortune rather slowly. He was invited to
-the Hague by a nobleman, who stood high in the favour of William III.,
-King of Great Britain; but he declined the invitation. His three great
-friends, to whom he was in some measure indebted for his success, were
-James Trigland, professor of theology, Daniel Alphen, and John Van den
-Berg, both of them successively chief magistrates of Leyden, and men of
-great influence.
-
-[171] While travelling in a tract-boat, one of his fellow-travellers
-more orthodox than well informed, attacked the system of Spinoza with
-so little spirit, that Boerhaave was tempted to ask him if he had ever
-read Spinoza. The polemic was obliged to confess that he had not; but
-he was so much provoked at this public exposure of his ignorance, that
-he propagated the report of Boerhaave’s attachment to Spinozism, and
-thus blasted his intention of becoming a clergyman.
-
-Van den Berg recommended him to the situation of professor of medicine
-in the University of Leyden, to which chair he was raised, fortunately
-for the reputation of the university, on the death of Drelincourt,
-in 1702. He not only gave public lectures on medicine, but was in
-the habit also of giving private instructions to his pupils. His
-success as a teacher was so great, that a report having been spread
-of his intention to quit Leyden, the curators of the university added
-considerably to his salary on condition that he would not leave them.
-
-This first step towards fortune and eminence having been made, others
-followed with great rapidity. He was appointed successively professor
-of botany and of chemistry, while rectorships and deanships were
-showered upon him with an unsparing hand. And such was the activity,
-the zeal, and the ability with which he filled all these chairs,
-that he raised the University of Leyden to the very highest rank of
-all the universities of Europe. Students flocked to him from all
-quarters--every country of Europe furnished him with pupils; Leyden
-was filled and enriched by an unusual crowd of strangers. Though his
-class-rooms were large, yet so great was the number of students, that
-it was customary for them to keep places, just as is done in a theatre
-when a first-rate actor is expected to perform. He died in the year
-1738, while still filling the three different chairs with undiminished
-reputation.
-
-It is not our object here to speak of Boerhaave as a physician, or as a
-teacher of medicine, or of botany; though in all these capacities he is
-entitled to the very highest eulogium; his practice was as unexampled
-as his success as a teacher. It is solely as a chemist that he claims
-our attention here. His system of chemistry, published in two quarto
-volumes in 1732, and of which we have an excellent English translation
-by Dr. Shaw, printed in 1741, was undoubtedly the most learned and
-most luminous treatise on chemistry that the world had yet seen; it
-is nothing less than a complete collection of all the chemical facts
-and processes which were known in Boerhaave’s time, collected from
-a thousand different sources, and from writings equally disgusting
-from their obscurity and their mysticism. Every thing is stated in
-the plainest way, stripped of all mystery, and chemistry is shown as
-a science and an art of the first importance, not merely to medicine,
-but to mankind in general. The processes given by him are too numerous
-and too tedious to have been all repeated by one man, how laborious
-soever he may have been: many of them have been taken upon trust, and,
-as no distinction is made in the book, between those which are stated
-upon his own authority and those which are merely copied from others,
-this treatise has been accused, and with some justice, as not always
-to be depended on. But the real information which it communicates is
-prodigious, and when we compare it with any other system of chemistry
-that preceded it, the superiority of Boerhaave’s information will
-appear in a very conspicuous point of view.
-
-After a short but valuable historical introduction he divides his work
-into two parts; the first treats of the _theory of chemistry_, the
-second of the _practical processes_.
-
-He defines chemistry as follows: “Chemistry is an art which teaches
-the manner of performing certain physical operations, whereby bodies
-cognizable to the senses, or capable of being rendered cognizable,
-and of being contained in vessels, are so changed by means of proper
-instruments, as to produce certain determinate effects; and at the same
-time discover the causes thereof; for the service of various arts.”
-
-This definition is not calculated to throw much light on chemistry to
-those who are unacquainted with its nature and object. Neither is it
-conformable to the modern notions entertained of chemistry; but it is
-requisite to keep in mind Boerhaave’s definition of chemistry, when
-we examine his system, that we may not accuse him of omissions and
-imperfections, which are owing merely to the state of the science when
-he gave his system to the world.
-
-In his theory of chemistry he begins with the metals, which he treats
-of in the following order: Gold, mercury, lead, silver, copper, iron,
-tin. The account of them, though imperfect, is much fuller and more
-satisfactory than any that preceded it. He then treats of the salts,
-which are, common salt, saltpetre, borax, sal ammoniac and alum. This
-it will be admitted is but a meagre list. However other salts occur in
-different parts of the book which are not described here. He next gives
-an account of sulphur. Here he introduces _white arsenic_, obtained,
-he says, from cobalt, and not known for more than two hundred years.
-He considers it as a real sulphur, and takes no notice of metallic
-arsenic, though it had been already alluded to by Paracelsus. He then
-treats of bitumens, including under the name not merely bitumens liquid
-and solid, but likewise pit-coal, amber, and ambergris. An account
-of stones and earths comes next, and constitutes the most defective
-part of the book. It is very surprising that in this part of his work
-he takes no notice of _lime_. The semi-metals come next: they are,
-antimony, bismuth, zinc. Here he gives an account of the three vitriols
-or sulphates of iron, copper, and zinc. He knew the composition of
-sulphate of iron; but was ignorant of that of sulphate of copper and
-sulphate of zinc. He considers semi-metals as compounds of a true metal
-and sulphur, and therefore enumerates cinnabar among the semi-metals.
-Lastly he treats of vegetables and animals; and it is needless to say
-that his account is very imperfect.
-
-He next treats of the utility of chemistry, and shows its importance
-in natural philosophy, medicine, and the arts. Afterwards he describes
-the instruments of chemistry. This constitutes the longest and the most
-important part of the whole work. He first treats of fire at great
-length. Here we have an account of the thermometer, of the expansion
-produced by heat, of steam, and in fact the germ of many of the most
-important parts of the science of heat, which have since been expanded
-and applied to the improvement, not merely of chemistry, but of the
-arts and resources of human industry. The experiments of Fahrenheit
-related by him, on the change of temperature induced by agitating water
-and mercury together at different degrees of heat, gave origin to the
-whole doctrine of specific heats. Though Boerhaave himself seemed not
-aware of the importance of these experiments, or indeed even to have
-considered them with any attention. But when afterwards analyzed by Dr.
-Black, these experiments gave origin to one of the most important parts
-of the whole science of heat.
-
-He next treats at great length on _fuel_. Here his opinions are often
-very erroneous, from his ignorance of a vast number of facts which
-have since come to light. It is curious that during the whole of his
-very long account of combustion he makes no allusion to the peculiar
-opinions of Stahl on the subject; though they were known to the public,
-and had been admitted by chemists in general, before his work was
-published. To what are we to ascribe this omission? It could scarcely
-have been owing to ignorance, Stahl’s reputation being too high to
-allow his opinions to be treated with neglect. We must suppose, I
-think, that Boerhaave did not adopt Stahl’s doctrine of combustion; but
-at the same time did not think it proper to enter into any controversy
-on the subject.
-
-He next treats of the heat produced when different liquids are mixed,
-as alcohol and water, &c. He gives many examples of such increase
-of temperature, and describes the phenomena very correctly. But he
-was unable to assign the cause of the evolution of this heat. The
-subject was elucidated many years after by Dr. Irvine, who showed that
-it was owing to a diminution of the specific heat which takes place
-when liquids combine chemically together. It is in this part of his
-work that he gives an account of phosphorus, of the action of nitric
-acid on volatile oils, and he concludes, from all the facts which he
-states, that elementary fire is a corporeal body. His explanation
-of the combustion of Homberg’s pyrophorus and of common phosphorus,
-shows clearly that he had no correct notion of the reason why air is
-necessary to maintain combustion, nor of the way in which that elastic
-fluid performs its part in the great phenomena of nature.
-
-He next treats of the mode of regulating fire for chemical purposes:
-then he treats of _air_, his account being chiefly taken from Boyle.
-He ascribes the discovery of the law of the elasticity of air both
-to Boyle and Mariotte. Boyle, I believe, was the first discoverer of
-it. The French are in the habit of calling it the law of Mariotte.
-He then treats of _water_, and lastly of _earth_; but even here no
-mention whatever is made of lime. In the last part of the theory of
-chemistry he treats at great length of menstruums. These are water,
-oils, alcohol, alkalies, acids, and neutral salts. He mentions potash
-and ammonia, but takes no notice of soda; the difference between potash
-and soda not being accurately known. Nor can we expect any particular
-account of the difference between the properties of mild and caustic
-potash; as this subject was not understood till the time of Dr. Black.
-The only acids which he mentions are the _acetic_, _sulphuric_,
-_nitric_, _muriatic_, and _aqua regia_. He subjoins a disquisition on
-the alcahest or universal solvent, which it is obvious enough, however,
-from the way in which he speaks of it, that he was not a believer in.
-The object of his practical part is to teach the method of making all
-the different chemical substances known when he wrote. This he does in
-two hundred and twenty-seven processes, in which all the manipulations
-are described with considerable minuteness. This part of the work must
-have been long considered as of great utility, and must have been long
-resorted to by the student as a mine of practical information upon
-almost every subject that could arrest his attention. So immense is
-the progress that chemistry has made since the days of Boerhaave, and
-so different are the researches that at present occupy chemists, and
-so much greater the degree of precision requisite to be attained, that
-his processes and directions are now of little or no use to a practical
-student of chemistry, as they convey little or none of the knowledge
-which it is requisite for him to possess.
-
-Boerhaave made a set of most elaborate experiments, to refute the ideas
-of the alchymists respecting the possibility of fixing mercury. He
-put a quantity of pure mercury into a glass vessel, and kept it for
-fifteen years at a temperature rather higher than 100°. It underwent no
-alteration whatever, excepting that a small portion of it was converted
-into a black powder. But this black powder was restored to the state of
-running mercury by trituration in a mortar. In this experiment the air
-had free access to the mercury. It was repeated in a close vessel with
-the same result, excepting that the mercury was kept hot for only six
-months instead of fifteen years.
-
-To show that mercury cannot be obtained from metals by the processes
-recommended by the alchymists, he dissolved pure nitrate of lead in
-water, and, mixing the solution with sal ammoniac, chloride of lead
-precipitated. Of this chloride he put a quantity into a retort, and
-poured over it a strong lixivium of caustic potash, The whole was
-digested at the temperature of 96° for six months and six days. It was
-then distilled in a glass retort, by a temperature gradually raised to
-redness, but not a particle of mercury was evaporated, as it had been
-alleged by the alchymists would be the case.
-
-Isaac Hollandus had stated that mercury could be easily obtained from
-the salt of lead made by means of distilled vinegar. To prove this he
-calcined a quantity of acetate of lead, ground the residue to powder,
-and triturated it with a very strong alkaline lixivium, and kept the
-lixivium over it covered with paper for months, taking care to add
-water in proportion as it evaporated. The calx was then distilled in
-a heat gradually raised to redness; but not a particle of mercury was
-obtained.[172]
-
-[172] Mem. Paris, 1734, p. 539.
-
-These were not the only laborious experiments which he made with this
-metal. He distilled it above five hundred times, and found that it
-underwent no alteration. When long agitated in a glass bottle it is
-convertible into a black acrid powder, obviously protoxide of mercury.
-This black powder, when distilled, is converted into running mercury.
-Exposure of mercury for some months in a heat of 180°, converts it also
-into protoxide; and if the heat be higher than this, the mercury is
-converted into a red acrid substance, obviously peroxide of mercury.
-But this peroxide, by simple distillation, is again reduced into the
-state of running mercury.[173]
-
-[173] Phil. Trans. 1733. No. 430, p. 145.
-
-Boerhaave combated the opinions of the iatro-chemists with great
-eloquence, and with a weight derived from his high reputation, and
-the extraordinary veneration in which his opinions were held by his
-disciples. His efforts were assisted by those of Bohn, who combated
-the medical opinions by arguments drawn both from experience and
-observation, and perfectly irresistible; and the ruin of the chemical
-sect was consummated by the exertions of the celebrated Frederick
-Hoffmann, the founder of the most perfect and satisfactory system of
-medicine that has ever appeared. His efforts were probably roused into
-action by a visit which he paid to England in 1683, during which he
-got acquainted with Boyle and with Sydenham; the former the greatest
-experimentalist, and the latter the greatest physician of the time; and
-both of whom were declared enemies to iatro-chemistry.
-
-
-
-
-CHAPTER VI.
-
-OF AGRICOLA AND METALLURGY.
-
-
-I have been induced by a wish to prosecute the history of the opinions
-first supported by Paracelsus, and carried so much further by Van
-Helmont and Sylvius, to give a connected view of their effects
-upon medical practice and medical theory; and I have come to the
-commencement of the eighteenth century, without taking notice of one
-of the most extraordinary men, and one of the greatest promoters of
-chemistry that ever existed: I mean George Agricola. I shall consecrate
-the whole of this chapter to his labours, and those of his immediate
-successors.
-
-George Agricola was born at Glaucha, in Misnia, in the year 1494.
-When a young man he acquired such a passion for mining and minerals,
-by frequenting the mountains of Bohemia, that he could not be
-persuaded to relinquish the study. He settled, indeed, as a physician,
-at Joachimstal; but his favourite study engrossed so much of his
-attention, that he succeeded but ill in his medical capacity. This
-induced him to withdraw to Chemnitz, where he devoted himself to his
-favourite pursuits. He studied the mineralogical writings of the
-ancients with the most minute accuracy; but not satisfied with this, he
-visited the mines in person, examined the processes followed by the
-miners in extracting the different ores, and in washing and sorting
-them. He made collections of all the different ores, and studied their
-nature and properties attentively: he likewise collected information
-about the methods of smelting them, and extracting from them the metals
-in a state of purity. The information which he collected, respecting
-the mines wrought in the different countries of Europe, is quite
-wonderful, if we consider the period in which he lived, the little
-intercourse which existed between nations, and the total want of all
-those newspapers and journals which now carry every new scientific fact
-with such rapidity to every part of the world.
-
-Agricola died at Chemnitz in the year 1555, after he had reached
-the sixty-first year of his age. Maurice, the celebrated Elector of
-Saxony, settled on him a pension, the whole of which he devoted to
-his metallurgic pursuits. To him we find him dedicating the edition
-of his works which he published in the year of his death, and which
-is dated the fourteenth before the calends of April, 1555. He even
-spent a considerable proportion of his own estate in following out
-his favourite investigations. In the earlier part of his life he had
-expressed himself rather favourable to the protestant opinions; but in
-his latter days he had attacked the reformed religion. This rendered
-him so odious to the Lutherans, at that time predominant in Chemnitz,
-that they suffered his body to remain unburied for five days together;
-so that it was necessary to remove it from Chemnitz to Zeitz, where it
-was interred in the principal church.
-
-His great work is his treatise De Re Metallica, in twelve books. In
-this work he gives an account of the instruments and machines, and
-every thing connected with mining and metallurgy; and even gives
-figures of all the different pieces of apparatus employed in his
-time. He has also exhibited the Latin and German names for all these
-different utensils. This work may be considered as a very complete
-treatise on metallurgy, as it existed in the sixteenth century. The
-first six books are occupied with an account of mining and smelting. In
-the seventh book he treats of _docimasy_, or the method of determining
-the quantity of metal which can be extracted from every particular
-ore. This he does so completely, that most of his processes are still
-followed by miners and smelters. He gives a minute and accurate account
-of the furnaces, muffles, crucibles, &c., almost such as are still
-employed, with minute directions for preparing the ores which are
-to be subjected to examination, the fluxes with which they must be
-mixed, and the precautions necessary in order to obtain a satisfactory
-result. In short, this book may be considered as a complete manual of
-docimasy. How much of the methods given originated with Agricola it
-is impossible to say. He probably did little more than collect the
-scattered processes employed by the smelters of metals, in different
-parts of the world, and reduce the whole to a regular system. But this
-was a great deal. Perhaps it is not saying too much, that the great
-progress made in the chemical investigation of the metals, was owing in
-a great measure to the labours of Agricola. Certainly the progress made
-by the moderns, in the difficult arts of mining and metallurgy, must in
-a great measure be ascribed to the labours of Agricola.
-
-In the eighth book he describes the mechanical preparation of the ores,
-and the mode of roasting them, either in the open air or in furnaces.
-The ninth book is occupied with an account of smelting-furnaces. It
-contains also a description of the processes for obtaining mercury,
-antimony, and bismuth, from their ores. The tenth book treats of the
-separation of silver and gold from each other, by means of nitric acid
-and aqua regia: minute directions for the preparation of which are
-given. The modes of purifying the precious metals by means of sulphur,
-antimony, and cementations, are also described. In the eleventh book
-he treats of the method of purifying silver from copper and iron, by
-means of lead. He gives an account also of the processes employed for
-smelting and purifying copper. In the twelfth book he treats of the
-methods of preparing common salt, saltpetre, alum, and green vitriol,
-or sulphate of iron: of the preparation and purification of sulphur,
-and of the mode of manufacturing glass. In short, Agricola’s work De Re
-Metallica is beyond comparison the most valuable chemical work which
-the sixteenth century produced, and places the author very high indeed
-among the list of the improvers of chemistry.
-
-The other works of Agricola are his treatise De Natura Fossilium,
-in ten books; De Ortu et Causis Subterraneorum, in five books; De
-Natura eorum quæ effluunt ex Terra, in four books; De veteribus et
-novis Metallis, in two books; and his Bermannus sive de re metallica
-Dialogus. The treatise De veteribus et novis Metallis is amusing.
-He not only collects together all the historical facts on record,
-respecting the first discoverers of the different metals and the
-first workers of mines, but he gives many amusing anecdotes nowhere
-else to be found, respecting the way in which some of the most
-celebrated German mines were discovered. In the second book he takes
-a geographical view of every part of the known world, and states
-the mines wrought and the metals found in each. We must not suppose
-that all his statements in this historical sketch are accurate: to
-admit it would be to allow him a greater share of information than
-could possibly belong to any one man. He frequently gives us the
-authority upon which his statements are founded; but he often makes
-statements without any authority whatever. Thus he says, that a mine of
-quicksilver had been recently discovered in Scotland: the fact however,
-is, that no quicksilver-mine ever existed in any part of Britain. There
-was, indeed, a foolish story circulated about thirty years ago, about
-a vein of quicksilver found under the town of Berwick-upon-Tweed; but
-it was an assertion unsupported by any authentic evidence.
-
-Many years elapsed before much addition was made to the processes
-described by Agricola. In the year 1566, Pedro Fernandes de Velasco
-introduced a method of extracting gold and silver from their ores
-in Mexico and Peru by means of quicksilver. But I have never seen
-a description of his process. Alonzo Barba claims for himself, and
-seemingly with justice, the method of amalgamating the ores of gold
-and silver by boiling. Barba was a Spanish priest, who lived about the
-year 1609, at Tarabuco, a market-town in the province of Charcso, eight
-miles from Plata, in South America. In the year 1615 he was curate at
-Tiaguacano, in the Province of Pacayes, and in 1617, he lived at Lepas
-in Peru. He is said to have been a native of Lepe, a small township
-in Andalusia, and had for many years the living of the church of St.
-Bernard at Potosi. His work on the amalgamation of gold and silver
-ores appeared at Madrid in the year 1640, in quarto.[174] In the year
-1629 a new edition of it appeared with an appendix, under the title of
-“Trattado de las Antiquas Minas de España de Alonzo Carillo Lasso.”
-The English minister at the Court of Madrid, the Earl of Sandwich,
-published the first part of it in an English translation at London,
-in 1674, under the title of “The First Book of the Art of Metals, in
-which is declared the manner of their generation, and the concomitants
-of them, written in Spanish by Albaro Alonzo Barba. By E. Earl of
-Sandwich.”
-
-[174] It is entitled, “El Arte de los Metales, en que se ensena el
-verdadero beneficio de los de oro y plata por azoque,” &c.
-
-The next improver of metallurgic processes was Lazarus Erckern,
-who was upper bar-master at Kuttenberg, in the year 1588, and was
-superintendent of the mines in Germany, Hungary, Transylvania, the
-Tyrol, &c., to three successive emperors. His work has been translated
-into English under the title of “Heta Minor; or the laws of art and
-nature in knowing, judging, assaying, fining, refining, and enlarging
-the bodies of confined metals. To which are added essays on metallic
-words, illustrated with sculptures. By Sir J. Pettus. London, 1683,
-folio.” But this translation is a very bad one. Erckern gives a plain
-account of all the processes employed in his time without a word of
-theory or reasoning. It is an excellent practical book; though it is
-obvious enough that the author was inferior in point of abilities to
-Agricola. His treatment of Don Juan de Corduba, who offered, in 1588,
-to put the Court of Vienna in possession of the Spanish method of
-extracting gold and silver from the ores by amalgamation, as related by
-Baron Born in his work on amalgamation, shows very clearly that Erckern
-was a very illiberal-minded man, and puffed up with an undue conceit
-of his own superior knowledge.[175] Had he condescended to assist the
-Spaniard, and to furnish him with proper materials to work upon, the
-Austrians might have been in possession of the process of amalgamation
-with all its advantages a couple of centuries before its actual
-introduction.
-
-[175] Born’s New Process of Amalgamation, translated by Raspe, p. 11.
-
-I need not take any notice of the docimastic treatises of Schindlers
-and Schlutter, which are of a much later date, and both of which have
-been translated into French, the former by Geoffroy, junior; the latter
-by Hellot. This last translation, in two large quartos, published in
-1764, constitutes a very valuable book, and exhibits all the docimastic
-and metallurgic processes known at that period with much fidelity
-and minuteness. Very great improvements have taken place since that
-period, but I am not aware of any work published in any of the European
-languages, that is calculated to give us an exact idea of the present
-state of the various mining and metallurgic processes--important as
-they are to civilized society.
-
-Gellert’s Metallurgic Chemistry, so far as it goes, is an excellent
-book.
-
-
-
-
-CHAPTER VII.
-
-OF GLAUBER, LEMERY, AND SOME OTHER CHEMISTS OF THE END OF THE
-SEVENTEENTH CENTURY.
-
-
-Hitherto I have treated of the alchymists, or iatro-chemists, and
-have brought the history of chemistry down to the beginning of the
-eighteenth century. But during the seventeenth century there existed
-several laborious chemists, who contributed very materially by their
-exertions, either to extend the bounds of the science, or to increase
-its popularity and respectability in the eyes of the world. Of some of
-the most eminent of these it is my intention to give an account in this
-chapter.
-
-Of John Rudolf Glauber, the first of these meritorious men in point of
-time, I know very few particulars. He was a German and a medical man,
-and spent most of his time at Salzburg, Ritzingen, Frankfort on the
-Maine, and at Cologne. Towards the end of his life he went to Holland,
-but during the greatest part of his residence in that country he was
-confined to a sick-bed. He died at Amsterdam in 1668, after having
-reached a very advanced age. Like Paracelsus, whom he held in high
-estimation, he was in open hostility with the Galenical physicians of
-his time. This led him into various controversies, and induced him
-to publish various apologies; most of which still remain among his
-writings. One of the most curious of these apologies is the one against
-Farmer. To this man Glauber had communicated certain secrets of his
-own, which were at that time considered as of great value; Farrner
-binding himself not to communicate them to any person. This obligation
-he not only broke, but publicly deprecated the skill and integrity of
-Glauber, and offered to communicate to others, for stipulated sums,
-a set of secrets of his own, which he vaunted of as particularly
-valuable. Glauber examines these secrets, and shows that every one
-of them possessed of any value, had been communicated by himself to
-Farrner, and to put an end to Farrner’s unfair attempt to make money by
-selling Glauber’s secrets, he in this apology communicates the whole
-processes to the public.
-
-Glauber’s works were published in Amsterdam, partly in Latin, and
-partly in the German language. In the year 1689 an English translation
-of them was published in London by Mr. Christopher Packe, in one
-large folio volume. Glauber was an alchymist and a believer in the
-universal medicine. But he did not confine his researches to these
-two particulars, but endeavoured to improve medicine and the arts by
-the application of chemical processes to them. In his treatise of
-_philosophical furnaces_ he does not confine himself to a description
-of the method of constructing furnaces, and explaining the use of
-them, but gives an account of a vast many processes, and medicinal and
-chemical preparations, which he made by means of these furnaces. One of
-the most important of these preparations was muriatic acid, which he
-obtained by distilling a mixture of common salt, sulphate of iron, and
-alum, in one of the furnaces which he describes.
-
-He makes known the method of dissolving most of the metals in muriatic
-acid, and the resulting chlorides, which he denominates oils of the
-respective metals, constitute in his opinion valuable medicines. He
-mentions particularly the chloride of gold, and from the mode of
-preparing it, the solution must have been strong. Yet he recommends it
-as an internal medicine, which he says may be taken with safety, and
-is a sovereign remedy in old ulcers of the mouth, tongue, and throat,
-arising from the French pox, leprosy, scorbute, &c. Thus we see the use
-of gold as a remedy for the venereal disease did not originate with M.
-Chretiens, of Montpelier. This chloride of gold is so violent a poison
-that it is remarkable that Glauber does not specify the dose that
-patients labouring under the diseases for which he recommends it ought
-to take.--The sesqui-chloride of iron he recommends as a most excellent
-application to ill-conditioned ulcers and cancers. We see from this
-that the use of iron in cancers, lately recommended, is not so new a
-remedy as has been supposed.
-
-He mentions the violent action of chloride of mercury (obviously
-corrosive sublimate), and says that he saw a woman suddenly killed by
-it, being administered internally by a surgeon. Butter of antimony
-he first recognised as nothing else than a combination of chlorine
-and antimony; before his time it had been always supposed to contain
-mercury.
-
-He describes the method of obtaining sulphuric acid by distilling
-sulphate of iron; gives an account of the mode of obtaining sulphate
-of iron and sulphate of copper, in crystals: the method of obtaining
-nitric acid from nitre by means of alum, was much improved by him. He
-gives a particular detail of the way of obtaining fulminating gold.
-This fulminating gold he says is of little use in medicine; but he
-gives a method of preparing from it a red tincture of gold, which he
-considers as one of the most useful and efficacious of all medicines:
-this tincture is nothing else than chloride of gold. It would take up
-too much space to attempt an analysis of all the curious facts and
-preparations described in this treatise on philosophical furnaces;
-but it will repay the perusal of any person who will take the trouble
-to look into it. All the different pharmacopœias of the seventeenth
-century borrowed from it largely. The third part of this treatise
-is peculiarly interesting. It will be seen that Glauber had already
-thought of the peculiar efficacy of applying solutions of sulphur,
-&c. to the skin, and had anticipated the various vapour and gaseous
-baths which have been introduced in Vienna and other places, during
-the course of the present century, and considered as new, and as
-constituting an important era in the healing art. In the fourth part
-he not only treats of the docimastic processes, so well described by
-Agricola and Erckern, but gives us the method of making glass, and
-of imitating the precious stones by means of coloured glasses. The
-fifth part is peculiarly valuable; in it he treats of the methods of
-preparing lutes for glass vessels, of the construction and qualities of
-crucibles, and of the vitrification of earthen vessels.
-
-Another of his tracts is called “The Mineral Work;” the object of which
-is to show the method of separating gold from flints, sand, clay,
-and other minerals, by the spirit of salt (_muriatic acid_), which
-otherwise cannot be purged; also a panacea, or universal antimonial
-medicine. This panacea was a solution of deutoxide of antimony in
-pyrotartaric acid; Glauber gives a most flattering account of its
-efficacy in removing the most virulent diseases, particularly all kinds
-of cutaneous eruptions. The second and third parts of The Mineral Work
-are entirely alchymistical. In the treatise called “Miraculum Mundi,”
-his chief object is to write a panegyric on _sulphate of soda_, of
-which he was the discoverer, and to which he gave the name of _sal
-mirabile_. The high terms in which he speaks of this innocent salt
-are highly amusing, and serve well to show the spirit of the age,
-and the dreams which still continued to haunt the most laborious and
-sober-minded chemists. The _sal mirabile_ was not merely a purgative,
-a virtue which it certainly possesses in a high degree, being as mild
-a purgative, perhaps the very best, of all the saline preparations
-yet tried; but it was a universal medicine, a panacea, a cure for all
-diseases: nor was Glauber contented with this, but pointed out many
-uses in the various arts and manufactures for which in his opinion
-it was admirably fitted. But by far the fullest account of this _sal
-mirabile_ is given by him in his treatise on the nature of salts.
-
-I shall satisfy myself with giving the titles of his other tracts.
-Every one of them contains facts of considerable importance, not to be
-found in any chemical writings that preceded him; but to attempt to
-connect these facts into one point of view would be needless, because
-they are not such as would be likely to interest the general reader.
-
-1. The Consolation of Navigators. This gives an account of a method by
-which sailors may carry with them a great deal of nourishment in very
-small bulk. The method consists in evaporating the wort of malt to
-dryness, and carrying the dry extract to sea. This method has been had
-recourse to in modern times, and has been found to furnish an effectual
-remedy against the scurvy. He recommends also the use of muriatic acid
-as a remedy for thirst, and a cure for the scurvy.
-
-2. A true and perfect Description of the extracting good Tartar from
-the Lees of Wine.
-
-3. The first part of the Prosperity of Germany; in which is treated of
-the concentration of wine, corn, and wood, and the more profitable use
-of them than has hitherto been.
-
-4. The second part of the Prosperity of Germany; wherein is shown by
-what means minerals may be concentrated by nitre, and turned into
-metallic and better bodies.
-
-5. The third part of the Prosperity of Germany; in which is delivered
-the way of most easily and plentifully extracting saltpetre out of
-various subjects, every where obvious and at hand. Together with a
-succinct explanation of Paracelsus’s prophecy; that is to say, in what
-manner it is to be understood the northern lion will institute or plant
-his political or civil monarchy; and that Paracelsus himself will not
-abide in his grave; and that a vast quantity of riches will offer
-itself. Likewise who the artist Elias is, of whose coming in the last
-days, and his disclosing abundance of secrets, Paracelsus and others
-have predicted.
-
-6. The fourth part of the Prosperity of Germany; in which are revealed
-many excellent, useful secrets, and such as are serviceable to the
-country; and withal several preparations of efficacious cates extracted
-out of the metals and appointed to physical uses; as also various
-confections of golden potions. To which is also adjoined a small
-treatise which maketh mention of my laboratory; in which there shall be
-taught and demonstrated (for the public good and benefit of mankind)
-wonderful secrets, and unto every body most profitable but hitherto
-unknown.
-
-7. The fifth part of the Prosperity of Germany; clearly and solidly
-demonstrating and as it were showing with the fingers, what alchymy is,
-and what benefit may, by the help thereof, be gotten every where and in
-most places of Germany. Written and published to the honour of God, the
-giver of all good things, primarily; and to the honour of all the great
-ones of the country; and for the health, profit, and assistance against
-foreign invasions, of all their inhabitants that are by due right and
-obedience subject unto them.
-
-8. The sixth and last part of the Prosperity of Germany; in which the
-arcanas already revealed in the fifth part, are not only illustrated
-and with a clear elucidation, but also such are manifested as are most
-highly necessary to be known for the defence of the country against
-the Turks. Together with an evident demonstration adjoined, showing,
-that both a particular and universal transmutation of the imperfect
-metals into more perfect ones by salt and fire, is most true; and
-withal, by what means any one, that is endued with but a mean knowledge
-in managing the fire, may experimentally try the truth hereof in
-twenty-four hours’ space.
-
-9. The first century of Glauber’s wealthy Storehouse of
-Treasures.--Many of the processes given in this treatise are mystically
-stated, or even concealed.
-
-10. The second, third, fourth, and fifth century of Glauber’s wealthy
-Storehouse of Treasures.
-
-11. New chemical Light; being a revelation of a certain new invented
-secret, never before manifested to the world.--This was a method of
-extracting gold from stones. Probably the gold found by Glauber in his
-processes existed in some of the reagents employed; this, at least, is
-the most natural way of accounting for the result of Glauber’s trials.
-
-15. The spagyrical Pharmacopœia, or Dispensatory.--In this book he
-treats chiefly of medicines peculiarly his own; one of those, on
-which he bestows the greatest praise, is _secret sal ammoniac_, or
-sulphate of ammonia. He describes the method of preparing this salt, by
-saturating sulphuric acid with ammonia. He informs us that it was much
-employed by Paracelsus and Van Helmont, who distinguished it by the
-name of _alkahest_.
-
-13. Book of Fires.--Full of enigmas.
-
-14. Treatise of the three Principles of Metals; viz. sulphur, mercury,
-and salt of philosophers; how they may be profitably used in medicine,
-alchymy, and other arts.
-
-15. A short Book of Dialogues. Chiefly relating to alchymy.
-
-16. Proserpine, or the Goddess of Riches.
-
-17. Of Elias the Artist.
-
-18. Of the three most noble Stones generated by three Fires.
-
-19. Of the Purgatory of Philosophers.
-
-20. Of the secret Fire of Philosophers.
-
-21. A Treatise concerning the Animal Stone.
-
-John Kunkel, who acquired a high reputation as a chemist, was born
-in the Duchy of Sleswick; in the year 1630: his father was a trading
-chemist, or apothecary; and Kunkel himself had, in his younger years,
-paid great attention to the business of an apothecary: he had also
-diligently studied the different processes of glass-making; and had
-paid particular attention to the assaying of metals. In the year 1659,
-he was chamberlain, chemist, and superintendent of apothecaries to the
-dukes Francis Charles and Julius Henry, of Lauenburg. While in this
-situation, he examined many pretended transmutations of metals, and
-undertook other researches of importance. From this situation he was
-invited, by John George II., Elector of Saxony, on the recommendation
-of Dr. Langelott and Counsellor Vogt, as chamberlain and superintendent
-of the elector’s laboratory, with a considerable salary. From this
-situation he went to Berlin, where he was chemist to the elector
-Frederick William; after whose death, his laboratory and glass-house
-were accidentally burnt. From Berlin he was invited to Stockholm by
-Charles XI., King of Sweden, who gave him the title of counsellor
-of metals, and raised him to the rank of a nobleman: here he died,
-in 1702, in the seventy-second year of his age. Kunkel’s greatest
-discovery was, the method of extracting phosphorus from urine. This
-curious substance had been originally discovered by Brandt, a chemist,
-of Hamburg, in the year 1669, as he was attempting to extract from
-human urine a liquid capable of converting silver into gold. He showed
-a specimen of it to Kunkel, with whom he was acquainted: Kunkel
-mentioned the fact as a piece of news to one Kraft, a friend of his in
-Dresden, where he then resided: Kraft immediately repaired to Hamburg,
-and purchased the secret from Brandt for 200 rix-dollars, doubtless
-exacting from him, at the same time, a promise not to reveal it to
-any other person. Soon after, he exhibited the phosphorus publicly
-in Britain and in France; whether for money, or not, does not appear.
-Kunkel, who had mentioned to his friend his intention of getting
-possession of the process, being vexed at the treacherous conduct of
-Kraft, attempted to discover it himself, and, after three or four years
-labour, he succeeded, though all that he knew from Brandt was, that
-urine was the substance from which the phosphorus was procured. In
-consequence of this success, phosphorus was at first distinguished by
-the epithet of _Kunkel_ added to the name.
-
-Kunkel published, in 1678, a treatise on phosphorus, in which he
-describes the properties of this substance, at that time a subject of
-great wonder and curiosity. In this treatise, he proposes phosphorus
-as a remedy of some efficacy, and gives a formula for preparing pills
-of it, to be taken internally. It is therefore erroneous to suppose,
-as has been done, that the introduction of this dangerous remedy into
-medicine is a modern discovery. Kunkel appears to have been acquainted
-with nitric ether. One of the most valuable of his books, is his
-treatise on glass-making, which was translated into French; and which,
-till nearly the end of the eighteenth century, constituted by far the
-best account of glass-making in existence. The following is a list of
-the most important of his works:
-
-1. Observations on fixed and volatile Salts, potable Gold and Silver,
-Spiritus Mundi, &c.; also of the colour and smell of metals, minerals,
-and bitumens.--This tract was published at Hamburg, in 1678, and has
-been several times reprinted since.
-
-2. Chemical Remarks on the chemical Principles, acid, fixed and
-volatile alkaline Salts, in the three kingdoms of nature, the mineral,
-vegetable, and animal; likewise concerning their colour and smell, &c.;
-with a chemical appendix against non-entia chymica.
-
-3. Treatise of the Phosphorus mirabilis, and its wonderful shining
-Pills; together with a discourse on what was formerly rightly named
-nitre, but is now called the _blood of nature_.
-
-4. An Epistle against Spirit of Wine without an acid.
-
-5. Touchstone de Acido et Urinoso, Sale calido et frigido.
-
-6. Ars Vitraria experimentalis.
-
-7. Collegium Physico-chymicum experimentale, _or_ Laboratorium
-chymicum.[176]
-
-[176] I have never seen a copy of this last work; it must have been
-valuable, as it was the book from which Scheele derived the first
-rudiments of his knowledge.
-
-Nicolas Lemery, the first Frenchman who completely stripped chemistry
-of its mysticism, and presented it to the world in all its native
-simplicity, deserves our particular attention, in consequence of the
-celebrity which he acquired, and the benefits which he conferred on
-the science. He was born at Rouen on the 17th of November, 1645. His
-father, Julian Lemery, was _procureur_ of the Parliament of Normandy,
-and a protestant. His son, when very young, showed a decided partiality
-for chemistry, and repaired to an apothecary in Rouen, a relation of
-his own, in hopes of being initiated into the science; but finding that
-little information could be procured from him, young Lemery left him in
-1666, and went to Paris, where he boarded himself with M. Glaser, at
-that time demonstrator of chemistry at the Jardin du Roi.
-
-Glaser was a _true chemist_, according to the meaning at that time
-affixed to the term--full of obscure notions--unwilling to communicate
-what knowledge he possessed--and not at all sociable. In two months
-Lemery quitted his house in disgust, and set out with a resolution to
-travel through France, and pick up chemical information as he best
-could, from those who were capable of giving him information on the
-subject. He first went to Montpelier, where he boarded in the house
-of M. Vershant, an apothecary in that town. With his situation there
-he was so much pleased, that he continued in it for three years:
-he employed himself assiduously in the laboratory, and in teaching
-chemistry to a number of young students who boarded with his host.
-Here his reputation gradually increased so much, that he drew round
-him the professors of the faculty of medicine of Montpelier, and all
-the curious of the place, to witness his experiments. Here, too, he
-practised medicine with considerable success.
-
-After travelling through all France, he returned to Paris in 1672.
-Here he frequented the different scientific meetings at that time
-held in that capital, and soon distinguished himself by his chemical
-knowledge. In a few years he got a laboratory of his own, commenced
-apothecary, and began to give public lectures on chemistry, which were
-speedily attended by great crowds of students from foreign countries.
-For example, we are told that on one occasion forty Scotchmen repaired
-to Paris on purpose to hear his lectures, and those of M. Du Verney
-on anatomy. The medicines which he prepared in his laboratory became
-fashionable, and brought him a great deal of money. The magistery
-of bismuth (or pearl-white), which he prepared as a cosmetic, was
-sufficient, we are told, to support the whole expense of his house. In
-the year 1675 he published his Cours de Chimie, certainly one of the
-most successful chemical books that ever appeared; it ran through a
-vast number of editions in a few years, and was translated into Latin,
-German, Spanish, and English.
-
-In 1681 he began to be troubled in consequence of his religious
-opinions. Louis XIV. was at that time in the height of his glory,
-entirely under the control of his priests, and zealously bent upon
-putting an end to the reformed religion in his dominions. Indeed, from
-the infamous conduct of Charles II. of England, and the bigotry of his
-successor, a prospect was opened to him, and of which he was anxious to
-avail himself, of annihilating the reformed religion altogether, and
-of plunging Europe a second time into the darkness of Roman Catholicism.
-
-Lemery found it expedient, in 1683, to pass over into England.
-Here he was well received by Charles II.: but England was at that
-time convulsed with those religious and political struggles, which
-terminated five years afterwards in the revolution. Lemery, in
-consequence of this state of things, found it expedient to leave
-England, and return to France. He took a doctor’s degree at Caen,
-in Normandy; and, returning to Paris, he commenced all at once
-practitioner in medicine and surgery, apothecary, and lecturer on
-chemistry. The edict of Nantes was revoked in 1685, when James II. had
-assured Louis of his intention to overturn the established religion,
-and bring Great Britain again under the dominion of the pope. Lemery
-was obliged to give up practice and conceal himself, in order to avoid
-persecution. Finding his success hopeless, as long as he continued
-a protestant, he changed his religion in 1686, and declared himself
-a Roman catholic. This step secured his fortune: he was now as much
-caressed and protected by the court and the clergy, as he had been
-formerly persecuted by them. In 1699 when the Academy of Sciences was
-new modelled, he was appointed associated chemist, and, on the death of
-Bourdelin, before the end of that year, he became a pensioner. He died
-on the 19th of June, 1715, at the age of seventy, in consequence of an
-attack of palsy, which terminated in apoplexy.
-
-Besides his System of Chemistry, which has been already mentioned, he
-published the following works:
-
-1. Pharmacopée universelle, contenant toutes les Operations de
-Pharmacie qui sont en usage dans la Médicine.
-
-2. Traité universelle des Drogues simples mis en ordre alphabétique.
-
-3. Traité de l’Antimoine, contenant l’analyse chimique de ce mineral.
-
-Besides these works, five different papers by Lemery were printed in
-the Memoirs of the French Academy, between 1700 and 1709 inclusive.
-These are as follow:
-
-1. Explication physique et chimique des Feux souterrains, des
-tremblemens de Terre, des Ouragans, des Eclairs et du Tonnere.--This
-explanation is founded on the heat and combustion produced by the
-mutual action of iron filings and sulphur on each other, when mixed in
-large quantities.
-
-2. Du Camphre.
-
-3. Du Miel et de son analyse chimique.
-
-4. De l’Urine de Vache, de ses effets en médicine et de son analyse
-chimique.
-
-5. Reflexions et Experiences sur le Sublimé Corrosive.--It appears from
-this paper, that in 1709, when Lemery wrote, corrosive sublimate was
-considered as a compound of mercury with the sulphuric and muriatic
-acids. Lemery’s statement, that he made corrosive sublimate simply
-by heating a mixture of mercury and decrepitated salt, is not easily
-explained. Probably the salt which he had employed was impure. This is
-the more likely, because, from his account of the matter which remained
-at the bottom of the matrass after sublimation, it must have either
-contained peroxide of iron or peroxide of mercury, for its colour he
-says was red.
-
-M. Lemery left a son, who was also a member of the French Academy; an
-active chemist, and author of various papers, in which he endeavours to
-give a mechanical explanation of chemical phenomena.
-
-Another very active member of the French Academy, at the same time with
-Lemery, was M. William Homberg, who was born on the 8th of January,
-1652, at Batavia, in the island of Java. His father, John Homberg, was
-a Saxon gentleman, who had been stripped of all his property during
-the thirty years war. After receiving some education by the care of a
-relation, he went into the service of the Dutch East India Company, and
-got the command of the arsenal at Batavia. There he married the widow
-of an officer, by whom he had four children, of whom William was the
-second.
-
-His father quitted the service of the India Company and repaired to
-Amsterdam with his family. Young Homberg studied with avidity: he
-devoted himself to the law, and in 1674 was admitted advocate of
-Magdeburg; but his taste for natural history and science was great.
-He collected plants in the neighbourhood, and made himself acquainted
-with their names and uses. At night he studied the stars, and learned
-the names and positions of the different constellations. Thus he
-became a self-taught botanist and astronomer. He constructed a hollow
-transparent celestial globe, on which, by means of a light placed
-within, the principal fixed stars were seen in the same relative
-positions as in the heavens.
-
-Otto Guericke was at that time burgomaster of Magdeburg. His
-experiments on a vacuum, and his invention of the air-pump, are
-universally known. Homberg attached himself to Otto Guericke, and
-this philosopher, though fond of mystery, either explained to him
-his secrets, in consequence of his admiration of his genius, or was
-unable to conceal them from his penetration. At last Homberg, quite
-tired of his profession of advocate, left Magdeburg and went to Italy.
-He sojourned for some time at Padua, where he devoted himself to the
-study of medicine, anatomy, and botany. At Bologna he examined the
-famous Bologna stone, the nature of which had been almost forgotten,
-and succeeded in making a pyrophorus out of it. At Rome he associated
-particularly with Marc-Antony Celio, famous for the large glasses for
-telescopes which he was able to grind. Nor did he neglect painting,
-sculpture, and music; pursuits in which, at that time, the Italians
-excelled all other nations.
-
-From Italy he went to France, and thence passed into England, where he
-wrought for some time in the laboratory of Mr. Boyle, at that time one
-of the most eminent schools of science in Europe. He then passed into
-Holland, studied anatomy under De Graaf, and after visiting his family,
-went to Wittemberg, where he took the degree of doctor of medicine.
-
-After this he visited Baldwin and Kunkel, to get more accurate
-information respecting the phosphorus which each had respectively
-discovered. He purchased a knowledge of Kunkel’s phosphorus, by giving
-in exchange a meteorological toy of Otto Guericke, now familiarly
-known, by which the moisture or dryness of the air was indicated--a
-little man came out of his house and stood at the door in dry weather,
-but retired under cover in moist weather. He next visited the mines
-of Saxony, Bohemia, and Hungary: he even went to Sweden, to visit the
-copper-mines of that country. At Stockholm he wrought in the chemical
-laboratory, lately established by the king, along with Hjerna, and
-contributed considerably to the success of that new establishment.
-
-He repaired a second time to France, where he spent some time,
-actively engaged with the men of science in Paris. His father strongly
-pressed him to return to Holland and settle as a physician: he at
-last consented, and the day of his departure was come, when, just as
-he was going into his carriage, he was stopped by a message from M.
-Colbert on the part of the king. Offers of so advantageous a nature
-were made him if he would consent to remain in France, that, after some
-consideration, he was induced to embrace them.
-
-In 1682 he changed his religion and became Roman catholic: this
-induced his father to disinherit him. In 1688 he went to Rome, where
-he practised medicine with considerable success. A few years after
-he returned to Paris, where his knowledge and discoveries gave him
-a very high reputation. In 1691 he became a member of the Academy
-of Sciences, and got the direction of the laboratory belonging to
-the academy: this enabled him to devote his undivided attention to
-chemical investigations. In 1702 he was taken into the service of the
-Duke of Orleans, who gave him a pension, and put him in possession of
-the most splendid and complete laboratory that had ever been seen. He
-was presented with the celebrated burning-glass of M. Tchirnhaus, by
-the Duke of Orleans, and was enabled by means of it to determine many
-points that had hitherto been only conjectural.
-
-In 1704 he was made first physician to the Duke of Orleans, who
-honoured him with his particular esteem. This appointment obliging him
-to reside out of Paris, would have made it necessary for him to resign
-his seat in the academy, had not the king made a special exemption in
-his favour. In 1708 he married a daughter of the famous M. Dodart, to
-whom he had been long attached. Some years after he was attacked by a
-dysentery, which was cured, but returned from time to time. In 1715 it
-returned with great violence, and Homberg died on the 24th of September.
-
-His knowledge was uncommonly great in almost every department of
-science. His chemical papers were very numerous; though there are few
-of them, in this advanced period of the science, that are likely to
-claim much attention from the chemical world. His pyrophorus, of which
-he has given a description in the Mémoires de l’Académie,[177] was made
-by mixing together human fæces and alum, and roasting the mixture till
-it was reduced to a dry powder. It was then exposed in a matrass to a
-red heat, till every thing combustible was driven off. Any combustible
-will do as a substitute for human fæces--gum, flour, sugar, charcoal,
-may be used. When a little of this phosphorus is poured upon paper, it
-speedily catches fire and kindles the paper. Davy first explained the
-nature of this phosphorus. The potash of the alum is converted into
-potassium, which, by its absorption of oxygen from the atmosphere,
-generates heat, and sets fire to the charcoal contained in the powder.
-
-[177] For 1711, p. 238.
-
-Homberg’s papers printed in the Memoirs of the French Academy amount
-to thirty-one. They are to be found in the volumes for 1699 to 1714
-inclusive.
-
-M. Geoffroy, who was a member of the academy about the same time with
-Lemery and Homberg, though he outlived them both, and who was an
-active chemist for a considerable number of years, deserves also to be
-mentioned here.
-
-Stephen Francis Geoffroy was born in Paris on the 13th of February,
-1672, where his father was an apothecary. While a young man, regular
-meetings of the most eminent scientific men of Paris were held in his
-father’s house, at which he was always present. This contributed very
-much to increase his taste for scientific pursuits. After this he
-studied botany, chemistry, and anatomy in Paris. In 1692 his father
-sent him to Montpelier, to study pharmacy in the house of a skilful
-apothecary, who at the same time sent his son to Paris, to acquire the
-same art in the house of M. Geoffroy, senior. Here he attended the
-different classes in the university, and his name began to be known as
-a chemist. After spending some time in Montpelier, he travelled round
-the coast to see the principal seaports, and was at St. Malo’s in 1693,
-when it was bombarded by the British fleet.
-
-In 1698 Count Tallard being appointed ambassador extraordinary to
-London, made choice of M. Geoffroy as his physician, though he had
-not taken a medical degree. Here he made many valuable acquaintances,
-and was elected a fellow of the Royal Society. From London he went to
-Holland, and thence into Italy, in 1700, where he went in the capacity
-of physician to M. de Louvois. The great object of M. Geoffroy was
-always natural history, and materia medica. In 1693 he had subjected
-himself to an examination, and he had been declared qualified to act
-as an apothecary; but his own object was to be a physician, while that
-of his father was that he should succeed himself as an apothecary:
-this in some measure regulated his education. At last he declared
-his intentions, and his father agreed to them; he became bachelor of
-medicine in 1702, and doctor of medicine in 1704.
-
-In 1709 he was made professor of medicine in the Royal College. In 1707
-he began to lecture on chemistry, at the Jardin du Roi, in place of M.
-Fagan, and continued to teach this important class during the remainder
-of his life. In 1726 he was chosen dean of the faculty of medicine;
-and, after the two years for which he was elected was finished, he was
-again chosen to fill the same situation. There existed at that time a
-lawsuit between the physicians and surgeons in Paris; a kind of civil
-war very injurious to both; and the mildness and suavity of his manners
-fitted him particularly for being at the head of the body of physicians
-during its continuance. He became a member of the academy in 1699, and
-died on the 6th of January, 1731.
-
-The most important of all his chemical labours, and for which he
-will always be remembered in the annals of the science, was the
-contrivance which he fell upon, in 1718, of exhibiting the order of
-chemical decompositions under the form of a table.[178] This method
-was afterwards much enlarged and improved. Such tables are now usually
-known by the name of _tables of affinity_; and, though they have been
-of late years somewhat neglected, there can be but one opinion of their
-importance when properly constructed.
-
-[178] Mem. Paris, 1718, p. 202; and 1720, p. 20.
-
-M. Geoffroy first communicated to the French chemists the mode of
-making Prussian blue, as Dr. Woodward did to the English.
-
-Claude Joseph Geoffroy, the younger brother of the preceding, was
-also a member of the Academy of Sciences, and a zealous cultivator
-of chemistry. Many of his chemical papers are to be found in the
-memoirs of the French Academy. He demonstrated the composition of sal
-ammoniac, which however was known to Glauber. He made many experiments
-upon the combustion of the volatile oils, by pouring nitric acid on
-them. He explained the pretended property which certain waters have
-of converting iron into copper, by showing that in such cases copper
-was held in solution in the water by an acid, and that the iron merely
-precipitated the copper, and was dissolved and combined with the acid
-in its place. He pointed out the constituents of the three vitriols,
-the green, the blue, and the white; showing that the two former were
-combinations of sulphuric acid with oxides of iron and copper, and the
-latter a solution of lapis calaminaris (_carbonate of zinc_) in the
-same acid. He has also a memoir on the emeticity of antimony, tartar
-emetic, and kermes mineral; but it is rather medical than chemical.
-He determined experimentally the nature of the salt of Seignette, or
-Rochelle salt, and showed that it was obtained by saturating cream of
-tartar with carbonate of soda, and crystallizing. It is curious that
-this discovery was made about the same time by M. Boulduc. I have
-noticed only a few of the papers of M. Geoffroy, junior; because,
-though they all do him credit, and contributed to the improvement of
-chemistry, yet none of them contain any of those great discoveries,
-which stand as landmarks in the progress of science, and constitute an
-era in the history of mankind. For the same reason I omit several other
-names that, in a more minute history of chemistry, would deserve to be
-particularized.
-
-
-
-
-CHAPTER VIII.
-
-OF THE ATTEMPTS TO ESTABLISH A THEORY IN CHEMISTRY.
-
-
-Bacon, Lord Verulam, as early as the commencement of the 17th century,
-had pointed out the importance of chemical investigations, and had
-predicted the immense advantages which would result from the science,
-when it came to be properly cultivated and extended; but he did not
-himself attempt either to construct a theory of chemistry, or even
-to extend it beyond the bounds which it had reached before he began
-to write. Neither did Boyle, notwithstanding the importance of his
-investigations, and his comparative freedom from the prejudices of the
-alchymists, attempt any thing like a theory of chemistry; though the
-observations which he made in his Sceptical Chemist, had considerable
-effect in overturning, or at least in hastening the downfall of the
-absurd chemical opinions which at that time prevailed, and the puerile
-hypotheses respecting the animal functions, and the pathology and
-treatment of diseases founded on these opinions. The first person who
-can with propriety be said to have attempted to construct a theory of
-chemistry, was Beccher.
-
-John Joachim Beccher, one of the most extraordinary men of the age in
-which he lived, was born at Spires, in Germany, in the year 1635. His
-father, as Beccher himself informs us, was a very learned Lutheran
-preacher. As he lost his father when he was very young, and as that
-part of Germany where he lived had been ruined by the thirty years’
-war, his family was reduced to great poverty. However, his passion
-for information was so great, that he contrived to educate himself by
-studying what books he could procure, and in this way acquired a great
-deal of knowledge. Afterwards he travelled through the greatest part of
-Germany, Italy, Sweden, and Holland.
-
-In the year 1666 he was appointed public professor of medicine in the
-University of Mentz, and soon after chief physician to the elector.
-In that capacity he took up his residence in Munich, where he was
-furnished by the elector with an excellent laboratory: but he soon fell
-into difficulties, the nature of which does not appear, and was obliged
-to leave the place. He took refuge in Vienna, where, from his knowledge
-of finance, he was appointed chamberlain to Count Zinzendorf, and
-through him acquired so much importance in the eyes of the court, that
-he was named a member of the newly-erected College of Commerce, and
-obtained the title of imperial commercial counsellor and chamberlain.
-But here also he speedily raised up so many enemies against himself,
-that he found it necessary to leave Vienna, and to carry with him his
-wife and children. He repaired to Holland, and settled at Haerlem in
-1678. Here he was likely to have been successful; but his enemies from
-Vienna followed him, and obliged him to leave Holland. In 1680 we
-find him in Great Britain, where he examined the Scottish lead-mines,
-and smelting-works; and in 1681, and 1682, he traversed Cornwall, and
-studied the mines and smelting-works of that great mining county; here
-he suggested several improvements and ameliorations. Soon after this
-an advantageous proposal was made to him by the Duke of Mecklenburg
-Gustrow, by means of Count Zinzendorf; but all his projects were
-arrested by his death, which took place in the year 1682. It is said
-that he died in London, but I have not been able to find any evidence
-of this.
-
-It would be a difficult task to particularize his various discoveries,
-which are scattered through a multiplicity of writings. He was
-undoubtedly the first discoverer of boracic acid, though the credit of
-the discovery has usually been given to Homberg.[179] But then he gives
-no account of boracic acid, nor does he seem to have attended to its
-qualities. The following is a list of Beccher’s writings:
-
-[179] In the sixth chemical thesis, in the second supplement to the
-Physica Subterranea (page 791, Stahl’s Edition. Lipsiæ, 1703), he says,
-“ubi etiam, continuato igne, ipsum sal volatile acquires, quod eadem
-methodo cum vitriolo seu spiritu aut oleo vitrioli, et oleo tartari,
-vel _borace_ succedit.”
-
-1. Metallurgia, or the Natural Science of Metals.
-
-2. Institutiones Chymicæ.
-
-3. Parnassus Medicinalis illustrata.
-
-4. Œdipus Chymicus seu Institutiones Chymicæ.
-
-5. Acta laboratorii Chymici Monacensis seu Physica Subterranea.--This,
-which is the most important of all his works, is usually known by the
-name of “Physica Subterranea.” This is the sole title affixed to it in
-the edition published at Leipsic, in 1703, to which Stahl has prefixed
-a long introduction. It is divided into seven sections. In the first he
-treats of the creation of the world; in the second he gives a chemical
-account of the motions and changes which are constantly going on in the
-earth; in the third he treats of the three principles of all bodies,
-which he calls _earths_. The first of these principles of metals and
-stones is the _fusible_ or _stony earth_; the second principle of
-minerals is the _fat earth_, improperly called _sulphur_; the third
-principle is the _fluid earth_, improperly called _mercury_; in the
-fourth section he treats of the action of subterraneous principles, or
-the formation of _mixts_; in the fifth he treats of the solution of the
-three classes of mixts, animals, vegetables, and metals; in the sixth
-he treats of _mixts_, in which he gives their chemical constituents.
-This section is very curious, because it gives Beccher’s views of the
-constitution of compound bodies. It will be seen from it that he had
-much more correct notions of the real objects of chemistry, than any of
-his contemporaries. In the seventh and last section he treats of the
-accidents and physical affections of subterraneous bodies.
-
-6. Experimentum Chymicum novum quo artificialis et instantanea
-metallorum generatio et transmutatio, ad oculum demonstratur.--This
-constitutes the first supplement to the Physica Subterranea.
-
-7. Supplementum secundum in Physicam subterraneam, demonstratio
-philosophica seu Theses Chymicæ, veritatem et possibilitatem
-transmutationis metallorum in aurum evincentes.
-
-8. Trifolium Beccherianum Hollandicum.
-
-9. Experimentum novum et curiosum de Minera arenaria perpetua, sive
-prodromus historiæ seu propositionis Præp. D.D. Hollandiæ ordinibus ab
-authore factæ, circa auri extractionem mediante arena littorali per
-modum mineræ perpetuæ seu operationis magnæ fusoriæ cum emolumento.
-Loco supplementi tertii in Physicam suam subterraneam.
-
-10. Chemical Luckpot, or great chemical agreement; in a collection of
-one thousand five hundred chemical processes.
-
-11. Foolish Wisdom and wise Folly.
-
-12. Magnalia Naturæ.
-
-13. Tripus Hermeticus fatidicus pandens oracula chemica; seu I.
-Laboratorium portatile, cum methodo vere spagyricæ seu juxta exigentiam
-naturæ laborandi. Accessit pro praxi et exemplo; II. Centrum mundi
-concatenatum seu Duumviratus hermeticus s. magnorum duorum productorum
-nitri et salis textura et anatomia atque in omnium præcedentium
-confirmationem adjunctum est; III. Alphabetum Minerale seu viginti
-quatuor theses de subterraneorum mineralium genesi, textura et analysi;
-his accessit concordantia mercurii lunæ et menstruorum.
-
-14. Chemical Rose-garden.
-
-15. Pantaleon delarvatus.
-
-16. Beccheri, Lancelotti, etc. Epistolæ quatuor Chemicæ.
-
-Beccher’s great merit was the contrivance of a chemical theory, by
-which all the known facts were connected together and deduced from one
-general principle. But as this theory was adopted and considerably
-modified by Stahl, it will be better to lay a sketch of it before the
-reader, after mentioning a few particulars of the life and labours of
-one of the most extraordinary men whom Germany has produced; a man who,
-in spite of the moroseness and haughtiness of his character, and in
-spite of the barbarity of his style, raised himself to the very first
-rank as a man of science; and had the rare or almost unique fortune of
-giving laws at the same time to two different and important sciences,
-which he cultivated together, without letting his opinions respecting
-the one influence him with regard to the other. These sciences were
-chemistry and medicine.
-
-George Ernest Stahl was born at Anspach, in the year 1660. He studied
-medicine at Jena under George Wolfgang Wedel; and got his doctor’s
-degree at the age of twenty-three. Immediately after this he began
-his career as a public lecturer. In 1687 the Duke of Weimar gave him
-the title of physician to the court. In 1694 he was named, at the
-solicitation of Frederick Hoffmann, second professor of medicine in
-the University of Halle, which had just been established. Hoffmann and
-he were at that time great friends, though they afterwards quarrelled.
-Both of them were men of the very highest talents and both were the
-founders of medical systems which, of course, each was anxious to
-support. Hoffmann had greatly the superiority in elegance and clearness
-of style, and in all the amenities of polite manners. But perhaps the
-moroseness of Stahl, and the obscurity, or rather mysticism of his
-style, contributed equally with the more amiable qualities of Hoffmann
-to excite the attention and produce the veneration with which he was
-viewed by his pupils, and, indeed, by the world at large.
-
-At Halle he continued as a teacher of medicine for twenty-two years. In
-1716 he was appointed physician to the King of Prussia. In consequence
-of this appointment he left Halle, and resided in Berlin, where he died
-in the year 1734, in the seventy-fifth year of his age. Notwithstanding
-the great figure that Stahl made as a chemist, there is no evidence
-that he ever taught that science in any public school. The Berlin
-Academy had been founded under the superintendence of Leibnitz, who was
-its first president; and therefore existed when Stahl was in Berlin:
-but, till it was renovated in 1745 by Frederick the Great, this academy
-possessed but little activity, and could scarcely, therefore, have
-stimulated Stahl to attend to chemical science. However, his Chymia
-rationalis et experimentalis was published in 1720, while he resided
-in Berlin. The same date is appended to the preface of his Fundamenta
-Chymiæ; but, from some expressions in that preface, it must, I should
-think, have been written, not by Stahl, but by some other person.[180]
-I suspect that the book had been written by some of his pupils, from
-the lectures of the author while at Halle. If this was really the
-case, it is obvious that Stahl must have taught chemistry as well as
-medicine in the University of Halle.
-
-[180] “Primus in his facem prætulit Beccherus; eumque magno cum artis
-progressu sequentem videmus in ostendenda corporum analysi et synthesi
-chymica versatissimum et acutissimum--_Stahlium_.”
-
-Stahl’s medical theory is not less deserving of notice than his
-chemical. But it is not the object of this work to enter into medical
-speculations. Like Van Helmont, he resolved all diseases into the
-actions of the _soul_, which was not merely the former of the body, but
-its ruler and regulator. When any of the functions are deranged, the
-soul exerts itself to restore them again to their healthy state; and
-she accomplishes this by what in common language is called disease.
-The business of a medical man, then, is not to prevent diseases, or to
-stop them short when they appear; because they are the efforts of the
-soul, the _vis medicatrix naturæ_, to restore the deranged state of the
-functions: but he must watch these diseases, and prevent the symptoms
-from becoming too violent. He must assist nature to produce the
-intended effect, and check her exertions when they become abnormal. It
-was a kind of modification of this theory, or rather a mixture of the
-Stahlian and Hoffmannian theories, that Dr. Cullen afterwards taught
-in Edinburgh with so much eclat. And these opinions, so far as medical
-theories have any influence on practice, still continue in some measure
-prevalent. Indeed, much of the vulgar practice followed by medical men,
-chiefly in consequence of the education which they have received, is
-deduced from these two theories. But it would be too great a digression
-from the object of this work to enter into any details: suffice it
-to say, that the rival theories of Hoffmann and Stahl for many years
-divided the medical world in Germany, if not in the greater part of
-Europe. It was no small matter of exultation to so young a medical
-school as Halle, to have at once within its walls two such eminent
-teachers as Hoffmann and Stahl.
-
-Let us turn our attention to the chemical writings of Stahl. Of
-these the most important is his Fundamenta Chymiæ dogmaticæ et
-experimentalis. It is divided, like the chemistry of Boerhaave, into a
-theoretical and practical part. The perusal of it is very disagreeable,
-as it is full of German words and phrases, and symbols are almost
-constantly substituted for words, as was at that time the custom.
-
-His definition of chemistry is much more exact than Boerhaave’s. It
-is, according to him, the art of resolving compound bodies into their
-constituents, and of again forming them by uniting these constituents
-together.
-
-He is inclined to believe with Beccher, that the simple principles are
-four in number. The _mixts_ are compounds of these principles; and he
-shows by the doctrine of permutations that if we suppose the simple
-principles four, then the number of mixts will be 40,340. He treats in
-the first place of _mixts_, _compounds_, and _aggregates_.
-
-The first object of chemistry is _corruption_, the second _generation_.
-Of these he treats at considerable length, giving an account of the
-different chemical processes, and of the apparatus employed.
-
-He next treats of _salts_, which he defines mixts composed of water
-and earth, both simple and pure, and intimately united. The salts are
-vitriol, alum, nitre, common salt, and sal ammoniac. He next treats of
-more compound salts. These are sugar, tartar, salts from the animal and
-salts from the mineral kingdom, and quicklime.
-
-After this comes sulphur, cinnabar, antimony, the sulphur of vitriol,
-the sulphur of nitre, resins, and distilled oils. Then he treats of
-water, which he divides into aqua _humida_ or common water, and aqua
-_sicca_ or mercury. Next he treats of earths, which are of two kinds,
-viz., _friable earths_, such as _clay_, _loam_, sand, &c., and metallic
-earths constituting the bases of the metals.
-
-He next treats of the metals; and, as a preliminary, we have a
-description of the method of smelting, and operating upon the different
-metals. The metals are then described successively in the following
-order: Gold, silver, copper, iron, tin, lead, bismuth, zinc, antimony.
-
-To this part of the system are added three sections. The first treats
-of mercuries, the second of the philosopher’s stone, and the third of
-the universal medicine. We must not suppose that Stahl was a believer
-in these ideal compositions; his object is merely to give a history of
-the different processes which had been recommended by the alchymists.
-
-The second part of his work is divided into two _tracts_. The first
-tract contains three sections. The first of these treats of the nature
-of solids and fluids, of solutions and menstrua, of the effects of heat
-and fire, of effervescence and boiling, of volatilization, of fusion
-and liquefaction, of distillation, of precipitation, of calcination
-and incineration, of detonation, of amalgamation, of crystallization
-and inspissation, and of the fixity and firmness of bodies. In the
-second section we have an account of salts, and of their generation
-and transmutation, of sulphur and inflammability, of phosphorus, of
-colours, and of the nature of metals and minerals. In this article
-he gives short definitions of these bodies, and shows how they may
-be known. The bodies thus defined are gold, silver, iron, copper,
-lead, tin, mercury, antimony, sulphur, arsenic, vitriol, common salt,
-nitre, alum, sal ammoniac, alkalies, and salts; viz., muriatic acid,
-sulphuric, nitric, and sulphurous.
-
-In the third section he treats of the method of reducing metallic
-calces, of the mode of separating metals from their scoriæ, of the mode
-of making artificial gems, and finally of the mode of giving copper a
-golden colour.
-
-The second tract is divided into two parts. The first part is
-subdivided into four sections. In the first section he treats of the
-instruments of chemical motion, of fire, of air, of water, of the most
-subtile earth or salt. In the second section he treats _de subjectis_,
-under the several heads of dissolving aggregates, of triturations and
-solutions, and of calcinations and combustions. In the third section
-he treats of the object of chemistry under the following heads: Of
-chemical corruption, consisting of compounds from liquids, of the
-separation of solids and fluids, of mixts, of the solution of compounds
-from solids. In the fourth section he treats of fermentation.
-
-The second part of this second tract treats of chemical generation,
-and is divided into two sections. In the first section he treats of
-the aggregate collection of bodies into fluids and solids. The section
-treats of compositions under the heads of volatile and solid bodies. He
-gives in the last article an account of the combination of mixts.
-
-The third and last part of this elaborate work discusses three
-subjects; viz. _zymotechnia_ or _fermentation_, _halotechnia_, or the
-production and properties of salts, and _pyrotechnia_, in which the
-whole of the Stahlian doctrine of _phlogiston_ is developed. This
-third part has all the appearance of having been notes written down by
-some person during the lectures of Stahl: for it consists of alternate
-sentences of Latin and German. It is not at all likely that Stahl
-himself would have produced such a piebald work; but if he lectured in
-Latin, as was at that time the universal custom, it was natural for a
-person occupied in taking down the lectures, to write as far as was
-possible in Latin, but when any of the Latin phrases were lost, or did
-not immediately occur to memory, it were equally natural to write down
-the meaning of what the professor stated in the language most familiar
-to the writer, which was undoubtedly the German.
-
-Another of Stahl’s works is entitled “Opusculum
-Chymico-physico-medicum,” published at Halle in a thick quarto volume,
-in the year 1715. It contains a great number of tracts, partly chemical
-and partly medical, which it is needless to specify. Perhaps the most
-curious of them all is his dissertation to show the way in which Moses
-ground the golden calf to powder, dissolved it in water, and obliged
-the children of Israel to drink it. He shows that a solution of hepar
-sulphuris (_sulphuret of potassium_), has the property of dissolving
-gold, and he draws as a conclusion from his experiments that this was
-the artifice employed by Moses. We have in the same volume a pretty
-detailed treatise on metallurgic pyrotechny and docimasy. This is the
-more curious, because Stahl never appears to have frequented the mines
-and smelting-houses of Germany. He must, therefore, have drawn his
-information from books and from experiment.
-
-Another of his books is entitled “Experimenta, Observationes,
-Animadversiones, CCC. Numero.” An octavo volume, printed at Berlin
-in 1731. Another of his books is entitled “Specimen Beccherianum.”
-There are also two chemical books of Stahl, which I have seen only in
-a French translation, viz., _Traité de Soufre_ and _Traité de Sels_.
-These are the only chemical writings of Stahl that I have seen. There
-are probably others; indeed I have seen the titles of several other
-chemical works ascribed to him. But as it is doubtful whether he really
-wrote them or not, I think it unnecessary to specify them here.
-
-Stahl’s writings evince the great progress which chemistry had
-made even since the time of Beccher. But it is difficult to say
-what particular new facts, which appear first in his writings were
-discovered by himself, and what by others. I shall not, therefore,
-attempt any enumeration of them. His reasoning is more subtile, and his
-views much more extensive and profound than those of his predecessors.
-The great improvement which he introduced into chemistry was the
-employment of _phlogiston_, to explain the phenomena of combustion
-and calcination. This theory had been originally broached by Beccher,
-from whom Stahl evidently borrowed it, but he improved and simplified
-it so much that the whole credit of it was given to him. It was called
-the Stahlian theory, and raised him to the highest rank among chemists.
-The sole objects of chemists for thirty or forty years after his time
-was to illucidate and extend his theory. It applied so happily to all
-the known facts, and was supported by experiments, which appeared
-so decisive that nobody thought of calling it in question, or of
-interrogating nature in any other way than he had pointed out. It will
-be requisite, therefore, before proceeding further with this historical
-sketch, to lay the outlines of the phlogistic theory before the reader.
-
-It was conceived by Beccher and Stahl that all _combustible_ bodies
-are compounds. One of the constituents they supposed to be dissipated
-during the combustion, while the other constituent remained behind.
-Now when combustible bodies are subjected to combustion, some of them
-leave an acid behind them; while others leave a fixed powdery matter,
-possessing the properties of an _earth_, and called usually the _calx_
-of the combustible body. The metals are the substances which leave
-a calx behind them when burnt, and sulphur and phosphorus leave an
-acid. With respect to those bodies that would not burn, chemists did
-not speculate much at first; but afterwards they came to think that
-they consisted of the fixed substance that remained after combustion.
-Hence the conclusion was natural, that they had already undergone
-combustion. Thus quicklime possessed properties very similar to the
-calces of metals. It was natural, therefore, to consider it as a calx,
-and to believe that if the matter dissipated during combustion could be
-again restored, lime would be converted into a substance similar to the
-metals.
-
-Combustibility then, according to this view of the subject, depends
-upon a principle or material substance, existing in every combustible
-body, and dissipated during the combustion. This substance was
-considered to be absolutely the same in all combustible bodies
-whatever; hence the difference between combustible bodies proceeded
-from the other principle or number of principles with which this common
-substance is combined. In consequence of this identity Stahl invented
-the term _phlogiston_, by which he denoted this common principle of
-combustible bodies. Inflammation, with the several phenomena that
-attend it, depended on the gradual separation of this principle,
-which being once separated, what remained of the body could no
-longer be an inflammable substance, but must be similar to the other
-kinds of matter. It was this opinion that combustibility is owing
-to the presence of phlogiston, and inflammation to its escape, that
-constituted the peculiar theory of Beccher, and which was afterwards
-illustrated by Stahl with so much clearness, and experiments to prove
-its truth were advanced by him of so much force, that it came to be
-distinguished by the name of the Stahlian theory.
-
-The identity of phlogiston in all combustible bodies was founded upon
-observations and experiments of so decisive a nature, that after the
-existence of the principle itself was admitted, they could not fail
-to be satisfactory. When phosphorus is made to burn it gives out a
-strong flame, much heat is evolved, and the phosphorus is dissipated
-in a white smoke: but if the combustion be conducted within a glass
-vessel of a proper shape, this white smoke will be deposited on the
-inside of the glass; it quickly absorbs moisture from the atmosphere,
-and runs into an acid liquid, known by the name of phosphoric acid.
-If this liquid be put into a platinum crucible, and gradually heated
-to redness, the water is dissipated, and a substance remains which,
-on cooling, congeals into a transparent colourless body like glass:
-this is dry _phosphoric_ acid. If now we mix phosphoric acid with
-a quantity of charcoal powder, and heat it sufficiently in a glass
-retort, taking care to exclude the external air, a _portion_ or the
-_whole_ of the charcoal will disappear, and phosphorus will be formed
-possessed of the same properties that it had before it was subjected
-to combustion. The conclusion deduced from this process appeared
-irresistible; the charcoal, or a portion of it, had combined with the
-phosphoric acid, and both together had constituted phosphorus.
-
-Now, in changing phosphoric acid into phosphorus, we may employ almost
-any kind of combustible substance that we please, provided it be
-capable of bearing the requisite heat; they will all equally answer,
-and will all convert the acid into phosphorus. Instead of charcoal we
-may take lamp-black, or sugar, or resin, or even several of the metals.
-Hence it was concluded that all of these bodies contain a common
-principle which they communicate to the phosphoric acid; and since the
-new body formed is in all cases identical, the principle communicated
-must also be identical. Hence combustible bodies contain an identical
-principle, and this principle is phlogiston.
-
-Sulphur by burning is converted into sulphuric acid; and if sulphuric
-acid be heated with charcoal, or phosphorus, or even sulphur, it is
-again converted into sulphur. Several of the metals produce the same
-effect. The reasoning here was the same as with regard to phosphoric
-acid, and the conclusion was similar.
-
-When lead is kept nearly at a red heat in the open air for some time,
-being constantly stirred to expose new surfaces to the air, it is
-converted into the beautiful pigment called _red lead_; this is a calx
-of lead. To restore this calx again to the state of metallic lead, we
-have only to heat it in contact with almost any combustible matter
-whatever. Pit-coal, peat, charcoal, sugar, flour, iron, zinc, &c.,
-all these bodies then must contain one common principle, which they
-communicate to red lead, and by so doing convert it into lead. This
-common principle is phlogiston.
-
-These examples are sufficient to show the reader the way in which
-Stahl proved the identity of phlogiston in all combustible bodies. And
-the demonstration was considered as so complete that the opinion was
-adopted by every chemist without exception.
-
-When we inquire further, and endeavour to learn what qualities
-phlogiston was supposed to have in its separate state, we find this
-part of the subject very unsatisfactory, and the opinions very
-unsettled. Beccher and Stahl represented phlogiston as a dry substance,
-or of an earthy nature, the particles of which are exquisitely
-subtile, and very much disposed to be agitated and set in motion with
-inconceivable velocity. This was called by Stahl _motus verticillaris_.
-When the particles of any body are agitated with this kind of motion,
-the body exhibits the phenomena of heat or ignition, or inflammation,
-according to the violence and rapidity of the motion.
-
-This very crude opinion of the earthy nature of phlogiston, appears to
-have been deduced from the insolubility of most combustible substances
-in water. If we except alcohol, and ether, and gums, very few of
-them are capable of being dissolved in that liquid. Thus the metals,
-sulphur, phosphorus, oils, resins, bitumens, charcoal, &c., are well
-known to be insoluble. Now, at the time that Beccher and Stahl lived,
-insolubility in water was considered as a character peculiar to earthy
-bodies; and as those bodies which contain a great deal of phlogiston
-are insoluble in water, though the other constituents be very soluble
-in that liquid, it was natural enough to conclude that phlogiston
-itself was of an earthy nature.
-
-But though the opinions of chemists about the nature and properties
-of phlogiston in a separate state were unsettled, no doubts were
-entertained respecting its existence, and respecting its identity in
-all combustible bodies. Its presence or its absence produced almost
-all the changes which bodies undergo. Hence chemistry and combustion
-came to be in some measure identified, and a theory of combustion was
-considered as the same thing with a theory of chemistry.
-
-Metals were compounds of _calces_ and phlogiston. The different
-species of metals depend upon the different species of calx which each
-contains; for there are as many _calces_ (each simple and peculiar) as
-there are metals. These calces are capable of uniting with phlogiston
-in indefinite proportions. The calx united to a little phlogiston still
-retains its earthy appearance--a certain additional portion restores
-the calx to the state of a metal. An enormous quantity of phlogiston
-with which some calces, as calx of manganese, are capable of combining,
-destroys the metallic appearance of the body, and renders it incapable
-of dissolving in acids.
-
-The affinity between a metallic calx and phlogiston is strong; but the
-facility of union is greatly promoted when the calx still retains a
-little phlogiston. If we drive off the whole phlogiston we can scarcely
-unite the calx with phlogiston again, or bring it back to the state of
-a metal: hence the extreme difficulty of reducing the calx of zinc, and
-even the red calx of iron.
-
-The various colours of bodies are owing to phlogiston, and these
-colours vary with every alteration in the proportion of phlogiston
-present.
-
-It was observed very early that when a metal was converted into a calx
-its weight was increased. But this, though known to Beecher and Stahl,
-does not seem to have had any effect on their opinions. Boyle, who does
-not seem to have been aware of the phlogistic theory, though it had
-been broached before his death, relates an experiment on tin which he
-made. He put a given weight of it into an open glass vessel, and kept
-it melted on the fire till a certain portion of it was converted into
-a calx: it was now found to have increased considerably in weight. This
-experiment he relates in order to prove the materiality of heat: in his
-opinion a certain quantity of heat had united to the tin and occasioned
-the increase of weight. This opinion of Boyle was incompatible with
-the Stahlian theory: for the tin had not only increased in weight, but
-had been converted into a calx. It was therefore the opinion of Boyle
-that calx of tin was a combination of _tin_ and _heat_. It could not
-consequently be true that calx of tin was tin deprived of phlogiston.
-
-When this difficulty struck the phlogistians, which was not till long
-after the time of Stahl, they endeavoured to evade it by assigning new
-properties to phlogiston. According to them it is not only destitute
-of weight, but endowed with a principle of levity. In consequence of
-this property, a body containing phlogiston is always lighter than it
-would otherwise be, and it becomes heavier when the phlogiston makes
-its escape: hence the reason why calx of tin is heavier than the same
-tin in the metallic state. The increase of weight is not owing, as
-Boyle believed, to the fixation of heat in the tin, but to the escape
-of phlogiston from it.
-
-Those philosophic chemists, who thus refined upon the properties of
-phlogiston, did not perceive that by endowing it with a principle of
-levity, they destroyed all the other characters which they had assigned
-to it. What is gravity? Is it not an attraction by means of which
-bodies are drawn towards each other, and remain united? And is there
-any reason for supposing that chemical attraction differs in its nature
-from the other kinds of attraction which matter possesses? If, then,
-phlogiston be destitute of gravity, it cannot possess any attraction
-for other bodies; if it be endowed with a principle of levity, it must
-have the property of repelling other bodies, for that is the only
-meaning that can be attached to the term. But if phlogiston has the
-property of repelling all other substances, how comes it to be fixed
-in combustible bodies? It must be united to the calces or the acids,
-which constitute the other principle of these bodies; and it could not
-be united, and remain united, unless a principle of attraction existed
-between it and these bases; that is to say, unless it possessed a
-principle the very opposite of levity.
-
-Thus the fact, that calces are heavier than the metals from which they
-are formed, in reality overturned the whole doctrine of phlogiston;
-and the only reason why the doctrine continued to be admitted after
-the fact was known is, that in these early days of chemistry, the
-balance was scarcely ever employed in experimenting: hence alterations
-in weight were little attended to or entirely overlooked. We shall
-see afterwards, that when Lavoisier introduced a more accurate mode
-of experimenting, and rendered it necessary to compare the original
-weights of the substances employed, with the weights of the products,
-he made use of this very experiment of Boyle, and a similar one made
-with mercury, to overturn the whole doctrine of phlogiston.
-
-The phlogistic school being thus founded by Stahl, in Berlin, a race
-of chemists succeeded him in that capital, who contributed in no
-ordinary degree to the improvement of the science. The most deservedly
-celebrated of these were Neumann, Pott, Margraaf, and Eller.
-
-Caspar Neumann was born at Zullichau, in Germany, in 1682. He was
-early received into favour by the King of Prussia, and travelled
-at the expense of that monarch into Holland, England, France, and
-Italy. During these travels he had an opportunity of making a
-personal acquaintance with the most eminent men of science in all
-the different countries which he visited. On his return home, in
-1724, he was appointed professor of chemistry in the Royal College of
-Physic and Surgery at Berlin, where he delivered a course of lectures
-annually. During the remainder of his life he enjoyed the situation of
-superintendent of the Royal Laboratory, and apothecary to the King of
-Prussia. He died in 1737. He was a Fellow of the Royal Society, and
-several papers of his appeared in the Transactions of that learned
-body. The following is a list of these papers, all of which were
-written in Latin:
-
-1. Disquisitio de camphora.
-
-2. De experimento probandi spiritum vini Gallici, per quam usitato, sed
-revera falso et fallaci.
-
-Some merchants in Holland, England, Hamburg, and Dantzic, were in
-possession of what they considered an infallible test to distinguish
-French brandy from every other kind of spirit. It was a dusky yellowish
-liquid. When one or two drops of it were let fall into a glass of
-French brandy, a beautiful blue colour appeared at the bottom of
-the glass, and when the brandy is stirred, the whole liquid becomes
-azure. But if the spirit tried be malt spirit, no such colour appears
-in the glass. Neumann ascertained that the test liquid was merely a
-solution of sulphate of iron in water, and that the blue colour was
-the consequence of the brandy having been kept in oak casks, and thus
-having dissolved a portion of tannin. Every spirit will exhibit the
-same colour, if it has been kept in oak casks.
-
-3. De salibus alkalino-fixis.
-
-4. De camphora thymi.
-
-5. De ambragrysea.
-
-His other papers, published in Germany, are the following:
-
-
-In the Ephemerides.
-
-1. De oleo distillato formicorum æthereo.
-
-2. De albumine ovi succino simili.
-
-
-In the Miscellania Berolinensia.
-
-1. Meditationes in binas observationes de aqua per putrefactionem
-rubra, vulgo pro tali in sanguinem versa habita.
-
-2. Succincta relatio exactis Pomeraniis de prodigio sanguinis in palude
-viso.
-
-3. De prodigio sanguinis ex Pomeranio nunciato.
-
-4. Disquisitio de camphora.
-
-5. De experimento probandi spiritum vini Gallicum.
-
-6. De spiritu urinoso caustico.
-
-7. Demonstratio syrupum violarum ad probanda liquida non sufficere.
-
-8. Examen correctionis olei raparum.
-
-9. De vi caustica et conversione salium alkalino-fixorum aëri
-expositorum in salia neutra.
-
-
-He published separately,
-
-1. De salibus alkalino-fixis et camphora.
-
-2. De succino, opio, caryophyllis aromaticis et castoreo.
-
-3. On saltpetre, sulphur, antimony, and iron.
-
-4. On tea, coffee, beer, and wine.
-
-5. Disquisitio de ambragrysea.
-
-6. On common salt, tartar, sal ammoniac and ants.
-
-After Neumann’s death, two copies of his chemical lectures were
-published. The first consisting of notes taken by one of his pupils,
-intermixed with incoherent compilations from other authors, was printed
-at Berlin in 1740. The other was printed by the booksellers of the
-Orphan Hospital of Zullichau (the place of Neumann’s birth), and is
-said to have been taken from the original papers in the author’s
-handwriting. Of this last an excellent translation, with many additions
-and corrections, was published by Dr. Lewis, in London, in the year
-1759; it was entitled, “The Chemical Works of Caspar Neumann, M.D.,
-Professor of Chemistry at Berlin, F.R.S., &c. Abridged and methodized;
-with large additions, containing the later discoveries and improvements
-made in Chemistry, and the arts depending thereon. By William
-Lewis, M.B., F.R.S. London, 1759.” This is an excellent book, and
-contains many things that still retain their value, notwithstanding
-the improvements which have been made since in every department of
-chemistry.
-
-I have reason to believe that the laborious part of this translation
-and compilation was made by Mr. Chicholm, whom Dr. Lewis employed as
-his assistant. Mr. Chicholm, when a young man, went to London from
-Aberdeen, where he had studied at the university, and acquired a
-competent knowledge of Greek and Latin, but no means of supporting
-himself. On his arrival in London, one of the first things that
-struck his attention was a Greek book, placed open against the pane
-of a bookseller’s window. Chicholm went up to the window, at which
-he continued standing till he had perused the whole Greek page thus
-exposed to his view. Dr. Lewis happened to be in the shop: he had
-been looking out for a young man whom he could employ to take charge
-of his laboratory, and manage his processes, and who should possess
-sufficient intelligence to read chemical works for him, and collect
-out of each whatever deserved to be known, either from its novelty
-or ingenuity. The appearance and manners of Chicholm struck him, and
-made him think of him as a man likely to answer the purposes which he
-had in view. He called him into the shop, and after some conversation
-with him, took him home, and kept him all his life as his assistant
-and operator. Chicholm was a laborious and painstaking man, and by
-continually working in Lewis’s laboratory, soon acquired a competent
-knowledge of chemistry. He compiled several manuscript volumes, partly
-consisting of his own experiments, and partly of collections from other
-authors. At Dr. Lewis’s death, all his books were sold by auction, and
-these manuscript volumes among the rest. They were purchased by Mr.
-Wedgewood, senior, who at the same time took Mr. Chicholm into his
-service, and gave him the charge of his own laboratory. It was Mr.
-Chicholm that was the constructor of the well-known piece of apparatus
-known by the name of Wedgewood’s pyrometer. After his death the
-instrument continued still to be constructed for some time; but so many
-complaints were made of the unequal contraction of the pieces, that
-Mr. Wedgewood, junior, who had succeeded to the pottery in consequence
-of the death of his father, put an end to the manufacture of them
-altogether.
-
-John Henry Pott was born at Halberstadt, in the year 1692. He was a
-scholar of Hoffmann and Stahl, and from this last he seems to have
-imbibed his taste for chemistry. He settled at Berlin, where he became
-assessor of the Royal College of Medicine and Surgery, inspector of
-medicines, superintendent of the Royal Laboratory, and dean of the
-Academy of Sciences of Berlin. He was chosen professor of theoretical
-chemistry at Berlin; and on the death of Neumann, in 1737, he succeeded
-him as professor of practical chemistry. He was beyond question the
-most learned and laborious chemist of his day. His erudition, indeed,
-was very great; and his historical introductions to his dissertation
-displays the extent of his reading on every subject of which he
-had occasion to treat. It has often struck me that the historical
-introductions which Bergmann has prefixed to his papers, are several
-of them borrowed from Pott. The Lithogeognosia of Pott is one of the
-most extraordinary productions of the age in which he lived. It was the
-result of a request of the King of Prussia, to discover the ingredients
-of which Saxon porcelain was made. Mr. Pott, not being able to procure
-any satisfactory information relative to the nature of the substances
-employed at Dresden, resolved to undertake a chemical examination
-of all the substances that were likely to be employed in such a
-manufacture. He tried the effect of fire upon all the stones, earths,
-and minerals, that he could procure, both separately and mixed together
-in various proportions. He made at least thirty thousand experiments
-in six years, and laid the foundation for a chemical knowledge of these
-bodies.[181] It is to this work of Pott that we are indebted for our
-knowledge of the effects of heat upon various earthy bodies, and upon
-mixtures of them. Thus he found that pure white clay, or mixtures of
-pure clay and quartz-sand, would not fuse at any temperature which he
-could produce; but clay, mixed with lime or with oxide of iron, enters
-speedily into fusion. Clay also fuses with its own weight of borax; it
-forms a compact mass with half its weight, and does not concrete into
-a hard body when mixed with a third of its weight of that salt. Clay
-fuses easily with fluor spar; it fuses, also, with twice its weight of
-protoxide of lead, and with its own weight of sulphate of lime, but
-with no other proportion tried. It was a knowledge of these mutual
-actions of bodies on each other, when exposed to heat, that gradually
-led to the methods of examining minerals by the blowpipe. These methods
-were brought to the present state of perfection by Assessor Gahn, of
-Fahlun, the result of whose labours has been published by Berzelius, in
-his treatise on the blowpipe. Pott died in 1777, in the eighty-fifth
-year of his age.
-
-[181] There is a French translation of this work, entitled
-“Litheognosie, ou Examen Chymique des Pierres et des Terres en
-général, et du Talc de la Topaz, et de la Steatite en particulier;
-avec une Dissertation sur le Feu et sur la Lumière.” Paris, 1753.
-With a continuation, constituting a second volume, in which all the
-experiments in the first volume are exhibited in the form of tables.
-
-His different chemical works (his Lithogeognosia excepted) were
-collected and translated into French by M. Demachy, in the year 1759,
-and published in four small octavo volumes. The chemical papers
-contained in these volumes are thirty-two in number. Some of these
-papers cannot but appear somewhat extraordinary to a modern chemist:
-for example, M. Duhamel had published in the memoirs of the French
-Academy, in the year 1737, a set of experiments on common salt, from
-which he deduced that its basis was a fixed alkali, which possessed
-properties different from those of potash, and which of course required
-to be distinguished by a peculiar name. It is sufficiently known that
-the term _soda_ was afterwards applied to this alkali; by which name it
-is known at present. Pott, in a very elaborate and long dissertation
-on the base of common salt, endeavours to refute these opinions
-of Duhamel. The subject was afterwards taken up by Margraaf, who
-demonstrated, by decisive experiments, that the base of common salt is
-_soda_; and that soda differs essentially in its properties from potash.
-
-Pott’s dissertation on _bismuth_ is of considerable value. He collects
-in it the statements and opinions of all preceding writers on this
-metal, and describes its properties with considerable accuracy and
-minuteness. The same observations apply to his dissertation on zinc.
-
-John Theodore Eller, of Brockuser, was born on the 29th of November,
-1689, at Pletzkau, in the principality of Anhalt Bernburg. He was
-the fourth son of Jobst Hermann Eller, a man of a respectable
-family, whose ancestors were proprietors of considerable estates in
-Westphalia and the Netherlands. Young Eller received the rudiments
-of his education in his father’s house, from which he went to the
-University of Quedlinburg; and from thence to the University of Jena,
-in 1709. He was sent thither to study law; but his passion was for
-natural philosophy, which led him to devote himself to the study of
-medicine. From Jena he went to Halle, and finally to Leyden, attracted
-by the reputation of the older Albinus, of Professor Sengerd and the
-celebrated Boerhaave, at that time in the height of his reputation.
-The only practical anatomist then in Leyden, was M. Bidloo, an old man
-of eighty, and of course unfit for teaching. This induced Eller to
-repair to Amsterdam, to study under Rau, and to inspect the anatomical
-museum of Ruysch. Bidloo soon dying, Rau was appointed his successor
-at Leyden, whither Eller followed him, and dissected under him till
-the year 1716. After taking his degree at Leyden, Eller returned to
-Germany, and devoted a considerable time to the study and examination
-of the mines of Saxony and the Hartz, and of the metallurgic processes
-connected with these mines. From these mines he repaired to France, and
-resumed his anatomical studies under Du Verney and Winslow. Chemistry
-also attracted a good deal of his attention, and he frequented the
-laboratories of Grosse, Lemery, Bolduc, and Homberg, at that time the
-most eminent chemists in Paris.
-
-From Paris he repaired to London, where he formed an acquaintance with
-the numerous medical men of eminence who at that time adorned this
-capital. On returning to Germany in 1721, he was appointed physician
-to Prince Victor Frederick of Anhalt Bernburg. From Bernburg he
-went to Magdeburg; and the King of Prussia called him to Berlin in
-1724, to teach anatomy in the great anatomic theatre which had been
-just erected. Soon after he was appointed physician to the king, a
-counsellor and professor in the Royal Medico-Chirurgical College,
-which had been just founded in Berlin. He was also appointed dean of
-the Superior College of Medicine, and physician to the army and to
-the great Hospital of Frederick. In the year 1755 Frederick the Great
-made him a privy-counsellor, which is the highest rank that a medical
-man can attain in Prussia. The same year he was made director of the
-Royal Academy of Sciences of Berlin. He died in the year 1760, in the
-seventy-first year of his age. He was twice married, and his second
-wife survived him.
-
-Many chemical papers of Eller are to be found in the memoirs of the
-Berlin Academy. They were of sufficient importance, at the time when
-he published them, to add considerably to his reputation, though not
-sufficiently so to induce me to give a catalogue of them here. I am
-not aware of any chemical discovery for which we are indebted to him;
-but have been induced to give this brief notice of him, because he is
-usually associated with Pott and Margraaf, making with them the three
-celebrated chemists who adorned Berlin, during the splendid reign of
-Frederick the Great.
-
-Andrew Sigismund Margraaf was born in Berlin, in the year 1709, and
-acquired the first principles of chemistry from his father, who was
-an apothecary in that city. He afterwards studied under Neumann, and
-travelling in quest of information to Frankfort, Strasburg, Halle, and
-Freyburg, he returned to Berlin enriched with all the knowledge of his
-favourite science which at that time existed. In 1760, on the death
-of Eller, he was made director of the physical class of the Berlin
-Academy of Sciences. He died in the year 1782, in the seventy-third
-year of his age. He gradually acquired a brilliant reputation in
-consequence of the numerous chemical papers which he successively
-published, each of which usually contained a new chemical fact, of
-more or less importance, deduced from a set of experiments generally
-satisfactory and convincing. His papers have a greater resemblance
-to those of Scheele than of any other chemist to whom we can compare
-them. He may be considered as in some measure the beginner of chemical
-analysis; for, before his time, the chemical analysis of bodies had
-hardly been attempted. His methods, as might have been expected,
-were not very perfect; nor did he attempt numerical results. His
-experiments on phosphorus and on the method of extracting it from urine
-are valuable; they communicated the first accurate notions relative
-to this substance and to phosphoric acid. He first determined the
-properties of the earth of alum, now known by the name of _alumina_;
-showed that it differed from every other, and that it existed in clay,
-and gave to that substance its peculiar properties. He demonstrated
-the peculiar nature of soda, the base of common salt, which Pott had
-called in question, and thus verified the conclusions of Duhamel. He
-gives an easy process for obtaining pure silver from the chloride of
-that metal: his method is to dissolve the pure chloride of silver in a
-solution of caustic ammonia, and to put into the liquid a sufficient
-quantity of pure mercury; the silver is speedily reduced and converted
-into an amalgam, and when this amalgam is exposed to a red heat the
-mercury is driven off and pure silver remains. The usual method of
-reducing the chloride of silver is to heat it in a crucible with a
-sufficient quantity of carbonate of potash, a process which was first
-recommended by Kunkel. But it is scarcely possible to prevent the loss
-of a portion of the silver when the chloride is reduced in this way.
-The modern process is undoubtedly the simplest and the best, to reduce
-it by means of hydrogen. If a few pieces of zinc be put into the bottom
-of a beer-glass and some dilute sulphuric acid be poured over it an
-effervescence takes place, and hydrogen gas is disengaged. Chloride of
-silver, placed above the zinc in the same glass, is speedily reduced by
-this hydrogen and converted into metallic silver.
-
-Margraaf’s chemical papers, down to the time of publication, were
-collected together, translated into French and published at Paris
-in the year 1762, in two very small octavo volumes, they consist of
-twenty-six different papers: some of the most curious and important
-of which are those that have been just particularized. Several other
-papers written by him appeared in the memoirs of the Berlin Academy,
-after this collection of his works was published, particularly “A
-demonstration of the possibility of drawing fixed alkaline salts
-from tartar by means of acids, without employing the action of a
-violent fire.” It was this paper, probably, that led Scheele, a few
-years after, to his well-known method of obtaining tartaric acid, a
-modification of which is still followed by manufacturers.
-
-“Observations concerning a remarkable volatilization of a portion of
-a kind of stone known by the names of flosse, flusse, fluor spar, and
-likewise by that of hesperos: which volatilization was effectuated by
-means of acids.” Pott had already shown the value of fluor spar as a
-flux. Three years after the appearance of Margraaf’s paper, Scheele
-discovered the nature of fluor spar, and first drew the attention of
-chemists to the peculiar properties of fluoric acid.
-
-In France, in consequence chiefly of the regulations established in
-the Academy of Sciences, in the year 1699, a race of chemists always
-existed, whose specific object was to cultivate chemistry, and extend
-and improve it. The most eminent of these chemical labourers, after the
-Stahlian theory was fully admitted in France till its credit began to
-be shaken, were Reaumur, Hellot, Duhamel, Rouelle, and Macquer. Besides
-these, who were the chief chemists in the academy, there were a few
-others to whom we are indebted for chemical discoveries that deserve to
-be recorded.
-
-René Antoine Ferchault, Esq., Seigneur de Reaumur, certainly one of the
-most extraordinary men of his age, was born at Rochelle, in 1683. He
-went to the school of Rochelle, and afterwards studied philosophy under
-the Jesuits at Poitiers. Hence he went to Bourges, to which one of his
-uncles, canon of the holy chapel in that city, had invited him. At this
-time he was only seventeen years of age, yet his parents ventured to
-intrust a younger brother to his care, and this care he discharged
-with all the fidelity and sagacity of a much older man. Here he devoted
-himself to mathematics and physics, and he soon after went to Paris to
-improve the happy talents which he had received from nature. He was
-fortunate enough to meet with a friend and relation in the president,
-Henault, equally devoted to study with himself, equally eager for
-information, and possessed of equal honour and integrity, and equally
-promising talents.
-
-He came to Paris in 1703. In 1708 he was admitted into the Academy of
-Sciences, in the situation of _élève_ of M. Varignon, vacant by the
-promotion of M. Saurin to the rank of associate.
-
-The first papers of his which were inserted in the Memoirs of the
-Academy were geometrical: he gave a general method of finding an
-infinity of curves, described by the extremity of a straight line,
-the other extremity of which, passing along the surface of a given
-curve, is always obliged to pass through the same point. Next year he
-gave a geometrical work on Developes; but this was the last of his
-mathematical tracts. He was charged by the academy with the task of
-giving a description of the arts, and his taste for natural history
-began to draw to that study the greatest part of his attention. His
-first work as a naturalist was his observations on the formation of
-shells. It was unknown whether shells increase by intussusception, like
-animal bodies, or by the exterior and successive addition of new parts.
-By a set of delicate observations he showed that shells are formed by
-the addition of new parts, and that this was the cause of the variety
-of colour, shape, and size which they usually affect. His observations
-on snails, with a view to the way in which their shells are formed,
-led him to the discovery of a singular insect, which not only lives on
-snails, but in the inside of their bodies, from which it never stirs
-till driven out by the snail.
-
-During the same year, he wrote his curious paper on the silk of
-spiders. The experiments of M. Bohn had shown that spiders could spin
-a silk that might be usefully employed. But it remained to be seen
-whether these creatures could be fed with profit, and in sufficiently
-great numbers to produce a sufficient quantity of silk to be of use.
-Reaumur undertook this disagreeable task, and showed that spiders could
-not be fed together without attacking and destroying one another.
-
-The next research which he undertook, was to discover in what way
-certain sea-animals are capable of attaching themselves to fixed
-bodies, and again disengaging themselves at pleasure. He discovered the
-various threads and pinnæ which some of them possess for this purpose,
-and the prodigious number of limbs by which the sea-star is enabled to
-attach itself to solid bodies. Other animals employ a kind of cement
-to glue themselves to those substances to which they are attached,
-while some fix themselves by forming a vacuum in the interval between
-themselves and the solid substances to which they are attached.
-
-It was at this period that he found great quantities of the buccinum,
-which yielded the purple dye of the ancients, upon the coast of Poitou.
-He observed, also, that the stones and little sandy ridges round which
-the shellfish had collected were covered with a kind of oval grains,
-some of which were white, and others of a yellowish colour, and having
-collected and squeezed some of these upon the sleeve of his shirt, so
-as to wet it with the liquid which they contained, he was agreeably
-surprised in about half an hour to find the wetted spot assume a
-beautiful purple colour, which was not discharged by washing. He
-collected a number of these grains, and carrying them to his apartment,
-bruised and squeezed different parcels of them upon bits of linen; but
-to his great surprise, after two or three hours, no colour appeared
-on the wetted part; but, at the same time, two or three spots of the
-plaster at the window, on which drops of the liquid had fallen, had
-become purple; though the day was cloudy. On carrying the pieces
-of linen to the window, and leaving them there, they also acquired
-a purple colour. It was the action of light, then, on the liquor,
-that caused it to tinge the linen. He found, likewise, that when the
-colouring matter was put into a phial, which filled it completely, it
-remained unchanged; but when the phial was not full, and was badly
-corked, it acquired colour. From these facts it is evident, that the
-purple colour is owing to the joint action of the light and the oxygen
-of the atmosphere upon the liquor of the shellfish.
-
-About this time, likewise, he made experiments upon a subject which
-attracted the attention of mechanicians--to determine whether the
-strength of a cord was greater, or less, or equal to the joint strength
-of all the fibres which compose it. The result of Reaumur’s experiments
-was, that the strength of the cord is less than that of all the fibres
-of which it is composed. Hence it follows, that the less that a cord
-differs from an assemblage of straight fibres, the stronger it is.
-This, at that time considered as a singular mechanical paradox, was
-afterwards elucidated by M. Duhamel.
-
-It was a popular opinion of all the inhabitants of the sea-shore, that
-when the claws of crabs, lobsters, &c., are lost by any means, they are
-gradually replaced by others, and the animal in a short time becomes as
-perfect as at first. This opinion was ridiculed by men of science as
-inconsistent with all our notions of true philosophy. Reaumur subjected
-it to the test of experiment, by removing the claws of these animals,
-and keeping them alone for the requisite time in sea-water: new claws
-soon sprang out, and perfectly replaced those that had been removed.
-Thus the common opinion was verified,and the contemptuous smile of the
-half-learned man of science was shown to be the result of ignorance,
-not of knowledge.
-
-Reaumur was not so fortunate in his attempts to explain the nature of
-the shock given by the torpedo; which we now know to be an electric
-shock produced by a peculiar apparatus within the animal. Reaumur
-endeavoured to prove, from dissection, that the shock was owing to the
-prodigious rapidity of the blow given by the animal in consequence of a
-peculiar structure of its muscles.
-
-The turquoise was at that time, as it still is, considerably admired in
-consequence of the beauty of its colour. Persia was the country from
-which this precious stone came, and it was at that time considered as
-the only country in the universe where it occurred. Reaumur made a set
-of experiments on the subject and showed that the fossil bones found in
-Languedoc, when exposed to a certain heat, assume the same beautiful
-green colour, and become turquoises equally beautiful with the Persian.
-It is now known, that the true Persian turquoise, the _calamite_
-of mineralogists, is quite different from fossil bones coloured
-with copper. So far, therefore, Reaumur deceived himself by these
-experiments; but at that time chemical knowledge was too imperfect to
-enable him to subject Persian turquoise to an analysis, and determine
-its constitution.
-
-About the same period, he undertook an investigation of the nature
-of imitation pearls, which resemble the true pearls so closely, that
-it is very difficult, from appearances, to distinguish the true from
-the false. He showed that the substance which gave the false pearls
-their colour and lustre, was taken from a small fish called by the
-French _able_, or _ablette_. He likewise undertook an investigation
-of the origin of true pearls, and showed that they were indebted for
-their production to a disease of the animal. It is now known, that
-the introduction of any solid body, as a grain of sand, within the
-shell of the living pearl-shellfish, gives occasion to the formation
-of pearl. Linnæus boasted that he knew a method of forming artificial
-pearls; and doubtless his process was merely introducing some solid
-particle of matter into the living shell. Pearls consist of alternate
-layers of carbonate of lime and animal membrane; and the colour and
-lustre to which they owe their value depends upon the thinness of the
-alternate coats.
-
-The next paper of Reaumur was an account of the rivers in France
-whose sand yielded gold-dust, and the method employed to extract the
-gold. This paper will well repay the labour of a perusal; it owes its
-interest in a great measure to the way in which the facts are laid
-before the reader.
-
-His paper on the prodigious bank of fossil shells at Touraine, from
-which the inhabitants draw manure in such quantities for their fields,
-deserves attention in a geological point of view. But his paper on
-flints and stones is not so valuable; it consists in speculations,
-which, from the infant state of chemical analysis when he wrote, could
-not be expected to lead to correct conclusions.
-
-I pass over many of the papers of this most indefatigable man, because
-they are not connected with chemistry; but his history of insects
-constitutes a charming book, and contains a prodigious number of facts
-of the most curious and important nature. This book alone, supposing
-Reaumur had done nothing else, would have been sufficient to have
-immortalized the author.
-
-In the year 1722 he published his work on the _art of converting iron
-into steel, and of softening cast-iron_. At that time no steel whatever
-was made in France; the nation was supplied with that indispensable
-article from foreign countries, chiefly from Germany. The object of
-Reaumur’s book was to teach his countrymen the art of making steel,
-and, if possible, to explain the nature of the process by which iron
-is changed into steel. Reaumur concluded from his experiments, that
-steel is iron impregnated with _sulphureous_ and _saline_ matters. The
-word _sulphureous_, as at that time used, was nearly synonymous with
-our present term _combustible_. The process which he found to answer,
-and which he recommends to be followed, was to mix together
-
-  4 parts of soot
-  2 parts of charcoal-powder
-  2 parts of wood-ashes
-  1½ parts of common salt.
-
-The iron bars to be converted into steel were surrounded with this
-mixture, and kept red-hot till converted into steel. Reaumur’s notion
-of the difference between iron and steel was an approximation to
-the truth. The saline matters which he added do not enter into the
-composition of steel; and if they did, so far from improving, they
-would injure its qualities. But the charcoal and soot, which consist
-chiefly of carbon, really produce the desired effect; for steel is a
-combination of _iron_ and _carbon_.
-
-In consequence of these experiments of Reaumur, it came to be an
-opinion entertained by chemists, that steel differed from iron merely
-by containing a greater proportion of phlogiston; for the charcoal
-and soot with which the iron bars were surrounded was considered as
-consisting almost entirely of phlogiston; and the only useful purpose
-which they could serve, was supposed to be to furnish phlogiston. This
-opinion continued prevalent till it was overturned towards the end of
-the last century, first by the experiments of Bergmann, and afterwards
-by those of Berthollet, Vandermond, and Monge, published in the Memoirs
-of the French Academy for 1786 (page 132). In this elaborate memoir the
-authors take a view of all the different processes followed in bringing
-iron from the ore to the state of steel: they then give an account of
-the researches of Reaumur and of Bergmann; and lastly relate their own
-experiments, from which they finally draw, as a conclusion, that steel
-is a compound of iron and carbon.
-
-The regent Orleans, who at that time administered the affairs of
-France, thought that this work of Reaumur was deserving a reward, and
-accordingly offered him a pension of 12,000 livres. Reaumur requested
-of the regent that this pension should be given in the name of the
-academy, and that after his death it should continue, and be devoted to
-defray the necessary expenses towards bringing the arts into a state of
-perfection. The request was granted, and the letters patent made out on
-the 22d of December, 1722.
-
-At that time tin-plate, as well as steel, was not made in France;
-but all the tin-plates wanted were brought from Germany, where the
-processes followed were kept profoundly secret. Reaumur undertook to
-discover a method of tinning iron sufficiently cheap to admit the
-article to be manufactured in France--and he succeeded. The difficulty
-consisted in removing the scales with which the iron plates, as
-prepared, were always covered. These scales consist of a vitrified
-oxide of iron, to which the tin will not unite. Reaumur found, that
-when these plates are steeped in water acidulated by means of bran,
-and then allowed to rust in stoves, the scales become loose, and are
-easily detached by rubbing the plates with sand. If after being thus
-cleansed they are plunged into melted tin, covered with a little tallow
-to prevent oxidizement, they are easily tinned. In consequence of this
-explanation of the process by Reaumur, tin-plate manufactories were
-speedily established in different parts of France. It was about the
-same time, or only a little before it, that tin-plate manufactories
-were first started in England. The English tin-plate was much more
-beautiful than the German, and therefore immediately preferred to it;
-because in Germany the iron was converted into plates by hammering,
-whereas in England it was rolled out. This made it much smoother, and
-consequently more beautiful.
-
-Another art, at that time unknown in France, and indeed in every part
-of Europe except Saxony, was the art of making porcelain, a name given
-to the beautiful translucent stoneware which is brought from China and
-Japan. Reaumur undertook to discover the process employed in making
-it. He procured specimens of porcelain from China and Japan, and also
-of the imitations of those vessels at that time made in various parts
-of France and other European countries. The true porcelain remained
-unaltered, though exposed to the most violent heat which he was capable
-of producing; but the imitations, in a furnace heated by no means
-violently, melted into a perfect glass. Hence he concluded, that the
-imitation-porcelains were merely glass, not heated sufficiently to be
-brought into fusion; but true porcelain he conceived to be composed
-of two different ingredients, one of which is capable of resisting
-the most violent heat which can be raised, but the other, when heated
-sufficiently, melts into a glass. It is this last ingredient that gives
-porcelain its translucency, while the other makes it refractory in
-the fire. This opinion of Reaumur was soon after confirmed by Father
-d’Entrecolles, a French missionary in China, who sent some time after
-a memoir to the academy, describing the mode followed by the Chinese
-in the manufactory of their porcelain. Two substances are employed
-by them, the one called _kaolin_ and the other _petunse_. It is now
-known that _kaolin_ is what we call porcelain-clay, and that _petunse_
-is a fine white felspar. Felspar is fusible in a violent heat, but
-porcelain-clay is refractory in the highest temperatures that we have
-it in our power to produce in furnaces.
-
-Reaumur made another curious observation on glass, which has been,
-since his time, employed very successfully to explain the appearances
-of many of our trap-rocks. If a glass vessel, properly secured in
-sand, be raised to a red heat, and then allowed to cool very slowly,
-it puts off the appearance of glass and assumes that of stoneware, or
-porcelain. Vessels thus altered have received the name of _Reaumur’s
-porcelain_. They are much more refractory than glass, and therefore
-may be exposed to a pretty strong red heat without any danger of
-softening or losing their shape. This change is occasioned by the
-glass being kept long in a soft state: the various substances of
-which it is composed are at liberty to exercise their affinities
-and to crystallize. This makes the vessel lose its glassy structure
-altogether. In like manner it was found by Sir James Hall and Mr.
-Gregory Watt, that when common greenstone was heated sufficiently,
-and then rapidly cooled, it melted and concreted into a glass; but if
-after having been melted it was allowed to cool exceedingly slowly, the
-constituents again crystallized and arranged themselves as at first--so
-that a true greenstone was again formed. In the same way lavas from a
-volcano either assume the appearance of slag or of stone, according as
-they have cooled rapidly or slowly. Many of the lavas from Vesuvius
-cannot be distinguished from our _greenstones_.
-
-Reaumur’s labours upon the thermometer must not be omitted here;
-because he gave his name to a thermometer, which was long used in
-France and in other parts of Europe. The first person that brought
-thermometers into a state capable of being compared with each other
-was Sir Isaac Newton, in a paper published in the Philosophical
-Transactions for 1701. Fahrenheit, of Amsterdam, was the first person
-that put Newton’s method in practice, by fixing two points on his
-scale, the freezing-water point and the boiling-water point, and
-dividing the interval between them into one hundred and eighty degrees.
-
-But no fixed point existed in the thermometers employed in France,
-every one graduating them according to his fancy; so that no two
-thermometers could be compared together. Reaumur graduated his
-thermometers by plunging them into freezing water or a mixture of
-snow and water. This point was marked zero, and was called the
-freezing-water point. The liquid used in his thermometers was spirit
-of wine: he took care that it should be always of the same strength,
-and the interval between the point of freezing and boiling water
-was divided into eighty degrees. Deluc afterwards rectified this
-thermometer, by substituting mercury for spirit of wine. This not only
-enabled the thermometer to be used to measure higher temperatures,
-but corrected an obvious error which existed in all the thermometers
-constructed upon Reaumur’s principle: for spirit of wine cannot bear
-a temperature of eighty degrees Reaumur without being dissipated
-into vapour--absolute alcohol boiling at a hundred and sixty-two
-degrees two-thirds. It is obvious from this, that the boiling point in
-Reaumur’s thermometer could not be accurate, and that it would vary,
-according to the quantity of empty space left above the alcohol.
-
-Finally, he contrived a method of hatching chickens by means of
-artificial heat, as is practised in Egypt.
-
-We are indebted to him also for a set of important observations on the
-organs of digestion in birds. He showed, that in birds of prey, which
-live wholly upon animal food, digestion is performed by solvents in
-the stomach, as is the case with digestion in man: while those birds
-that live upon vegetable food have a very powerful stomach or gizzard,
-capable of triturating the seeds which they swallow. To facilitate this
-triturating process, these fowls are in the habit of swallowing small
-pebbles.
-
-The moral qualities of M. Reaumur seem not to have been inferior to the
-extent and variety of his acquirements. He was kind and benevolent, and
-remarkably disinterested. He performed the duties of intendant of the
-order of St. Louis from the year 1735 till his death, without accepting
-any of the emoluments of the office, all of which were most religiously
-given to the person to whom they belonged, had she been capable of
-performing the duties of the place. M. Reaumur died on the 17th of
-October, 1756, after having lived very nearly seventy-five years.
-
-John Hellot was born in Paris in the year 1685, on the 20th of
-November. His father, Michael Hellot, was of a respectable family, and
-the early part of his son’s education was at home: it seems to have
-been excellent, as young Hellot acquired the difficult art of writing
-on all manner of subjects in a precise, clear, and elegant style. His
-father intended him for the church; but his own taste led him decidedly
-to the study of chemistry. He had an uncle a physician, some of whose
-papers on chemical subjects fell into his hands. This circumstance
-kindled his natural taste into a flame: he formed an acquaintance with
-M. Geoffroy, whose reputation as a chemist was at that time high, and
-this friendship was afterwards cemented by Geoffroy marrying the niece
-of M. Hellot.
-
-His circumstances being easy, he went over to England, to form a
-personal acquaintance with the many eminent philosophers who at that
-time adorned that country. His fortune was considerably deranged by
-Law’s celebrated scheme during the regency of the Duke of Orleans. This
-obliged him to look out for some resource: he became editor of the
-Gazette de France, and continued in this employment from 1718 to 1732.
-During these fourteen years, however, he did not neglect chemistry,
-though his progress was not so rapid as it would have been, could he
-have devoted to that science his undivided attention. In 1732 he was
-put forward by his friends as a candidate for a place in the Academy of
-Sciences; and in the year 1735 he was chosen adjunct chemist, vacant by
-the promotion of M. de la Condamine to the place of associate. Three
-years after he was declared a supernumerary pensioner, without passing
-through the step of associate. His reputation as a chemist was already
-considerable, and after he became a member of the academy, he devoted
-himself to the investigations connected with his favourite science.
-
-His first labours were on zinc; in two successive papers he endeavoured
-to decompose this metal, and to ascertain the nature of its
-constituents. Though his labour was unsuccessful, yet he pointed out
-many new properties of this metal, and various new compounds into which
-it enters. Neither was he more successful in his attempt to account for
-the origin of the red vapours which are exhaled from nitre in certain
-circumstances. He ascribed them to the presence of ferruginous matters
-in the nitre; whereas they are owing to the expulsion and partial
-decomposition of the nitric acid of the nitre, in consequence of the
-action of some more powerful acid.
-
-His paper on sympathetic ink is of more importance. A German chemist
-had shown him a saline solution of a red colour which became blue when
-heated: this led him to form a sympathetic ink, which was pale red,
-while the paper was moist, but became blue upon drying it by holding it
-to the fire. This sympathetic ink was a solution of cobalt in muriatic
-acid. It does not appear from Hellot’s paper that he was exactly aware
-of the chemical constitution of the liquid which constituted his
-sympathetic ink; though it is clear he knew that cobalt constitutes an
-essential part of it.
-
-Kunkel’s phosphorus, though it had been originally discovered in
-Germany, could not be prepared by any of the processes which had been
-given to the public. Boyle had taught his operator, Godfrey Hankwitz,
-the method of making it. This man had, after Boyle’s death, opened a
-chemist’s shop in London, and it was he that supplied all Europe with
-this curious article: on that account it was usually distinguished
-by the name of _English phosphorus_. But in the year 1737 a stranger
-appeared in Paris, who offered for a stipulated reward to communicate
-the method of manufacturing this substance to the Academy of Sciences.
-The offer was accepted by the French government, and a committee of
-the academy, at the head of which was Hellot, was appointed to witness
-the process, and ascertain all its steps. The process was repeated
-with success; and Hellot drew up a minute detail of the whole, which
-was inserted in the Memoirs of the Academy, for the year 1737. The
-publication of this paper constitutes an era in the preparation of
-phosphorus: it was henceforward in the power of every chemist to
-prepare it for himself. A few years after the process was much improved
-by Margraaf; and, within little more than twenty years after, the very
-convenient process still in use was suggested by Scheele. Hellot’s
-experiments on the comparative merits of the salts of Peyrac, and of
-Pecais were of importance, because they decided a dispute--they may
-also perhaps be considered as curiosities in an historical point of
-view; because we see from them the methods which Hellot had recourse to
-at that early period in order to determine the purity of common salt.
-They are not entitled, however, to a more particular notice here.
-
-In the year 1740 M. Hellot was charged with the general inspection of
-dyeing; a situation which M. du Foy had held till the time of his death
-in 1739. It was this appointment, doubtless, which turned his attention
-to the theory of dyeing, which he tried to explain in two memoirs read
-to the academy in 1740 and 1741. The subject was afterwards prosecuted
-by him in subsequent memoirs which were published by the academy.
-
-In 1745 he was named to go to Lyons in order to examine with care the
-processes followed for refining gold and silver. Before his return
-he took care to give to these processes the requisite precision and
-exactness. Immediately after his return to Paris he was appointed to
-examine the different mines and assay the different ores in France;
-this appointment led him to turn his thoughts to the subject. The
-result of this was the publication of an excellent work on assaying
-and metallurgy, entitled “De la Fonte des Mines, des Fonderies, &c.
-Traduit de l’Allemand de Christophe-André Schlutter.” The first volume
-of this book appeared in 1750, and the second in 1753. Though this book
-is called by Hellot a translation, it contains in fact a great deal
-of original matter; the arrangement is quite altered; many processes
-not noticed by Schlutter are given, and many essential articles are
-introduced, which had been totally omitted in the original work. He
-begins with an introduction, in which he gives a short sketch of all
-the mines existing in every part of France, together with some notice
-of the present state of each. The first volume treats entirely of
-docimasy, or the art of assaying the different metallic ores. Though
-this art has been much improved since Hellot’s time, yet the processes
-given in this volume are not without their value. The second volume
-treats of the various metallurgic processes followed in order to
-extract metals from their ores. This volume is furnished with no fewer
-than fifty-five plates, in which all the various furnaces, &c. used in
-these processes are exhibited to the eye.
-
-While occupied in preparing this work for the press he was chosen to
-endeavour to bring the porcelain manufactory at Sevre to a greater
-state of perfection than it had yet reached. In this he was successful.
-He even discovered various new colours proper for painting upon
-porcelain; which contributed to give to this manufactory the celebrity
-which it acquired.
-
-In the year 1763 a phenomenon at that time quite new to France took
-place in the coal-mine of Briançon. A quantity of carburetted hydrogen
-gas had collected in the bottom of the mine, and being kindled by
-the lights employed by the miners, it exploded with great violence,
-and killed or wounded every person in the mine. This destructive gas,
-distinguished in this country by the name of _fire-damp_, had been
-long known in Great Britain and in the Low Countries, though it had
-not before been known in France. The Duke de Choiseul, informed of
-this event, had recourse to the academy for assistance, who appointed
-Messrs. de Montigny, Duhamel, and Hellot, a committee to endeavour
-to discover the remedies proper to prevent any such accident from
-happening for the future. The report of these gentlemen was published
-in the Memoirs of the Academy;[182] they give an account both of the
-fire-damp, and _choke-damp_, or _carbonic acid gas_, which sometimes
-also makes its appearance in coal-mines. They very justly observe
-that the proper way to obviate the inconveniency of these gases is to
-ventilate the mine properly; and they give various methods by which
-this ventilation may be promoted by means of fires lighted at the
-bottom of the shaft, &c.
-
-[182] 1763, p. 235.
-
-In 1763 M. Hellot was appointed, conjointly with M. Tillet, to examine
-the process followed for assaying gold and silver. They showed that the
-cupels always retained a small portion of the silver assayed, and that
-this loss, ascribed to the presence of a foreign metal, made the purity
-of the silver be always reckoned under the truth, which occasioned a
-loss to the proprietor.
-
-His health continued tolerably good till he reached his eightieth year:
-he was then struck with palsy, but partially recovered from the first
-attack; but a second attack, on the 13th of February, 1765, refused
-to yield to every medical treatment, and he died on the 15th of that
-month, at an age a little beyond eighty.
-
-Henry Louis Duhamel du Monceau was born at Paris in the year 1700.
-He was descended from Loth Duhamel, a Dutch gentleman, who came to
-France in the suite of the infamous Duke of Burgundy, about the year
-1400. Young Duhamel was educated in the College of Harcourt; but the
-course of study did not suit his taste. He left it with only one fact
-engraven on his memory--that men, by observing nature, had created a
-science called _physics_; and he resolved to profit by his freedom
-from restraint and turn the whole of his attention to that subject. He
-lodged near the Jardin du Roi, where alone, at that time, physics were
-attended to in Paris. Dufoy, Geoffroy, Lemery, Jussieu, and Vaillant,
-were the friends with whom he associated on coming to Paris. His
-industry was stimulated solely by a love of study, and by the pleasure
-which he derived from the increase of knowledge; love of fame does not
-appear to have entered into his account.
-
-In the year 1718 saffron, which is much cultivated in that part of
-France formerly distinguished by the name of Gâtinois, where Duhamel’s
-property lay, was attacked by a malady which appeared contagious.
-Healthy bulbs, when placed in the neighbourhood of those that were
-diseased, soon became affected with the same malady. Government
-consulted the academy on the subject; and this learned body thought
-they could not do better than request M. Duhamel to investigate the
-cause of the disease; though he was only eighteen years of age, and
-not even a member of the academy. He ascertained that the malady was
-owing to a parasitical plant, which attached itself to the bulb of the
-saffron, and drew nourishment from it. This plant extended under the
-earth, from one bulb to another, and thus infected the whole saffron
-plantations.
-
-M. Duhamel formed the resolution at the commencement of his scientific
-career to devote himself to public utility, and to prosecute those
-subjects which were likely to contribute most effectually to the
-comfort of the lower ranks of men. Much of his time was spent in
-endeavouring to promote the culture of vegetables, and in rendering
-that culture more useful to society. This naturally led to a careful
-study of the physiology of trees. The fruit of this study he gave to
-the world in the year 1758, when his Physique des Arbres was published.
-This constitutes one of the most important works on the subject which
-has ever appeared. It contains a great number of new and original
-facts; and contributed very much indeed to advance this difficult, but
-most important branch of science: nor is it less remarkable for modesty
-than for value. The facts gathered from other sources, even those
-which make against his own opinions, are most carefully and accurately
-stated: the experiments that preceded his are repeated and verified
-with much care; and the reader is left to discover the new facts and
-new views of the author, without any attempt on his part to claim them
-as his own.
-
-M. Duhamel had been attached to the department of the marine by M. de
-Maurepas, who had given him the title of _inspector-general_. This led
-him to turn his attention to naval science in general. The construction
-of vessels, the weaving of sailcloths, the construction of ropes and
-cables, the method of preserving the wood, occupied his attention
-successively, and gave birth to several treatises, which, like all
-his works, contain immense collections of facts and experiments. He
-endeavours always to discover which is the best practice, to reduce
-it to fixed rules, and to support it by philosophical principles; but
-abstains from all theory when it can be supported only by hypothesis.
-
-From the year 1740, when he became an academician, till his death
-in 1781, he made a regular set of meteorological observations at
-Pithiviers, with details relative to the direction of the needle, to
-agriculture, to the medical constitution of the year, and to the time
-of nest-building, and of the passage of birds.
-
-Above sixty memoirs of his were published in the Transactions of the
-French Academy of Sciences. They are so multifarious in their nature,
-and embrace such a variety of subjects, that I shall not attempt even
-to give their titles, but satisfy myself with stating such only as bear
-more immediately upon the science of chemistry.
-
-It will be proper in conducting this review to notice the result of
-his labours connected with the ossification of bones; because, though
-not strictly chemical, they throw light upon some branches of the
-animal economy, more closely connected with chemistry than with any
-other of the sciences. He examined, in the first place, whether the
-ossification of bones, and their formation and reparation, did not
-follow the same law that he had assigned to the increments of trees,
-and he established, by a set of experiments, that bones increase by
-the ossification of layers of the periosteum, as trees do by the
-hardening of their cortical layers. Bones in a soft state increase in
-every direction, like the young branches of plants; but after their
-induration they increase only like trees, by successive additions of
-successive layers. This organization was incompatible with the opinion
-of those who thought that bones increased by the addition of an earthy
-matter deposited in the meshes of the organized network which forms
-the texture of bones. M. Duhamel combated this opinion by an ingenious
-experiment. He had been informed by Sir Hans Sloane that the bones
-of young animals fed upon madder were tinged red. He conceived the
-plan of feeding them alternately with food mingled with madder, and
-with ordinary food. The bones of animals thus treated were found to
-present alternate concentric layers of red and white, corresponding
-to the different periods in which the animal had been fed with
-food containing or not containing madder. When these bones are sawn
-longitudinally we see the thickness of the coloured layers, greater or
-less, according to the number of plates of the periosteum that have
-ossified. As for the portions still soft, or susceptible of extending
-themselves in every direction, such as the plates in the neighbourhood
-of the marrow, the reservoir of which increases during a part of the
-time that the animal continues to grow, the red colour marks equally
-the progress of their ossification by coloured points more or less
-extended.
-
-This opinion was attacked by Haller, and defended by M. Fougeroux,
-nephew of M. Duhamel; but it is not our business here to inquire how
-far correct.
-
-One of the most important of M. Duhamel’s papers, which will secure
-his name a proud station in the annals of chemistry, is that which was
-inserted in the Memoirs of the Academy for 1737, in which he shows
-that the base of common salt is a true fixed alkali, different in some
-respects from the alkali extracted from land plants, and known by the
-name of _potash_, but similar to that obtained by the incineration of
-marine plants. We are surprised that a fact so simple and elementary
-was disputed by the French chemists, and rather indicated than proved
-by Stahl and his followers. The conclusions of Duhamel were disputed
-by Pott; but finally confirmed by Margraaf. M. Duhamel carried his
-researches further, he wished to know if the difference between potash
-and soda depends on the plants that produce them, or on the nature
-of the soil in which they grow. He sowed kali at Denainvilliers, and
-continued his experiments during a great number of years. M. Cadet, at
-his request, examined the salts contained in the ashes of the kali of
-Denainvilliers. He found that during the first year soda predominated
-in these ashes. During the successive years the potash increased
-rapidly, and at last the soda almost entirely disappeared. It was
-obvious from this, that the alkalies in plants are drawn at least
-chiefly from the soil in which they vegetate.
-
-The memoirs of M. Duhamel on ether, at that time almost unknown, on
-soluble tartars, and on lime, contain many facts both curious and
-accurately stated; though our present knowledge of these bodies is
-so much greater than his--the new facts ascertained respecting them
-are so numerous and important, that the contributions of this early
-experimenter, which probably had a considerable share in the success
-of subsequent investigations, are now almost forgotten. Nor would many
-readers bear patiently with an attempt to enumerate them.
-
-There is a curious paper of his in the Memoirs of the Academy for
-1757. In this he gives the details of a spontaneous combustion of
-large pieces of cloth soaked in oil and strongly pressed. Cloth thus
-prepared had often produced similar accidents. Those who were fortunate
-enough to prevent them, took care to conceal the facts, partly from
-ignorance of the real cause of the combustion, and partly from a fear
-that if they were to state what they saw, their testimony would not
-gain credit. If the combustion had not been prevented, then the public
-voice would have charged those who had the care of the cloths with
-culpable negligence, or even with criminal conduct. The observation
-of M. Duhamel, therefore, was useful, in order to prevent such unjust
-suspicions from hindering those concerned from taking the requisite
-precautions. Yet, twenty years after the publication of his paper,
-two accidental spontaneous combustions, in Russia, were ascribed to
-treason. The empress Catharine II. alone suspected that the combustion
-was spontaneous, and experiments made by her orders fully confirmed the
-evidence previously advanced by the French philosopher.
-
-One man alone would have been insufficient for all the labours
-undertaken by M. Duhamel; but he had a brother who lived upon his
-estate at Denainvilliers (the name of which he bore), and divided his
-time between the performance of benevolent actions and studying the
-operations of nature. M. Denainvilliers prosecuted in his retreat the
-observations and experiments intrusted by his brother to his charge.
-Thus in fact the memoirs of Duhamel exhibit the assiduous labours
-of two individuals, one of whom contentedly remained unknown to the
-world, satisfied with the good which he did, and the favours which he
-conferred upon his country and the human race.
-
-The works of M. Duhamel are very voluminous, and are all written with
-the utmost plainness. Every thing is elementary, no previous knowledge
-is taken for granted. His writings are not addressed to philosophers,
-but to all those who are in quest of practical knowledge. He has been
-accused of diffuseness of style, and of want of correctness; but
-his style is simple and clear; and as his object was to inform, not
-philosophers, but the common people, greater conciseness would have
-been highly injudicious.
-
-Neither he nor his brother ever married, but thought it better to
-devote their undivided attention to study. Both were assiduous in no
-ordinary degree, but the ardour of Duhamel himself continued nearly
-undiminished till within a year of his death; when, though he still
-attended the meetings of the academy, he no longer took the same
-interest in its proceedings. On the 22d of July, 1781, just after
-leaving the academy, he was struck with apoplexy, and died after
-lingering twenty-two days in a state of coma.
-
-He was without doubt one of the most eminent men of the age in which
-he lived; but his merits as a chemist will chiefly be remembered
-in consequence of his being the first person who demonstrated
-by satisfactory evidence the peculiar nature of soda, which had
-been previously confounded with potash. His merits as a vegetable
-physiologist and agriculturist were of a very high order.
-
-Peter Joseph Macquer was born at Paris, in 1718. His father, Joseph
-Macquer, was descended from a noble Scottish family, which had
-sacrificed its property and its country, out of attachment to the
-family of the Stuarts.[183] Young Macquer made choice of medicine as
-a profession, and devoted himself chiefly to chemistry, for which
-he showed early a decided taste. He was admitted a member of the
-Academy of Sciences in the year 1745, when he was twenty-seven years
-of age. Original researches in chemistry, the composition of chemical
-elementary works, and the study of the arts connected with chemistry,
-occupied the whole remainder of his life.
-
-[183] I do not know what the true name was of which Macquer is a
-corruption. Ker is a Scottish name belonging to two noble families,
-the Duke of Roxburgh and the Marquis of Lothian; but I am not aware of
-M’Ker being a Scottish name: besides, neither of these families was
-attached to the house of Stuart.
-
-His first paper treated of the effect produced by heating a mixture of
-saltpetre and white arsenic. It was previously known, that when such a
-mixture is distilled nitric acid comes over tinged with a blue colour;
-but nobody had thought of examining the residue of this distillation.
-Macquer found it soluble in water and capable of crystallizing into a
-neutral salt composed of potash (the base of saltpetre), and an acid
-into which the arsenic was changed by the nitric acid communicating
-oxygen to it.
-
-Macquer found that a similar salt might be obtained with soda or
-ammonia for its base. Thus he was the first person who pointed out
-the existence of arsenic acid, and ascertained the properties of some
-of the salts which it forms. But he made no attempt to obtain arsenic
-acid in a separate state, or to determine its properties. That very
-important step was reserved for Scheele, for Macquer seems to have had
-no suspicion of the true nature of the salt which he had formed.
-
-His next set of experiments was on Prussian blue. He made the first
-step towards the discovery of the nature of the principle to which
-that pigment owes its colour. Prussian blue had been accidentally
-discovered by Diesbach, an operative chemist of Berlin, in 1710, but
-the mode of producing it was kept secret till it was published in
-1724, by Dr. Woodward in the Philosophical Transactions. It consisted
-in mixing potash and blood together, and heating the mixture in a
-covered crucible, having a small hole in the lid, till it ceased to
-give out smoke. The solution of this mixture in water, when mixed with
-a solution of sulphate of iron, threw down a green powder, which became
-blue when treated with muriatic acid: this blue matter was _Prussian
-blue_. Macquer ascertained that when Prussian blue is exposed to a
-red heat its blue colour disappears, and it is converted into common
-peroxide of iron. Hence he concluded that Prussian blue is a compound
-of oxide of iron, and of something which is destroyed or driven off
-by a red heat. He showed that this something possessed the characters
-of an acid; for when Prussian blue is boiled with caustic potash it
-loses its blue colour, and if the potash be boiled with successive
-portions of Prussian blue, as long as it is capable of discolouring
-them, it loses the characters of an acid and assumes those of a neutral
-salt, and at the same time acquires the property of precipitating iron
-from the solutions of the sulphate at once of a blue colour. Macquer
-ascribed the green colour thrown down, by mixing the blood-lie and
-sulphate of iron to the potash in the blood-lie, not being saturated
-with the colouring matter of Prussian blue. Hence a portion of the iron
-is thrown down in the state of Prussian blue, and another portion in
-that of yellow oxide of iron: these two being mixed form a green. The
-muriatic acid dissolves the yellow oxide and leaves the Prussian blue
-untouched. Macquer, however, did not succeed in determining the nature
-of the colouring matter; a task reserved for Scheele, whose lot it was
-to take up the half-finished investigations of Macquer, and throw upon
-them a new and brilliant light. Macquer thought that this colouring
-matter was _phlogiston_. On that account the potash saturated with
-it, which was employed by chemists to detect the presence of iron by
-forming with it Prussian blue, was called _phlogisticated alkali_.
-
-Macquer, conjointly with Baumé, subjected the grains of crude platinum,
-to which the attention of chemists had been newly drawn, to experiment.
-Their principle object was to examine its fusibility and ductility.
-They succeeded in fusing it imperfectly, by means of a burning
-mirror, and found that the grains thus treated were not destitute of
-ductility. But upon the whole the experiments of these chemists threw
-but little light upon the subject. Many years elapsed before chemists
-were able to work this refractory metal, and to make it into vessels
-fitted for the uses of the laboratory. For this important improvement,
-which constitutes an era in chemistry, the chemical world was chiefly
-indebted to Dr. Wollaston.
-
-In the year 1750 M. Macquer was charged with a commission by the court.
-There existed at that time in Brittany a man, the Count de la Garaie,
-who, yielding to a passion for benevolence, had for forty years devoted
-himself to the service of suffering humanity. He had built an hospital
-by the side of a chemical laboratory: he took care of the patients in
-the hospital himself; and treated them with medicines prepared in his
-laboratory. Some of these were new, and, in his opinion, excellent
-medicines; and he offered to sell them to government for the service of
-his hospital. Macquer was charged by government with the examination of
-these medicines. The project of the Count de la Garaie was to extract
-the salutary parts of minerals, by a long maceration with neutral
-salts. Among other things he had prepared a mercurial tincture, by a
-process which lasted several months: but this tincture was merely a
-solution of corrosive sublimate in spirit of wine. Such is the history
-of most of those boasted secrets; sometimes they are chimerical, and
-sometimes known to all the world, except to those who purchase them.
-
-M. Macquer had the fortune to live at a time when chemistry began to
-be freed from the reveries of alchymists; but methodical arrangement
-was a merit still unknown to the elementary chemical books, especially
-in France, where a residue of Cartesianism added to the natural
-obscurity of the science, by surcharging it with pretended mechanical
-explanations. Macquer was the first French chemist who gave to an
-elementary treatise the same clearness, simplicity, and method,
-which is to be found in the other branches of science. This was no
-small merit, and undoubtedly contributed considerably to the rapid
-improvement of the science which so speedily followed. His elements
-of chemistry were translated into different languages, especially
-into English; and long constituted the textbook employed in the
-different European universities. Dr. Black recommended it for many
-years in the University of Edinburgh. Indeed, it was only superseded in
-consequence of the new views introduced into chemistry by Lavoisier,
-which, requiring a new language to render them intelligible, naturally
-superseded all the elementary chemical books which had preceded the
-introduction of that language.
-
-Macquer, during a number of years, delivered regular courses of
-chemical lectures, conjointly with Baumé. In these courses he preferred
-that arrangement which appeared to him to require the least preliminary
-knowledge of chemistry. He described the experiments, stated the facts
-with clearness and precision, and explained them in the way which
-appeared to him most plausible, according to the opinions generally
-received; but without placing much confidence in the accuracy of these
-explanations. He thought it necessary to theorize a little, to enable
-his pupils the better to connect the facts and to remember them; and to
-put an end to that painful state of uncertainty which always results
-from a collection of facts without any theoretical links to bind
-them together. When the discoveries of Lavoisier began to shake the
-foundation of the Stahlian theory, Macquer was old; and it appears from
-a letter of his, published by Delametherie in the Journal de Physique,
-that he was alarmed at the prophetic announcements of Lavoisier in
-the academy that the reign of Phlogiston was drawing towards an end.
-M. Condorcet assures us that his attachment to theory, by which he
-means phlogiston, was by no means strong;[184] but his own letter to
-Delametherie rather shows that this statement was not quite correct.
-How, indeed, could he fail to experience an attachment to opinions
-which it had been the business of his whole life to inculcate?
-
-[184] Hist. de l’Acad. R. des Sciences, 1784, p. 24.
-
-Macquer also published a dictionary of chemistry, which was very
-successful, and which was translated into most of the European
-languages. This mode of treating chemistry was well suited to a science
-still in its infancy, and which did not yet constitute a complete
-whole. It enabled him to discuss the different topics in succession,
-and independent of each other: and thus to introduce much important
-matter which could not easily have been introduced into a systematic
-work on chemistry. The second edition of this dictionary was published
-just at the time when the gases began to attract the attention of
-scientific men; when facts began to multiply with prodigious rapidity,
-and to shake the confidence of chemists in all received theories. He
-acquitted himself of the difficult task of collecting and stating
-these new facts with considerable success; and doubtless communicated
-much new information to his countrymen: for the discoveries connected
-with the gases originated, and were chiefly made, in England, from
-which, on account of the revolutionary American war, there was some
-difficulty of obtaining early information.
-
-M. Hellot, who was commissioner of the counsel for dyeing, and chemist
-to the porcelain manufacture, requested to have M. Macquer for an
-associate. This request did much honour to Hellot, as he was conscious
-that the reputation of Macquer as a chemist was superior to his
-own. Macquer endeavoured, in the first place, to lay down the true
-principles of the art of dyeing, as the best method of dissipating the
-obscurity which still hung over it. A great part of his treatise on
-the art of dyeing silk, published in the collection of the Academy of
-Sciences, has these principles for its object. He gave processes also
-for dyeing silk with Prussian blue, and for giving to silk, by means
-of cochineal, as brilliant a scarlet colour as can be given to woollen
-cloth by the same dye-stuff. He published nothing on the porcelain
-manufacture, though he attended particularly to the processes, and
-introduced several ameliorations. The beautiful porcelain earth at
-present used at Sevre, was discovered in consequence of a premium which
-he offered to any person who could point out a clay in every respect
-proper for making porcelain.
-
-Macquer passed a great part of his life with a brother, whom he
-affectionately loved: after his death he devoted himself entirely to
-his wife and two children, whose education he superintended. He was
-rather averse to society, but conducted himself while in it with much
-sweetness and affability. He was fond of tranquillity and independence.
-Though his health had been injured a good many years before his death,
-the calmness and serenity of his temper prevented strangers from being
-aware that he was afflicted with any malady. He himself was sensible
-that his strength was gradually sinking; he predicted his approaching
-end to his wife, whom he thanked for the happiness which she had spread
-over his life. He left orders that his body should be opened after his
-decease, that the cause of his death might be discovered. He died on
-the 15th of February, 1784. An ossification of the aorta, and several
-calculous concretions found in the cavities of the heart, had been the
-cause of the disease under which he had suffered for several years
-before his death.
-
-These four chemists, of whose lives a sketch has just been given, were
-the most eminent that France ever produced belonging to the Stahlian
-school of chemistry. Baron, Malouin, Rouelle senior, Tillet, Cadet,
-Baumé, Sage, and several others whose names I purposely omit, likewise
-cultivated chemistry, during that period, with assiduity and success;
-and were each of them the authors of papers which deserve attention,
-but which it would be impossible to particularize without swelling this
-work into a size greatly beyond its proper limits.
-
-Hilaire-Marin Rouelle, who was born at Caen in 1718, was, however, too
-eminent a chemist to be passed over in silence. His elder brother,
-William Francis, was a member of the Academy of Sciences, and
-demonstrator to Macquer, who gave lectures in the Jardin du Roi. At
-the death of Macquer, in 1770, Hilaire-Marin Rouelle succeeded him. He
-devoted the whole of his time and money to this situation, and quite
-altered the nature of the experimental course of chemistry given in the
-Jardin du Roi. He was in some measure the author of the chemistry of
-animal bodies, at least in France. When he published his experiments
-on the salts of urine, and of blood, he had scarcely any model; and
-though he committed some considerable mistakes, he ascertained several
-essential and important facts, which have been since fully confirmed
-by more modern experimenters. He died on the 7th of April, 1779, aged
-sixty-one years. His temper was peculiar, and he was too honest and
-too open for the situation in which he was placed, and for a state of
-society in which every thing was carried by intrigue and finesse. This
-is the reason why, in France, his reputation was lower than it ought
-to have been. It accounts, too, for his never becoming a member of
-the Academy of Sciences, nor of any of the other numerous academies
-which at that time swarmed in France. Nothing is more common than to
-find these unjust decisions raise or depress men of science far above
-or far below their true standard. Romé de Lisle, the first person who
-commenced the study of crystals, and placed that study in a proper
-point of view, was a man of the same stamp with the younger Rouelle,
-and never on that account, became a member of any academy, or acquired
-that reputation during his lifetime, to which his laborious career
-justly entitled him. It would be an easy, though an invidious task, to
-point out various individuals, especially in France, whose reputation,
-in consequence of accidental and adventitious circumstances, rose just
-as much above their deserts, as those of Rouelle, and Romé de Lisle
-were sunk below.
-
-
-
-
-CHAPTER IX.
-
-OF THE FOUNDATION AND PROGRESS OF SCIENTIFIC CHEMISTRY IN GREAT BRITAIN.
-
-
-The spirit which Newton had infused for the mathematical science
-was so great, that during many years they drew within their vortex
-almost all the scientific men in Great Britain. Dr. Stephen Hales is
-almost the only remarkable exception, during the early part of the
-eighteenth century. His vegetable statics constituted a most ingenious
-and valuable contribution to vegetable physiology. His hæmastatics was
-a no less valuable contribution to iatro-mathematics, at that time
-the fashionable medical theory in Great Britain. While his _analysis
-of air_, and experiments on the animal calculus constituted, in all
-probability, the foundation-stone of the whole discoveries respecting
-the gases to which the great subsequent progress of chemistry is
-chiefly owing.
-
-Dr. William Cullen, to whom medicine lies under deep obligations,
-and who afterwards raised the medical celebrity of the College of
-Edinburgh to so high a pitch, had the merit of first perceiving the
-importance of scientific chemistry, and the reputation which that man
-was likely to earn, who should devote himself to the cultivation of
-it. Hitherto chemistry in Great Britain, and on the continent also,
-was considered as a mere appendage to medicine, and useful only so
-far as it contributed to the formation of new and useful remedies.
-This was the reason why it came to constitute an essential part of the
-education of every medical man, and why a physician was considered as
-unfit for practice unless he was also a chemist. But Dr. Cullen viewed
-the science as far more important; as capable of throwing light on the
-constitution of bodies, and of improving and amending of those arts and
-manufactures that are most useful to man. He resolved to devote himself
-to its cultivation and improvement; and he would undoubtedly have
-derived celebrity from this science, had not his fate led rather to the
-cultivation of medicine. But Dr. Cullen, as the true commencer of the
-study of scientific chemistry in Great Britain, claims a conspicuous
-place in this historical sketch.
-
-William Cullen was born in Lanarkshire, in Scotland, in the year
-1712, on the 11th of December. His father, though chief magistrate of
-Hamilton, was not in circumstances to lay out much money on his son.
-William, therefore, after serving an apprenticeship to a surgeon in
-Glasgow, went several voyages to the West Indies, as surgeon, in a
-trading-vessel from London; but tiring of this, he settled, when very
-young, in the parish of Shotts; and after residing for a short time
-among the farmers and country people, he went to Hamilton, with a view
-of practising as a physician.
-
-While he resided near Shotts, it happened that Archibald, Duke of
-Argyle, who at that time bore the chief political sway in Scotland,
-paid a visit to a gentleman of rank in that neighbourhood. The duke
-was fond of science, and was at that time engaged in some chemical
-researches which required to be elucidated by experiment. Eager in
-these pursuits, while on his visit he found himself at a loss for some
-piece of chemical apparatus which his landlord could not furnish; but
-he mentioned young Cullen to the duke as a person fond of chemistry,
-and likely therefore to possess the required apparatus. He was
-accordingly invited to dine, and introduced to his Grace. The duke
-was so pleased with his knowledge, politeness, and address, that an
-acquaintance commenced, which laid the foundation of all Cullen’s
-future advancement.
-
-His residence in Hamilton naturally made his name known to the Duke of
-Hamilton, whose palace is situated in the immediate vicinity of that
-town. His Grace being taken with a sudden illness, sent for Cullen,
-and was highly delighted with the sprightly character, and ingenious
-conversation of the young physician. He found no difficulty, especially
-as young Cullen was already known to the Duke of Argyle, in getting him
-appointed to a place in the University of Glasgow, where his singular
-talents as a teacher soon became very conspicuous.
-
-It was while Dr. Cullen was a practitioner in Shotts that he formed a
-connexion with William, afterwards Doctor Hunter, the famous lecturer
-on anatomy in London, who was a native of the same part of the country
-as Cullen. These two young men, stimulated by genius, though thwarted
-by the narrowness of their circumstances, entered into a copartnery
-business, as surgeons and apothecaries, in the country. The chief
-object of their contract was to furnish the parties with the means
-of carrying on their medical studies, which they were not able to do
-separately. It was stipulated that one of them, alternately, should be
-allowed to study in whatever college he preferred, during the winter,
-while the other carried on the common business in his absence. In
-consequence of this agreement, Cullen was first allowed to study in
-the University of Edinburgh, for a winter. When it came to Hunter’s
-turn next winter, he rather chose to go to London. There his singular
-neatness in dissecting, and uncommon dexterity in making anatomical
-preparations, his assiduity in study, his mild manners, and easy
-temper, drew upon him the attention of Dr. Douglas, who at that time
-read lectures on anatomy and midwifery in the capital. He engaged
-him as his assistant, and he afterwards succeeded him in the same
-department with much honour to himself, and advantage to the public.
-Thus was dissolved a copartnership of perhaps as singular a kind as any
-that occurs in the annals of science. Cullen was not disposed to let
-any engagement with him prove a bar to his partner’s advancement in the
-world. The articles were abandoned, and Cullen and Hunter kept up ever
-after a friendly correspondence; though there is reason to believe that
-they never afterwards met.
-
-It was while a country practitioner that young Cullen married a Miss
-Johnston, daughter of a neighbouring clergyman. The connexion was
-fortunate and lasting. She brought her husband a numerous family, and
-continued his faithful companion through all the alterations of his
-fortune. She died in the summer of 1786.
-
-In the year 1746 Cullen, who had now taken the degree of doctor of
-medicine, was appointed lecturer on chemistry in the University of
-Glasgow; and in the month of October began a course on that science.
-His singular talent for arrangement, his distinctness of enunciation,
-his vivacity of manner, and his knowledge of the science which he
-taught, rendered his lectures interesting to a degree which had
-been till then unknown in that university: he was adored by the
-students. The former professors were eclipsed by the brilliancy of his
-reputation, and he had to encounter all those little rubs and insults
-that disappointed envy naturally threw in his way. But he proceeded in
-his career regardless of these petty mortifications; and supported by
-the public, he was more than consoled for the contumely heaped upon him
-by the ill nature and pitiful malignity of his colleagues. His practice
-as a physician increased every day, and a vacancy occurring in the
-chair in 1751, he was appointed by the crown professor of medicine,
-which put him on a footing of equality with his colleagues in the
-university. This new appointment called forth powers which he was not
-before known to possess, and thus served still further to increase his
-reputation.
-
-At that time the patrons of the University of Edinburgh were eagerly
-bent on raising the reputation of their medical school, and were in
-consequence on the look out for men of abilities and reputation to fill
-their respective chairs. Their attention was soon drawn towards Cullen,
-and on the death of Dr. Plummer, in 1756, he was unanimously invited to
-fill the vacant _chemical chair_. He accepted the invitation, and began
-his academical career in the College of Edinburgh in October of that
-year, and here he continued during the remainder of his life.
-
-The appearance of Dr. Cullen in the College of Edinburgh constitutes
-a memorable era in the progress of that celebrated school. Hitherto
-chemistry being reckoned of little importance, had been attended by
-very few students; when Cullen began to lecture it became a favourite
-study, almost all the students flocking to hear him, and the chemical
-class becoming immediately more numerous than any other in the college,
-anatomy alone excepted. The students in general spoke of the new
-professor with that rapturous ardour so natural to young men when
-highly pleased. These eulogiums were doubtless extravagant, and proved
-disgusting to his colleagues. A party was formed to oppose this new
-favourite of the public. His opinions were misrepresented, it was
-affirmed that he taught doctrines which excited the alarm of some of
-the most moderate and conscientious of his colleagues. Thus a violent
-ferment was excited, and some time elapsed before the malignant arts by
-which this flame had been blown up were discovered.
-
-During this time of public ferment Cullen went steadily forward; he
-never gave an ear to the gossip brought him respecting the conduct
-of his colleagues, nor did he take any notice of the doctrines which
-they taught. Some of their unguarded strictures on himself might
-occasionally have come to his ears; but if it was so, he took no notice
-of them whatever; they seemed to have made no impression on him.
-
-This futile attempt to lower his character being thus baffled, his fame
-as a professor, and his reputation as a physician, increased daily: nor
-could it be otherwise; his professional knowledge was always great, and
-his manner of lecturing singularly clear and intelligible, lively, and
-entertaining. To his patients his conduct was so pleasing, his address
-so affable and engaging, and his manner so open, so kind, and so little
-regulated by pecuniary considerations, that those who once applied to
-him for medical assistance could never afterwards dispense with it: he
-became the friend and companion of every family he visited, and his
-future acquaintance could not be dispensed with.
-
-His private conduct to his students was admirable, and deservedly
-endeared him to every one of them. He was so uniformly attentive to
-them, and took so much interest in the concerns of those who applied
-to him for advice; was so cordial and so warm, that it was impossible
-for any one, who had a heart susceptible of generous emotions, not to
-be delighted with a conduct so uncommon and so kind. It was this which
-served more than any thing else to extend his reputation over every
-civilized quarter of the globe. Among ingenuous youth gratitude easily
-degenerates into rapture; hence the popularity which he enjoyed, and
-which to those who do not well weigh the causes which operated on the
-students must appear excessive.
-
-The general conduct of Cullen to his students was this: with all
-such as he observed to be attentive and diligent he formed an early
-acquaintance, by inviting them by twos, by threes, and by fours at a
-time to sup with him; conversing with them at such times with the most
-engaging ease, entering freely with them into the subject of their
-studies, their amusements, their difficulties, their hopes and future
-prospects. In this way he usually invited the whole of his numerous
-class till he made himself acquainted with their private character,
-their abilities, and their objects of pursuit. Those of whom he formed
-the highest opinion were of course invited most frequently, till an
-intimacy was gradually formed which proved highly beneficial to them.
-To their doubts and difficulties he listened with the most obliging
-condescension, and he solved them to the utmost of his power. His
-library was at all times open for their accommodation: in short, he
-treated them as if they had been all his relatives and friends. Few men
-of distinction left the University of Edinburgh, in his time, with whom
-he did not keep up a correspondence till they were fairly established
-in business. This enabled him gradually to form an accurate knowledge
-of the state of medicine in every country, and the knowledge thus
-acquired put it in his power to direct students in the choice of places
-where they might have an opportunity of engaging in business with a
-reasonable prospect of success.
-
-Nor was it in this way alone that he befriended the students in the
-University of Edinburgh. Remembering the difficulties with which he had
-himself to struggle in his younger days, he was at all times singularly
-attentive to the pecuniary wants of the students. From the general
-intimacy which he contracted with them he found no difficulty in
-discovering those whose circumstances were contracted, or who laboured
-under any pecuniary embarrassment, without being under the necessity of
-hurting their feelings by a direct inquiry. To such persons, when their
-habits of study admitted it, he was peculiarly attentive: they were
-more frequently invited to his house than others, they were treated
-with unusual kindness and familiarity, they were conducted to his
-library and encouraged by the most delicate address to borrow from it
-freely whatever books he thought they had occasion for; and as persons
-under such circumstances are often extremely shy, books were sometimes
-pressed upon them as a sort of task, the doctor insisting upon knowing
-their opinion of such and such passages which they had not read, and
-desiring them to carry the book home for that purpose: in short, he
-behaved to them as if he had courted their company. He thus raised
-them in the opinion of their acquaintances, which, to persons in their
-circumstances, was of no little consequence. They were inspired at the
-same time with a secret sense of dignity, which elevated their minds,
-and excited an uncommon ardour, instead of that desponding inactivity
-so natural to depressed circumstances. Nor was he less delicate in the
-manner of supplying their wants: he often found out some polite excuse
-for refusing to take money for a first course, and never was at a loss
-for one to an after course. Sometimes (as his lectures were never
-written) he would request the favour of a sight of their notes, if he
-knew that they were taken with care, in order to refresh his memory.
-Sometimes he would express a wish to have their opinion of a particular
-part of his course, and presented them with a ticket for the purpose.
-By such delicate pieces of address, in which he greatly excelled, he
-took care to anticipate their wants. Thus he not only gave them the
-benefit of his own lectures, but by refusing to take money enabled them
-to attend such others as were necessary for completing their course of
-medical study.
-
-He introduced another general rule into the university dictated by the
-same spirit of disinterested benevolence. Before he came to Edinburgh,
-it was the custom of the medical professors to accept of fees for their
-medical attendance when wanted, even from medical students themselves,
-though they were perhaps attending the professor’s lectures at the
-time. But Dr. Cullen never would take a fee from any student of the
-university, though he attended them, when called on as a physician,
-with the same assiduity and care as if they had been persons of the
-first rank who paid him most liberally. This gradually led others
-to follow his example; and it has now become a general rule for
-medical professors to decline taking any fees when their assistance
-is necessary to a student. For this useful reform, as well as for
-many others, the students in the University of Edinburgh are entirely
-indebted to Dr. Cullen.
-
-The first lectures which Dr. Cullen delivered in Edinburgh were on
-chemistry; and for many years he also gave lectures on the cases
-that occurred in the infirmary. In the month of February, 1763, Dr.
-Alston died, after having begun his usual course of lectures on the
-materia medica. The magistrates of Edinburgh, who are the patrons of
-the university, appointed Dr. Cullen to that chair, requesting that
-he would finish the course of lectures that had been begun by his
-predecessor. This he agreed to do, and, though he had only a few days
-to prepare himself, he never once thought of reading the lectures of
-his predecessor, but resolved to deliver a new course, which should be
-entirely his own. Some idea may be formed of the popularity of Cullen,
-by the increase of students to a class nearly half finished: Dr. Alston
-had been lecturing to ten; as soon as Dr. Cullen began, a hundred new
-students enrolled themselves.
-
-Some years after, on the death of Dr. Whytt, professor of the theory of
-medicine, Dr. Cullen was appointed to give lectures in his stead. It
-was then that he thought it requisite to resign the chemical chair in
-favour of Dr. Black, his former pupil, whose talents in that department
-of science were well known. Soon after, on the death of Dr. Rutherford,
-professor of the practice of medicine, Dr. John Gregory having become a
-candidate for this place, along with Dr. Cullen, a sort of compromise
-took place between them, by which they agreed to give lectures
-alternately, on the theory and practice of medicine, during their joint
-lives, the longest survivor being allowed to hold either of the classes
-he should incline. Unluckily this arrangement was soon destroyed, by
-the sudden and unexpected death of Dr. Gregory, in the flower of his
-age. Dr. Cullen thenceforth continued to give lectures on the practice
-of medicine till within a few months of his death, which happened on
-the 5th of February, 1790, when he was in the seventy-seventh year of
-his age.
-
-It is not our business to follow Dr. Cullen’s medical career, nor
-to point out the great benefits which he conferred on nosology and
-the practice of medicine. He taught four different classes in the
-University of Edinburgh, which we are not aware to have happened to any
-other individual, except to professor Dugald Stewart.
-
-Notwithstanding the important impulse which he gave to chemistry,
-he published nothing upon that science, except a short paper on the
-cold produced by the evaporation of ether, which made its appearance
-in one of the volumes of the Edinburgh Physical and Literary Essays.
-Dr. Cullen employed Dr. Dobson of Liverpool, at that time his pupil,
-to make experiments on the heat and cold produced by mixing liquids
-and solids with each other. Dr. Dobson, in making these experiments,
-observed that the thermometer, when lifted out of many of the liquids,
-and suspended a short time in the air beside them, fell to a lower
-degree than indicated by another thermometer which had undergone no
-such process. After varying his observations on this phenomenon, he
-found reason to conclude that it was occasioned by the evaporation of
-the last drop of liquid which adhered to the bulb of the thermometer;
-the sinking of the thermometer being always greatest when this
-instrument was taken out of the most volatile liquids. Dr. Cullen
-had the curiosity to try whether the same phenomenon would appear
-on repeating these experiments under the exhausted receiver of an
-air-pump. To satisfy himself, he put on the plate of the air-pump
-a glass goblet containing water; and in the goblet he placed a
-wide-mouthed phial containing sulphuric ether. The whole was covered
-with an air-pump receiver, having at the upper end a collar of leathers
-in a brass socket, through which a thick smooth wire could be moved;
-and from the lower end of this wire, projecting into the receiver, was
-suspended a thermometer. By pushing down the wire, the thermometer
-could be dipped into the ether; by drawing it up it could be taken out,
-and suspended over the phial.
-
-The apparatus being thus adjusted, the air-pump was worked to extract
-the air. An unexpected phenomenon immediately appeared, which prevented
-the experiment from being made in the way intended. The ether was
-thrown into a violent agitation, which Dr. Cullen ascribed to the
-extrication of a great quantity of air: in reality, however, it was
-boiling violently. What was still more remarkable, the ether, by this
-boiling or rapid evaporation, became all of a sudden so cold, as to
-freeze the water in the goblet around it; though the temperature of
-the air and of all the materials were at the fifty-fourth degree of
-Fahrenheit at the beginning of the experiment.
-
-I have been particular in giving an account of this curious phenomenon,
-as it was the only direct contribution to the science of chemistry
-which Dr. Cullen communicated to the public. The nature of the
-phenomenon was afterwards explained by Dr. Black; in addition to Dr.
-Cullen, a philosopher, whom the grand stimulus which his lectures gave
-to the cultivation of scientific chemistry in this country, had the
-important merit of bringing forward.
-
-Joseph Black was born in France, on the banks of the Garonne, in the
-year 1728: his father, Mr. John Black, was a native of Belfast, but
-of a Scottish family which had been for some time settled there. Mr.
-Black resided for the most part at Bordeaux, where he was engaged in
-the wine trade. He married a daughter of Mr. Robert Gordon, of the
-family of Hillhead, in Aberdeenshire, who was also engaged in the same
-trade at Bordeaux. Mr. Black was a gentleman of most amiable manners,
-candid and liberal in his sentiments, and of no common information.
-These qualities, together with the warmth of his heart, appear very
-conspicuous in a series of letters to his son, which that son preserved
-with the nicest care. His good qualities did not escape the discerning
-eye of the great Montesquieu, one of the presidents of the court of
-justice in that province. This illustrious and excellent man honoured
-Mr. Black with a friendship and intimacy altogether rare; of which his
-descendants were justly proud.
-
-Long before Mr. Black retired from business, his son Joseph was sent
-home to Belfast, that he might have the education of a British subject.
-This was in the year 1740, when he was twelve years of age. After the
-ordinary instruction at the grammar-school, he was sent, in 1746, to
-continue his education in the University of Glasgow. Here he studied
-with much assiduity and success: physical science, however, chiefly
-engrossed his attention. He was a favourite pupil of Dr. Robert Dick,
-professor of natural philosophy, and the intimate companion of his
-son and successor. This young professor was of a character peculiarly
-suited to Dr. Black’s taste, having the clearest conception, and
-soundest judgment, accompanied by a modesty that was very uncommon.
-When he succeeded his father, in 1751, he became the delight of the
-students. He was carried off by a fever in 1757.
-
-Young Black being required by his father to make choice of a
-profession, he preferred that of medicine as the most suitable to the
-general habits of his studies. Fortunately Dr. Cullen had just begun
-his great career in the College of Glasgow, and having made choice
-of the field of philosophical chemistry which lay as yet unoccupied
-before him. Hitherto chemistry had been treated as a curious and useful
-art; but Cullen saw in it a vast department of the science of nature,
-depending on principles as immutable as the laws of mechanism, and
-capable of being formed into a system as comprehensive and as complete
-as astronomy itself. He conceived the resolution of attempting himself
-to explore this magnificent field, and expected much reputation from
-accomplishing his object. Nor was he altogether disappointed. He
-quickly took the science out of the hands of artists, and exhibited
-it as a study fit for a gentleman. Dr. Black attended his chemical
-lectures, and, from the character which has already been given of him,
-it is needless to say that he soon discovered the uncommon value of
-his pupil, and attached him to himself, rather as a co-operator and a
-friend, than a pupil. He was considered as his assistant in all his
-operations, and his experiments were frequently adduced in the lecture
-as good authority.
-
-Young Black laid down a very comprehensive and serious plan of study.
-This appears from a number of note-books found among his papers. There
-are some in which he seems to have inserted every thing as it took his
-fancy, in medicine, chemistry, jurisprudence, or matters of taste. Into
-others, the same things are transferred, but distributed according
-to their scientific connexions. In short, he kept a journal and
-ledger of his studies, and has posted his books like a merchant. What
-particularly strikes one in looking over these books, is the steadiness
-with which he advanced in any path of knowledge. Things are inserted
-for the first time from some present impression of their singularity or
-importance, but without any allusion to their connexions. When a thing
-of the same kind is mentioned again, there is generally a reference
-back to its fellow; and thus the most isolated facts often acquired a
-connexion which gave them importance.
-
-He went to Edinburgh to finish his medical studies in 1750 or 1751,
-where he lived with his cousin german, Mr. James Russel, professor of
-natural philosophy in that university.
-
-It was the good fortune of chemical science, that at this very time
-the opinions of professors were divided concerning the manner in
-which certain lithontriptic medicines, particularly lime-water, acted
-in alleviating the excruciating pains of the stone and gravel. The
-students usually partake of such differences of opinion: they are
-thereby animated to more serious study, and science gains by their
-emulation. This was a subject quite to the taste of young Mr. Black,
-one of Dr. Cullen’s most zealous and intelligent chemical pupils. It
-was, indeed, a most interesting subject, both to the chemist and the
-physician.
-
-All the medicines which were then in vogue as solvents of urinary
-calculi had a greater or less resemblance to caustic potash or soda;
-substances so acrid, when in a concentrated state, that in a short time
-they reduce the fleshy parts of the animal body to a mere pulp. Thus,
-though they might possess lithontriptic properties, their exhibition
-was dangerous, if in unskilful hands. They all seemed to derive their
-efficacy from quicklime, which again derives its power from the fire.
-It was therefore very natural for them to ascribe its power to igneous
-matter imbibed from the fire, retained by the lime, and communicated by
-it to alkalies, which it renders powerfully acrid. Hence, undoubtedly,
-the term _caustic_ applied to the alkalies in that state, and hence
-also the _acidum pingue_ of Mayer, which was a peculiar state of fire.
-It appears from Dr. Black’s note-books, that he originally entertained
-the opinion, that caustic alkalies acquired igneous matter from
-quicklime. In one of them he hints at some way of catching this matter
-as it escapes from lime, while it becomes mild by exposure to the
-air; but on the opposite blank page is written, “Nothing escapes--the
-cup rises considerably by absorbing air.” A few pages further on,
-he compares the loss of weight sustained by an ounce of chalk when
-calcined, with its loss while dissolved in muriatic acid. Immediately
-after this, a medical case is mentioned, which occurred in November,
-1752. Hence it would appear, that he had before that time suspected the
-real cause of the difference between limestone and burnt lime. He had
-prosecuted his inquiry with vigour; for the experiments with magnesia
-are soon after mentioned.
-
-These experiments laid open the whole mystery, as appears by another
-memorandum. “When I precipitate lime by a common alkali there is no
-effervescence: the air quits the alkali for the lime; but it is lime no
-longer, but C. C. C.: it now effervesces, which good lime will not.”
-What a multitude of important consequences naturally flowed from this
-discovery! He now knew to what the causticity of alkalies is owing,
-and how to induce it or remove it at pleasure. The common notion was
-entirely reversed. Lime imparts nothing to the alkalies; it only
-removes from them a peculiar kind of air (_carbonic acid gas_) with
-which they were combined, and which prevented their natural caustic
-properties from being developed. All the former mysteries disappear,
-and the greatest simplicity appears in those operations of nature which
-before appeared so intricate and obscure.
-
-Dr. Black had fixed upon this subject for his inaugural dissertation,
-and was induced, in consequence, to defer applying for his degree till
-he had succeeded in establishing his doctrine beyond the possibility of
-contradiction. The inaugural essay was delivered at a moment peculiarly
-favourable to the advancement of science. Dr. Cullen had been just
-removed to Edinburgh, and there was a vacancy in the chemical chair
-in Glasgow: it could not be bestowed better than on such an _alumnus_
-of the university--on one who had distinguished himself both as a
-chemist and an excellent reasoner; for few finer models of inductive
-investigation exist than are displayed in Black’s essay on quicklime
-and magnesia. He was appointed professor of anatomy and lecturer on
-chemistry in the University of Glasgow in 1756. It was a fortunate
-circumstance both for himself and for the public, that a situation thus
-presented itself, just at the time when he was under the necessity of
-settling in the world--a situation which allowed him to dedicate his
-talents chiefly to the cultivation of chemistry, his favourite science.
-
-When Dr. Black took his degree in medicine, he sent some copies of his
-essay to his father at Bordeaux. A copy was given by the old gentleman
-to his friend, the President Montesquieu, who, after a few days called
-on Mr. Black, and said to him, “Mr. Black, my very good friend, I
-rejoice with you; your son will be the honour of your name and family.”
-This anecdote was told Professor John Robison by the brother of Dr.
-Black.
-
-Thus Dr. Black, while in Glasgow, taught at one and the same time two
-different classes. He did not consider himself very well qualified to
-teach anatomy, but determined to do his utmost; but he soon afterwards
-made arrangements with the professor of medicine, who, with the
-concurrence of the university, exchanged his own chair for that of Dr.
-Black.
-
-Black’s medical lectures constituted his chief task while in
-Glasgow. They gave the greatest satisfaction by their perspicuity
-and simplicity, and by the cautious moderation of all his general
-doctrines: and, indeed, all his perspicuity, and all his neatness
-of manner in exhibiting simple truths, were necessary to create a
-relish for moderation and caution, after the brilliant prospects of
-systematic knowledge to which the students had been accustomed by Dr.
-Cullen, his celebrated predecessor. But Dr. Black had no wish to form
-a medical school, distinguished by some all-comprehending doctrine: he
-satisfied himself with a clear account of as much of physiology as he
-thought founded on good principles, and a short sketch of such general
-doctrines as were maintained by the most eminent authors, though
-perhaps on a less firm foundation. He then endeavoured to deduce a few
-canons of medical practice, and concluded with certain rules founded
-on successful practice only, but not deducible from the principles of
-physiology previously laid down. With his medical lectures he does not
-appear to have been himself entirely satisfied: he did not encourage
-conversation on the different topics, and no remains of these lectures
-were to be found among his papers. The preceding account of them was
-given to Professor Robison by a surgeon in Glasgow, who attended the
-two last medical courses which Dr. Black ever delivered.
-
-Dr. Black’s reception at Glasgow by the university was in the highest
-degree encouraging. His former conduct as a student had not only done
-him credit in his classes, but had conciliated the affection of the
-professors to a very high degree. He became immediately connected
-in the strictest friendship with the celebrated Dr. Adam Smith--a
-friendship which continued intimate and confidential through the
-whole of their lives. Both were remarkable for a certain simplicity
-of character and the most incorruptible integrity. Dr. Smith used to
-say, that no one had less nonsense in his head than Dr. Black; and he
-often acknowledged himself obliged to him for setting him right in his
-judgment of character, confessing that he himself was too apt to form
-his opinion from a single feature.
-
-It was during his residence in Glasgow, between the years 1759 and
-1763, that he brought to maturity those speculations concerning the
-combination of _heat_ with _matter_, which had frequently occupied
-a portion of his thoughts. It had long been known that ice has the
-property of continuing always at the temperature of 32° till it be
-melted. This happens equally though it be placed in contact with the
-warm hand or surrounded with bodies many degrees hotter than itself.
-The hotter the bodies are that surround it, the sooner is it melted;
-but its temperature during the whole process of melting, continues
-uniformly the same. Yet, during the whole process of melting, it is
-constantly robbing the surrounding bodies of heat; for it makes them
-colder, without acquiring itself any sensible heat.
-
-Dr. Black had some vague notion that the heat so received by the ice,
-during its conversion into water, was not lost, but was contained in
-the water. This opinion was founded chiefly on a curious observation
-of Fahrenheit, recorded by Boerhaave; namely, that water might in some
-cases be made considerably colder than melting snow, without freezing.
-In such cases, when disturbed it would freeze in a moment, and in the
-act of freezing always gave out a quantity of heat. This opinion was
-confirmed by observing the slowness with which water is converted
-into ice, and ice into water. A fine winter-day of sunshine is never
-sufficient to clear the hills of snow; nor is one frosty night capable
-of covering the ponds with a thick coating of ice. The phenomena
-satisfied him that much heat was absorbed and fixed in the water which
-trickles from wreaths of snow, and that much heat emerged from it while
-water was slowly converted into ice; for during a thaw the melting snow
-is always colder than the air, and must, therefore, be always receiving
-heat from it; while, during a frost, the air is always colder than the
-freezing water, and must therefore be always receiving heat from it.
-These observations, and many others which it is needless to state,
-satisfied Dr. Black that when ice is converted into water it unites
-with a quantity of heat, without increasing in temperature; and that
-when water is frozen into ice it gives out a quantity of heat without
-diminishing in temperature. The heat thus combined is the cause of the
-fluidity of the water. As it is not sensible to the thermometer, Dr.
-Black called it _latent heat_. He made an experiment to determine the
-quantity of heat necessary to convert ice into water. This he estimated
-by the length of time necessary to melt a given weight of ice,
-measuring how much heat entered into the same weight of water, reduced
-as nearly to the temperature of ice as possible during the first
-half-hour that the experiment lasted. As the ice continued during the
-whole of its melting at the same temperature as at first, he concluded
-that it would absorb, every half-hour that the process lasted, as much
-heat as the water did during the first half hour. The result of this
-experiment was, that the latent heat of water amounts to 140°; or, in
-other words, that this heat, if thrown into a quantity of water, equal
-in weight to that of the ice melted, would raise its temperature 140°.
-
-Dr. Black, having established this discovery in the most
-incontrovertible manner by simple and decisive experiments, drew up an
-account of the whole investigation, and the doctrine which he founded
-upon it, and read it to a literary society which met every Friday in
-the faculty-room of the college, consisting of the members of the
-university and several gentlemen of the city, who had a relish for
-science and literature. This paper was read on the 23d of April, as
-appears by the registers of the society.
-
-Dr. Black quickly perceived the vast importance of this discovery, and
-took a pleasure in laying before his students a view of the beneficial
-effects of this habitude of heat in the economy of nature. During the
-summer season a vast magazine of heat was accumulated in the water,
-which, by gradually emerging during congelation, serves to temper the
-cold of winter. Were it not for this accumulation of heat in water and
-other bodies, the sun would no sooner go a few degrees to the south of
-the equator, than we should feel all the horrors of winter. He did not
-confine his views to the congelation of water alone, but extended them
-to every case of congelation and liquefaction which he has ascribed
-equally to the evolution or fixation of latent heat. Even those bodies
-which change from solid to fluid, not all at once, but by slow degrees,
-as butter, tallow, resins, owe, he found, their gradual softening to
-the same absorption of heat, and the same combination of it with the
-substance undergoing liquefaction.
-
-Another subject that engaged his attention at this time, was an
-examination of the scale of the thermometer, to learn whether
-equal differences of expansion corresponded to equal additions or
-abstractions of heat. His mode was to mix together equal weights of
-water of different temperatures, and to measure the temperature of the
-mixture by a thermometer. It is obvious that the temperature must be
-the exact mean of that of the two portions of water; and that if the
-expansion or contraction of the mercury in the thermometer be an exact
-measure of the difference of temperature, a thermometer, so placed,
-will indicate the exact mean. Suppose one pound of water at 100° to
-be mixed with one pound of water at 200°, and the whole heat still
-to remain in the mixture, it is obvious that it would divide itself
-equally between the two portions of water. The water of 100° would
-become hotter, and the water of 200° would become colder: and the
-increase of temperature in the colder portion would be just as much
-as the diminution of temperature in the hotter portion. The colder
-portion would become hotter by 50°, while the hotter portion would
-become colder by 50°. Hence the real temperature, after mixture, would
-be 150°; and a thermometer plunged into such a mixture, if a true
-measurer of heat, would indicate 150°. The result of his experiments
-was, that as high up as he could try by mixing water of different
-temperatures, the mercurial thermometer is an accurate measurer of the
-alterations of temperature.
-
-An account of his experiments on this subject was drawn up by him, and
-read to the literary society of the College of Glasgow, on the 28th of
-March, 1760. Dr. Black, at the time he made these experiments, did not
-know that he had been already anticipated in them by Dr. Brooke Taylor,
-the celebrated mathematician, who had obtained similar results, and had
-consigned his experiments to the Royal Society, in whose Transactions
-for 1723 they were published. It has been since found by Coulomb
-and Petit, that at higher temperatures than 212° the rate of the
-expansion of mercury begins to increase. Hence it happens that at high
-temperatures the expansion of mercury is no longer an accurate measurer
-of temperature. Fortunately, the expansion of glass very nearly equals
-the increment of that of mercury. The consequence is, that in a common
-glass-thermometer mercury measures the true increments of temperature
-very nearly up to its boiling point; for the boiling point of mercury
-measured by an air-thermometer is 662°: and if a glass mercurial
-thermometer be plunged into boiling mercury, it will indicate 660°, a
-difference of only 2° from the true point.
-
-There is such an analogy between the cessation of thermometric
-expansion during the liquefaction of ice, and during the conversion of
-water into steam, that there could be no hesitation about explaining
-both in the same way. Dr. Black immediately concluded that as water is
-ice united to a certain quantity of _latent heat_, so steam is water
-united to a still greater quantity. The slow conversion of water into
-steam, notwithstanding the great quantity of heat constantly flowing
-into it from the fire, left no reasonable doubt about the accuracy of
-this conclusion. In short, all the phenomena are precisely similar to
-those of the conversion of ice into water; and so, of course, must
-the explanation be. So much was he convinced of this, that he taught
-the doctrine in his lectures in 1761, before he had made a single
-experiment on the subject; and he explained, with great felicity of
-argument, many phenomena of nature, which result from this vaporific
-combination of heat. From notes taken in his class during this session,
-it appears that nothing more was wanting to complete his views on this
-subject, than a set of experiments to determine the exact quantity
-of heat which was combined in steam in a state not indicated by the
-thermometer, and therefore _latent_, in the same sense that the heat of
-liquefaction in water is _latent_.
-
-The requisite experiments were first attempted by Dr. Black, in 1764.
-They consisted merely in measuring the time requisite to convert a
-certain weight of water of a given temperature into steam. The water
-was put into a tin-plate wide-mouthed vessel, and laid upon a red-hot
-plate of iron, the initial temperature of the water was marked, and the
-time necessary to heat it from that point to the boiling point noted,
-and then the time requisite to boil the whole to dryness. It was taken
-for granted that as much heat would enter into the water during every
-minute that the experiment lasted, as did during the first minute. From
-this it was concluded that the latent heat of steam is not less than
-810 degrees.
-
-Mr. James Watt afterwards repeated these experiments with a better
-apparatus and very great care, and calculated from his results that the
-latent heat of steam is not under 950 degrees. Lavoisier and Laplace
-afterwards made experiments in a different way, and deduced 1000° as
-the result of their experiments. The subsequent experiments of Count
-Rumford, made in a very ingenious manner, so as to obviate most of the
-sources of error, to which such researches are liable, come very nearly
-to those of Lavoisier. 1000° therefore, is usually now-a-days adopted
-as the number which denotes the true latent heat of steam.
-
-Dr. Black continued in the University of Glasgow from 1756 to 1766,
-much esteemed as an eminent professor, much employed as an able and
-attentive physician, and much beloved as an amiable and accomplished
-man, happy in the enjoyment of a small but select society of friends.
-Meanwhile his reputation as a chemical philosopher was every day
-increasing, and pupils from foreign countries carried home with them
-the peculiar doctrines of his courses--so that _fixed air_ and _latent
-heat_ began to be spoken of among the naturalists of the continent. In
-1766 Dr. Cullen, at that time professor of chemistry in Edinburgh, was
-appointed professor of medicine, and thus a vacancy was made in the
-chemical chair of that university. There was but one wish with regard
-to a successor. Indeed, when the vacancy happened in 1756, on the death
-of Dr. Plummer, the reputation of Dr. Black, who had just taken his
-degree, was so high, both as a chemist and an accurate thinker and
-reasoner, that, had the choice depended on the university, he would
-have been the new professor of chemistry. He had now, in 1766, greatly
-added to his claim of merit by his important discovery of latent heat;
-and he had acquired the esteem of all by the singular moderation and
-scrupulous caution which marked all his researches.
-
-Dr. Black was appointed to the chemical chair in Edinburgh in 1766, to
-the general satisfaction of the public, but the University of Glasgow
-suffered an irreparable loss. In this new situation his talents were
-more conspicuous and more extensively useful. He saw that the case was
-so, and while he could not but be gratified by the number of students
-whom the high reputation of Edinburgh, as a medical school, brought
-together, his mind was forcibly struck by the importance of his duties
-as a teacher. This led him to form the resolution of devoting the
-whole of his study to the improvement of his pupils in the elementary
-knowledge of chemistry. Many of them came to his class with a very
-scanty stock of previous knowledge. Many from the workshop of the
-manufacturer had little or none. He was conscious that the number
-of this kind of pupils must increase with the increasing activity
-and prosperity of the country; and they appeared to him by no means
-the least important part of his auditory. To engage the attention of
-such pupils, and to be perfectly understood by the most illiterate
-of his audience, Dr. Black considered as a sacred duty: he resolved,
-therefore, that plain doctrines taught in the plainest manner, should
-henceforth employ his chief study. To render his lectures perfectly
-intelligible they were illustrated by suitable experiments, by the
-exhibition of specimens, and by the repetition of chemical processes.
-
-To this method of lecturing Dr. Black rigidly adhered, endeavouring
-every year to make his courses more plain and familiar, and
-illustrating them by a greater variety of examples in the way of
-experiment. No man could perform these more neatly or successfully;
-they were always ingeniously and judiciously contrived, clearly
-establishing the point in view, and were never more complicated than
-was sufficient for the purpose. Nothing that had the least appearance
-of quackery; nothing calculated to surprise and astonish his audience;
-nothing savouring of a showman or sleight-of-hand man was ever
-permitted in his lecture-room. Every thing was simple, neat, and
-elegant, calculated equally to please and to inform: indeed simplicity
-and neatness stamped his character. It was this that constituted the
-charm of his lectures, and rendered them so delightful to his pupils.
-I can speak of them from experience, for I was fortunate enough to
-hear the last course of lectures which he ever delivered. I can say
-with perfect truth that I never listened to any lectures with so
-much pleasure as to his: and it was the elegant simplicity of his
-manner, the perfect clearness of his statements, and the vast quantity
-of information which he contrived in this way to communicate, that
-delighted me. I was all at once transported into a new world--my views
-were suddenly enlarged, and I looked down from a height which I had
-never before reached; and all this knowledge was communicated without
-any apparent effort either on the part of the professor or his pupils.
-His illustrations were just sufficient to answer completely the object
-in view, and nothing more. No quackery, no trickery, no love of mere
-dazzle and glitter, ever had the least influence upon his conduct. He
-constituted the most complete model of a perfect chemical lecturer that
-I have ever had an opportunity of witnessing.
-
-The discovery which Dr. Black had made that marble is a combination
-of lime and a peculiar substance, to which he gave the name of _fixed
-air_, began gradually to attract the attention of chemists in other
-parts of the world. It was natural in the first place to examine the
-nature and properties of this fixed air, and the circumstances under
-which it is generated. It may seem strange and unaccountable that Dr.
-Black did not enter with ardour into this new career which he had
-himself opened, and that he allowed others to reap the corn after
-having himself sown the grain. Yet he did take some steps towards
-ascertaining the properties of _fixed air_; though I am not certain
-what progress he made. He knew that a candle would not burn in it,
-and that it is destructive to life, when any living animal attempts
-to breathe it. He knew that it was formed in the lungs during the
-breathing of animals, and that it is generated during the fermentation
-of wine and beer. Whether he was aware that it possesses the properties
-of an acid I do not know; though with the knowledge which he possessed
-that it combines with alkalies and alkaline earths, and neutralizes
-them, or at least blunts and diminishes their alkaline properties,
-the conclusion that it partook of alkaline properties was scarcely
-avoidable. All these, and probably some other properties of _fixed air_
-he was in the constant habit of stating in his lectures from the very
-commencement of his academical career; though, as he never published
-anything on the subject himself, it is not possible to know exactly
-how far his knowledge of the properties of _fixed air_ extended. The
-oldest manuscript copy of his lectures that I have seen was taken
-down in writing in the year 1773; and before that time Mr. Cavendish
-had published his paper on _fixed air_ and _hydrogen gas_, and had
-detailed the properties of each. It was impossible from the manuscript
-of Dr. Black’s lectures to know which of the properties of _fixed air_
-stated by him were discovered by himself, and which were taken from Mr.
-Cavendish.
-
-This languor and listlessness, on the part of Dr. Black, is chiefly to
-be ascribed to the delicate state of his health, which precluded much
-exertion, and was particularly inconsistent with any attempt at putting
-his thoughts down upon paper. Hence, probably, that carelessness
-about posthumous fame, and that regardlessness of reputation, which,
-however it may be accounted for from bodily ailment, must still be
-considered as a blemish. How differently did Paschal act in a similar
-state of health! With what energy did he exert himself in spite of
-bodily ailment! But the tone of his mind was quite different from that
-of Dr. Black. Gentleness, diffidence, and perhaps even slowness of
-apprehension, were the characteristic features by which the latter was
-distinguished.
-
-There is an anecdote of Black which I was told by the late Mr. Benjamin
-Bell, of Edinburgh, author of a well-known system of surgery, and
-he assured me that he had it from the late Sir George Clarke, of
-Pennicuik, who was a witness of the circumstance related. Soon after
-the appearance of Mr. Cavendish’s paper on hydrogen gas, in which he
-made an approximation to the specific gravity of that body, showing
-that it was at least ten times lighter than common air, Dr. Black
-invited a party of his friends to supper, informing them that he had
-a curiosity to show them. Dr. Hutton, Mr. Clarke of Elden, and Sir
-George Clarke of Pennicuik, were of the number. When the company
-invited had assembled, he took them into a room. He had the allentois
-of a calf filled with hydrogen gas, and upon setting it at liberty,
-it immediately ascended, and adhered to the ceiling. The phenomenon
-was easily accounted for: it was taken for granted that a small black
-thread had been attached to the allentois, that this thread passed
-through the ceiling, and that some one in the apartment above, by
-pulling the thread, elevated it to the ceiling, and kept it in this
-position. This explanation was so probable, that it was acceded to
-by the whole company; though, like many other plausible theories, it
-turned out wholly unfounded; for when the allentois was brought down no
-thread whatever was found attached to it. Dr. Black explained the cause
-of the ascent to his admiring friends; but such was his carelessness
-of his own reputation, and of the information of the public, that he
-never gave the least account of this curious experiment even to his
-class; and more than twelve years elapsed before this obvious property
-of hydrogen gas was applied to the elevation of air-balloons, by M.
-Charles, in Paris.
-
-The constitution of Dr. Black had always been exceedingly delicate. The
-slightest cold, the most trifling approach to repletion, immediately
-affected his chest, occasioned feverishness, and if the disorder
-continued for two or three days, brought on a spitting of blood.
-In this situation, nothing restored him to ease, but relaxation of
-thought, and gentle exercise. The sedentary life to which study
-confined him, was manifestly hurtful; and he never allowed himself to
-indulge in any investigation that required intense thought, without
-finding these complaints increased.
-
-Thus situated, Dr. Black was obliged to be a contented spectator of the
-rapid progress which chemistry was making, without venturing himself to
-engage in any of the numerous investigations which presented themselves
-on every side. Such indeed was the eagerness with which chemistry was
-at that time prosecuted, and such the passion for discovery, that there
-was some risk that his undoubted claim to originality and priority
-in his own great discoveries, might be called in question, and even
-rendered doubtful. His friends at least were afraid of this, and often
-urged him to do justice to himself, by publishing an account of his
-own discoveries. He more than once began the task; but was so nice in
-his notions of the manner in which it should be executed, that the
-pains he took in forming a plan of the work never failed to affect
-his health, and oblige him to desist. It is known that he felt hurt
-at the publication of several of Lavoisier’s papers, in the Mémoires
-de l’Académie, without any allusion whatever to what he himself had
-previously done on the same subject. How far Lavoisier was really
-culpable, and whether he did not intend to do full justice to all the
-claims of his predecessors, cannot now be known; as he was cut off
-in the midst of his career, while so many of his scientific projects
-remained unexecuted. From the posthumous works of Lavoisier, there
-is some reason for believing that if he had lived, he would have
-done justice to all parties; but there is no doubt that Dr. Black,
-in the mean time, thought himself aggrieved, and that he formed the
-intention of doing himself justice, by publishing an account of his own
-discoveries; however this intention was thwarted and prevented by bad
-health.
-
-No one contributed more largely to establish, to support, and to
-increase, the high character of the medical school in the University
-of Edinburgh than Dr. Black. His talent for communicating knowledge
-was not less eminent than his faculty of observation. He soon became
-one of the principal ornaments of the university; and his lectures
-were attended by an audience which continued increasing from year to
-year for more than thirty years. His personal appearance and manners
-were those of a gentleman, and peculiarly pleasing: his voice, in
-lecturing, was low, but fine; and his articulation so distinct, that he
-was perfectly well heard by an audience consisting of several hundreds.
-While in Glasgow, he had practised extensively as a physician; but in
-Edinburgh he declined general practice, and confined his attendance to
-a few families of intimate and respected friends. He was, however, a
-physician of good repute in a place where the character of a physician
-implied no common degree of liberality, propriety, and dignity of
-manners, as well as of learning and skill.
-
-Such was Dr. Black as a public man. While young, his countenance was
-comely and interesting; and as he advanced in years, it continued to
-preserve that pleasing expression of inward satisfaction which, by
-giving ease to the beholder, never fails to please. His manners were
-simple, unaffected, and graceful; he was of the most easy approach,
-affable, and readily entered into conversation, whether serious
-or trivial: for he was not merely a man of science, but was well
-acquainted with the elegant accomplishments. He had an accurate musical
-ear, and a voice which would obey it in the most perfect manner; he
-sang and performed on the flute with great taste and feeling; and could
-sing a plain air at sight, which many instrumental performers cannot
-do. Music was his amusement in Glasgow; after his removal to Edinburgh
-he gave it up entirely. Without having studied drawing he had acquired
-a considerable power of expression with his pencil, both in figures
-and in landscape. He was peculiarly happy in expressing the passions,
-and seemed in this respect to have the talents of a historical
-painter. Figure indeed, of every kind, attracted his attention; in
-architecture, furniture, ornament of every sort, it was never a matter
-of indifference to him. Even a retort, or a crucible, was to his eye
-an example of beauty, or deformity. These are not indifferent things;
-they are features of an elegant mind, and they account for some part of
-that satisfaction and pleasure which persons of different habits and
-pursuits felt in Dr. Black’s company and conversation.
-
-Those circumstances of form, and in which Dr. Black perceived or sought
-for beauty, were suitableness or propriety: something that rendered
-them well adapted for the purposes for which they were intended. This
-love of propriety constituted the leading feature in Dr. Black’s mind;
-it was the standard to which he constantly appealed, and which he
-endeavoured to make the directing principle of his conduct.
-
-Dr. Black was fond of society, and felt himself beloved in it. His
-chief companions, in the earlier part of his residence in Edinburgh,
-were Dr. Adam Smith, Mr. David Hume, Dr. Adam Ferguson, Mr. John Home,
-Dr. Alexander Carlisle, and a few others. Mr. Clarke of Elden, and his
-brother Sir George, Dr. Roebuck, and Dr. James Hutton, particularly
-the latter, were affectionately attached to him, and in their society
-he could indulge in his professional studies. Dr. Hutton was the
-only person near him to whom Dr. Black imparted every speculation in
-chemical science, and who knew all his literary labours: seldom were
-the two friends asunder for two days together.
-
-Towards the close of the eighteenth century, the infirmities of
-advanced life began to bear more heavily on his feeble constitution.
-Those hours of walking and gentle exercise, which had hitherto
-been necessary for his ease, were gradually curtailed. Company and
-conversation began to fatigue: he went less abroad, and was visited
-only by his intimate friends. His duty at college became too heavy for
-him, and he got an assistant, who took a share of the lectures, and
-relieved him from the fatigue of the experiments. The last course of
-lectures which he delivered was in the winter of 1796-7. After this,
-even lecturing was too much for his diminished strength, and he was
-obliged to absent himself from the class altogether; but he still
-retained his usual affability of temper, and his habitual cheerfulness,
-and even to the very last was accustomed to walk out and take
-occasional exercise. As his strength declined, his constitution became
-more and more delicate. Every cold he caught occasioned some degree of
-spitting of blood; yet he seemed to have this unfortunate disposition
-of body almost under command, so that he never allowed it to proceed
-far, or to occasion any distressing illness. He spun his thread of
-life to the very last fibre. He guarded against illness by restricting
-himself to an abstemious diet; and he met his increasing infirmities
-with a proportional increase of attention and care, regulating his food
-and exercise by the measure of his strength. Thus he made the most of a
-feeble constitution, by preventing the access of disease from abroad.
-And enjoyed a state of health which was feeble, indeed, but scarcely
-interrupted; as well as a mind undisturbed in the calm and cheerful use
-of its faculties. His only apprehension was that of a long-continued
-sick-bed--from the humane consideration of the trouble and distress
-that he might thus occasion to attending friends; and never was such
-generous wish more completely gratified than in his case.
-
-On the 10th of November, 1799, in the seventy-first year of his age, he
-expired without any convulsion, shock, or stupor, to announce or retard
-the approach of death. Being at table with his usual fare, some bread,
-a few prunes, and a measured quantity of milk, diluted with water,
-and having the cup in his hand when the last stroke of his pulse was
-to be given, he set it down on his knees, which were joined together,
-and kept it steady with his hand in the manner of a person perfectly
-at ease; and in this attitude expired without spilling a drop, and
-without a writhe in his countenance; as if an experiment had been
-required to show to his friends the facility with which he departed.
-His servant opened the door to tell him that some one had left his
-name; but getting no answer, stepped about halfway to him; and seeing
-him sitting in that easy posture, supporting his basin of milk with one
-hand, he thought that he had dropped asleep, which was sometimes wont
-to happen after meals. He went back and shut the door; but before he
-got down stairs some anxiety, which he could not account for, made him
-return and look again at his master. Even then he was satisfied, after
-coming pretty near him, and turned to go away; but he again returned,
-and coming close up to him, he found him without life. His very near
-neighbour, Mr. Benjamin Bell, the surgeon, was immediately sent for;
-but nothing whatever could be done.[185]
-
-[185] The preceding character of Dr. Black is from Professor Robison,
-who knew him intimately; and from Dr. Adam Ferguson, who was his next
-relation. See the preface to Dr. Black’s lectures. The portrait of Dr.
-Black prefixed to these lectures is an excellent likeness.
-
-Dr. Black’s writings are exceedingly few, consisting altogether of
-no more than three papers. The first, entitled “Experiments upon
-Magnesia alba, Quicklime, and other Alkaline Substances,” constituted
-the subject of his inaugural dissertation. It afterwards appeared
-in an English dress in one of the volumes of The Edinburgh Physical
-and Literary Essays, in the year 1755. Mr. Creech, the bookseller,
-published it in a separate pamphlet, together with Dr. Cullen’s
-little essay on the “cold produced by evaporating fluids,” in the
-year 1796. This essay exhibits one of the very finest examples of
-inductive reasoning to be found in the English language. The author
-shows that magnesia is a peculiar earthy body, possessed of properties
-very different from lime. He gives the properties of lime in a pure
-state, and proves that it differs from limestone merely by the absence
-of the carbonic acid, which is a constituent of limestone. Limestone
-is a _carbonate of lime_; quicklime is the pure uncombined earth. He
-shows that magnesia has also the property of combining with carbonic
-acid; that caustic potash, or soda, is merely these bodies in a pure
-or isolated state; while the mild alkalies are combinations of these
-bodies with carbonic acid. The reason why quicklime converts mild
-into caustic alkali is, that the lime has a stronger affinity for
-the carbonic acid than the alkali; hence the lime is converted into
-carbonate of lime, and the alkali, deprived of its carbonic acid,
-becomes caustic. Mild potash is a carbonate of potash; caustic potash,
-is potash freed from carbonic acid.--The publication of this essay
-occasioned a controversy in Germany, which was finally settled by
-Jacquin and Lavoisier, who repeated Dr. Black’s experiments and showed
-them to be correct.
-
-Dr. Black’s second paper was published in the Philosophical
-Transactions for 1775. It is entitled “The supposed Effect of boiling
-on Water, in disposing it to freeze more readily, ascertained by
-Experiments.” He shows, that when water that has been recently boiled
-is exposed to cold air, it begins to freeze as soon as it reaches the
-freezing point; while water that has not been boiled may be cooled some
-degrees below the freezing point before it begins to congeal. But if
-the unboiled water be constantly stirred during the whole time of its
-exposure, it begins to freeze when cooled down to the freezing point as
-well as the other. He shows that the difference between the two waters
-consists in this, that the boiled water is constantly absorbing air,
-which disturbs it, whereas the other water remains in a state of rest.
-
-His last paper was “An Analysis of the Water of some boiling Springs
-in Iceland,” published in the Transactions of the Royal Society of
-Edinburgh. This was the water of the Geyser spring, brought from
-Iceland by Sir J. Stanley. Dr. Black found it to contain a great deal
-of silica, held in solution in the water by caustic soda.
-
-The tempting career which Dr. Black opened, and which he was unable to
-prosecute for want of health, soon attracted the attention of one of
-the ablest men that Great Britain has produced--I mean Mr. Cavendish.
-
-The Honourable Henry Cavendish was born in London on the 10th of
-October, 1731: his father was Lord Charles Cavendish, a cadet of the
-house of Devonshire, one of the oldest families in England. During his
-father’s lifetime he was kept in rather narrow circumstances, being
-allowed an annuity of £500 only; while his apartments were a set of
-stables, fitted up for his accommodation. It was during this period
-that he acquired those habits of economy, and those singular oddities
-of character, which he exhibited ever after in so striking a manner. At
-his father’s death he was left a very considerable fortune; and an aunt
-who died at a later period bequeathed him a very handsome addition to
-it; but, in consequence of the habits of economy which he had acquired,
-it was not in his power to spend the greater part of his annual income.
-This occasioned a yearly increase to his capital, till at last it
-accumulated so much, without any care on his part, that at the period
-of his death he left behind him nearly £1,300,000; and he was at that
-time the greatest proprietor of stock in the Bank of England.
-
-On one occasion, the money in the hands of his bankers had accumulated
-to the amount of £70,000. These gentlemen thinking it improper to keep
-so large a sum in their hands, sent one of the partners to wait upon
-him, in order to learn how he desired it disposed of. This gentleman
-was admitted; and, after employing the necessary precautions to a man
-of Mr. Cavendish’s peculiar disposition, stated the circumstance, and
-begged to know whether it would not be proper to lay out the money at
-interest. Mr. Cavendish dryly answered, “You may lay it out if you
-please,” and left the room.
-
-He hardly ever went into any other society than that of his scientific
-friends: he never was absent from the weekly dinner of the Royal
-Society club at the Crown and Anchor Tavern in the Strand. At these
-dinners, when he happened to be seated near those that he liked, he
-often conversed a great deal; though at other times he was very silent.
-He was likewise a constant attendant at Sir Joseph Banks’s Sunday
-evening meetings. He had a house in London, which he only visited
-once or twice a-week at stated times, and without ever speaking to
-the servants: it contained an excellent library, to which he gave all
-literary men the freest and most unrestrained access. But he lived
-in a house on Clapham Common, where he scarcely ever received any
-visitors. His relation, Lord George Cavendish, to whom he left by will
-the greatest part of his fortune, visited him only once a-year, and the
-visit hardly ever exceeded ten or twelve minutes.
-
-He was shy and bashful to a degree bordering on disease; he could not
-bear to have any person introduced to him, or to be pointed out in any
-way as a remarkable man. One Sunday evening he was standing at Sir
-Joseph Banks’s in a crowded room, conversing with Mr. Hatchett, when
-Dr. Ingenhousz, who had a good deal of pomposity of manner, came up
-with an Austrian gentleman in his hand, and introduced him formally to
-Mr. Cavendish. He mentioned the titles and qualifications of his friend
-at great length, and said that he had been peculiarly anxious to be
-introduced to a philosopher so profound and so universally known and
-celebrated as Mr. Cavendish. As soon as Dr. Ingenhousz had finished,
-the Austrian gentleman began, and assured Mr. Cavendish that his
-principal reason for coming to London was to see and converse with one
-of the greatest ornaments of the age, and one of the most illustrious
-philosophers that ever existed. To all these high-flown speeches Mr.
-Cavendish answered not a word, but stood with his eyes cast down quite
-abashed and confounded. At last, spying an opening in the crowd, he
-darted through it with all the speed of which he was master; nor did he
-stop till he reached his carriage, which drove him directly home.
-
-Of a man, whose habits were so retired, and whose intercourse with
-society was so small, there is nothing else to relate except his
-scientific labours: the current of his life passed on with the utmost
-regularity; the description of a single day would convey a correct idea
-of his whole existence. At one time he was in the habit of keeping
-an individual to assist him in his experiments. This place was for
-some time filled by Sir Charles Blagden; but they did not agree well
-together, and after some time Sir Charles left him. Mr. Cavendish died
-on the 4th of February, 1810, aged seventy-eight years, four months,
-and six days. When he found himself dying, he gave directions to his
-servant to leave him alone, and not to return till a certain time which
-he specified, and by which period he expected to be no longer alive.
-The servant, however, who was aware of the state of his master, and
-was anxious about him, opened the door of the room before the time
-specified, and approached the bed to take a look at the dying man. Mr.
-Cavendish, who was still sensible, was offended at the intrusion, and
-ordered him out of the room with a voice of displeasure, commanding him
-not by any means to return till the time specified. When he did come
-back at that time, he found his master dead. What a contrast between
-the characters of Mr. Cavendish and Dr. Black!
-
-The appearance of Mr. Cavendish did not much prepossess strangers in
-his favour; he was somewhat above the middle size, his body rather
-thick, and his neck rather short. He stuttered a little in his speech,
-which gave him an air of awkwardness: his countenance was not strongly
-marked, so as to indicate the profound abilities which he possessed.
-This was probably owing to the total absence of all the violent
-passions. His education seems to have been very complete; he was an
-excellent mathematician, a profound electrician, and a most acute
-and ingenious chemist. He never ventured to give an opinion on any
-subject, unless he had studied it to the bottom. He appeared before
-the world first as a chemist, and afterwards as an electrician. The
-whole of his literary labours consist of eighteen papers, published
-in the Philosophical Transactions, which, though they occupy only a
-few pages, are full of the most important discoveries and the most
-profound investigations. Of these papers, there are ten which treat
-of chemical subjects, two treat of electricity, two of meteorology,
-three are connected with astronomy, and there is one, the last which
-he wrote, which gives his method of dividing astronomical instruments.
-Of the papers in question, those alone which treat of Chemistry can be
-analyzed in a work like this.
-
-1. His first paper, entitled, “Experiments on fictitious Air,” was
-published in the year 1766, when Mr. Cavendish was thirty-five years
-of age. Dr. Hales had demonstrated (as had previously been done by
-Van Helmont and Glauber) that _air_ is given out by a vast number of
-bodies in peculiar circumstances. But he never suspected that any of
-the _airs_ which he obtained differed from common air. Indeed common
-air had always been considered as an elementary substance to which
-every elastic fluid was referred. Dr. Black had shown that the mild
-alkalies and limestone, and carbonate of magnesia, were combinations
-of these bodies with a gaseous substance, to which he had given
-the name of _fixed air_; and he had pointed out various methods of
-collecting this fixed air; though he himself had not made much progress
-in investigating its properties. This paper of Mr. Cavendish may be
-considered as a continuation of the investigations begun by Dr. Black.
-He shows that there exist two species of air quite different in their
-properties from common air: and he calls them _inflammable air_ and
-_fixed air_.
-
-Inflammable air (hydrogen gas) is evolved when iron, zinc, or tin,
-are dissolved in dilute sulphuric or muriatic acid. Iron yielded
-about 1-22d part of its weight, of inflammable air, zinc about
-1-23d or 1-24th of its weight, and tin about 1-44th of its weight.
-The properties of the inflammable air were the same, whichever of
-the three metals was used to procure it, and whether they were
-dissolved in sulphuric or muriatic acids. When the sulphuric acid was
-concentrated, iron and zinc dissolved in it with difficulty and only
-by the assistance of heat. The air given out was not inflammable, but
-consisted of sulphurous acid. These facts induced Mr. Cavendish to
-conclude that the inflammable air evolved in the first case was the
-unaltered _phlogiston_ of the metals, while the sulphurous acid evolved
-in the second case, was a compound of the same phlogiston and a portion
-of the acid, which deprived it of its inflammability. This opinion was
-very different from that of Stahl, who considered combustible bodies as
-compounds of phlogiston with acids or calces.
-
-Cavendish found the specific gravity of his inflammable air about
-eleven times less than that of common air. This determination is under
-the truth; but the error is, at least in part, owing to the quantity
-of water held in solution by the air, and which, as Mr. Cavendish
-showed, amounted to about 1-9th of the weight of the air. He tried
-the combustibility of the inflammable air, when mixed with various
-proportions of common air, and found that it exploded with the greatest
-violence when mixed with rather more than its bulk of common air.
-
-Copper he found, when dissolved in muriatic acid by the assistance of
-heat, yielded no inflammable air, but an air which lost its elasticity
-when it came in contact with water. This _air_, the nature of which Mr.
-Cavendish did not examine, was _muriatic acid gas_, the properties of
-which were afterwards investigated by Dr. Priestley.
-
-The _fixed air_ (_carbonic acid gas_) on which Mr. Cavendish made his
-experiments was obtained by dissolving marble in muriatic acid. He
-found that it might be kept over mercury for any length of time without
-undergoing any alteration; that it was gradually absorbed by cold
-water; and that 100 measures of water of the temperature 55° absorbed
-103·8 measures of fixed air. The whole of the air thus absorbed was
-separated again by exposing the water to a boiling heat, or by leaving
-it for sometime in an open vessel. Alcohol (the specific gravity not
-mentioned) absorbed 2¼ times its bulk of this air, and olive-oil about
-1-3d of its bulk.
-
-The specific gravity of fixed air he found 1·57, that of common air
-being 1.[186] Fixed air is incapable of supporting combustion, and
-common air, when mixed with it, supports combustion a much shorter time
-than when pure. A small wax taper burnt eighty seconds in a receiver
-which held 180 ounce measures, when filled with common air only. The
-same taper burnt fifty-one seconds in the same receiver when filled
-with a mixture of one volume fixed air, and nineteen volumes of common
-air. When the fixed air was 3-40ths of the whole volume the taper
-burnt twenty-three seconds. When the fixed air was 1-10th, the taper
-burnt eleven seconds. When it was 6-55ths or 1-9·16 of the whole
-mixture, the taper would not burn at all.
-
-[186] This I apprehend to be a little above the truth, the true
-specific gravity of carbonic acid gas being 1·5277, that of air being
-unity.
-
-Mr. Cavendish was of opinion that more than one kind of fixed air was
-given out by marble; in other words, that the elastic fluid emitted,
-consisted of two different airs, one more absorbable by water than
-the other. He drew his conclusion from the circumstance that after a
-solution of potash had been exposed to a quantity of fixed air for
-some time, it ceased to absorb any more; yet, if the residual portion
-of air were thrown away and new fixed air substituted in its place, it
-began to absorb again; but Mr. Dalton has since given a satisfactory
-explanation of this seeming anomaly by showing that the absorbability
-of fixed air in water is proportional to its purity, and that when
-mixed with a great quantity of common air or any other gas not soluble
-in water, it ceases to be sensibly absorbed.
-
-Mr. Cavendish ascertained the quantity of fixed air contained in
-marble, carbonate of ammonia, common pearlashes, and carbonate of
-potash: but notwithstanding the care with which these experiments were
-made they are of little value; because the proper precautions could not
-be taken, in that infant state of chemical science, to have these salts
-in a state of purity. The following were the results obtained by Mr.
-Cavendish:
-
-  1000 grains of marble contained 408 grs. fixed air.
-  1000   --   carb. of ammonia    533        --
-  1000   --   pearlashes          284        --
-  1000   --   carb. of potash     423        --
-
-Supposing the marble, carbonate of ammonia, and carbonate of potash, to
-have been pure anhydrous simple salts, their composition would be
-
-  1000 grains of marble contain 440 grs. fixed air.
-  1000   --   carb. of ammonia  709·6      --
-  1000   --   carb. of potash   314·2      --
-
-Bicarbonate of potash was first obtained by Dr. Black. Mr. Cavendish
-formed the salt by dissolving pearlashes in water, and passing a
-current of carbonic acid gas through the solution till it deposited
-crystals. These crystals were not altered by exposure to the air, did
-not deliquesce, and were soluble in about four times their weight of
-cold water.
-
-Dr. M’Bride had already ascertained that vegetable and animal
-substances yield fixed air by putrefaction and fermentation. Mr.
-Cavendish found by experiment that sugar when dissolved in water
-and fermented, gives out 57-100ths of its weight of fixed air,
-possessing exactly the properties of fixed air from marble. During
-the fermentation no air was absorbed, nor was any change induced on
-the common air, at the surface of the fermenting liquor. Apple-juice
-fermented much faster than sugar; but the phenomena were the same,
-and the fixed air emitted amounted to 381/1000 of the weight of the
-solid extract of apples. Gravy and raw meat yielded inflammable air
-during their putrefaction, the former in much greater quantity than the
-latter. This air, as far as Mr. Cavendish’s experiments went, he found
-the same as the inflammable air from zinc by dilute sulphuric acid; but
-its specific gravity was a little higher.
-
-This paper of Mr. Cavendish was the first attempt by chemists to
-collect the different kinds of air, and endeavour to ascertain their
-nature. Hence all his processes were in some measure new: they served
-as a model to future experimenters, and were gradually brought to their
-present state of simplicity and perfection. He was the first person
-who attempted to determine the specific gravity of airs, by comparing
-their weight with that of the same bulk of common air; and though
-his apparatus was defective, yet the principle was good, and is the
-very same which is still employed to accomplish the same object. Mr.
-Cavendish then first began the true investigation of gases, and in his
-first paper he determined the peculiar nature of two very remarkable
-gases, _carbonic_ and _hydrogen_.
-
-2. Mineral waters have at all times attracted the attention of the
-faculty in consequence of their peculiar properties and medical
-virtues. Some faint steps towards their investigation were taken by
-Boyle. Du Clos attempted a chemical analysis of the mineral waters in
-France; and Hierne made a similar investigation of the mineral waters
-of Sweden. Though these experiments were rude and inaccurate, they
-led to the knowledge of several facts respecting mineral waters which
-chemists were unable to explain. One of these was the existence of a
-considerable quantity of _calcareous earth_ in some mineral waters,
-which was precipitated by boiling. Nobody could conceive in what way
-this insoluble substance (_carbonate of lime_) was held in solution,
-nor why it was thrown down when the water was raised to a boiling
-heat. It was to determine this point that Mr. Cavendish made his
-experiments on Rathbone-place water, which were published in the year
-1767, and which may be considered as the first analysis of a mineral
-water that possessed tolerable accuracy. Rathbone-place water was
-raised by a pump, and supplied the portion of London in its immediate
-neighbourhood. Mr. Cavendish found that when boiled, it deposited a
-quantity of earthy matter, consisting chiefly of lime, but containing
-also a little magnesia. This he showed was held in solution by fixed
-air; and he proved experimentally, that when an excess of this gas
-is present, it has the property of holding lime and magnesia in
-solution.[187] Besides these earthy carbonates, the water was found to
-contain a little ammonia, some sulphate of lime, and some common salt.
-Mr. Cavendish examined, likewise, some other pump-water in London, and
-showed that it contained lime, held in solution by carbonic acid.
-
-[187] The salts held in solution are in the state of bicarbonates of
-lime and magnesia. Boiling drives off half the carbonic acid, and the
-simple carbonates being insoluble are precipitated.
-
-3. Dr. Priestley, at a pretty early period of his chemical career,
-had discovered that when nitrous gas is mixed with common air over
-water, a diminution of bulk takes place; that there is a still greater
-diminution of bulk when oxygen gas is employed instead of common
-air; and that the diminution is always proportional to the quantity
-of oxygen gas present in the gas mixed with the nitrous gas. This
-discovery induced him to employ nitrous gas as a test of the quantity
-of oxygen present in common air; and various instruments were contrived
-to facilitate the mixture of the gases, and the measurement of the
-diminution of volume which took place. As the goodness of air, or its
-fitness to support combustion, and maintain animal life, was conceived
-to depend upon the proportion of oxygen gas which it contained, these
-instruments were distinguished by the name of _eudiometers_; the
-simplest of them was contrived by Fontana, and is usually distinguished
-by the name of the _eudiometer of Fontana_. Philosophers, in examining
-air by means of this instrument, at various seasons, and in various
-places, had found considerable differences in the diminution of
-bulk: hence they inferred that the proportion of oxygen varies in
-different places; and to this variation they ascribed the healthiness
-or noxiousness of particular situations. For example, Dr. Ingenhousz
-had found a greater proportion of oxygen in the air above the sea, and
-on the sea-coast; and to this he ascribed the healthiness of maritime
-situations. Mr. Cavendish examined this important point with his usual
-patient industry and acute discernment, and published the result in the
-Philosophical Transactions for 1783. He ascertained that the apparent
-variations were owing to inaccuracies in making the experiment; and
-that when the requisite precautions are taken, the proportion of oxygen
-in air is found constant in all places, and at all seasons. This
-conclusion has since been confirmed by numerous observations in every
-part of the globe. Mr. Cavendish also analyzed common air, and found it
-to consist of
-
-   79·16 volumes azotic gas,
-   20·84 volumes oxygen gas.
-  ------
-  100·00
-
-4. For many years it was the opinion of chemists that mercury is
-essentially liquid, and that no degree of cold is capable of congealing
-it. Professor Braun’s accidental discovery that it may be frozen by
-cold, like other liquids, was at first doubted; and when it was finally
-established by the most conclusive experiments, it was inferred from
-the observations of Braun that the freezing point of mercury is several
-hundred degrees below zero on Fahrenheit’s scale. It became an object
-of great importance to determine the exact point of the congelation
-of this metal by accurate experiments. This was done at Hudson’s Bay,
-by Mr. Hutchins, who followed a set of directions given him by Mr.
-Cavendish, and from his experiments Mr. Cavendish, in a paper inserted
-in the Philosophical Transactions for 1783, deduced that the freezing
-point of mercury is 38·66 degrees below the zero of Fahrenheit’s
-thermometer.
-
-5. These experiments naturally drew the attention of Mr. Cavendish to
-the phenomena of freezing, to the action of freezing mixtures, and the
-congelation of acids. He employed Mr. M’Nab, who was settled in the
-neighbourhood of Hudson’s Bay, to make the requisite experiments; and
-he published two very curious and important papers on these subjects
-in the Philosophical Transactions for 1786 and 1788. He explained the
-phenomena of congelation exactly according to the theory of Dr. Black,
-but rejecting the hypothesis that heat is a _substance_ sui generis,
-and thinking it more probable, with Sir Isaac Newton, that it is
-owing to the rapid internal motion of the particles of the hot body.
-The latent heat of water, he found to be 150°. The observations on the
-congelation of nitric and sulphuric acids are highly interesting: he
-showed that their freezing points vary considerably, according to the
-strength of each; and drew up tables indicating the freezing points of
-acids, of various degrees of strength.
-
-6. But the most splendid and valuable of Mr. Cavendish’s chemical
-experiments were published in two papers, entitled, “Experiments on
-Air,” in the Transactions of the Royal Society for 1784 and 1785. The
-object of these experiments was to determine what happened during the
-_phlogistication of air_, as it was at that time termed; that is, the
-change which air underwent when metals were calcined in contact with
-it, when sulphur or phosphorus was burnt in it, and in several similar
-processes. He showed, in the first place, that there was no reason for
-supposing that carbonic acid was formed, except when some animal or
-vegetable substance was present; that when _hydrogen gas_ was burnt
-in contact with air or oxygen gas, it _combined_ with that gas, and
-formed _water_; that _nitrous gas_, by combining with the oxygen of the
-atmosphere, formed _nitrous acid_; and that when _oxygen_ and _azotic_
-gas are mixed in the requisite proportions, and electric sparks passed
-through the mixture, they _combine_, and form _nitric_ acid.
-
-The first of these opinions occasioned a controversy between Mr.
-Cavendish, and Mr. Kirwan, who maintained that carbonic acid is always
-produced when air is phlogisticated. Two papers on this subject by
-Kirwan, and one by Cavendish, are inserted in the Philosophical
-Transactions for 1784, each remarkable examples of the peculiar manner
-of the respective writers. All the arguments of Kirwan are founded on
-the experiments of others. He displays great reading, and a strong
-memory; but does not discriminate between the merits of the chemists
-on whose authority he founds his opinions. Mr. Cavendish, on the other
-hand, never advances a single opinion, which he has not put to the
-test of experiment; and never suffers himself to go any further than
-his experiment will warrant. Whatever is not accurately determined
-by unexceptionable trials, is merely stated as a conjecture on which
-little stress is laid.
-
-In the first of these celebrated papers, Mr. Cavendish has drawn a
-comparison between the phlogistic and antiphlogistic theories of
-chemistry; he has shown that each of them is capable of explaining
-the phenomena in a satisfactory manner; though it is impossible to
-demonstrate the truth of either; and he has given the reasons which
-induced him to prefer the phlogistic theory--reasons which the French
-chemists were unable to refute, and which they were wise enough not
-to notice. There cannot be a more striking proof of the influence of
-fashion, even in science, and of the unwarrantable precipitation with
-which opinions are rejected or embraced by philosophers, than the total
-inattention paid by the chemical world to this admirable dissertation.
-Had Mr. Kirwan adopted the opinions of Mr. Cavendish, when he undertook
-the defence of phlogiston, instead of trusting to the vague experiments
-of inaccurate chemists, he would not have been obliged to yield to his
-French antagonists, and the antiphlogistic theory would not so speedily
-have gained ground.
-
-Such is an epitome of the chemical papers of Mr. Cavendish. They
-contain five notable discoveries; namely, 1. The nature and properties
-of hydrogen gas. 2. The solubility of bicarbonates of lime and magnesia
-in water. 3. The exact proportion of the constituents of common air. 4.
-The composition of water. 5. The composition of nitric acid. It is to
-him also that we are indebted for our knowledge of the freezing point
-of mercury; and he was likewise the first person who showed that potash
-has a stronger affinity for acids than soda has. His experiments on the
-subject are to be found in a paper on Mineral Waters, published in the
-Philosophical Transactions, by Dr. Donald Monro.
-
-
-
-
-END OF VOL. I.
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-comprising a Biographical Sketch of the Historian; and his Anabasis, or
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-comprising a Biographical Sketch of the Historian; and the first two
-Books of his History, containing a Narrative of the Acquisition of
-the Kingdom of Lydia by Crœsus, and the subsequent overthrow of the
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-and Lacedæmon; with an account of Egypt, its Customs, Manners, and
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-[Transcriber’s Note:
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-Inconsistent spelling and hyphenation are as in the original.
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-Page 51: “zeb” changed to read “zahav”.
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-<pre>
-
-The Project Gutenberg EBook of The History of Chemistry, Volume 1 (of 2), by 
-Thomas Thomson
-
-This eBook is for the use of anyone anywhere in the United States and most
-other parts of the world at no cost and with almost no restrictions
-whatsoever.  You may copy it, give it away or re-use it under the terms of
-the Project Gutenberg License included with this eBook or online at
-www.gutenberg.org.  If you are not located in the United States, you'll have
-to check the laws of the country where you are located before using this ebook.
-
-Title: The History of Chemistry, Volume 1 (of 2)
-
-Author: Thomas Thomson
-
-Release Date: November 27, 2015 [EBook #50565]
-
-Language: English
-
-Character set encoding: UTF-8
-
-*** START OF THIS PROJECT GUTENBERG EBOOK HISTORY OF CHEMISTRY, VOL 1 ***
-
-
-
-
-Produced by MWS, Wayne Hammond and the Online Distributed
-Proofreading Team at http://www.pgdp.net (This file was
-produced from images generously made available by The
-Internet Archive)
-
-
-
-
-
-
-</pre>
-
-
-<div class="figcenter">
-<img id="coverpage" src="images/cover.jpg"
-alt="" />
-<p class="copy">The cover image was created by the transcriber and is placed in the public domain.</p>
-</div>
-
-<hr class="chap" />
-
-<div class="figcenter">
-<img src="images/i_frontis.jpg"
-alt="" />
-<span class="table" style="width: 450px">
-  <span class="trow">
-    <span class="tcell tdl"><i>Raeburn. pinx<sup>t</sup>.</i></span>
-    <span class="tcell tdr"><i>Dean, sculp<sup>t</sup>.</i></span>
-  </span>
-</span>
-<span class="caption">JOSEPH BLACK, M.D. F.R.S.E.<br />
-<small><i>London. Published by Henry Colburn &amp; Richard Bentley. 1830.</i></small>
-</span>
-</div>
-
-<hr />
-
-<h1><span class="medium">THE</span><br />
-
-HISTORY<br />
-
-<span class="medium">OF</span><br />
-
-CHEMISTRY.<br />
-
-<span class="medium">BY</span><br />
-<span class="xlarge">THOMAS THOMSON, M.D. F.R.S.E.</span><br />
-<span class="small">PROFESSOR OF CHEMISTRY IN THE UNIVERSITY OF GLASGOW.</span><br />
-
-<span class="large">IN TWO VOLUMES.</span><br />
-
-<span class="xlarge">VOL. I.</span><br />
-
-<span class="large">LONDON:<br />
-HENRY COLBURN, AND RICHARD BENTLEY,</span><br />
-<span class="medium">NEW BURLINGTON STREET.<br />
-
-1830.</span><br />
-
-<span class="pagenum" id="Page_i">i</span>
-
-<span class="medium">C. WHITING, BEAUFORT HOUSE, STRAND.</span></h1>
-
-<hr class="chap" />
-
-<p><span class="pagenum" id="Page_ii">ii</span></p>
-
-<h2 id="PREFACE">PREFACE.</h2>
-
-<p>It may be proper, perhaps, to state here, in a very
-few words, the objects which the author had in view
-in drawing up the following History of Chemistry.
-Alchymy, or the art of making gold, with which the
-science originated, furnishes too curious a portion of
-the aberrations of the human intellect to be passed over
-in silence. The writings of the alchymists are so voluminous
-and so mystical, that it would have afforded
-materials for a very long work. But I was prevented
-<span class="pagenum" id="Page_iii">iii</span>
-from extending this part of the subject to any greater
-length than I have done, by considering the small
-quantity of information which could have been gleaned
-from the reveries of these fanatics or impostors; I
-thought it sufficient to give a general view of the nature
-of their pursuits: but in order to put it in the
-power of those who feel inclined to prosecute such investigations,
-I have given a catalogue of the most
-eminent of the alchymists and a list of their works, so
-far as I am acquainted with them. This catalogue
-might have been greatly extended. Indeed it would
-have been possible to have added several hundred
-names. But I think the works which I have quoted
-are more than almost any reasonable man would think
-it worth his while to peruse; and I can state, from experience,
-that the information gained by such a perusal
-will very seldom repay the trouble.</p>
-
-<hr class="tb" />
-
-<p>The account of the chemical arts, with which the
-ancients were acquainted, is necessarily imperfect;
-because all arts and trades were held in so much contempt
-by them that they did not think it worth their
-while to make themselves acquainted with the processes.
-<span class="pagenum" id="Page_iv">iv</span>
-My chief guide has been Pliny, but many of
-his descriptions are unintelligible, obviously from his
-ignorance of the arts which he attempts to describe.
-Thus circumstanced, I thought it better to be short
-than to waste a great deal of paper, as some have done,
-on hypothesis and conjecture.</p>
-
-<hr class="tb" />
-
-<p>The account of the Chemistry of the Arabians is
-almost entirely limited to the works of Geber, which I
-consider to be the first book on Chemistry that ever
-was published, and to constitute, in every point of
-view, an exceedingly curious performance. I was
-much struck with the vast number of facts with which
-he was acquainted, and which have generally been supposed
-to have been discovered long after his time. I
-have, therefore, been at some pains in endeavouring to
-convey a notion of Geber’s opinions to the readers of
-this history; but am not sure that I have succeeded.
-I have generally given his own words, as literally as
-possible, and, wherever it would answer the purpose,
-have employed the English translation of 1678.</p>
-
-<p>Paracelsus gave origin to so great a revolution in medicine
-and the sciences connected with it, that it would
-<span class="pagenum" id="Page_v">v</span>
-have been unpardonable not to have attempted to lay
-his opinions and views before the reader; but, after perusing
-several of his most important treatises, I found
-it almost impossible to form accurate notions on the
-subject. I have, therefore, endeavoured to make use
-of his own words as much as possible, that the want
-of consistency and the mysticism of his opinions may
-fall upon his own head. Should the reader find any
-difficulty in understanding the philosophy of Paracelsus,
-he will be in no worse a situation than every one
-has been who has attempted to delineate the principles
-of this prince of quacks and impostors. Van
-Helmont’s merits were of a much higher kind, and I
-have endeavoured to do him justice; though his weaknesses
-are so visible that it requires much candour
-and patience to discriminate accurately between his
-excellencies and his foibles.</p>
-
-<hr class="tb" />
-
-<p>The history of Iatro-chemistry forms a branch of
-our subject scarcely less extraordinary than Alchymy
-itself. It might have been extended to a much greater
-length than I have done. The reason why I did not
-enter into longer details was, that I thought the subject
-<span class="pagenum" id="Page_vi">vi</span>
-more intimately connected with the history of medicine
-than of chemistry: it undoubtedly contributed to the
-improvement of chemistry; not, however, by the
-opinions or the physiology of the iatro-chemists, but by
-inducing their contemporaries and successors to apply
-themselves to the discovery of chemical medicines.</p>
-
-<hr class="tb" />
-
-<p>The History of Chemistry, after a theory of combustion
-had been introduced by Beccher and Stahl, becomes
-much more important. It now shook off the
-trammels of alchymy, and ventured to claim its station
-among the physical sciences. I have found it necessary
-to treat of its progress during the eighteenth century
-rather succinctly, but I hope so as to be easily intelligible.
-This made it necessary to omit the names of
-many meritorious individuals, who supplied a share of
-the contributions which the science was continually
-receiving from all quarters. I have confined myself
-to those who made the most prominent figure as chemical
-discoverers. I had no other choice but to follow
-this plan, unless I had doubled the size of this little
-work, which would have rendered it less agreeable and
-less valuable to the general reader.
-<span class="pagenum" id="Page_vii">vii</span></p>
-
-<hr class="tb" />
-
-<p>With respect to the History of Chemistry during
-that portion of the nineteenth century which is already
-past, it was beset with several difficulties. Many of
-the individuals, of whose labours I had occasion to
-speak, are still actively engaged in the prosecution of
-their useful works. Others have but just left the
-arena, and their friends and relations still remain to
-appreciate their merits. In treating of this branch of
-the science (by far the most important of all) I have
-followed the same plan as in the history of the preceding
-century. I have found it necessary to omit many
-names that would undoubtedly have found a place in a
-larger work, but which the limited extent to which I
-was obliged to confine myself, necessarily compelled
-me to pass over. I have been anxious not to injure the
-character of any one, while I have rigidly adhered to
-truth, so far as I was acquainted with it. Should I
-have been so unfortunate as to hurt the feelings of any
-individual by any remarks of mine in the following
-pages, it will give me great pain; and the only alleviation
-will be the consciousness of the total absence on
-my part of any malignant intention. To gratify the
-wishes of every individual may, perhaps, be impossible;
-<span class="pagenum" id="Page_viii">viii</span>
-but I can say, with truth, that my uniform
-object has been to do justice to the merits of all, so far
-as my own limited knowledge put it in my power
-to do.
-<span class="pagenum" id="Page_ix">ix</span>
-<span class="pagenum" id="Page_x">x</span></p>
-
-<hr class="chap" />
-<h2 id="CONTENTS">CONTENTS<br />
-
-<span class="medium">OF</span><br />
-
-<span class="large">THE FIRST VOLUME.</span></h2>
-
-<table>
-  <tr>
-    <td></td>
-    <td class="tdr">Page</td>
-  </tr>
-  <tr>
-    <td><a href="#INTRODUCTION">Introduction</a></td>
-    <td class="tdr">1</td>
-  </tr>
-  <tr>
-    <th colspan="2"><a href="#CHAPTER_I">CHAPTER I.</a></th>
-  </tr>
-  <tr>
-    <td>Of Alchymy</td>
-    <td class="tdr">3</td>
-  </tr>
-  <tr>
-    <th colspan="2"><a href="#CHAPTER_II">CHAPTER II.</a></th>
-  </tr>
-  <tr>
-    <td>Of the chemical knowledge possessed by the Ancients</td>
-    <td class="tdr">49</td>
-  </tr>
-  <tr>
-    <th colspan="2"><a href="#CHAPTER_III">CHAPTER III.</a></th>
-  </tr>
-  <tr>
-    <td>Chemistry of the Arabians</td>
-    <td class="tdr">110</td>
-  </tr>
-  <tr>
-    <th colspan="2"><a href="#CHAPTER_IV">CHAPTER IV.</a></th>
-  </tr>
-  <tr>
-    <td>Of the progress of Chemistry under Paracelsus and his disciples</td>
-    <td class="tdr">140</td>
-  </tr>
-  <tr>
-    <th colspan="2"><a href="#CHAPTER_V">CHAPTER V.</a></th>
-  </tr>
-  <tr>
-    <td>Of Van Helmont and the Iatro-Chemists</td>
-    <td class="tdr">179</td>
-  </tr>
-  <tr>
-    <th colspan="2"><a href="#CHAPTER_VI">CHAPTER VI.</a></th>
-  </tr>
-  <tr>
-    <td>Of Agricola and metallurgy</td>
-    <td class="tdr">219</td>
-  </tr>
-  <tr>
-    <th colspan="2"><a href="#CHAPTER_VII">CHAPTER VII.</a></th>
-  </tr>
-  <tr>
-    <td>Of Glauber, Lemery, and some other chemists of the end of the seventeenth century</td>
-    <td class="tdr">226</td>
-  </tr>
-  <tr>
-    <th colspan="2"><a href="#CHAPTER_VIII">CHAPTER VIII.</a></th>
-  </tr>
-  <tr>
-    <td>Of the attempts to establish a theory in chemistry</td>
-    <td class="tdr">246</td>
-  </tr>
-  <tr>
-    <th colspan="2"><a href="#CHAPTER_IX">CHAPTER IX.</a></th>
-  </tr>
-  <tr>
-    <td>Of the foundation and progress of scientific chemistry in Great Britain</td>
-    <td class="tdr">303</td>
-  </tr>
-</table>
-<p><span class="pagenum" id="Page_xi">xi</span></p>
-
-<hr class="chap" />
-
-<p><span class="pagenum" id="Page_1">1</span></p>
-
-<p class="ph1">HISTORY OF CHEMISTRY.</p>
-
-<hr class="chap" />
-<h2 id="INTRODUCTION">INTRODUCTION.</h2>
-
-<p>Chemistry, unlike the other sciences, sprang originally
-from delusion and superstition, and was at its
-commencement exactly on a level with magic and
-astrology. Even after it began to be useful to
-man, by furnishing him with better and more powerful
-medicines than the ancient physicians were acquainted
-with, it was long before it could shake off
-the trammels of alchymy, which hung upon it like a
-nightmare, cramping and blunting all its energies,
-and exposing it to the scorn and contempt of the
-enlightened part of mankind. It was not till about
-the middle of the eighteenth century that it was
-able to free itself from these delusions, and to venture
-abroad in all the native dignity of a useful science.
-It was then that its utility and its importance
-began to attract the attention of the world; that it
-drew within its vortex some of the greatest and most
-active men in every country; and that it advanced
-towards perfection with an accelerated pace. The
-field which it now presents to our view is vast and
-imposing. Its paramount utility is universally acknowledged.
-It has become a necessary part of education.
-<span class="pagenum" id="Page_2">2</span>
-It has contributed as much to the progress of
-society, and has done as much to augment the comforts
-and conveniences of life, and to increase the
-power and the resources of mankind, as all the other
-sciences put together.</p>
-
-<p>It is natural to feel a desire to be acquainted with
-the origin and the progress of such a science; and to
-know something of the history and character of those
-numerous votaries to whom it is indebted for its progress
-and improvement. The object of this little work
-is to gratify these laudable wishes, by taking a rapid
-view of the progress of Chemistry, from its first rude
-and disgraceful beginnings till it has reached its present
-state of importance and dignity. I shall divide
-the subject into fifteen chapters. In the first I shall
-treat of Alchymy, which may be considered as the inauspicious
-commencement of the science, and which,
-in fact, consists of little else than an account of dupes
-and impostors; every where so full of fiction and obscurity,
-that it is a hopeless and almost impossible
-task to reach the truth. In the second chapter I shall
-endeavour to point out the few small chemical rills,
-which were known to the ancients. These I shall follow
-in their progress, in the succeeding chapters, till
-at last, augmented by an infinite number of streams
-flowing at once from a thousand different quarters,
-they have swelled to the mighty river, which now flows
-on majestically, wafting wealth and information to the
-civilized world.
-<span class="pagenum" id="Page_3">3</span></p>
-
-<hr class="chap" />
-<h2 id="CHAPTER_I">CHAPTER I.<br />
-
-<span class="large">OF ALCHYMY.</span></h2>
-
-<p>The word <i>chemistry</i> (χημεια, <i>chemeia</i>) first occurs in
-Suidas, a Greek writer, who is supposed to have lived
-in the eleventh century, and to have written his
-lexicon during the reign of Alexius Comnenus.<a id="FNanchor_1" href="#Footnote_1" class="fnanchor">1</a>
-Under the word χημεια in his dictionary we find the
-following passage:</p>
-
-<p>“<span class="smcap">Chemistry</span>, the preparation of silver and gold.
-The books on it were sought out by Dioclesian and
-burnt, on account of the new attempts made by the
-Egyptians against him. He treated them with cruelty
-and harshness, as he sought out the books written by
-the ancients on the chemistry (Περι χημειας) of gold
-and silver, and burnt them. His object was to prevent
-the Egyptians from becoming rich by the knowledge
-of this art, lest, emboldened by abundance of
-wealth, they might be induced afterwards to resist the
-Romans.”<a id="FNanchor_2" href="#Footnote_2" class="fnanchor">2</a>
-<span class="pagenum" id="Page_4">4</span></p>
-
-<p>Under the word Δερας, <i>deras</i> (<i>a skin</i>), in the lexicon,
-occurs the following passage: “Δερας, the golden fleece,
-which Jason and the Argonauts (after a voyage through
-the Black Sea to Colchis) took, together with Medea,
-daughter of &AElig;tes, the king. But this was not what
-the poets represent, but a treatise written on skins
-(δερμασι), teaching how gold might be prepared by
-chemistry. Probably, therefore, it was called by
-those who lived at that time, <i>golden</i>, on account of
-its great importance.”<a id="FNanchor_3" href="#Footnote_3" class="fnanchor">3</a></p>
-
-<p>From these two passages there can be no doubt that
-the word <i>chemistry</i> was known to the Greeks in the eleventh
-century; and that it signified, at that time, the
-art of making gold and silver. It appears, further,
-that in Suidas’s opinion, this art was known to the
-Egyptians in the time of Dioclesian; that Dioclesian
-was convinced of its reality; and that, to put an end
-to it, he collected and burnt all the chemical writings
-to be found in Egypt. Nay, Suidas affirms that a
-book, describing the art of making gold, existed at
-the time of the Argonauts: and that the object of
-Jason and his followers was to get possession of that
-invaluable treatise, which the poets disguised under
-the term <i>golden fleece</i>.</p>
-
-<p>The first meaning, then, of chemistry, was the <i>art
-of making gold</i>. And this art, in the opinion of
-Suidas, was understood at least as early as one thousand
-<span class="pagenum" id="Page_5">5</span>
-two hundred and twenty-five years before the
-Christian era: for that is the period at which the Argonautic
-expedition is commonly fixed by chronologists.</p>
-
-<p>Though the lexicon of Suidas be the first printed
-book in which the word Chemistry occurs, yet it is
-said to be found in much earlier tracts, which still
-continue in manuscript. Thus Scaliger informs us
-that he perused a Greek manuscript of Zosimus, the
-Panapolite, written in the fifth century, and deposited
-in the King of France’s library. Olaus Borrichius
-mentions this manuscript; but in such terms that it
-is difficult to know whether he had himself read it;
-though he seems to insinuate as much.<a id="FNanchor_4" href="#Footnote_4" class="fnanchor">4</a> The title
-of this manuscript is said to be “A faithful Description
-of the sacred and divine Art of making Gold
-and Silver, by Zosimus, the Panapolite.”<a id="FNanchor_5" href="#Footnote_5" class="fnanchor">5</a> In this
-treatise, Zosimus distinguishes the art by the name
-χημια, <i>chemia</i>. From a passage in this manuscript,
-quoted by Scaliger, and given also by Olaus Borrichius,
-it appears that Zosimus carries the antiquity of
-the art of making gold and silver, much higher than
-Suidas has ventured to do. The following is a literal
-translation of this curious passage:</p>
-
-<p>“The sacred Scriptures inform us that there exists
-a tribe of genii, who make use of women. Hermes
-mentions this circumstance in his Physics; and almost
-every writing (λογος), whether sacred (φανερος) or apocryphal,
-states the same thing. The ancient and
-divine Scriptures inform us, that the angels, captivated
-by women, taught them all the operations of nature.
-Offence being taken at this, they remained out of
-heaven, because they had taught mankind all manner
-<span class="pagenum" id="Page_6">6</span>
-of evil, and things which could not be advantageous
-to their souls. The Scriptures inform us that the
-giants sprang from these embraces. Chema is the
-first of their traditions respecting these arts. The
-book itself they called Chema; hence the art is called
-<i>Chemia</i>.”</p>
-
-<p>Zosimus is not the only Greek writer on Chemistry.
-Olaus Borrichius has given us a list of thirty-eight
-treatises, which he says exist in the libraries of Rome,
-Venice, and Paris: and Dr. Shaw has increased this
-list to eighty-nine.<a id="FNanchor_6" href="#Footnote_6" class="fnanchor">6</a> But among these we find the
-names of Hermes, Isis, Horus, Democritus, Cleopatra,
-Porphyry, Plato, &amp;c.&mdash;names which undoubtedly have
-been affixed to the writings of comparatively modern
-and obscure authors. The style of these authors, as
-Borrichius informs us, is barbarous. They are chiefly
-the production of ecclesiastics, who lived between the
-fifth and twelfth centuries. In these tracts, the art
-of which they treat is sometimes called <i>chemistry</i>
-(χημεια); sometimes the <i>chemical art</i> (χημευτικα);
-sometimes the <i>holy art</i>; and the <i>philosopher’s stone</i>.</p>
-
-<p>It is evident from this, that between the fifth century
-and the taking of Constantinople in the fifteenth
-century, the Greeks believed in the possibility of making
-gold and silver artificially; and that the art which
-professed to teach these processes was called by them
-Chemistry.</p>
-
-<p>These opinions passed from the Greeks to the Arabians,
-when, under the califs of the family of Abassides,
-they began to turn their attention to science,
-about the beginning of the ninth century; and when
-the enlightened zeal of the Fatimites in Africa, and
-the Ommiades in Spain, encouraged the cultivation
-of the sciences. From Spain they gradually made
-their way into the different Christian kingdoms of Europe.
-From the eleventh to the sixteenth century, the art
-<span class="pagenum" id="Page_7">7</span>
-of making gold and silver was cultivated in Germany,
-Italy, France, and England, with considerable assiduity.
-The cultivators of it were called <i>Alchymists</i>;
-a name obviously derived from the Greek word <i>chemia</i>,
-but somewhat altered by the Arabians. Many
-alchymistical tracts were written during that period.
-A considerable number of them were collected by
-Lazarus Zetzner, and published at Strasburg in 1602,
-under the title of “Theatrum Chemicum, pr&aelig;cipuos
-selectorum auctorum tractatus de Chemi&aelig; et Lapidis
-Philosophici Antiquitate, veritate, jure, pr&aelig;stantia,
-et operationibus continens in gratiam ver&aelig; Chemi&aelig;
-et Medicin&aelig; Chemic&aelig; Studiosorum (ut qui uberrimam
-unde optimorum remediorum messem facere poterunt)
-congestum et in quatuor partes seu volumina digestum.”
-This book contains one hundred and five
-different alchymistical tracts.</p>
-
-<p>In the year 1610 another collection of alchymistical
-tracts was published at Basil, in three volumes, under
-the title of “Artis Aurifer&aelig; quam Chemiam vocant volumina
-tria.” It contains forty-seven different tracts.</p>
-
-<p>In the year 1702 Mangetus published at Geneva
-two very large folio volumes, under the name of “Bibliotheca
-Chemica Curiosa, seu rerum ad Alchymiam
-pertinentium thesaurus instructissimus, quo non tantum
-Artis Aurifer&aelig; ac scriptorum in ea nobiliorum
-Historia traditur; lapidis veritas Argumentis et Experimentis
-innumeris, immo et Juris Consultorum Judiciis
-evincitur; Termini obscuriores explicantur; Cautiones
-contra Impostores et Difficultates in Tinctura
-Universali conficienda occurrentes declarantur: verum
-etiam Tractatus omnes Virorum Celebriorum, qui in
-Magno sudarunt Elixyre, quique ab ipso Hermete, ut
-dicitur, Trismegisto, ad nostra usque tempora de Chrysopoea
-scripserunt, cum pr&aelig;cipuis suis Commentariis,
-concinno ordine dispositi exhibentur.” This Bibliotheca
-contains one hundred and twenty-two alchymistical
-treatises, many of them of considerable length.
-<span class="pagenum" id="Page_8">8</span></p>
-
-<p>Two additional volumes of the Theatrum Chemicum
-were afterwards published; but these I have never
-had an opportunity of seeing.</p>
-
-<p>From these collections, which exhibit a pretty complete
-view of the writings of the alchymists, a tolerably
-accurate notion may be formed of their opinions. But
-before attempting to lay open the theories and notions
-by which the alchymists were guided, it will be proper
-to state the opinions which were gradually adopted
-respecting the origin of Alchymy, and the contrivances
-by which these opinions were supported.</p>
-
-<p>Zosimus, the Panapolite, in a passage quoted above
-informs us, that the art of making gold and silver was
-not a human invention; but was communicated to
-mankind by angels or demons. These angels, he says,
-fell in love with women, and were induced by their
-charms to abandon heaven altogether, and take up
-their abode upon earth. Among other pieces of information
-which these spiritual beings communicated
-to their paramours, was the sublime art of Chemistry,
-or the fabrication of gold and silver.</p>
-
-<p>It is quite unnecessary to refute this extravagant
-opinion, obviously founded on a misunderstanding of
-a passage in the sixth chapter of Genesis. “And it
-came to pass, when men began to multiply on the face
-of the earth, and daughters were born unto them,
-that the sons of God saw the daughters of men, that
-they were fair; and they took them wives of all which
-they chose.&mdash;There were giants in the earth in those
-days; and also after that, when the sons of God came
-in unto the daughters of men, and they bare <i>children</i>
-to them; the same became mighty men, which were of
-old, men of renown.”</p>
-
-<p>There is no mention whatever of angels, or of any
-information on science communicated by them to
-mankind.</p>
-
-<p>Nor is it necessary to say much about the opinion
-advanced by some, and rather countenanced by Olaus
-<span class="pagenum" id="Page_9">9</span>
-Borrichius, that the art of making gold was the invention
-of Tubal-cain, whom they represent as the same as
-Vulcan. All the information which we have respecting
-Tubal-cain, is simply that he was an instructor of
-every artificer in brass and iron.<a id="FNanchor_7" href="#Footnote_7" class="fnanchor">7</a> No allusion whatever
-is made to gold. And that in these early ages of
-the world there was no occasion for making gold artificially,
-we have the same authority for believing. For
-in the second chapter of Genesis, where the garden of
-Eden is described, it is said, “And a river went out
-of Eden to water the garden; and from thence it was
-parted, and came into four heads: the name of the
-first is Pison, that is it which encompasseth the whole
-land of Havilah, where there is gold. And the gold
-of that land is good: there is bdellium and onyx-stone.”</p>
-
-<p>But the most generally-received opinion is, that
-alchymy originated in Egypt; and the honour of the
-invention has been unanimously conferred upon
-Hermes Trismegistus. He is by some supposed to be
-the same person with Chanaan, the son of Ham,
-whose son Mizraim first occupied and peopled Egypt.
-Plutarch informs us, that Egypt was sometimes called
-<i>Chemia</i>.<a id="FNanchor_8" href="#Footnote_8" class="fnanchor">8</a> This name is supposed to be derived from
-Chanaan (ןענכ); thence it was believed that Chanaan
-was the true inventor of alchymy, to which he
-affixed his own name. Whether the Hermes (Ἑρμης)
-of the Greeks was the same person with Chanaan or
-his son Mizraim, it is impossible at this distance of
-time to decide; but to Hermes is assigned the invention
-of alchymy, or the art of making gold, by almost
-the unanimous consent of the adepts.</p>
-
-<p>Albertus Magnus informs us, that “Alexander the
-Great discovered the sepulchre of Hermes, in one of
-his journeys, full of all treasures, not metallic, but
-golden, written on a table of <i>zatadi</i>, which others call
-<span class="pagenum" id="Page_10">10</span>
-emerald.” This passage occurs in a tract of Albertus
-<i>de secretis chemicis</i>, which is considered as supposititious.
-Nothing is said of the source whence the information
-contained in this passage was drawn: but,
-from the quotations produced by Kriegsmann, it
-would appear that the existence of this emerald table
-was alluded to by Avicenna and other Arabian writers.
-According to them, a woman called Sarah took it
-from the hands of the dead body of Hermes, some
-ages after the flood, in a cave near Hebron. The inscription
-on it was in the Phœnician language. The
-following is a literal translation of this famous inscription,
-from the Latin version of Kriegsmann:<a id="FNanchor_9" href="#Footnote_9" class="fnanchor">9</a></p>
-
-<p>1. I speak not fictitious things, but what is true and
-most certain.
-<span class="pagenum" id="Page_11">11</span></p>
-
-<p>2. What is below is like that which is above, and
-what is above is similar to that which is below, to accomplish
-the miracles of one thing.</p>
-
-<p>3. And as all things were produced by the meditation
-of one Being, so all things were produced from
-this one thing by adaptation.</p>
-
-<p>4. Its father is <i>Sol</i>, its mother <i>Luna</i>; the wind
-carried it in its belly, the earth is its nurse.</p>
-
-<p>5. It is the cause of all perfection throughout the
-whole world.</p>
-
-<p>6. Its power is perfect, if it be changed into earth.</p>
-
-<p>7. Separate the earth from the fire, the subtile
-from the gross, acting prudently and with judgment.</p>
-
-<p>8. Ascend with the greatest sagacity from the earth
-<span class="pagenum" id="Page_12">12</span>
-to heaven, and then again descend to the earth, and
-unite together the powers of things superior and things
-inferior. Thus you will possess the glory of the whole
-world; and all obscurity will fly far away from you.</p>
-
-<p>9. This thing has more fortitude than fortitude itself;
-because it will overcome every subtile thing, and
-penetrate every solid thing.</p>
-
-<p>10. By it this world was formed.</p>
-
-<p>11. Hence proceed wonderful things, which in this
-wise were established.</p>
-
-<p>12. For this reason I am called Hermes Trismegistus,
-because I possess three parts of the philosophy of
-the whole world.</p>
-
-<p>13. What I had to say about the operation of <i>Sol</i>
-is completed.</p>
-
-<p>Such is a literal translation of the celebrated inscription
-of Hermes Trismegistus upon the emerald
-tablet. It is sufficiently obscure to put it in the power
-of commentators to affix almost any explanation to it
-that they choose. The two individuals who have devoted
-most time to illustrate this tablet, are Kriegsmann
-and Gerard Dorneus, whose commentaries may
-be seen in the first volume of Mangetus’s Bibliotheca
-Chemica. They both agree that it refers to the <i>universal
-medicine</i>, which began to acquire celebrity
-about the time of Paracelsus, or a little earlier.</p>
-
-<p>This exposition, which appears as probable as any
-other, betrays the time when this celebrated inscription
-seems to have been really written. Had it been
-taken out of the hands of the dead body of Hermes by
-Sarah (obviously intended for the wife of Abraham) as
-is affirmed by Avicenna, it is not possible that Herodotus,
-and all the writers of antiquity, both Pagan and
-Christian, should have entirely overlooked it; or how
-could Avicenna have learned what was unknown to all
-those who lived nearest the time when the discovery
-was supposed to have been made? Had it been discovered
-in Egypt by Alexander the Great, would it
-<span class="pagenum" id="Page_13">13</span>
-have been unknown to Aristotle, and to all the numerous
-tribe of writers whom the Alexandrian school produced,
-not one of whom, however, make the least allusion
-to it? In short, it bears all the marks of a forgery
-of the fifteenth century. And even the tract ascribed
-to Albertus Magnus, in which the tablet of Hermes is
-mentioned, and the discovery related, is probably also
-a forgery; and doubtless a forgery of the same individual
-who fabricated the tablet itself, in order to
-throw a greater air of probability upon a story which
-he wished to palm upon the world as true. His object
-was in some measure accomplished; for the authenticity
-of the tablet was supported with much zeal
-by Kriegsmann, and afterwards by Olaus Borrichius.</p>
-
-<p>There is another tract of Hermes Trismegistus, entitled
-“Tractatus Aureus de Lapidis Physici Secreto;”
-on which no less elaborate commentaries have been
-written. It professes to teach the process of making
-the <i>philosopher’s stone</i>; and, from the allusions in it,
-to the use of this stone, as a universal medicine, was
-probably a forgery of the same date as the emerald
-tablet. It would be in vain to attempt to extract any
-thing intelligible out of this Tractatus Aureus: it may
-be worth while to give a single specimen, that the reader
-may be able to form some idea of the nature of the style.</p>
-
-<p>“Take of moisture an ounce and a half; of meridional
-redness, that is the soul of the sun, a fourth
-part, that is half an ounce; of yellow seyr, likewise
-half an ounce; and of auripigmentum, a half ounce,
-making in all three ounces. Know that the vine of
-wise men is extracted in threes, and its wine at last is
-completed in thirty.”<a id="FNanchor_10" href="#Footnote_10" class="fnanchor">10</a>
-<span class="pagenum" id="Page_14">14</span></p>
-
-<p>Had the opinion, that gold and silver could be artificially
-formed originated with Hermes Trismegistus,
-or had it prevailed among the ancient Egyptians, it
-would certainly have been alluded to by Herodotus,
-who spent so many years in Egypt, and was instructed
-by the priests in all the science of the Egyptians. Had
-<i>chemistry</i> been the name of a science, real or fictitious,
-which existed as early as the expedition of the
-Argonauts, and had so many treatises on it, as Suidas
-alleges existed in Egypt before the reign of Dioclesian,
-it could hardly have escaped the notice of Pliny, who
-was so curious and so indefatigable in his researches,
-and who has collected in his natural history a kind of
-digest of all the knowledge of the ancients in every
-department of practical science. The fact that the
-term chemistry (χημεια) never occurs in any Greek or
-Roman writer prior to Suidas, who wrote so late as the
-eleventh century, seems to overturn all idea of the
-existence of that pretended science among the ancients,
-notwithstanding the elaborate attempts of
-Olaus Borrichius to prove the contrary.</p>
-
-<p>I am disposed to believe, that chemistry or alchymy,
-understanding by the term the <i>art of making gold
-and silver</i>, originated among the Arabians, when
-they began to turn their attention to medicine, after
-the establishment of the caliphs; or if it had previously
-been cultivated by Greeks (as the writings of
-Zosimus, the Panapolite, if genuine, would lead us to
-suppose), that it was taken up by the Arabians, and
-reduced by them into regular form and order.
-If the works of Geber be genuine, they leave little
-doubt on this point. Geber is supposed to have been
-a physician, and to have written in the seventh century.
-He admits, as a first principle, that metals are
-compounds of mercury and sulphur. He talks of the
-philosopher’s stone; professes to give the mode of preparing
-it; and teaches the way of converting the
-different metals, known in his time, into medicines, on
-<span class="pagenum" id="Page_15">15</span>
-whose efficacy he bestows the most ample panegyrics.
-Thus the principles which lie at the bottom of alchymy
-were implicitly adopted by him. Yet I can nowhere
-find in him any attempt to make gold artificially. His
-chemistry was entirely devoted to the improvement of
-medicine. The subsequent pretensions of the alchymists
-to convert the baser metals into gold are no
-where avowed by him. I am disposed from this to
-suspect, that the theory of gold-making was started
-after Geber’s time, or at least that it was after the
-seventh century, before any alchymist ventured to
-affirm that he himself was in possession of the secret,
-and could fabricate gold artificially at pleasure. For
-there is a wide distance between the opinion that gold
-may be made artificially and the affirmation that we
-are in possession of a method by which this transmutation
-of the baser metals into gold can be accomplished.
-The first may be adopted and defended with
-much plausibility and perfect honesty; but the second
-would require a degree of skill far exceeding that of
-the most scientific votary of chemistry at present
-existing.</p>
-
-<p>The opinion of the alchymists was, that all the metals
-are compounds; that the baser metals contain
-the same constituents as gold, contaminated, indeed,
-with various impurities, but capable, when their impurities
-are removed or remedied, of assuming all the
-properties and characters of gold. The substance
-possessing this wonderful power they distinguish by
-the name of <i>lapis philosophorum</i>, or, philosopher’s
-stone, and they usually describe it as a red powder,
-having a peculiar smell. Few of the alchymists who
-have left writings behind them boast of being possessed
-of the philosopher’s stone. Paracelsus, indeed,
-affirms, that he was acquainted with the method of
-making it, and gives several processes, which, however,
-are not intelligible. But many affirm that they
-<span class="pagenum" id="Page_16">16</span>
-had seen the philosopher’s stone; that they had portions
-of it in their possession; and that they had seen
-several of the inferior metals, especially lead and
-quicksilver, converted by means of it into gold. Many
-stories of this kind are upon record, and so well authenticated,
-that we need not be surprised at their
-having been generally credited. It will be sufficient
-if we state one or two of those which depend upon
-the most unexceptionable evidence. The following
-relation is given by Mangetus, on the authority of
-M. Gros, a clergyman of Geneva, of the most unexceptionable
-character, and at the same time a skilful
-physician and expert chemist:</p>
-
-<p>“About the year 1650 an unknown Italian came to
-Geneva, and took lodgings at the sign of the <i>Green
-Cross</i>. After remaining there a day or two, he requested
-De Luc, the landlord, to procure him a man
-acquainted with Italian, to accompany him through
-the town and point out those things which deserved to
-be examined. De Luc was acquainted with M. Gros,
-at that time about twenty years of age, and a student
-in Geneva, and knowing his proficiency in the Italian
-language, requested him to accompany the stranger.
-To this proposition he willingly acceded, and attended
-the Italian every where for the space of a fortnight.
-The stranger now began to complain of want of money,
-which alarmed M. Gros not a little&mdash;for at that
-time he was very poor&mdash;and he became apprehensive,
-from the tenour of the stranger’s conversation, that he
-intended to ask the loan of money from him. But
-instead of this, the Italian asked him if he was acquainted
-with any goldsmith, whose bellows and other
-utensils they might be permitted to use, and who
-would not refuse to supply them with the different
-articles requisite for a particular process which he
-wanted to perform. M. Gros named a M. Bureau, to
-whom the Italian immediately repaired. He readily
-<span class="pagenum" id="Page_17">17</span>
-furnished crucibles, pure tin, quicksilver, and the
-other things required by the Italian. The goldsmith
-left his workshop, that the Italian might be under the
-less restraint, leaving M. Gros, with one of his own
-workmen, as an attendant. The Italian put a quantity
-of tin into one crucible, and a quantity of quicksilver
-into another. The tin was melted in the fire and the
-mercury heated. It was then poured into the melted
-tin, and at the same time a red powder enclosed in wax
-was projected into the amalgam. An agitation took
-place, and a great deal of smoke was exhaled from
-the crucible; but this speedily subsided, and the
-whole being poured out, formed six heavy ingots,
-having the colour of gold. The goldsmith was called
-in by the Italian, and requested to make a rigid examination
-of the smallest of these ingots. The goldsmith,
-not content with the touchstone and the application
-of aqua fortis, exposed the metal on the cupel
-with lead, and fused it with antimony, but it sustained
-no loss. He found it possessed of the ductility
-and specific gravity of gold; and full of admiration,
-he exclaimed that he had never worked before
-upon gold so perfectly pure. The Italian made him a
-present of the smallest ingot as a recompence, and
-then, accompanied by M. Gros, he repaired to the
-Mint, where he received from M. Bacuet, the mintmaster,
-a quantity of Spanish gold coin, equal in
-weight to the ingots which he had brought. To M.
-Gros he made a present of twenty pieces, on account
-of the attention that he had paid to him; and, after
-paying his bill at the inn, he added fifteen pieces
-more, to serve to entertain M. Gros and M. Bureau
-for some days, and in the mean time he ordered a
-supper, that he might, on his return, have the pleasure
-of supping with these two gentlemen. He went
-out, but never returned, leaving behind him the
-greatest regret and admiration. It is needless to add,
-that M. Gros and M. Bureau continued to enjoy
-<span class="pagenum" id="Page_18">18</span>
-themselves at the inn till the fifteen pieces, which the
-stranger had left, were exhausted.”<a id="FNanchor_11" href="#Footnote_11" class="fnanchor">11</a></p>
-
-<p>Mangetus gives also the following relation, which he
-states upon the authority of an English bishop, who
-communicated it to him in the year 1685, and at the
-same time gave him about half an ounce of the gold
-which the alchymist had made:</p>
-
-<p>A stranger, meanly dressed, went to Mr. Boyle, and
-after conversing for some time about chemical processes,
-requested him to furnish him with antimony,
-and some other common metallic substances, which
-then fortunately happened to be in Mr. Boyle’s laboratory.
-These were put into a crucible, which was
-then placed in a melting-furnace. As soon as these
-metals were fused, the stranger showed a powder to the
-attendants, which he projected into the crucible, and
-instantly went out, directing the servants to allow the
-crucible to remain in the furnace till the fire went out
-of its own accord, and promising at the same time to
-return in a few hours. But, as he never fulfilled this
-promise, Boyle ordered the cover to be taken off the
-crucible, and found that it contained a yellow-coloured
-metal, possessing all the properties of pure gold, and
-only a little lighter than the weight of the materials
-originally put into the crucible.<a id="FNanchor_12" href="#Footnote_12" class="fnanchor">12</a></p>
-
-<p>The following strange story is related by Helvetius,
-physician to the Prince of Orange, in his Vitulus Aureus:
-Helvetius was a disbeliever of the philosopher’s stone,
-and the universal medicine, and even turned Sir
-Kenelm Digby’s sympathetic powder into ridicule.
-On the 27th of December, 1666, a stranger called
-upon him, and after conversing for some time about a
-universal medicine, showed a yellow powder, which he
-affirmed to be the philosopher’s stone, and at the same
-time five large plates of gold, which had been made
-<span class="pagenum" id="Page_19">19</span>
-by means of it. Helvetius earnestly entreated that he
-would give him a little of this powder, or at least that
-he would make a trial of its power; but the stranger
-refused, promising however to return in six weeks. He
-returned accordingly, and after much entreaty he gave
-to Helvetius a piece of the stone, not larger than the
-size of a rape-seed. When Helvetius expressed his
-doubt whether so small a portion would be sufficient
-to convert four grains of lead into gold, the adept
-broke off one half of it, and assured him that what
-remained was more than sufficient for the purpose.
-Helvetius, during the first conference, had concealed
-a little of the stone below his nail. This he threw into
-melted lead, but it was almost all driven off in smoke,
-leaving only a vitreous earth. When he mentioned
-this circumstance, the stranger informed him that the
-powder must be enclosed in wax, before it be thrown
-into the melted lead, lest it should be injured by the
-smoke of the lead. The stranger promised to return
-next day, and show him the method of making the
-projection; but having failed to make his appearance,
-Helvetius, in the presence of his wife and son, put six
-drachms of lead into a crucible, and as soon as it was
-melted he threw into it the fragment of philosopher’s
-stone in his possession, previously covered over with
-wax. The crucible was now covered with its lid, and
-left for a quarter of an hour in the fire, at the end of
-which time he found the whole lead converted into
-gold. The colour was at first a deep green; being
-poured into a conical vessel, it assumed a blood-red
-colour; but when cold, it acquired the true tint of
-gold. Being examined by a goldsmith, he considered
-it as pure gold. He requested Porelius, who had the
-charge of the Dutch mint, to try its value. Two
-drachms of it being subjected to quartation, and solution
-in aqua fortis, were found to have increased in
-weight by two scruples. This increase was doubtless
-owing to the silver, which still remained enveloped in
-<span class="pagenum" id="Page_20">20</span>
-the gold, after the action of the aqua fortis. To endeavour
-to separate the silver more completely, the
-gold was again fused with seven times its weight of
-antimony, and treated in the usual manner; but no
-alteration took place in the weight.<a id="FNanchor_13" href="#Footnote_13" class="fnanchor">13</a></p>
-
-<p>It would be easy to relate many other similar narratives;
-but the three which I have given are the best
-authenticated of any that I am acquainted with. The
-reader will observe, that they are all stated on the
-authority, not of the persons who were the actors, but
-of others to whom they related them; and some of
-these, as the English bishop, perhaps not very familiar
-with chemical processes, and therefore liable to leave
-out or misstate some essential particulars. The evidence,
-therefore, though the best that can be got, is
-not sufficient to authenticate these wonderful stories.
-A little latent vanity might easily induce the narrators
-to suppress or alter some particulars, which, if known,
-would have stripped the statements of every thing marvellous
-which they contain, and let us into the secret
-of the origin of the gold, which these alchymists
-boasted that they had fabricated. Whoever will read
-the statements of Paracelsus, respecting his knowledge
-of the philosopher’s stone, which he applied not to the
-formation of gold but to medicine, or whoever will
-examine his formulas for making the stone, will easily
-satisfy himself that Paracelsus possessed no real knowledge
-on the subject.<a id="FNanchor_14" href="#Footnote_14" class="fnanchor">14</a></p>
-
-<p>But to convey as precise ideas on this subject as
-possible, it may be worth while to state a few of the
-methods by which the alchymists persuaded themselves
-that they could convert the baser metals into gold.</p>
-
-<p>In the year 1694 an old gentleman called upon
-Mr. Wilson, at that time a chemist in London, and
-informed him that at last, after forty years’ search, he
-<span class="pagenum" id="Page_21">21</span>
-had met with an ample recompence for all his trouble
-and expenses. This he confirmed with some oaths
-and imprecations; but, considering his great weakness
-and age, he looked upon himself as incapable to undergo
-the fatigues of the process. “I have here,”
-says he, “a piece of sol (<i>gold</i>) that I made from
-silver, about four years ago, and I cannot trust any
-man but you with so rare a secret. We will share
-equally the charges and profit, which will render us
-wealthy enough to command the world.” The nature
-of the process being stated, Mr. Wilson thought it not
-unreasonable, especially as he aimed at no peculiar
-advantage for himself. He accordingly put it to the
-trial in the following manner:</p>
-
-<p>1. Twelve ounces of Japan copper were beat into
-thin plates, and laid <i>stratum super stratum</i> with three
-ounces of flowers of sulphur, in a crucible. It was
-exposed in a melting-furnace to a gentle heat, till the
-sulphureous flames expired. When cold, the &aelig;s ustum
-(<i>sulphuret of copper</i>) was pounded, and stratified
-again; and this process was repeated five times. Mr.
-Wilson does not inform us whether the powder was mixed
-with flowers of sulphur every time that it was heated;
-but this must have been the case, otherwise the sulphuret
-would have been again converted into metallic
-copper, which would have melted into a mass. By
-this first process, then, bisulphuret of copper was formed,
-composed of equal weights of sulphur and copper.</p>
-
-<p>2. Six pounds of iron wire were put into a large
-glass body, and twelve pounds of muriatic acid poured
-upon it. Six days elapsed (during which it stood in
-a gentle heat) before the acid was saturated with the
-iron. The solution was then decanted off, and filtered,
-and six pounds of new muriatic acid poured on the
-undissolved iron. This acid, after standing a sufficient
-time, was decanted off, and filtered. Both liquids
-were put into a large retort, and distilled by a sand-heat.
-Towards the end, when the drops from the
-<span class="pagenum" id="Page_22">22</span>
-retort became yellow, the receiver was changed, and
-the fire increased to the highest degree, in which the
-retort was kept between four and six hours. When
-all was cold, the receiver was taken off, and a quantity
-of flowers was found in the neck of the retort,
-variously coloured, like the rainbow. The yellow
-liquor in the receiver weighed ten ounces and a half;
-the flowers (<i>chloride of iron</i>), two ounces and three
-drams. The liquid and flowers were put into a clean
-bottle.</p>
-
-<p>3. Half a pound of sal enixum (<i>sulphate of potash</i>)
-and a pound and a half of nitric acid were put into a
-retort. When the salt had dissolved in the acid, ten
-ounces of mercury (previously distilled through quicklime
-and salt of tartar) were added. The whole being
-distilled to dryness, a fine yellow mass (<i>pernitrate of
-mercury</i>) remained in the bottom of the retort. The
-liquor was returned, with half a pound of fresh nitric
-acid, and the distillation repeated. The distillation
-was repeated a third time, urging this last cohobation
-with the highest degree of fire. When all was cold, a
-various-coloured mass was found in the bottom of the
-retort: this mass was doubtless a mixture of sulphate
-of potash, and pernitrate of mercury, with some oxide
-of mercury.</p>
-
-<p>4. Four ounces of fine silver were dissolved in a
-pound of aqua fortis; to the solution was added, of
-the bisulphuret of copper four ounces; of the mixture
-of sulphate of potash, pernitrate of mercury, and oxide
-of mercury one ounce and a half, and of the solution
-of perchloride of iron two ounces and a half. When
-these had stood in a retort twenty-four hours, the
-liquor was decanted off, and four ounces of nitric acid
-were poured upon the little matter that was not dissolved.
-Next morning a total dissolution was obtained.
-The whole of this dissolution was put into a retort and
-distilled almost to dryness. The liquid was poured
-back, and the distillation repeated three times; the
-<span class="pagenum" id="Page_23">23</span>
-last time the retort being urged by a very strong fire
-till no fumes appeared, and not a drop fell.</p>
-
-<p>5. The matter left in the bottom of the retort was
-now put into a crucible, all the corrosive fumes were
-gently evaporated, and the residue melted down with
-a fluxing powder.</p>
-
-<p>This process was expected to yield five ounces of
-pure gold; but on examination the silver was the same
-(except the loss of half a pennyweight) as when dissolved
-in the aqua fortis: there were indeed some grains
-among the scoria, which appeared like gold, and would
-not dissolve in aqua fortis. No doubt they consisted
-of peroxide of iron, or, perhaps, persulphuret of iron.<a id="FNanchor_15" href="#Footnote_15" class="fnanchor">15</a></p>
-
-<p>Mr. Wilson’s alchymistical friend, not satisfied with
-this first failure, insisted upon a repetition of the process,
-with some alteration in the method and the addition
-of a certain quantity of gold. The whole was
-accordingly gone through again; but it is unnecessary
-to say that no gold was obtained, or at least, the two
-drams of gold employed had increased in weight by
-only two scruples and thirteen grains; this addition
-was doubtless owing to a little silver from which it had
-not been freed.<a id="FNanchor_16" href="#Footnote_16" class="fnanchor">16</a></p>
-
-<p>I shall now give a process for making the philosopher’s
-stone, which was considered by Mangetus as of
-great value, and on that account was given by him in
-the preface to his Bibliotheca Chemica.</p>
-
-<p>1. Prepare a quantity of spirit of wine, so free from
-water that it is wholly combustible, and so volatile that
-when a drop of it is let fall it evaporates before it
-reaches the ground;&mdash;this constitutes the first menstruum.</p>
-
-<p>2. Take pure mercury, revived in the usual manner
-from cinnabar, put it into a glass vessel with common
-salt and distilled vinegar; agitate violently, and when
-the vinegar acquires a black colour pour it off and add
-<span class="pagenum" id="Page_24">24</span>
-new vinegar; agitate again, and continue these repeated
-agitations and additions till the vinegar ceases
-to acquire a black colour from the mercury: the mercury
-is now quite pure and very brilliant.</p>
-
-<p>3. Take of this mercury four parts; of sublimed
-mercury<a id="FNanchor_17" href="#Footnote_17" class="fnanchor">17</a> (<i>mercurii meteoresati</i>), prepared with your
-own hands, eight parts; triturate them together in a
-wooden mortar with a wooden pestle, till all the grains
-of running mercury disappear. This process is tedious
-and rather difficult.</p>
-
-<p>4. The mixture thus prepared is to be put into an
-aludel, or a sand-bath, and exposed to a subliming
-heat, which is to be gradually raised till the whole
-sublimes. Collect the sublimed matter, put it again
-into the aludel, and sublime a second time; this process
-must be repeated five times. Thus a very sweet
-and crystallized sublimate is obtained: it constitutes
-the salt of wise men (<i>sal sapientum</i>), and possesses
-wonderful properties.<a id="FNanchor_18" href="#Footnote_18" class="fnanchor">18</a></p>
-
-<p>5. Grind it in a wooden mortar, and reduce it to
-powder; put it into a glass retort, and pour upon it
-the spirit of wine (No. 1) till it stands about three
-finger-breadths above the powder; seal the retort
-hermetically, and expose it to a very gentle heat for
-seventy-four hours, shaking it several times a-day;
-then distil with a gentle heat and the spirit of wine
-will pass over, together with spirit of mercury. Keep
-this liquid in a well-stopped bottle, lest it should
-evaporate. More spirit of wine is to be poured upon
-the residual salt, and after digestion it must be distilled
-off as before; and this process must be repeated
-till the whole salt is dissolved, and distilled over with
-the spirit of wine. You have now performed a great
-work. The mercury is now rendered in some measure
-volatile, and it will gradually become fit to receive the
-tincture of gold and silver. Now return thanks to
-<span class="pagenum" id="Page_25">25</span>
-God, who has hitherto crowned your wonderful work
-with success; nor is this great work involved in Cimmerian
-darkness, but clearer than the sun; though
-preceding writers have imposed upon us with parables,
-hieroglyphics, fables, and enigmas.</p>
-
-<p>6. Take this mercurial spirit, which contains our
-magical steel in its belly, put it into a glass retort, to
-which a receiver must be well and carefully luted:
-draw off the spirit by a very gentle heat, there will
-remain in the bottom of the retort the quintessence or
-soul of mercury; this is to be sublimed by applying a
-stronger heat to the retort that it may become volatile,
-as all the philosophers express themselves&mdash;
-
-<span class="table">
-<span class="trow">Si fixum solvas faciesque volare solutum,<br /></span>
-<span class="trow">Et volucrum figas faciet te vivere tutum.<br /></span>
-</span>
-
-This is our luna, our fountain, in which the king and
-queen may bathe. Preserve this precious quintessence
-of mercury, which is very volatile, in a well-shut vessel
-for further use.</p>
-
-<p>8. Let us now proceed to the operation of common
-gold, which we shall communicate clearly and distinctly,
-without digression or obscurity; that from vulgar
-gold we may obtain our philosophical gold, just as
-from common mercury we obtained, by the preceding
-processes, philosophical mercury.</p>
-
-<p>In the name of God, then, take common gold, purified
-in the usual way by antimony, convert it into
-small grains, which must be washed with salt and vinegar,
-till it be quite pure. Take one part of this gold,
-and pour on it three parts of the quintessence of mercury;
-as philosophers reckon from seven to ten, so we
-also reckon our number as philosophical, and we begin
-with three and one; let them be married together like
-husband and wife, to produce children of their own
-kind, and you will see the common gold sink and
-plainly dissolve. Now the marriage is consummated;
-now two things are converted into one: thus the philosophical
-<span class="pagenum" id="Page_26">26</span>
-sulphur is at hand, as the philosophers say,
-<i>the sulphur being dissolved the stone is at hand</i>.
-Take then, in the name of God, our philosophical vessel,
-in which the king and queen embrace each other
-as in a bedchamber, and leave it till the water is converted
-into earth, then peace is concluded between
-the water and fire, then the elements have no longer
-any thing contrary to each other; because, when the
-elements are converted into earth they no longer oppose
-each other; for in earth all elements are at rest.
-For the philosophers say, “When you shall have seen
-the water coagulate itself, think that your knowledge
-is true, and that your operations are truly philosophical.”
-The gold is now no longer common, but
-ours is philosophical, on account of our processes: at
-first exceedingly fixed; then exceedingly volatile, and
-finally exceedingly fixed; and the whole science depends
-upon the change of the elements. The gold at
-first was a metal, now it is a sulphur, capable of converting
-all metals into its own sulphur. Now our
-tincture is wholly converted into sulphur, which possesses
-the energy of curing all diseases: this is our
-universal medicine against all the most deplorable
-diseases of the human body; therefore, return infinite
-thanks to Almighty God for all the good things which
-he has bestowed upon us.</p>
-
-<p>9. In this great work of ours, two modes of fermenting
-and projecting are wanting, without which the
-uninitiated will not easily follow our process. The
-mode of fermenting is as follows: Take of our sulphur
-above described one part, and project it upon three
-parts of very pure gold fused in a furnace; in a moment
-you will see the gold, by the force of the sulphur,
-converted into a red sulphur of an inferior quality to
-the first sulphur; take one part of this, and project it
-upon three parts of fused gold, the whole will be again
-converted into a sulphur, or a friable mass; mixing
-one part of this with three parts of gold, you will have
-<span class="pagenum" id="Page_27">27</span>
-a malleable and extensible metal. If you find it so,
-well; if not add other sulphur and it will again pass into
-sulphur. Now the sulphur will be sufficiently fermented,
-or our medicine will be brought into a metallic
-nature.</p>
-
-<p>10. The mode of projecting is this: Take of the fermented
-sulphur one part, and project it upon ten parts
-of mercury, heated in a crucible, and you will have a
-perfect metal; if its colour is not sufficiently deep,
-fuse it again, and add more fermented sulphur, and
-thus it will acquire colour. If it becomes frangible,
-add a sufficient quantity of mercury and it will be
-perfect.</p>
-
-<p>Thus, friend, you have a description of the universal
-medicine, not only for curing diseases and prolonging
-life, but also for transmuting all metals into gold.
-Give therefore thanks to Almighty God, who, taking
-pity on human calamities, has at last revealed this
-inestimable treasure, and made it known for the common
-benefit of all.<a id="FNanchor_19" href="#Footnote_19" class="fnanchor">19</a></p>
-
-<p>Such is the formula (slightly abridged) of Carolus
-Musitanus, by which the philosopher’s stone, according
-to him, may be formed. Compared with the formulas
-of most of the alchymists, it is sufficiently plain.
-What the <i>sublimed mercury</i> is does not appear; from
-the process described we should be apt to consider it
-as <i>corrosive sublimate</i>; on that supposition, the sal
-sapientum formed in No. 5, would be calomel: the
-only objection to this supposition is the process described
-in No. 5; for calomel is not soluble in alcohol.
-The philosopher’s stone prepared by this elaborate
-process could hardly have been any thing else than an
-<i>amalgam of gold</i>; it could not have contained chloride
-of gold, because such a preparation, instead of
-acting medicinally, would have proved a most virulent
-poison. There is no doubt that amalgam of gold, if
-<span class="pagenum" id="Page_28">28</span>
-projected into melted lead or tin, and afterwards cupellated,
-would leave a portion of gold&mdash;all the gold of
-course that existed previously in the amalgam. It
-might therefore have been employed by impostors to
-persuade the ignorant that it was really the philosopher’s
-stone; but the alchymists who prepared the
-amalgam could not be ignorant that it contained gold.</p>
-
-<p>There is another process given in the same preface
-of a very different nature, but too long to be transcribed
-here, and the nature of the process is not sufficiently
-intelligible to render an account of it of much
-consequence.<a id="FNanchor_20" href="#Footnote_20" class="fnanchor">20</a></p>
-
-<p>The preceding observations will give the reader some
-notion of the nature of the pursuits which occupied the
-alchymists: their sole object was the preparation of a
-substance to which they gave the name of the philosopher’s
-stone, which possessed the double property of
-converting the baser metals into gold, and of curing all
-diseases, and of preserving human life to an indefinite
-extent. The experiments of Wilson, and the formula
-of Musitanus, which have been just inserted, will give
-the reader some notion of the way in which they attempted
-to manufacture this most precious substance.
-Being quite ignorant of the properties of bodies, and
-of their action on each other, their processes were
-guided by no scientific analogies, and one part of the
-labour not unfrequently counteracted another; it would
-be a waste of time, therefore, to attempt to analyze their
-numerous processes, even though such an attempt
-could be attended with success. But in most cases,
-from the unintelligible terms in which their books are
-<span class="pagenum" id="Page_29">29</span>
-written, it is impossible to divine the nature of the
-processes by which they endeavoured to manufacture
-the philosopher’s stone, or the nature of the substances
-which they obtained.<a id="FNanchor_21" href="#Footnote_21" class="fnanchor">21</a></p>
-
-<p>In consequence of the universality of the opinion
-that gold could be made by art, there was a set of
-impostors who went about pretending that they were
-in possession of the philosopher’s stone, and offering
-to communicate the secret of making it for a suitable
-reward. Nothing is more astonishing than that
-persons should be found credulous enough to be the
-dupes of such impostors. The very circumstance of
-their claiming a reward was a sufficient proof that
-they were ignorant of the secret which they pretended
-to reveal; for what motive could a man have for asking
-a reward who was in possession of a method of
-creating gold at pleasure? To such a person money
-could be no object, as he could procure it in any
-quantity. Yet, strange as it may appear, they met
-with abundance of dupes credulous enough to believe
-their asseverations, and to supply them with money
-to enable them to perform the wished-for processes.
-The object of these impostors was either to pocket the
-money thus furnished, or they made use of it to purchase
-various substances from which they extracted
-oils, acids, or similar products, which they were
-enabled to sell at a profit. To keep the dupes, who
-thus supplied them with the means of carrying on
-these processes, in good spirits, it was necessary to
-show them occasionally small quantities of the baser
-metals converted into gold; this they performed in
-various ways. M. Geoffroy, senior, who had an opportunity
-of witnessing many of their performances,
-<span class="pagenum" id="Page_30">30</span>
-has given us an account of a number of their tricks. It
-may be worth while to state a few by way of specimen.</p>
-
-<p>Sometimes they made use of crucibles with a false
-bottom; at the real bottom they put a quantity of
-oxide of gold or silver, this was covered with a portion
-of powdered crucible, glued together by a little
-gummed water or a little wax; the materials being put
-into this crucible, and heat applied, the false bottom
-disappears, the oxide of gold or silver is reduced, and
-at the end of the process is found at the bottom of
-the crucible, and considered as the product of the
-operation.</p>
-
-<p>Sometimes they make a hole in a piece of charcoal
-and fill it with oxide of gold or silver, and stop up
-the mouth with a little wax; or they soak charcoal in
-solutions of these metals; or they stir the mixtures in
-the crucible with hollow rods containing oxide of gold
-or silver within, and the bottom shut with wax: by these
-means the gold or silver wanted is introduced during the
-process, and considered as a product of the operation.</p>
-
-<p>Sometimes they have a solution of silver in nitric
-acid, or of gold in aqua regia, or an amalgam of gold
-or silver, which being adroitly introduced, furnishes
-the requisite quantity of metal. A common exhibition
-was to dip nails into a liquid, and take them out half converted
-into gold. The nails consisted of one-half gold,
-neatly soldered to the iron, and covered with something
-to conceal the colour, which the liquid removed.
-Sometimes they had metals one-half gold the other
-half silver, soldered together, and the gold side whitened
-with mercury; the gold half was dipped into the transmuting
-liquid and then the metal heated; the mercury
-was dissipated, and the gold half of the metal appeared.<a id="FNanchor_22" href="#Footnote_22" class="fnanchor">22</a></p>
-
-<p>As the alchymists were assiduous workmen&mdash;as they
-mixed all the metals, salts, &amp;c. with which they were
-<span class="pagenum" id="Page_31">31</span>
-acquainted, in various ways with each other, and subjected
-such mixtures to the action of heat in close
-vessels, their labours were occasionally repaid by the
-discovery of new substances, possessed of much greater
-activity than any with which they were previously
-acquainted. In this way they were led to the discovery
-of sulphuric, nitric, and muriatic acids. These,
-when known, were made to act upon the metals; solutions
-of the metals were obtained, and this gradually
-led to the knowledge of various metalline salts and
-preparations, which were introduced with considerable
-advantage into medicine. Thus the alchymists, by
-their absurd pursuits, gradually formed a collection of
-facts, which led ultimately to the establishment of
-scientific chemistry. On this account it will be proper
-to notice, in this place, such of them as appeared in
-Europe during the darker ages, and acquired the
-highest reputation either on account of their skill as
-physicians, or their celebrity as chemists.<a id="FNanchor_23" href="#Footnote_23" class="fnanchor">23</a></p>
-
-<p>1. The first alchymist who deserves notice is Albertus
-Magnus, or Albert Groot, a German, who was
-born, it is supposed, in the year 1193, at Bollstaedt,
-and died in the year 1282.<a id="FNanchor_24" href="#Footnote_24" class="fnanchor">24</a> When very young he is
-said to have been so remarkable for his dulness, that
-he became the jest of his acquaintances. He studied
-the sciences at Padua, and afterwards taught at
-Cologne, and finally in Paris. He travelled through
-all Germany as Provincial of the order of Dominican
-Monks, visited Rome, and was made bishop of Ratisbon:
-but his passion for science induced him to give
-up his bishopric, and return to a cloister at Cologne,
-where he continued till his death.</p>
-
-<p>Albertus was acquainted with all the sciences cultivated in
-<span class="pagenum" id="Page_32">32</span>
-his time. He was at once a theologian, a
-physician, and a man of the world: he was an astronomer
-and an alchymist, and even dipped into magic
-and necromancy. His works are very voluminous.
-They were collected by Petr. Jammy, and published
-at Leyden in twenty-one folio volumes, in 1651. His
-principal alchymistical tracts are the following:
-
-<span class="table">
-<span class="trow">1. De Rebus Metallicis et Mineralibus.</span>
-
-<span class="trow">2. De Alchymia.</span>
-
-<span class="trow">3. Secretorum Tractatus.</span>
-
-<span class="trow">4. Breve Compendium de Ortu Metallorum.</span>
-
-<span class="trow">5. Concordantia Philosophorum de Lapide.</span>
-
-<span class="trow">6. Compositum de Compositis.</span>
-
-<span class="trow">7. Liber octo Capitum de Philosophorum Lapide.</span>
-</span></p>
-
-<p>Most of these tracts have been inserted in the
-Theatrum Chemicum. They are in general plain and
-intelligible. In his treatise De Alchymia, for example,
-he gives a distinct account of all the chemical substances
-known in his time, and of the manner of
-obtaining them. He mentions also the apparatus then
-employed by chemists, and the various processes which
-they had occasion to perform. I may notice the most
-remarkable facts and opinions which I have observed
-in turning over these treatises.</p>
-
-<p>He was of opinion that all metals are composed of
-sulphur and mercury; and endeavoured to account
-for the diversity of metals partly by the difference in
-the purity, and partly by the difference in the proportions
-of the sulphur and mercury of which they are
-composed. He thought that water existed also as a
-constituent of all metals.</p>
-
-<p>He was acquainted with the water-bath, employed
-alembics for distillation, and aludels for sublimation;
-and he was in the habit of employing various lutes,
-the composition of which he describes.</p>
-
-<p>He mentions alum and caustic alkali, and seems
-to have known the alkaline basis of cream of tartar.
-He knew the method of purifying the precious metals
-<span class="pagenum" id="Page_33">33</span>
-by means of lead and of gold, by cementation; and
-likewise the method of trying the purity of gold, and
-of distinguishing pure from impure gold.</p>
-
-<p>He mentions red lead, metallic arsenic, and liver of
-sulphur. He was acquainted with green vitriol and
-iron pyrites. He knew that arsenic renders copper
-white, and that sulphur attacks all the metals except
-gold.</p>
-
-<p>It is said by some that he was acquainted with gunpowder;
-but nothing indicating any such knowledge
-occurs in any of his writings that I have had an opportunity
-of perusing.<a id="FNanchor_25" href="#Footnote_25" class="fnanchor">25</a></p>
-
-<p>2. Albertus is said to have had for a pupil, while
-he taught in Paris, the celebrated Thomas Aquinas, a
-Dominican, who studied at Bologna, Rome, and
-Naples, and distinguished himself still more in divinity
-and scholastic philosophy than in alchymy. He
-wrote,
-
-<span class="table">
-<span class="trow">1. Thesaurum Alchymi&aelig; Secretissimum.</span>
-<span class="trow">2. Secreta Alchymi&aelig; Magnalia.</span>
-<span class="trow">3. De Esse et Essentia Mineralium;
-and perhaps some other works, which I have not seen.</span>
-</span></p>
-
-<p>These works, so far as I have perused them, are
-exceedingly obscure, and in various places unintelligible.
-Some of the terms still employed by modern
-chemists occur, for the first time, in the writings of
-Thomas Aquinas. Thus the term <i>amalgam</i>, still employed
-to denote a compound of mercury with another
-metal, occurs in them, and I have not observed it in
-any earlier author.</p>
-
-<p>3. Soon after Albertus Magnus, flourished Roger
-Bacon, by far the most illustrious, the best informed,
-and the most philosophical of all the alchymists. He
-was born in 1214, in the county of Somerset. After
-studying in Oxford, and afterwards in Paris, he became
-a cordelier friar; and, devoting himself to philosophical
-<span class="pagenum" id="Page_34">34</span>
-investigations, his discoveries, notwithstanding the
-pains which he took to conceal them, made such a
-noise, that he was accused of magic, and his brethren
-in consequence threw him into prison. He died, it is
-said, in the year 1284, though Sprengel fixes the year
-of his death to be 1285.</p>
-
-<p>His writings display a degree of knowledge and
-extent of thought scarcely credible, if we consider the
-time when he wrote, the darkest period of the dark
-ages. In his small treatise De Mirabili Potestate Artis
-et Natur&aelig;, he begins by pointing out the absurdity of
-believing in magic, necromancy, charms, or any of those
-similar opinions which were at that time universally
-prevalent. He points out the various ways in which
-mankind are deceived by jugglers, ventriloquists, &amp;c.;
-mentions the advantages which physicians may derive
-from acting on the imaginations of their patients by
-means of charms, amulets, and infallible remedies:
-he affirms that many of those things which are considered
-as supernatural, are merely so because mankind
-in general are unacquainted with natural philosophy.
-To illustrate this he mentions a great number of natural
-phenomena, which had been reckoned miraculous; and
-concludes with several secrets of his own, which he
-affirms to be still more extraordinary imitations of some
-of the most singular processes of nature. These he
-delivers in the enigmatical style of the times; induced,
-as he tells us, partly by the conduct of other philosophers,
-partly by the propriety of the thing, and partly
-by the danger of speaking too plainly.</p>
-
-<p>From an attentive perusal of his works, many of
-which have been printed, it will be seen that Bacon
-was a great linguist, being familiar with Latin, Greek,
-Hebrew, and Arabic; and that he had perused the
-most important books at that time existing in all these
-languages. He was also a grammarian; he was well
-versed in the theory and practice of perspective; he
-understood the use of convex and concave glasses, and
-<span class="pagenum" id="Page_35">35</span>
-the art of making them. The camera obscura, burning-glasses,
-and the powers of the telescope, were
-known to him. He was well versed in geography and
-astronomy. He knew the great error in the Julian
-calendar, assigned the cause, and proposed the remedy.
-He understood chronology well; he was a skilful physician,
-and an able mathematician, logician, metaphysician,
-and theologist; but it is as a chemist that
-he claims our attention here. The following is a list
-of his chemical writings, as given by Gmelin, the
-whole of which I have never had an opportunity of
-seeing:
-
-<span class="table">
-<span class="trow">1. Speculum Alchymi&aelig;.<a id="FNanchor_26" href="#Footnote_26" class="fnanchor">26</a></span>
-
-<span class="trow">2. Epistola de Secretis Operibus Artis et Natur&aelig; et
-de Nullitate Magi&aelig;.</span>
-
-<span class="trow">3. De Mirabili Potestate Artis et Natur&aelig;.</span>
-
-<span class="trow">4. Medulla Alchymi&aelig;.</span>
-
-<span class="trow">5. De Arte Chemi&aelig;.</span>
-
-<span class="trow">6. Breviorium Alchymi&aelig;.</span>
-
-<span class="trow">7. Documenta Alchymi&aelig;.</span>
-
-<span class="trow">8. De Alchymistarum Artibus.</span>
-
-<span class="trow">9. De Secretis.</span>
-
-<span class="trow">10. De Rebus Metallicis.</span>
-
-<span class="trow">11. De Sculpturis Lapidum.</span>
-
-<span class="trow">12. De Philosophorum Lapide.</span>
-
-<span class="trow">13. Opus Majus, <i>or</i> Alchymia Major.</span>
-
-<span class="trow">14. Breviarium de Dono Dei.</span>
-
-<span class="trow">15. Verbum abbreviatum de Leone Viridi.</span>
-
-<span class="trow">16. Secretum Secretorum.</span>
-
-<span class="trow">17. Tractatus Trium Verborum.</span>
-
-<span class="trow">18. Speculum Secretorum.</span>
-</span>
-
-A number of these were collected together, and published
-at Frankfort in 1603, under the title of “Rogeri
-Baconis Angli de Arte Chemi&aelig; Scripta,” in a small
-duodecimo volume. The Opus Majus was published
-in London in 1733, by Dr. Jebb, in a folio volume.
-<span class="pagenum" id="Page_36">36</span>
-Several of his tracts still continue in manuscript in
-the Harleian and Bodleian libraries at Oxford. He
-considered the metals as compound of mercury and
-sulphur. Gmelin affirms that he was aware of the
-peculiar nature of manganese, and that he was acquainted
-with bismuth; but after perusing the whole
-of the Speculum Alchymi&aelig;, the third chapter of which
-he quotes as containing the facts on which he founds
-his opinion, I cannot find any certain allusion either
-to manganese or bismuth. The term <i>magnesia</i> indeed
-occurs, but nothing is said respecting its nature: and
-long after the time of Paracelsus, bismuth (<i>bisematum</i>)
-was considered as an impure kind of <i>lead</i>. That he
-was acquainted with the composition and properties of
-<i>gunpowder</i> admits of no doubt. In the sixth chapter
-of his epistle De Secretis Operibus Artis et Natur&aelig; et
-de Nullitate Magi&aelig;, the following passage occurs:</p>
-
-<p>“For sounds like thunder, and coruscations like
-lightning, may be made in the air, and they may be
-rendered even more horrible than those of nature herself.
-A small quantity of matter, properly manufactured,
-not larger than the human thumb, may be made
-to produce a horrible noise and coruscation. And this
-may be done many ways, by which a city or an army
-may be destroyed, as was the case when Gideon and
-his men broke their pitchers and exhibited their lamps,
-fire issuing out of them with inestimable noise, destroyed
-an infinite number of the army of the Midianites.”
-And in the eleventh chapter of the same epistle
-occurs the following passage: “Mix together saltpetre,
-luru vopo vir con utriet, and sulphur, and you
-will make thunder and lightning, if you know the
-method of mixing them.” Here all the ingredients of
-gunpowder are mentioned except charcoal, which is
-doubtless concealed under the barbarous terms <i>luru
-vopo vir con utriet</i>.</p>
-
-<p>But though Bacon was acquainted with gunpowder,
-we have no evidence that he was the inventor. How
-<span class="pagenum" id="Page_37">37</span>
-far the celebrated Greek fire, concerning which so
-much has been written, was connected with gunpowder,
-it is impossible to say; but there is good evidence to
-prove that gunpowder was known and used in China
-before the commencement of the Christian era; and
-Lord Bacon is of opinion that the thunder and lightning
-and magic stated by the Macedonians to have
-been exhibited in Oxydrakes, when it was besieged by
-Alexander the Great, was nothing else than gunpowder.
-Now as there is pretty good evidence that
-the use of gunpowder had been introduced into Spain
-by the Moors, at least as early as the year 1343, and
-as Roger Bacon was acquainted with Arabic, it is by
-no means unlikely that he might have become acquainted
-with the mode of making the composition,
-and with its most remarkable properties, by perusing
-some Arabian writer, with whom we are at present
-unacquainted. Barbour, in his life of Bruce, informs
-us that guns were first employed by the English at the
-battle of Werewater, which was fought in 1327, about
-forty years after the death of Bacon.</p>
-
-<div class="poetry">
-<div class="poem"><div class="stanza">
-<span class="i0">Two novelties that day they saw,<br /></span>
-<span class="i0">That forouth in Scotland had been nene;<br /></span>
-<span class="i0">Timbers for helmes was the ane<br /></span>
-<span class="i0">That they thought then of great beautie,<br /></span>
-<span class="i0">And also wonder for to see.<br /></span>
-<span class="i0">The other <i>crakys</i> were of war<br /></span>
-<span class="i0">That they before heard never air.<br /></span>
-</div></div>
-</div>
-
-<p>In another part of the same book we have the
-phrase <i>gynnys for crakys</i>, showing that the term
-crakys was used to denote a gun or musket of some
-form or other. It is curious that the English would
-seem to have been the first European nation that employed
-gunpowder in war; they used it in the battle
-of Crecy, fought in 1346, when it was unknown to the
-French, and it is supposed to have contributed materially
-to the brilliant victory which was obtained.
-<span class="pagenum" id="Page_38">38</span></p>
-
-<p>4. Raymond Lully is said to have been a scholar
-and a friend of Roger Bacon. He was a most voluminous
-writer, and acquired as high a reputation as
-any of the alchymists. According to Mutius he was
-born in Majorca in the year 1235. His father was
-seneschal to King James the First of Arragon.
-In his younger days he went into the army; but
-afterwards held a situation in the court of his sovereign.
-Devoting himself to science he soon acquired
-a competent knowledge of Latin and Arabic. After
-studying in Paris he got the degree of doctor conferred
-upon him. He entered into the order of Minorites,
-and induced King James to establish a cloister of that
-order in Minorca. He afterwards travelled through
-Italy, Germany, England, Portugal, Cyprus, Armenia
-and Palestine. He is said by Mutius to have died in
-the year 1315, and to have been buried in Majorca.
-The following epitaph is given by Olaus Borrichius as
-engraven on his tomb:</p>
-
-<div class="poetry">
-<div class="poem"><div class="stanza">
-<span class="i0">Raymundus Lulli, cujus pia dogmata nulli<br /></span>
-<span class="i0">Sunt odiosa viro, jacet hic in marmore miro<br /></span>
-<span class="i0">Hic M. et CC. Cum P. cœpit sine sensibus esse.<br /></span>
-</div></div>
-</div>
-
-<p>M C C C in these lines denote 1300, and P which
-is the 15th letter of the alphabet denotes 15, so that
-if this epitaph be genuine it follows that his death
-took place in the year 1315.</p>
-
-<p>It seems scarcely necessary to notice the story that
-Raymond Lully made a present to Edward, King of England,
-of six millions of pieces of gold, to enable him to
-make war on the Saracens, which sum that monarch employed,
-contrary to the intentions of the donor, in his
-French wars. This story cannot apply to Edward III.,
-because in 1315, at the time of Raymond’s death, that
-monarch was only three years of age. It can scarcely
-apply to Edward II., who ascended the throne in
-1305: but who had no opportunity of making war,
-either on the Saracens or French, being totally occupied
-in opposing the intrigues of his queen and rebellious
-<span class="pagenum" id="Page_39">39</span>
-subjects, to whom he ultimately fell a sacrifice.
-Edward the First made war both upon the Saracens
-and the French, and lived during the time of Raymond:
-but his wars with the Saracens were finished
-before he ascended the throne, and during the whole of
-his reign he was too much occupied with his projected
-conquest of Scotland, to pay much serious attention
-to any French war whatever. The story, therefore,
-cannot apply to any of the three Edwards, and cannot
-be true. Raymond Lully is said to have been stoned
-to death in Africa for preaching Christianity in the
-year 1315. Others will have it that he was alive in
-England in the year 1332, at which time his age
-would have been 97.</p>
-
-<p>The following table exhibits a list of his numerous
-writings, most of which are to be found in the Theatrum
-Chemicum, the Artis Aurifer&aelig;, or the Biblotheca
-Chemica.
-
-<span class="table">
-<span class="trow">1. Praxis Universalis Magni Operis.</span>
-
-<span class="trow">2. Clavicula.</span>
-
-<span class="trow">3. Theoria et Practica.</span>
-
-<span class="trow">4. Compendium Anim&aelig; Transmutationis Artis Metallorum.</span>
-
-<span class="trow">5. Ultimum Testamentum. Of this work, which
-professes to give the whole doctrine of alchymy, there
-is an English translation.</span>
-
-<span class="trow">6. Elucidatio Testamenti.</span>
-
-<span class="trow">7. Potestas Divitiorum cum Expositione Testamenti
-Hermetis.</span>
-
-<span class="trow">8. Compendium Artis Magic&aelig;, quoad Compositionem
-Lapidis.</span>
-
-<span class="trow">9. De Lapide et Oleo Philosophorum.</span>
-
-<span class="trow">10. Modus accipiendi Aurum Potabile.</span>
-
-<span class="trow">11. Compendium Alchymi&aelig; et Naturalis Philosophi&aelig;.</span>
-
-<span class="trow">12. Lapidarium.</span>
-
-<span class="trow">13. Lux Mercuriorum.</span>
-
-<span class="trow">14. Experimenta.
-<span class="pagenum" id="Page_40">40</span></span>
-
-<span class="trow">15. Ars Compendiosa vel Vademecum.</span>
-
-<span class="trow">16. De Accurtatione Lapidis.</span>
-</span></p>
-
-<p>Several other tracts besides these are named by
-Gmelin; but I have never seen any of them. I have
-attempted several times to read over the works of
-Raymond Lully, particularly his Last Will and Testament,
-which is considered the most important of
-them all. But they are all so obscure, and filled with
-such unintelligible jargon, that I have found it impossible
-to understand them. In this respect they
-form a wonderful contrast with the works of Albertus
-Magnus and Roger Bacon, which are comparatively
-plain and intelligible. For an account, therefore, of
-the chemical substances with which he was acquainted,
-I am obliged to depend on Gmelin; though
-I put no great confidence in his accuracy.</p>
-
-<p>Like his predecessors, he was of opinion that all
-the metals are compounds of sulphur and mercury.
-But he seems first to have introduced those hieroglyphical
-figures or symbols, which appear in such
-profusion in the English translation of his Last Will
-and Testament, and which he doubtless intended to
-illustrate his positions. Though what other purpose
-they could serve, than to induce the reader to consider
-his statements as allegorical, it is not easy to conjecture.
-Perhaps they may have been designed to impose
-upon his contemporaries by an air of something
-very profound and inexplicable. For that he possessed
-a good deal of charlatanry is pretty evident, from the
-slightest glance at his performances.</p>
-
-<p>He was acquainted with cream of tartar, which he
-distilled: the residue he burnt, and observed that the
-alkali extracted deliquesced when exposed to the air.
-He was acquainted with nitric acid, which he obtained
-by distilling a mixture of saltpetre and green
-vitriol. He mentions its power of dissolving, not
-merely mercury, but likewise other metals. He could
-form aqua regia by adding sal ammoniac or common
-<span class="pagenum" id="Page_41">41</span>
-salt to nitric acid, and he was aware of the property
-which it had of dissolving gold.</p>
-
-<p>Spirit of wine was well known to him, and distinguished
-by him by the names of aqua vit&aelig; ardens and
-argentum vivum vegetabile. He knew the method of
-rendering it stronger by an admixture of dry carbonate
-of potash, and of preparing vegetable tinctures by
-means of it. He mentions alum from Rocca, marcasite,
-white and red mercurial precipitate. He knew the
-volatile alkali and its coagulations by means of alcohol.
-He was acquainted with cupellated silver, and
-first obtained rosemary oil by distilling the plant with
-water. He employed a mixture of flour and white of
-egg spread upon a linen cloth to cement cracked
-glass vessels, and used other lutes for similar purposes.<a id="FNanchor_27" href="#Footnote_27" class="fnanchor">27</a></p>
-
-<p>5. Arnoldus de Villa Nova is said to have been
-born at Villeneuve, a village of Provence, about the
-year 1240. Olaus Borrichius assures us, that in his
-time his posterity lived in the neighbourhood of Avignon;
-that he was acquainted with them, and that
-they were by no means destitute of chemical knowledge.
-He is said to have been educated at Barcelona,
-under John Casamila, a celebrated professor of medicine.
-This place he was obliged to leave, in consequence
-of foretelling the death of Peter of Arragon. He went
-to Paris, and likewise travelled through Italy. He
-afterwards taught publicly in the University of Montpelier.
-His reputation as a physician became so
-great, that his attendance was solicited in dangerous
-cases by several kings, and even by the pope himself.
-He was skilled in all the sciences of his time, and was
-besides a proficient in Greek, Hebrew, and Arabic.
-When at Paris he studied astrology, and calculating
-the age of the world, he found that it was to terminate
-in the year 1335. The theologians of Paris exclaimed
-<span class="pagenum" id="Page_42">42</span>
-against this and several other of his opinions,
-and condemned our astrologer as a heretic. This
-obliged him to leave France; but the pope protected
-him. He died in the year 1313, on his way to visit
-Pope Clement V. who lay sick at Avignon. The following
-table exhibits a pretty full list of his works:
-
-<span class="table">
-<span class="trow">1. Antidotorium</span>
-
-<span class="trow">2. De Vinis.</span>
-
-<span class="trow">3. De Aquis Laxativis.</span>
-
-<span class="trow">4. Rosarius Philosophorum.</span>
-
-<span class="trow">5. Lumen Novum.</span>
-
-<span class="trow">6. De Sigillis.</span>
-
-<span class="trow">7. Flos Florum.</span>
-
-<span class="trow">8. Epistol&aelig; super Alchymia ad Regem Neapolitanum.</span>
-
-<span class="trow">9. Liber Perfectionis Magisterii.</span>
-
-<span class="trow">10. Succosa Carmina.</span>
-
-<span class="trow">11. Questiones de Arte Transmutationis Metallorum.</span>
-
-<span class="trow">12. Testamentum.</span>
-
-<span class="trow">13. Lumen Luminum.</span>
-
-<span class="trow">14. Practica.</span>
-
-<span class="trow">15. Speculum Alchymi&aelig;.</span>
-
-<span class="trow">16. Carmen.</span>
-
-<span class="trow">17. Questiones ad Bonifacium.</span>
-
-<span class="trow">18. Semita Semit&aelig;.</span>
-
-<span class="trow">19. De Lapide Philosophorum.</span>
-
-<span class="trow">20. De Sanguine Humano.</span>
-
-<span class="trow">21. De Spiritu Vini, Vino Antimonii et Gemmorum Viribus.</span>
-</span></p>
-
-<p>Perhaps the most curious of all these works is the
-<i>Rosarium</i>, which is intended as a complete compend
-of all the alchymy of his time. The first part of it
-on the theory of the art is plain enough; but the second
-part on the practice, which is subdivided into
-thirty-two chapters, and which professes to teach the
-art of making the philosopher’s stone, is in many
-places quite unintelligible to me.
-<span class="pagenum" id="Page_43">43</span></p>
-
-<p>He considered, like his predecessors, mercury as a
-constituent of metals, and he professed a knowledge
-of the philosopher’s stone, which he could increase at
-pleasure. Gold and gold-water was, in his opinion,
-one of the most precious of medicines. He employed
-mercury in medicine. He seems to designate bismuth
-under the name <i>marcasite</i>. He was in the habit of
-preparing oil of turpentine, oil of rosemary, and spirit
-of rosemary, which afterwards became famous under
-the name of Hungary-water. These distillations
-were made in a glazed earthen vessel with a glass top
-and helm.</p>
-
-<p>His works were published at Venice in a single
-folio volume, in the year 1505. There were seven
-subsequent editions, the last of which appeared at
-Strasburg in 1613.</p>
-
-<p>6. John Isaac Hollandus and his countryman of the
-same name, were either two brothers or a father and
-son; it is uncertain which. For very few circumstances
-respecting these two laborious and meritorious
-men have been handed down to posterity. They were
-born in the village of Stolk in Holland, it is supposed
-in the 13th century. They certainly were after Arnoldus
-de Villa Nova, because they refer to him in
-their writings. They wrote many treatises on chemistry,
-remarkable, considering the time when they
-wrote, for clearness and precision, describing their processes
-with accuracy, and even giving figures of the
-instruments which they employed. This makes their
-books intelligible, and they deserve attention because
-they show that various processes, generally supposed
-of a more modern date were known to them. Their
-treatises are written partly in Latin and partly in German.
-The following list contains the names of most
-of them:
-
-<span class="table">
-<span class="trow">1. Opera Vegetabilia ad ejus alia Opera Intelligenda Necessaria.
-<span class="pagenum" id="Page_44">44</span></span>
-
-<span class="trow">2. Opera Mineralia seu de Lapide Philosophico Libri duo.</span>
-
-<span class="trow">3. Tractat vom stein der Weisen.</span>
-
-<span class="trow">4. Fragmenta Qu&aelig;dam Chemica.</span>
-
-<span class="trow">5. De Triplice Ordine Elixiris et Lapidis Theorea.</span>
-
-<span class="trow">6. Tractatus de Salibus et Oleis Metallorum.</span>
-
-<span class="trow">7. Fragmentum de Opere Philosophorum.</span>
-
-<span class="trow">8. Rariores Chemi&aelig; Operationes.</span>
-
-<span class="trow">9. Opus Saturni.</span>
-
-<span class="trow">10. De Spiritu Urin&aelig;.</span>
-
-<span class="trow">11. Hand der Philosopher.</span>
-</span></p>
-
-<p>Olaus Borrichius complains that their <i>opera mineralia</i>
-abound with processes; but that they are ambiguous,
-and such that nothing certain can be deduced
-from them even after much labour. Hence they draw
-on the unwary tyro from labour to labour. I am
-disposed myself to draw a different conclusion, from
-what I have read of that elaborate work. It is true
-that the processes which profess to make the philosopher’s
-stone, are fallacious, and do not lead to the
-manufacture of gold, as the author intended, and expected:
-but it is a great deal when alchymistical
-processes are delivered in such intelligible language
-that you know the substances employed. This enables
-us easily to see the results in almost every case, and
-to know the new compounds which were formed during
-a vain search for the philosopher’s stone. Had the
-other alchymists written as plainly, the absurdity of
-their researches would have been sooner discovered,
-and thus a useless or pernicious investigation would
-have sooner terminated.</p>
-
-<p>7. Basil Valentine is said to have been born about
-the year 1394, and is, perhaps, the most celebrated of
-all the alchymists, if we except Paracelsus. He was
-a Benedictine monk, at Erford, in Saxony. If we
-believe Olaus Borrichius, his writings were enclosed
-in the wall of a church at Erford, and were discovered
-<span class="pagenum" id="Page_45">45</span>
-long after his death, in consequence of the wall having
-been driven down by a thunderbolt. But this story is
-not well authenticated, and is utterly improbable.
-Much of his time seems to have been taken up in the
-preparation of chemical medicines. It was he that
-first introduced antimony into medicine; and it is
-said, though on no good authority, that he first tried
-the effects of antimonial medicines upon the monks of
-his convent, upon whom it acted with such violence
-that he was induced to distinguish the mineral from
-which these medicines had been extracted, by the
-name of <i>antimoine</i> (hostile to monks). What shows
-the improbability of this story is, that the works of
-Basil Valentine, and in particular his Currus triumphalis
-Antimonii, were written in the German language.
-Now the German name for antimony is not
-<i>antimoine</i>, but <i>speissglass</i>. The Currus triumphalis
-Antimonii was translated into Latin by Kerkringius,
-who published it, with an excellent commentary, at
-Amsterdam, in 1671.</p>
-
-<p>Basil Valentine writes with almost as much virulence
-against the physicians of his time, as Paracelsus himself
-did afterwards. As no particulars of his life have
-been handed down to posterity, I shall satisfy myself
-with giving a catalogue of his writings, and then
-pointing out the most striking chemical substances
-with which he was acquainted.</p>
-
-<p>The books which have appeared under the name of
-Basil Valentine, are very numerous; but how many
-of them were really written by him, and how many
-are supposititious, is extremely doubtful. The following
-are the principal:
-
-<span class="table">
-<span class="trow">1. Philosophia Occulta.</span>
-
-<span class="trow">2. Tractat von naturlichen und ubernaturlichen
-Dingen; auch von der ersten tinctur, Wurzel und
-Geiste der Metallen.</span>
-
-<span class="trow">3. Von dern grossen stein der Uhralten.
-<span class="pagenum" id="Page_46">46</span></span>
-
-<span class="trow">4. Vier tractatlein vom stein der Weisen.</span>
-
-<span class="trow">5. Kurzer anhang und klare repetition oder Wiederholunge
-vom grosen stein der Uhralten.</span>
-
-<span class="trow">6. De prima Materia Lapidis Philosophici.</span>
-
-<span class="trow">7. Azoth Philosophorum seu Aureli&aelig; occult&aelig; de
-Materia Lapidis Philosophorum.</span>
-
-<span class="trow">8. Apocalypsis Chemica.</span>
-
-<span class="trow">9. Claves 12 Philosophi&aelig;.</span>
-
-<span class="trow">10. Practica.</span>
-
-<span class="trow">11. Opus pr&aelig;clarum ad utrumque, quod pro Testamento
-dedit Filio suo adoptivo.</span>
-
-<span class="trow">12. Letztes Testament.</span>
-
-<span class="trow">13. De Microcosmo.</span>
-
-<span class="trow">14. Von der grosen Heimlichkeit der Welt und ihrer
-Arzney.</span>
-
-<span class="trow">15. Von der Wissenschaft der sieben Planeten.</span>
-
-<span class="trow">16. Offenbahrung der verborgenen Handgriffe.</span>
-
-<span class="trow">17. Conclusiones or Schlussreden.</span>
-
-<span class="trow">18. Dialogus Fratris Alberti cum Spiritu.</span>
-
-<span class="trow">19. De Sulphure et fermento Philosophorum.</span>
-
-<span class="trow">20. Haliographia.</span>
-
-<span class="trow">21. Triumph wagen Antimonii.</span>
-
-<span class="trow">22. Einiger Weg zur Wahrheit.</span>
-
-<span class="trow">23. Licht der Natur.</span>
-</span></p>
-
-<p>The only one of these works that I have read with
-care, is Kerkringius’s translation and commentary on
-the Currus triumphalis Antimonii. It is an excellent
-book, written with clearness and precision, and contains
-every thing respecting antimony that was known
-before the commencement of the 19th century. How
-much of this is owing to Kerkringius I cannot say, as
-I have never had an opportunity of seeing a copy of
-the original German work of Basil Valentine.</p>
-
-<p>Basil Valentine, like Isaac Hollandus, was of opinion
-that the metals are compounds of salt, sulphur,
-and mercury. The philosopher’s stone was composed
-of the same ingredients. He affirmed, that there exists
-<span class="pagenum" id="Page_47">47</span>
-a great similarity between the mode of purifying gold
-and curing the diseases of men, and that antimony
-answers best for both. He was acquainted with
-arsenic, knew many of its properties, and mentions
-the red compound which it forms with sulphur. Zinc
-seems to have been known to him, and he mentions
-bismuth, both under its own name, and under that of
-<i>marcasite</i>. He was aware that manganese was employed
-to render glass colourless. He mentions nitrate
-of mercury, alludes to corrosive sublimate, and seems
-to have known the red oxide of mercury. It would be
-needless to specify the preparations of antimony with
-which he was acquainted; scarcely one was unknown
-to him which, even at present, exists in the European
-Pharmacopœias. Many of the preparations of lead
-were also familiar to him. He was aware that lead
-gives a sweet taste to vinegar. He knew sugar of
-lead, litharge, yellow oxide of lead, white carbonate
-of lead; and mentions that this last preparation was
-often adulterated in his time. He knew the method
-of making green vitriol, and the double chloride of
-iron and ammonia. He was aware that iron could be
-precipitated from its solution by potash, and that iron
-has the property of throwing down copper. He was
-aware that tin sometimes contains iron, and ascribed
-the brittleness of Hungarian iron to copper. He knew
-that oxides of copper gave a green colour to glass;
-that Hungarian silver contained gold; that gold is
-precipitated from aqua regia by mercury, in the state
-of an amalgam. He mentions fulminating gold. But
-the important facts contained in his works are so
-numerous, while we are so uncertain about the genuineness
-of the writings themselves, that it will scarcely
-be worth while to proceed further with the catalogue.</p>
-
-<p>Thus I have brought the history of alchymy to the
-time of Paracelsus, when it was doomed to undergo a
-new and important change. It will be better, therefore,
-<span class="pagenum" id="Page_48">48</span>
-not to pursue the history of alchymy further, but
-to take up the history of true chemistry; and in the
-first place to endeavour to determine what chemical
-facts were known to the Ancients, and how far the
-science had proceeded to develop itself before the time
-of Paracelsus.
-<span class="pagenum" id="Page_49">49</span></p>
-
-<hr class="chap" />
-<h2 id="CHAPTER_II">CHAPTER II.<br />
-
-<span class="large">OF THE CHEMICAL KNOWLEDGE POSSESSED BY THE
-ANCIENTS.</span></h2>
-
-<p>Notwithstanding the assertions of Olaus Borrichius,
-and various other writers who followed him on
-the same side, nothing is more certain than that the
-ancients have left no chemical writings behind them,
-and that no evidence whatever exists to prove that the
-science of chemistry was known to them. Scientific
-chemistry, on the contrary, took its origin from the collection
-and comparison of the chemical facts, made
-known by the practice and improvement of those
-branches of manufactures which can only be conducted
-by chemical processes. Thus the smelting of ores, and
-the reduction of the metals which they contain, is a
-chemical process; because it requires, for its success,
-the separation of certain bodies which exist in the ore
-chemically combined with the metals; and it cannot be
-done, except by the application or mixture of a new
-substance, having an affinity for these substances, and
-capable, in consequence, of separating them from the
-metal, and thus reducing the metal to a state of
-purity. The manufacture of glass, of soap, of leather,
-are all chemical, because they consist of processes, by
-means of which bodies, having an affinity for each
-other, are made to unite in chemical combination.
-Now I shall in this chapter point out the principal
-chemical manufactures that were known to the ancients,
-<span class="pagenum" id="Page_50">50</span>
-that we may see how much they contributed towards
-laying the foundation of the science. The chief sources
-of our information on this subject are the writings of
-the Greeks and Romans. Unfortunately the arts and
-manufactures stood in a very different degree of estimation
-among the ancients from what they do among
-the moderns. Their artists and manufacturers were
-chiefly slaves. The citizens of Greece and Rome devoted
-themselves to politics or war. Such of them
-as turned their attention to learning confined themselves
-to <i>oratory</i>, which was the most fashionable
-and the most important study, or to history, or poetry.
-The only scientific pursuits which ever engaged their
-attention, were politics, ethics, and mathematics. For,
-unless Archimedes is to be considered as an exception,
-scarcely any of the numerous branches of physics and
-mechanical philosophy, which constitute so great a
-portion of modern science, even attracted the attention
-of the ancients.</p>
-
-<p>In consequence of the contemptible light in which
-all mechanical employments were viewed by the ancients,
-we look in vain in any of their writings for
-accurate details respecting the processes which they
-followed. The only exception to this general neglect
-and contempt for all the arts and trades, is Pliny the
-Elder, whose object, in his natural history, was to
-collect into one focus, every thing that was known at
-the period when he lived. His work displays prodigious
-reading, and a vast fund of erudition. It is to
-him that we are chiefly indebted for the knowledge of
-the chemical arts which were practised by the ancients.
-But the low estimation in which these arts were held,
-appears evident from the wonderful want of information
-which Pliny so frequently displays, and the
-erroneous statements which he has recorded respecting
-these processes. Still a great deal may be drawn from
-the information which has been collected and transmitted
-to us by this indefatigable natural historian.
-<span class="pagenum" id="Page_51">51</span></p>
-
-<p><span class="smcap">I.</span>&mdash;The ancients were acquainted with <span class="smcap">SEVEN
-METALS</span>; namely, gold, silver, mercury, copper, iron,
-tin, and lead. They knew and employed various preparations
-of zinc, and antimony, and arsenic; though
-we have no evidence that these bodies were known to
-them in the metallic state.</p>
-
-<p>1. Gold is spoken of in the second chapter of Genesis
-as existing and familiarly known before the flood.</p>
-
-<p>“The name of the first is Pison; that is it which
-encompasseth the whole land of Havilah, where there
-is gold. And the gold of that land is good: there is
-bdellium and the onyx-stone.” The Hebrew word for
-gold, בהז (<i>zahav</i>) signifies to be clear, to shine; alluding,
-doubtless, to the brilliancy of that metal. The term
-<i>gold</i> occurs frequently in the writings of Moses, and
-the metal must have been in common use among the
-Egyptians, when that legislator led the children of
-Israel out of Egypt.<a id="FNanchor_28" href="#Footnote_28" class="fnanchor">28</a> Gold is found in the earth almost
-always in a native state. There can be no doubt that
-it was much more abundant on the surface of the earth,
-and in the beds of rivers in the early periods of society,
-than it is at present: indeed this is obvious,
-from the account which Pliny gives of the numerous
-places in Asia and Greece, and other European countries,
-where gold was found in his time.</p>
-
-<p>Gold, therefore, could hardly fail to attract the attention
-of the very first inhabitants of the globe; its
-beauty, its malleability, its indestructibility, would
-give it value: accident would soon discover the possibility
-of melting it by heat, and thus of reducing the
-grains or small pieces of it found on the surface of the
-earth into one large mass. It would be speedily made
-into ornaments and utensils of various kinds, and
-thus gradually would come into common use. This
-we find to have occurred in America, when it was discovered
-<span class="pagenum" id="Page_52">52</span>
-by Columbus. The inhabitants of the tropical
-parts of that vast continent were familiarly acquainted
-with gold; and in Mexico and Peru it existed in great
-abundance; indeed the natives of these countries
-seem to have been acquainted with no other metal, or
-at least no other metal was brought into such general
-use, except silver, which in Peru was, it is true, still
-more common than gold.</p>
-
-<p>Gold, then, was probably the first metal with which
-man became acquainted; and that knowledge must
-have preceded the commencement of history, since it
-is mentioned as a common and familiar substance in
-the Book of Genesis, the oldest book in existence, of
-the authenticity of which we possess sufficient evidence.
-The period of leading the children of Israel out of
-Egypt by Moses, is generally fixed to have been one
-thousand six hundred and forty-eight years before
-the commencement of the Christian era. So early,
-then, we are certain, that not only gold, but the
-other six malleable metals known to the ancients, were
-familiar to the inhabitants of Egypt. The Greeks
-ascribe the discovery of gold to the earliest of their
-heroes. According to Pliny, it was discovered on
-Mount Pang&aelig;us by Cadmus, the Phœnician: but
-Cadmus’s voyage into Greece was nearly coeval with
-the exit of the Israelites out of Egypt, at which time
-we learn from Moses that gold was in common use
-in Egypt. All that can be meant, then, is, that Cadmus
-first discovered gold in Greece; not that he made
-mankind first acquainted with it. Others say that
-Thoas and Eaclis, or Sol, the son of Oceanus, first
-found gold in Panchaia. Thoas was a contemporary
-of the heroes of the Trojan war, or at least was posterior
-to the Argonautic expedition, and consequently long
-posterior to Moses and the departure of the children
-of Israel from Egypt.</p>
-
-<p>2. Silver also was not only familiarly known to the
-Egyptians in the time of Moses, but, as we learn from
-<span class="pagenum" id="Page_53">53</span>
-Genesis, was coined into money before Joseph was set
-over the land of Egypt by Pharaoh, which happened one
-thousand eight hundred and seventy-two years before
-the commencement of the Christian era, and consequently
-two hundred and twenty-four years before the
-departure of the children of Israel out of Egypt.</p>
-
-<p>“And Joseph gathered up all the money that was
-found in the land of Egypt, and in the land of Canaan,
-for the corn which they bought; and Joseph brought
-the money into Pharaoh’s house.”<a id="FNanchor_29" href="#Footnote_29" class="fnanchor">29</a> The Hebrew word
-ףםכ (<i>keseph</i>), translated <i>money</i>, signifies silver, and
-was so called from its pale colour. Silver occurs in
-many other passages of the writings of Moses.<a id="FNanchor_30" href="#Footnote_30" class="fnanchor">30</a> The
-Greeks inform us, that Erichthonius the Athenian, or
-Ceacus, were the discoverers of silver; but both of
-these individuals were long posterior to the time of
-Joseph.</p>
-
-<p>Silver, like gold, occurs very frequently in the
-metallic state. This, no doubt, was a still more frequent
-occurrence in the early ages of the world; it would
-therefore attract the attention of mankind as early as
-gold, and for the same reason. It is very ductile,
-very beautiful, and much more easily fused than
-gold: it would be therefore more easily reduced into
-masses, and formed into different utensils and ornaments
-than even gold itself. The ores of it which occur
-in the earth are heavy, and would therefore draw the
-attention of even rude men to them: they have, most
-of them at least, the appearance of being metallic, and
-the most common of them may be reduced to the state
-of metallic silver, simply by keeping them a sufficient
-time in fusion. Accordingly we find that the Peruvians,
-before they were overrun by the Spaniards, had
-made themselves acquainted with the mode of digging
-out and smelting the ores of silver which occur in
-<span class="pagenum" id="Page_54">54</span>
-their country, and that many of their most common
-utensils were made of that metal.</p>
-
-<p>Silver and gold approached each other nearer in
-value among the ancients than at present: an ounce
-of fine gold was worth from ten to twelve ounces of fine
-silver, the variation depending upon the accidental
-relation of the supply of both metals. But after the
-discovery of America, the quantity of silver found in
-that continent, especially in Mexico, was so great,
-compared with that of the gold found, that silver
-became considerably cheaper; so that an ounce of
-fine gold came to be equivalent to about fourteen
-ounces and a half of fine silver. Of course these
-relative values have fluctuated a little according to
-the abundance of the supply of silver. Though the
-revolution in the Spanish American colonies has considerably
-diminished the supply of silver from the
-mines, that deficiency seems to have been supplied by
-other ways, and thus the relative proportion between
-the value of gold and silver has continued nearly unaltered.</p>
-
-<p>3. That copper must have been known in the earliest
-ages of society, is sufficiently evident. It occurs frequently
-native, and could not fail to attract the attention
-of mankind, from its colour, weight, and malleability.
-It would not be difficult to fuse it even in the
-rudest ages: and when melted into masses, as it is
-malleable and ductile, it would not require much skill
-to convert it into useful and ornamental utensils. The
-Hebrew word תשחנ (<i>nechooshat</i>) translated <i>brass</i>, obviously
-means <i>copper</i>. We have the authority of the
-Book of Genesis to satisfy us that copper was known
-before the flood, and probably as early as either silver
-or gold.</p>
-
-<p>“And Zillah, she also bore Tubal-cain, an instructor
-of every artificer in brass (<i>copper</i>) and iron.”<a id="FNanchor_31" href="#Footnote_31" class="fnanchor">31</a>
-<span class="pagenum" id="Page_55">55</span></p>
-
-<p>The word <i>copper</i> occurs in many other passages of
-the writings of Moses.<a id="FNanchor_32" href="#Footnote_32" class="fnanchor">32</a> That the Hebrew word translated
-<i>brass</i> must have meant copper is obvious, from
-the following passage: “Out of whose hills thou
-mayest dig brass.”<a id="FNanchor_33" href="#Footnote_33" class="fnanchor">33</a> Brass does not exist in the earth,
-nor any ore of it, it is always made artificially; it
-must therefore have been copper, or an ore of copper,
-that was alluded to by Moses.</p>
-
-<p>Copper must have been discovered and brought into
-common use long before iron or steel; for Homer represents
-his heroes of the Trojan war as armed with
-swords, &amp;c. of copper. Copper itself is too soft to be
-made into cutting instruments; but the addition of a
-little tin gives it the requisite hardness. Now we learn
-from the analyses of Klaproth, that the copper swords
-of the ancients were actually hardened by the addition
-of tin.<a id="FNanchor_34" href="#Footnote_34" class="fnanchor">34</a></p>
-
-<p>Copper was the metal in common use in the early
-part of the Roman commonwealth. Romulus coined
-copper money alone. Numa established a college of
-workers in copper (<i>&aelig;rariorum fabrum</i>).<a id="FNanchor_35" href="#Footnote_35" class="fnanchor">35</a></p>
-
-<p>The Latin word <i>&aelig;s</i> sometimes signifies copper, and
-sometimes brass. It is plain from what Pliny says on
-the subject, that he did not know the difference between
-copper and brass; he says, that an ore of <i>&aelig;s</i> occurs
-in Cyprus, called <i>chalcitis</i>, where <i>&aelig;s</i> was first discovered.
-Here <i>&aelig;s</i> obviously means copper. In another
-place he says, that <i>&aelig;s</i> is obtained from a mineral called
-<i>cadmia</i>. Now from the account of cadmia by Pliny
-and Dioscorides, there cannot be a doubt that it is the
-ore to which the moderns have given the name of
-<i>calamine</i>, by means of which brass is made. It is
-sometimes a silicate and sometimes a carbonate of
-zinc; for both of these ores are confounded together
-<span class="pagenum" id="Page_56">56</span>
-under the name of cadmia, and both are employed in
-the manufacture of brass.</p>
-
-<p>Solinus says, that <i>&aelig;s</i> was first made at Chalcis, a
-town in Eubœa. Hence the Greek name, χαλκος
-(<i>chalkos</i>), by which copper was distinguished.</p>
-
-<p>The proper name for brass, by which is meant an
-alloy of copper and zinc, was <i>aurichalcum</i>, or golden,
-or yellow copper. Pliny says, that long before his
-time, the ore of aurichalcum was exhausted, so that
-no more of that beautiful alloy was made. Are we to
-conclude from this, that there once existed an ore consisting
-of calamine and ore of copper, mixed or
-united together? After the exhaustion of the aurichalcum
-mine, the <i>salustianum</i> became the most famous;
-but it soon gave place to the <i>livianum</i>, a copper-mine
-in Gaul, named after Livia, the wife of
-Augustus. Both these mines were exhausted in the
-time of Pliny. The <i>&aelig;s marianum</i>, or copper of Cordova,
-was the most celebrated in his time. This last
-<i>&aelig;s</i>, he says, absorbs most cadmia, and acquires the
-greatest resemblance to aurichalcum. We see from
-this, that in Pliny’s time brass was made artificially,
-and by a process similar to that still followed by the
-moderns.</p>
-
-<p>The most celebrated alloy of copper among the
-ancients, was the <i>&aelig;s corinthium</i>, or Corinthian copper,
-formed accidentally, as Pliny informs us, during
-the burning of Corinth by Mummius in the year 608,
-after the building of Rome, or one hundred and forty-five
-years before the commencement of the Christian
-era. There were four kinds of it, of which Pliny gives
-the following description; not, however, very intelligible:
-
-<span class="table">
-<span class="trow">1. White. It resembled silver much in its lustre,
-and contained an excess of that metal.</span>
-
-<span class="trow">2. Red. In this kind there is an excess of gold.</span>
-
-<span class="trow">3. In the third kind, gold, silver, and copper are
-mixed in equal proportions.
-<span class="pagenum" id="Page_57">57</span></span>
-
-<span class="trow">4. The fourth kind is called <i>hepatizon</i>, from its
-having a liver colour. It is this colour which gives it
-its value.<a id="FNanchor_36" href="#Footnote_36" class="fnanchor">36</a></span>
-</span></p>
-
-<p>Copper was put by the ancients to almost all the
-uses to which it is put by the moderns. One of the
-great sources of consumption was bronze statues,
-which were first introduced into Rome after the conquest
-of Asia Minor. Before that time, the statues of
-the Romans were made of wood or stoneware. Pliny
-gives various formulas for making bronze for statues.
-Of these it may be worth while to put down the most
-material.</p>
-
-<p>1. To new copper add a third part of old copper. To
-every hundred pounds of this mixture, twelve pounds
-and a half of tin<a id="FNanchor_37" href="#Footnote_37" class="fnanchor">37</a> are added, and the whole melted
-together.</p>
-
-<p>2. Another kind of bronze for statues was formed,
-by melting together
-
-<span class="table">
-  <span class="trow">
-    <span class="tcell tdr">100lbs.</span>
-    <span class="tcell">copper,</span>
-  </span>
-  <span class="trow">
-    <span class="tcell tdr">10lbs.</span>
-    <span class="tcell">lead,</span>
-  </span>
-  <span class="trow">
-    <span class="tcell tdr">5lbs.</span>
-    <span class="tcell">tin.</span>
-  </span>
-</span></p>
-
-<p>3. Their copper-pots for boiling consisted of 100lbs.
-of copper, melted with three or four pounds of tin.</p>
-
-<p>The four celebrated statues of horses which, during
-the reign of Theodosius II. were transported from
-Chio to Constantinople; and, when Constantinople
-was taken and plundered by the Crusaders and Venetians
-in 1204, were sent by Martin Zeno and set up
-by the doge, Peter Ziani, in the portal of St. Mark;
-were in 1798, transported by the French to Paris; and
-finally, after the overthrow of Buonaparte, and the
-restoration of the Bourbons in 1815, returned to
-<span class="pagenum" id="Page_58">58</span>
-Venice and placed upon their ancient pedestals. The
-metal of which these horses had been made was examined
-by Klaproth, and found by him composed of
-
-<span class="table">
-  <span class="trow">
-    <span class="tcell">Copper,</span>
-    <span class="tcell tdr">993</span>
-    <span class="tcell">&nbsp;</span>
-  </span>
-  <span class="trow">
-    <span class="tcell">Tin,</span>
-    <span class="tcell tdr">7</span>
-    <span class="tcell">&nbsp;</span>
-  </span>
-  <span class="trow">
-    <span class="tcell">&nbsp;</span>
-    <span class="tcell tdr bt">1000</span>
-    <span class="tcell"><a id="FNanchor_38" href="#Footnote_38" class="fnanchor">38</a></span>
-  </span>
-</span></p>
-
-<p>Klaproth also analyzed an ancient bronze statue in
-one of the German cabinets, and found it composed of
-
-<span class="table">
-  <span class="trow">
-    <span class="tcell">Copper,</span>
-    <span class="tcell tdr">916</span>
-    <span class="tcell">&nbsp;</span>
-  </span>
-  <span class="trow">
-    <span class="tcell">Tin,</span>
-    <span class="tcell tdr">75</span>
-    <span class="tcell">&nbsp;</span>
-  </span>
-  <span class="trow">
-    <span class="tcell">Lead,</span>
-    <span class="tcell tdr">97</span>
-    <span class="tcell">&nbsp;</span>
-  </span>
-  <span class="trow">
-    <span class="tcell">&nbsp;</span>
-    <span class="tcell tdr bt">1000</span>
-    <span class="tcell"><a id="FNanchor_39" href="#Footnote_39" class="fnanchor">39</a></span>
-  </span>
-</span></p>
-
-<p>Several other old brass and bronze pieces of metal,
-very ancient, but found in Germany, were also analyzed
-by Klaproth. The result of his analyses was as
-follows:</p>
-
-<p>The metal of which the altar of Krodo was made
-consisted of
-
-<span class="table">
-  <span class="trow">
-    <span class="tcell">Copper,</span>
-    <span class="tcell tdr">69</span>
-    <span class="tcell">&nbsp;</span>
-  </span>
-  <span class="trow">
-    <span class="tcell">Zinc,</span>
-    <span class="tcell tdr">18</span>
-    <span class="tcell">&nbsp;</span>
-  </span>
-  <span class="trow">
-    <span class="tcell">Lead,</span>
-    <span class="tcell tdr">13</span>
-    <span class="tcell">&nbsp;</span>
-  </span>
-  <span class="trow">
-    <span class="tcell">&nbsp;</span>
-    <span class="tcell tdr bt">100</span>
-    <span class="tcell"><a id="FNanchor_40" href="#Footnote_40" class="fnanchor">40</a></span>
-  </span>
-</span></p>
-
-<p>The emperor’s chair, which had in the eleventh century
-been transported from Harzburg to Goslar, where
-it still remains, was found to be composed of
-
-<span class="table">
-  <span class="trow">
-    <span class="tcell">Copper,</span>
-    <span class="tcell tdr">92&middot;5</span>
-    <span class="tcell">&nbsp;</span>
-  </span>
-  <span class="trow">
-    <span class="tcell">Tin,</span>
-    <span class="tcell tdr">5&middot;0</span>
-    <span class="tcell">&nbsp;</span>
-  </span>
-  <span class="trow">
-    <span class="tcell">Lead,</span>
-    <span class="tcell tdr">2&middot;5</span>
-    <span class="tcell">&nbsp;</span>
-  </span>
-  <span class="trow">
-    <span class="tcell">&nbsp;</span>
-    <span class="tcell tdr bt">100</span>
-    <span class="tcell"><a id="FNanchor_41" href="#Footnote_41" class="fnanchor">41</a></span>
-  </span>
-</span></p>
-
-<p>Another piece of metal, which enclosed the high altar
-in a church in Germany, was composed of
-<span class="pagenum" id="Page_59">59</span>
-
-<span class="table">
-  <span class="trow">
-    <span class="tcell">Copper,</span>
-    <span class="tcell tdr">75&middot;0</span>
-    <span class="tcell">&nbsp;</span>
-  </span>
-  <span class="trow">
-    <span class="tcell">Tin,</span>
-    <span class="tcell tdr">12&middot;5</span>
-    <span class="tcell">&nbsp;</span>
-  </span>
-  <span class="trow">
-    <span class="tcell">Lead,</span>
-    <span class="tcell tdr">12&middot;5</span>
-    <span class="tcell">&nbsp;</span>
-  </span>
-  <span class="trow">
-    <span class="tcell">&nbsp;</span>
-    <span class="tcell tdr bt">100</span>
-    <span class="tcell"><a id="FNanchor_42" href="#Footnote_42" class="fnanchor">42</a></span>
-  </span>
-</span></p>
-
-<p>These analyses, though none of them corresponds
-exactly with the proportions given by Pliny, confirms
-sufficiently his general statement, that the bronze of
-the ancients employed for statues was copper, alloyed
-with lead and tin.</p>
-
-<p>Some of the bronze statues cast by the ancients were
-of enormous dimensions, and show decisively the great
-progress which had been made by them in the art of
-working and casting metals. The addition of the lead
-and tin would not only add greatly to the hardness of
-the alloy, but would at the same time render it more
-easily fusible. The bronze statue of Apollo, placed in
-the capitol at the time of Pliny, was forty-five feet
-high, and cost 500 talents, equivalent to about &pound;50,000
-of our money. It was brought from Apollonia, in
-Pontus, by Lucullus. The famous statue of the sun
-at Rhodes was the work of Chares, a disciple of Lysippus;
-it was ninety feet high, was twelve years in
-making, and cost 300 talents (about &pound;30,000). It
-was made out of the engines of war left by Demetrius
-when he raised the siege of Rhodes. After standing
-fifty-six years, it was overthrown by an earthquake.
-It lay on the ground 900 years, and was sold by
-Mauvia, king of the Saracens, to a merchant, who
-loaded 900 camels with the fragments of it.</p>
-
-<p>Copper was introduced into medicine at rather an
-early period of society, and various medicinal preparations
-of it are described by Dioscorides and Pliny.
-It remains for us to notice the most remarkable of
-these. Pliny mentions an institution, to which he
-gives the name of <i>Seplasia</i>; the object of which was,
-<span class="pagenum" id="Page_60">60</span>
-to prepare medicines for the use of medical men. It
-seems, therefore, to have been similar to our apothecaries’
-shops of the present day. Pliny reprobates the
-conduct of the persons who had the charge of these
-Seplasi&aelig; in his time. They were in the habit of adulterating
-medicines to such a degree, that nothing good
-or genuine could be procured from them.<a id="FNanchor_43" href="#Footnote_43" class="fnanchor">43</a></p>
-
-<p>Both the oxides of copper were known to the ancients,
-though they were not very accurately distinguished
-from each other: they were known by the
-names <i>flos &aelig;ris</i> and <i>scoria &aelig;ris</i>, or <i>squama &aelig;ris</i>.
-They were obtained by heating bars of copper red-hot
-and letting them cool, exposed to the air. What fell
-off during the cooling was the <i>flos</i>, what was driven
-off by blows of a hammer was the <i>squama</i> or <i>scoria
-&aelig;ris</i>. It is obvious, that all these substances were
-nearly of the same nature, and that they were in
-reality mixtures of the black and red oxides of copper.</p>
-
-<p><i>Stomoma</i> seems also to have been an oxide of copper,
-which was gradually formed upon the surface of
-the metal, when it was kept in a state of fusion.</p>
-
-<p>These oxides of copper were used as external applications
-in cases of polypi of the nose, diseases of
-the anus, ear, mouth, &amp;c., seemingly as escharotics.</p>
-
-<p><i>&AElig;rugo</i>, verdigris, was a subacetate of copper,
-doubtless often mixed with subacetate of zinc, as not
-only copper but brass also was used for preparing it.
-The mode of preparing this substance was similar to
-the process still followed. Whether verdigris was
-employed as a paint by the ancients does not appear;
-for Pliny takes no notice of any such use of it.</p>
-
-<p><i>Chalcantum</i>, called also <i>atramentum sutorium</i>,
-was probably a mixture of sulphate of copper and
-sulphate of iron. Pliny’s account of the mode of procuring
-it is too imperfect to enable us to form precise
-ideas concerning it; but it was crystallized on strings,
-<span class="pagenum" id="Page_61">61</span>
-which were extended for the purpose in the solution:
-its colour was blue, and it was transparent like glass.
-This description might apply to sulphate of copper;
-but as the substance was used for blackening leather,
-and on that account was called <i>atramentum sutorium</i>,
-it is obvious that it must have contained also <i>sulphate
-of iron</i>.</p>
-
-<p><i>Chalcitis</i> was the name for an ore of copper. The
-account given of it by Pliny agrees best with copper
-pyrites, which is now known to be a <i>sulphur salt</i>,
-composed of one atom of sulphide of copper (the
-acid) united to one atom of sulphide of iron (the
-base). Pliny informs us, that it is a mixture of <i>copper</i>,
-<i>misy</i>, and <i>sory</i>: its colour is that of honey. By
-age, he says, it changes into sory. I think it most
-probable that native sory, of which Pliny speaks, was
-sulphuret of copper, and artificial sory sulphate of
-copper. The native sory is said to constitute black
-veins in chalcitis. Pliny’s description of misy (μισυ)
-best agrees with copper pyrites. Dioscorides describes
-it as hard, as having the colour of gold, and as shining
-like a star.<a id="FNanchor_44" href="#Footnote_44" class="fnanchor">44</a> All this agrees pretty well with copper
-pyrites.</p>
-
-<p><i>Scoleca</i> (so called because it assumed the shape of
-a worm) was formed by triturating alumen, carbonate of
-soda, and white vinegar, till the matter became green.
-It was probably a mixture of sulphate of soda, acetate
-of soda, acetate of alumina, and acetate of copper,
-probably with more or less oxide of copper, &amp;c., depending
-upon the proportions of the respective constituents
-employed.</p>
-
-<p>Such are the preparations of copper, employed by
-the ancients. They were only used as external applications,
-partly as escharotics, and partly to induce
-ulcers to put on a healthy appearance. It does not
-appear that copper was ever used by the ancients as
-an internal remedy.
-<span class="pagenum" id="Page_62">62</span></p>
-
-<p>4. Though <i>zinc</i> in the metallic state was unknown
-to the ancients, yet as they knew some of its ores,
-and employed preparations of it in medicine, and
-were in the habit of alloying copper with it, and converting
-it into brass, it will be proper to state here
-what was known to them concerning it.</p>
-
-<p>Pliny nowhere makes us acquainted with the process
-by which copper was converted into brass, nor
-does he seem to have been acquainted with it; but
-from several facts incidentally mentioned by him, it
-is obvious that their process was similar to that which
-is followed at present by modern brass-makers. The
-copper in grains is mixed with a certain quantity of
-calamine (cadmia) and charcoal, and exposed for some
-time to a moderate heat in a covered crucible. The
-calamine is reduced to the metallic state, and imbibed
-by the copper grains. When the copper is thus converted
-into brass, the temperature is raised sufficiently
-high to melt the whole: it is then poured out and cast
-into a slab or ingot.</p>
-
-<p>The cadmia employed by the ancients in medicine
-was not calamine, but oxide of zinc, which sublimed
-during the fusion of brass in an open vessel. It was
-distinguished by a variety of names, according to the
-state in which it was obtained: the lighter portion was
-called <i>capnitis</i>. <i>Botryitis</i> was the name of the portion
-in the interior of the chimney: the name was derived
-from some resemblance which it was supposed
-to have to a bunch of grapes. It had two colours,
-ash and red. The red variety was reckoned best. This
-red colour it might derive from some copper mixed
-with it, but more probably from iron; for a small
-quantity of oxide of iron is sufficient to give oxide of
-zinc a rather beautiful red colour. The portion collected
-on the sides of the furnace was called <i>placitis</i>:
-it constituted a crust, and was distinguished by different
-names, according to its colour; <i>onychitis</i> when
-it was blue externally, but spotted internally: <i>ostracitis</i>,
-<span class="pagenum" id="Page_63">63</span>
-when it was black and dirty-looking. This last
-variety was considered as an excellent application to
-wounds. The best cadmia in Pliny’s time was furnished
-by the furnaces of the Isle of Cyprus: it was
-used as an external application in ulcers, inflammations,
-eruptions, &amp;c., so that its use in medicine was
-pretty much the same as at present. Sulphate and
-acetate of zinc were unknown to the ancients. No attempt
-seems to have been made by them to introduce
-any preparations of zinc as internal medicines.</p>
-
-<p><i>Pompholyx</i> was the name given to oxide of zinc,
-sublimed by the combustion of the zinc which exists in
-brass. <i>Spodos</i> seems to have been a mixture of oxides
-of zinc and copper. There were different varieties of
-it distinguished by various names.<a id="FNanchor_45" href="#Footnote_45" class="fnanchor">45</a></p>
-
-<p>5. Iron exists very rarely in the earth in a metallic
-state, but most commonly in the state of an oxide;
-and the processes necessary to extract metallic iron
-from these ores are much more complicated, and require
-much greater skill, than the reduction of gold,
-silver, or copper from their respective ores. This
-would lead us to expect that iron would have been
-much longer in being discovered than the three metals
-whose names have been just given. But we learn from
-the Book of Genesis that iron, like copper and gold,
-was known before the flood, Tubal-cain being represented
-as an artificer in copper and iron.<a id="FNanchor_46" href="#Footnote_46" class="fnanchor">46</a> The Hebrew
-word for iron, לזרב (<i>barzel</i>), is said to be derived
-from רב (<i>bar</i>), bright, לזנ (<i>nazal</i>), to melt;
-and would lead one to the suspicion, that it referred
-to <i>cast</i> iron rather than <i>malleable</i> iron. It is possible
-that in these early times native iron may have existed
-as well as native gold, silver, and copper; and in this
-way Tubal-cain may have become acquainted with the
-existence and properties of this metal. In the time
-of Moses, who was learned in all the wisdom of the
-<span class="pagenum" id="Page_64">64</span>
-Egyptians, iron must have been in common use in
-Egypt: for he mentions furnaces for working iron;<a id="FNanchor_47" href="#Footnote_47" class="fnanchor">47</a>
-ores from which it was extracted;<a id="FNanchor_48" href="#Footnote_48" class="fnanchor">48</a> and tells us that
-swords,<a id="FNanchor_49" href="#Footnote_49" class="fnanchor">49</a> knives,<a id="FNanchor_50" href="#Footnote_50" class="fnanchor">50</a> axes,<a id="FNanchor_51" href="#Footnote_51" class="fnanchor">51</a> and tools for cutting stones,<a id="FNanchor_52" href="#Footnote_52" class="fnanchor">52</a>
-were then made of that metal. Now iron in its pure
-metallic state is too soft to be applied to these uses:
-it is obvious, therefore, that in Moses’s time, not
-only iron but steel also must have been in common
-use in Egypt. From this we see how much further
-advanced the Egyptians were than the Greeks in the
-knowledge of the manufacture of this most important
-metal: for during the Trojan war, which was several
-centuries after the time of Moses, Homer represents
-his heroes as armed with swords of copper, hardened
-by tin, and as never using any weapons of iron whatever.
-Nay, in such estimation was it held, that
-Achilles, when he celebrated games in honour of Patrocles,
-proposes a ball of iron as one of his most valuable
-prizes.<a id="FNanchor_53" href="#Footnote_53" class="fnanchor">53</a></p>
-
-<div class="poetry">
-<div class="poem"><div class="stanza">
-<span class="i0">“Then hurl’d the hero, thundering on the ground,<br /></span>
-<span class="i0">A mass of iron (an enormous round),<br /></span>
-<span class="i0">Whose weight and size the circling Greeks admire,<br /></span>
-<span class="i0">Rude from the furnace and but shaped by fire.<br /></span>
-<span class="i0">This mighty quoit &AElig;tion wont to rear,<br /></span>
-<span class="i0">And from his whirling arm dismiss’d in air;<br /></span>
-<span class="i0">The giant by Achilles slain, he stow’d<br /></span>
-<span class="i0">Among his spoils this memorable load.<br /></span>
-<span class="i0">For this he bids those nervous artists vie<br /></span>
-<span class="i0">That teach the disk to sound along the sky.<br /></span>
-<span class="i0">Let him whose might can hurl this bowl, arise;<br /></span>
-<span class="i0">Who farthest hurls it, takes it as his prize:<br /></span>
-<span class="i0">If he be one enrich’d with large domain<br /></span>
-<span class="i0">Of downs for flocks and arable for grain,<br /></span>
-<span class="i0">Small stock of iron needs that man provide,<br /></span>
-<span class="i0">His hinds and swains whole years shall be supplied<br /></span>
-<span class="i0">From hence: nor ask the neighbouring city’s aid<br /></span>
-<span class="i0">For ploughshares, wheels, and all the rural trade.”<br /></span>
-</div></div>
-</div>
-<p><span class="pagenum" id="Page_65">65</span></p>
-
-<p>The mass of iron was large enough to supply a
-shepherd or a ploughman with iron for five years.
-This circumstance is a sufficient proof of the high estimation
-in which iron was held during the time of
-Homer. Were a modern poet to represent his hero
-as holding out a large lump of iron as a prize, and
-were he to represent this prize as eagerly contended
-for by kings and princes, it would appear to us perfectly
-ridiculous.</p>
-
-<p>Hesiod informs us, that the knowledge of iron was
-brought over from Phrygia to Greece by the Dactyli,
-who settled in Crete during the reign of Minos I.,
-about 1431 years before the commencement of the
-Christian era, and consequently about sixty years
-before the departure of the children of Israel from
-Egypt: and it does not appear, that in Homer’s
-time, which was about five hundred years later, the art
-of smelting iron had been so much improved, as to
-enable men to apply it to the common purposes of
-life, as had long before been done by the Egyptians.
-The general opinion of the ancients was, that the method
-of smelting iron ore had been brought to perfection
-by the Chalybes, a small nation situated near the
-Black Sea,<a id="FNanchor_54" href="#Footnote_54" class="fnanchor">54</a> and that the name <i>chalybs</i>, occasionally
-used for steel, was derived from that people.</p>
-
-<p>Pliny informs us, that the ores of iron are scattered
-very profusely almost every where: that they exist in
-Elba; that there was a mountain in Cantabria composed
-entirely of iron ore; and that the earth in Cappadocia,
-when watered from a certain river, is converted
-into iron.<a id="FNanchor_55" href="#Footnote_55" class="fnanchor">55</a> He gives no account of the mode of
-smelting iron ores; nor does he appear to have been
-acquainted with the processes; for he says that iron
-is reduced from its ore precisely in the same way as
-copper is. Now we know, that the processes for
-smelting copper and iron are quite different, and
-<span class="pagenum" id="Page_66">66</span>
-founded upon different principles. He says, that in
-his time many different kinds of iron existed, and
-they were <i>strictur&aelig;</i>, in Latin <i>a stringenda acie</i>.</p>
-
-<p>That steel was well known and in common use when
-Pliny wrote is obvious from many considerations; but
-he seems to have had no notion of what constituted
-the difference between iron and steel, or of the method
-employed to convert iron into steel. In his opinion
-it depended upon the nature of the water, and
-consisted in heating iron red-hot, and plunging it,
-while in that state, into certain waters. The waters
-at Bilbilis and Turiasso, in Spain, and at Comum,
-in Italy, possessed this extraordinary virtue. The
-best steel in Pliny’s time came from China; the next
-best, in point of quality, was manufactured in
-Parthia.</p>
-
-<p>It would appear, that at Noricum steel was manufactured
-directly from the ore of iron. This process
-was perfectly practicable, and it is said still to be practised
-in certain cases.</p>
-
-<p>The ancients were acquainted with the method of
-rendering iron, or rather steel, magnetic; as appears
-from a passage in the fourteenth chapter of the thirty-fourth
-book of Pliny. Magnetic iron was distinguished
-by the name of <i>ferrum vivum</i>.</p>
-
-<p>When iron is dabbed over with alumen and vinegar
-it becomes like copper, according to Pliny. Cerussa,
-gypsum, and liquid pitch, keep it from rusting. Pliny
-was of opinion that a method of preventing iron from
-rusting had been once known, but had been lost before
-his time. The iron chains of an old bridge over
-the Euphrates had not rusted in Pliny’s time; but a
-few new links, which had been added to supply the
-place of some that had decayed, were become rusty.</p>
-
-<p>It would appear from Pliny, that the ancients made
-use of something very like <i>tractors</i>; for he says that
-pain in the side is relieved by holding near it the
-point of a dagger that has wounded a man. Water
-<span class="pagenum" id="Page_67">67</span>
-in which red-hot iron had been plunged was recommended
-as a cure for the dysentery; and the actual
-cautery with red-hot iron, Pliny informs us, prevents
-hydrophobia, when a person has been bitten by a mad
-dog.</p>
-
-<p>Rust of iron and scales of iron were used by the
-ancients as astringent medicines.</p>
-
-<p>6. Tin, also, must have been in common use in the
-time of Moses; for it is mentioned without any observation
-as one of the common metals.<a id="FNanchor_56" href="#Footnote_56" class="fnanchor">56</a> And from
-the way in which it is spoken of by Isaiah and Ezekiel,
-it is obvious that it was considered as of far inferior
-value to silver and gold. Now tin, though the
-ores of it where it does occur are usually abundant,
-is rather a scarce metal: that is to say, there are but
-few spots on the face of the earth where it is known
-to exist. Cornwall, Spain, in the mountains of Gallicia,
-and the mountains which separate Saxony and
-Bohemia, are the only countries in Europe where tin
-occurs abundantly. The last of these localities has
-not been known for five centuries. It was from Spain
-and from Britain that the ancients were supplied with
-tin; for no mines of tin exist, or have ever been
-known to exist, in Africa or Asia, except in the East
-Indies. The Phœnicians were the first nation which
-carried on a great trade by sea. There is evidence
-that at a very early period they traded with Spain
-and with Britain, and that from these countries they
-drew their supplies of tin. It was doubtless the Phœnicians
-that supplied the Egyptians with this metal.
-They had imbibed strongly a spirit of monopoly; and
-to secure the whole trade of tin they carefully concealed
-the source from which they drew that metal.
-Hence, doubtless, the reason why the Grecian geographers,
-who derived their information from the Phœnicians,
-represented the Insul&aelig; Cassiterides, or tin
-<span class="pagenum" id="Page_68">68</span>
-islands, as a set of islands lying off the north coast
-of Spain. We know that in fact the Scilly islands,
-in these early ages, yielded tin, though doubtless the
-great supply was drawn from the neighbouring province
-of Cornwall. It was probably from these islands
-that the Greek name for <i>tin</i> was derived (κασσιτερος).
-Even Pliny informs us, that in his time tin was obtained
-from the Cassiterides, and from Lusitania
-and Gallicia. It occurs, he says, in grains in alluvial
-soil, from which it is obtained by washing. It is in
-black grains, the metallic nature of which is only recognisable
-by the great weight. This is a pretty accurate
-description of <i>stream tin</i>, which we know formerly
-constituted the only ore of that metal wrought
-in Cornwall. He says that the ore occurs also along
-with grains of gold; that it is separated from the soil
-by washing along with the grains of gold, and afterwards
-smelted separately.</p>
-
-<p>Pliny gives no particulars about the mode of reducing
-the ore of tin to the metallic state; nor is it at
-all likely that he was acquainted with the process.</p>
-
-<p>The Latin term for tin was <i>plumbum album</i>. <i>Stannum</i>
-is also used by Pliny; but it is impossible to
-understand the account which he gives of it. There
-is, he says, an ore consisting of lead, united to silver.
-When this ore is smelted, the first metal that flows
-out is <i>stannum</i>. What flows next is <i>silver</i>. What
-remains in the furnace is <i>galena</i>. This being smelted,
-yields <i>lead</i>.</p>
-
-<p>Were we to admit the existence of an ore composed
-of lead and silver, it is obvious that no such products
-could be obtained by simply smelting it.</p>
-
-<p>Cassiteros, or tin, is mentioned by Homer; and,
-from the way in which the metal is said by him to
-have been used, it is obvious that in his time it bore a
-much higher price, and, consequently, was more valued
-than at present. In his description of the breastplate
-of Agamemnon, he says that it contained ten bands
-<span class="pagenum" id="Page_69">69</span>
-of steel, twelve of gold, and twenty of tin (κασσιτεροιο).<a id="FNanchor_57" href="#Footnote_57" class="fnanchor">57</a>
-And in the twenty-third book of the Iliad (line 561),
-Achilles describes a copper breastplate surrounded
-with shining tin (φαεινου κασσιτεροιο). Pliny informs
-us, that in his time tin was adulterated by adding to
-it about one-third of white copper. A pound of tin,
-when Pliny lived, cost ten denarii. Now, if we reckon
-a denarius at 7&frac34;<i>d.</i>, with Dr. Arbuthnot, this would make
-a Roman pound of tin to cost 6<i>s.</i> 5&frac12;<i>d.</i> But, as the
-Roman pound was only equal to three-fourths of our
-avoirdupois pound, it is plain that in the time of Pliny
-an avoirdupois pound of tin was worth 8<i>s.</i> 7&frac14;<i>d.</i>, which
-is almost seven times the price of tin in the present
-day.</p>
-
-<p>Tin, in the time of Pliny, was used for covering the
-inside of copper vessels, as it is at this day. And, no
-doubt, the process still followed is of the same nature
-as the process used by the ancients for tinning copper.
-Pliny remarks, with surprise, that copper thus tinned
-does not increase in weight. Now Bayen ascertained
-that a copper pan, nine inches in diameter, and three
-inches three lines in depth, when tinned, only acquired
-an additional weight of twenty-one grains.
-These measures and weights are French. When we
-convert them into English, we have a copper pan 9&middot;59
-inches in diameter, and 3&middot;46 inches deep, which, when
-tinned, increased in weight 17&middot;23 troy grains. Now
-the surface of the copper pan, thus tinned, was 176&middot;468
-square inches. Hence it follows, that a square inch
-of copper, when tinned, increases in weight only 0&middot;097
-grains. This increase is so small, that we may excuse
-Pliny, who probably had never seen the increase of
-weight determined, except by means of a rude Roman
-statera, for concluding that there was no increase of
-weight whatever.</p>
-
-<p>Tin was employed by the ancients for mirrors: but
-<span class="pagenum" id="Page_70">70</span>
-mirrors of silver were gradually substituted; and these
-in Pliny’s time had become so common, that they were
-even employed by female servants or slaves.</p>
-
-<p>That Pliny’s knowledge of the properties of tin
-was very limited, and far from accurate, is obvious
-from his assertion that <i>tin</i> is less fusible than
-silver.<a id="FNanchor_58" href="#Footnote_58" class="fnanchor">58</a> It is true that the ancients had no measure
-to determine the different degrees of heat; but as
-tin melts at a heat under redness, while silver requires
-a bright red heat to bring it into fusion, a single
-comparative trial would have shown him which was
-most fusible. This trial, it is obvious, had never been
-made by him.</p>
-
-<p>The ancients seem to have been ignorant of the
-method of tinning iron. At least, no reference to
-<i>tin plate</i> is made by Pliny, or by any other ancient
-author, that I have had an opportunity of consulting.</p>
-
-<p>It would appear from Pliny, that both copper and
-brass were tinned by the Gauls at an early period.
-Tinned brass was called <i>&aelig;ra coctilia</i>, and was so beautiful
-that it almost passed for silver. <i>Plating</i> (or
-covering the metal with plates of silver), was gradually
-substituted for tinning; and finally <i>gilding</i> took the
-place of plating. The trappings of horses, chariots,
-&amp;c., were thus ornamented. Pliny nowhere gives a
-description of the process of plating; but there can
-be little doubt that it was similar to that at present
-practised. Gilding was accomplished by laying an
-amalgam of gold on the copper or brass, as at present.</p>
-
-<p>7. Lead appears also to have been in common use
-among the Egyptians, at the time of Moses.<a id="FNanchor_59" href="#Footnote_59" class="fnanchor">59</a> It was
-distinguished among the Romans by the name of <i>plumbum
-nigrum</i>. In Pliny’s time the lead-mines existed
-chiefly in Spain and Britain. In Britain lead was so
-<span class="pagenum" id="Page_71">71</span>
-abundant, that it was prohibited to extract above a
-certain quantity in a year. The mines lay on the
-surface of the earth. Derbyshire was the county in
-which lead ores were chiefly wrought by the Romans.
-The rich mines in the north of England seem to have
-been unknown to them.</p>
-
-<p>Pliny was of opinion that if a lead-mine, after being
-exhausted, be shut up for some time, the ore will be
-again renewed.</p>
-
-<p>In the time of Pliny leaden pipes were commonly used
-for conveying water. The vulgar notion that the ancients
-did not know that water will always rise in pipes
-as high as the source from which it proceeds, and that
-it was this ignorance which led to the formation of
-aqueducts, is quite unfounded. Nobody can read
-Pliny without seeing that this important fact was well
-known in his time.</p>
-
-<p>Sheet lead was also used in the time of Pliny, and
-applied to the same purposes as at present. But lead
-was much higher priced among the ancients than it is
-at present. Pliny informs us that its price was to
-that of tin as 7 to 10. Hence it must have sold at
-the rate of 6<i>s.</i> 0&frac14;<i>d.</i> per pound. The present price of
-lead does not much exceed three halfpence the pound.
-It is therefore only 1-48th part of the price which it
-bore in the time of Pliny. This difference must be
-chiefly owing to the improvements made by the moderns
-in working the mines and smelting the ores of
-lead.</p>
-
-<p>Tin, in Pliny’s time, was used as a solder for lead.
-For this purpose it is well adapted, as it is so much
-easier smelted than lead. But when he says that lead
-is used also as a solder for tin, his meaning is not so
-clear. Probably he means an alloy of lead and tin,
-which, fusing at a lower point than tin, may be used
-to solder that metal. The addition of some bismuth
-reduces the fusing point materially; but that metal
-was unknown to the ancients.
-<span class="pagenum" id="Page_72">72</span></p>
-
-<p><i>Argentarium</i> is an alloy of equal parts of lead and
-tin. <i>Tertiarium</i>, of two parts lead and one part tin.
-It was used as a solder.</p>
-
-<p>Some preparations of lead were used by the ancients
-in medicine, as we know from the description of them
-given us by Dioscorides and Pliny. These preparations
-consisted chiefly of protoxide of lead and lead reduced
-to powder, and partially oxidized by triturating it
-with water in a mortar. They were applied to ulcers,
-and employed externally as astringents.</p>
-
-<p><i>Molybdena</i> was also employed in medicine. Pliny
-says it was the same as galena. From his description
-it is obvious that it was <i>litharge</i>; for it was in scales,
-and was more valued the nearer its colour approached
-to that of gold. It was employed, as it still is, for
-making plasters. Pliny gives us the process for
-making the plaster employed by the Roman surgeons.
-It was made by heating together
-
-<span class="table">
-<span class="trow">
-<span class="tcell tdr">3</span>
-<span class="tcell">lbs. molybdena or litharge,</span>
-</span>
-<span class="trow">
-<span class="tcell tdr">1</span>
-<span class="tcell">lb. wax,</span>
-</span>
-<span class="trow">
-<span class="tcell tdr">3</span>
-<span class="tcell">hemin&aelig;, or 1&frac12; pint, of olive oil.</span>
-</span>
-</span>
-
-This process is very nearly the same as the one at present
-followed by apothecaries for making adhesive
-plaster.</p>
-
-<p><i>Psimmythium</i>, or <i>cerussa</i>, was the same as our <i>white
-lead</i>. It was made by exposing lead in sheets to the
-fumes of vinegar. It would seem probable from Pliny’s
-account, though it is confused and inaccurate, that
-the ancients were in the habit of dissolving cerussa in
-vinegar, and thus making an impure acetate of lead.</p>
-
-<p>Cerussa was used in medicine. It constituted also
-a common white paint. At one time, Pliny says, it
-was found native; but in his time all that was used
-was prepared artificially.</p>
-
-<p><i>Cerussa usta</i> seems to have been nearly the same as
-our <i>red lead</i>. It was formed accidentally from cerussa
-during the burning of the Pyr&aelig;us. The colour was
-purple. It was imitated at Rome by burning <i>silis</i>
-<span class="pagenum" id="Page_73">73</span>
-<i>marmarosus</i>, which was probably a variety of some of
-our ochres.</p>
-
-<p>8. Besides the metals above enumerated, the ancients
-were also acquainted with quicksilver. Nothing
-is known about the first discovery of this metal; though
-it obviously precedes the commencement of history.
-I am not aware that the term occurs in the writings of
-Moses. We have therefore no evidence that it was
-known to the Egyptians at that early period; nor do
-I find any allusion to it in the works of Herodotus.
-But this is not surprising, as that author confines himself
-chiefly to subjects connected with history. Dioscorides
-and Pliny both mention it as common in their
-time. Dioscorides gives a method of obtaining it by
-sublimation from cinnabar. It is remarkable, because
-it constitutes the first example of a process which ultimately
-led to distillation.<a id="FNanchor_60" href="#Footnote_60" class="fnanchor">60</a></p>
-
-<p>Cinnabar is also described by Theophrastus. The
-term <i>minium</i> was applied to it also, till in consequence
-of the adulteration of cinnabar with <i>red lead</i>, the
-term minium came at last to be restricted to that preparation
-of lead. Theophrastus describes an artificial
-cinnabar, which came from the country above Ephesus.
-It was a shining red-coloured sand, which was collected
-and reduced to a fine powder by pounding it in
-vessels of stone. We do not know what it was. The
-native cinnabar was found in Spain, and was used
-chiefly as a paint. Dioscorides employs <i>minium</i> as
-the name for what we at present call cinnabar, or bisulphuret
-of mercury. His cinnabar was a red paint
-from Africa, produced in such small quantity that
-painters could scarcely procure enough of it to answer
-their purposes.</p>
-
-<p>Mercury is described by Pliny as existing native in
-the mines of Spain, and Dioscorides gives the process
-for extracting it from cinnabar. It was employed in
-<span class="pagenum" id="Page_74">74</span>
-gilding precisely as it is by the moderns. Pliny was
-aware of its great specific gravity, and of the readiness
-with which it dissolves gold. The amalgam was squeezed
-through leather, which separated most of the quicksilver.
-When the solid amalgam remaining was heated, the
-mercury was driven off and pure gold remained.</p>
-
-<p>It is obvious from what Dioscorides says, that the
-properties of mercury were very imperfectly known to
-him. He says that it may be kept in vessels of glass,
-or of lead, or of tin, or of silver.<a id="FNanchor_61" href="#Footnote_61" class="fnanchor">61</a> Now it is well
-known that it dissolves lead, tin, and silver with so
-much rapidity, that vessels of these metals, were mercury
-put into them, would be speedily destroyed.
-Pliny’s account of quicksilver is rather obscure. It
-seems doubtful whether he was aware that native <i>argentum
-vivum</i> and the <i>hydrargyrum</i> extracted from
-cinnabar were the same.</p>
-
-<p>Cinnabar was occasionally used as an external
-medicine; but Pliny disapproves of it, assuring his
-readers that quicksilver and all its preparations are
-virulent poisons. No other mercurial preparations
-except cinnabar and the amalgam of mercury seem
-to have been known to the ancients.<a id="FNanchor_62" href="#Footnote_62" class="fnanchor">62</a></p>
-
-<p>9. The ancients were unacquainted with the metal
-to which we at present give the name of <i>antimony</i>;
-but several of the ores of that metal, and of the products
-of these ores were not altogether unknown to
-them. From the account of stimmi and stibium, by
-Dioscorides<a id="FNanchor_63" href="#Footnote_63" class="fnanchor">63</a> and Pliny,<a id="FNanchor_64" href="#Footnote_64" class="fnanchor">64</a> there can be little doubt that
-these names were applied to the mineral now called
-<i>sulphuret of antimony</i> or crude antimony. It is found
-most commonly, Pliny says, among the ores of silver,
-<span class="pagenum" id="Page_75">75</span>
-and consists of two kinds, the male and the female;
-the latter of which is most valued.</p>
-
-<p>This pigment was known at a very early period,
-and employed by the Asiatic ladies in painting their
-eyelashes, or rather the insides of their eyelashes,
-black. Thus it is said of Jezebel, that when Jehu
-came to Jezreel she painted her face. The original
-is, <i>she put her eyes in sulphuret of antimony</i>.<a id="FNanchor_65" href="#Footnote_65" class="fnanchor">65</a> A
-similar expression occurs in Ezekiel, “For whom
-thou didst wash thyself, paintedst thy eyes”&mdash;literally,
-put thy eyes in sulphuret of antimony.<a id="FNanchor_66" href="#Footnote_66" class="fnanchor">66</a> This custom
-of painting the eyes black with antimony was transferred
-from Asia to Greece, and while the Moors occupied
-Spain it was employed by the Spanish ladies
-also. It is curious that the term <i>alcohol</i>, at present
-confined to <i>spirit of wine</i>, was originally applied to
-the powder of sulphuret of antimony.<a id="FNanchor_67" href="#Footnote_67" class="fnanchor">67</a> The ancients
-were in the habit of roasting sulphuret of antimony,
-and thus converting it into an impure oxide. This
-preparation was also called stimmi and stibium. It was
-employed in medicine as an external application, and
-was conceived to act chiefly as an astringent; Dioscorides
-describes the method of preparing it. We
-see, from Pliny’s account of stibium, that he did not
-distinguish between sulphuret of antimony and oxide
-of antimony.<a id="FNanchor_68" href="#Footnote_68" class="fnanchor">68</a></p>
-
-<p>9. Some of the compounds of arsenic were also
-known to the ancients; though they were neither acquainted
-with this substance in the metallic state, nor
-with its oxide; the nature of which is so
-violent that had it been known to them it could not
-have been omitted by Dioscorides and Pliny.
-<span class="pagenum" id="Page_76">76</span></p>
-
-<p>The word σανδαραχη (<i>sandarache</i>) occurs in Aristotle,
-and the term αρῥενιχον (<i>arrhenichon</i>) in Theophrastus.<a id="FNanchor_69" href="#Footnote_69" class="fnanchor">69</a>
-Dioscorides uses likewise the same name with Aristotle.
-It was applied to a scarlet-coloured mineral, which occurs
-native, and is now known by the name of <i>realgar</i>.
-It is a compound of arsenic and sulphur. It was employed
-in medicine both externally and internally, and
-is recommended by Dioscorides, as an excellent remedy
-for an inveterate cough.</p>
-
-<p><i>Auripigmentum</i> and <i>arsenicum</i> were names given to
-the native yellow sulphuret of arsenic. It was used
-in the same way, and considered by Dioscorides and
-Pliny as of the same nature with realgar. But there
-is no reason for supposing that the ancients were acquainted
-with the compositions of either of these
-bodies; far less that they had any suspicion of the
-existence of the metal to which we at present give the
-name of arsenic.</p>
-
-<p>Such is a sketch of the facts known to the ancients
-respecting metals. They knew the six malleable
-metals which are still in common use, and applied
-them to most of the purposes to which the moderns
-apply them. Scarcely any information has been left us
-of the methods employed by them to reduce these
-metals from their ores. But unless the ores were
-of a much simpler nature than the modern ores of
-these metals, of which we have no evidence, the
-smelting processes with which the ancients were familiar,
-could scarcely have been contrived without a
-knowledge of the substances united with the different
-metals in their ores, and of the means by which these
-foreign bodies could be separated, and the metals isolated
-from all impurities. This doubtless implied a
-certain quantity of chemical knowledge, which having
-been handed down to the moderns, served as a foundation
-upon which the modern science of chemistry was
-<span class="pagenum" id="Page_77">77</span>
-gradually reared: at the same time it will be admitted
-that this foundation was very slender, and would of
-itself have led to little. Most of the oxides, sulphurets,
-&amp;c., and almost all the salts into which these
-metallic bodies enter, were unknown to the ancients.</p>
-
-<p>Besides the working in metals there were some other
-branches of industry practised by the ancients, so intimately
-connected with chemical science, that it
-would be improper to pass them over in silence. The
-most important of these are the following:</p>
-
-<h3>II.&mdash;COLOURS USED BY PAINTERS.</h3>
-
-<p>It is well known that the ancient Grecian artists
-carried the art of painting to the highest degree of
-perfection, and that their paintings were admired and
-sought after by the most eminent and accomplished
-men of antiquity; and Pliny gives us a catalogue of
-a great number of first-rate pictures, and a historical
-account of a vast many celebrated painters of antiquity.
-In his own time, he says, the art of painting had
-lost its importance, statues and tablets having
-came in place of pictures.</p>
-
-<p>Two kinds of colours were employed by the ancients;
-namely, the florid and the austere. The florid
-colours, as enumerated by Pliny, were <i>minium</i>, <i>armenium</i>,
-<i>cinnaberis</i>, <i>chrysocolla</i>, <i>purpurissum</i>, and <i>indicum
-purpurissum</i>.</p>
-
-<p>The word <i>minium</i> as used by Pliny means <i>red
-lead</i>; though Dioscorides employs it for bisulphuret
-of mercury or cinnabar.</p>
-
-<p><i>Armenium</i> was obviously an ochre, probably of a
-yellow or orange colour.</p>
-
-<p><i>Cinnaberis</i> was bisulphuret of mercury, which is
-known to have a scarlet colour. Dioscorides employs
-it to denote a vegetable red colour, probably similar to
-the resin at present called <i>dragon’s blood</i>.</p>
-
-<p><i>Chrysocolla</i> was a green-coloured paint, and from
-<span class="pagenum" id="Page_78">78</span>
-Pliny’s description of it, could have been nothing else
-than carbonate of copper or malachite.</p>
-
-<p><i>Purpurissum</i> was a <i>lake</i>, as is obvious from the
-account of its formation given by Pliny. The colouring
-matter is not specified, but from the term used
-there can be little doubt that it was the liquor from the
-shellfish that yielded the celebrated purple dye of
-the Tyrians.</p>
-
-<p><i>Indicum purpurissum</i> was probably <i>indigo</i>. This
-might be implied from the account of it given by
-Pliny.</p>
-
-<p>The austere colours used by the ancient painters
-were of two kinds, native and artificial. The native
-were <i>sinopis</i>, <i>rubrica</i>, <i>par&aelig;tonium</i>, <i>melinum</i>, <i>eretria</i>,
-<i>auripigmentum</i>. The artificial were, <i>ochra</i>, <i>cerussa
-usta</i>, <i>sandaracha</i>, <i>sandyx</i>, <i>syricum</i>, <i>atramentum</i>.</p>
-
-<p><i>Sinopis</i> is the red substance now known by the
-name of reddle, and used for marking. On that account
-it is sometimes called <i>red chalk</i>. It was found
-in Pontus, in the Balearian islands, and in Egypt.
-The price was three denarii, or 1<i>s.</i> 11&frac14;<i>d.</i> the pound
-weight. The most famous variety of <i>sinopis</i> was
-from the isle of Lemnos; it was sold sealed and
-stamped: hence it was called <i>sphragis</i>. It was employed
-to adulterate minium. In medicine it was
-used to appease inflammation, and as an antidote to
-poison.</p>
-
-<p><i>Ochre</i> is merely sinopis heated in a covered vessel.
-The higher the temperature to which it has been exposed
-the better it is.</p>
-
-<p><i>Leucophorum</i> is a compound of
-
-<span class="table">
-<span class="trow">6 lbs. sinopis of Pontus,</span>
-<span class="trow">10 lbs. siris,</span>
-<span class="trow">2 lbs. melinum,</span>
-</span>
-triturated together for thirty days. It was used to
-make gold adhere to wood.</p>
-
-<p><i>Rubrica</i> from the name, was probably a red ochre.</p>
-
-<p><i>Par&aelig;tonium</i> was a white colour, so called from a
-<span class="pagenum" id="Page_79">79</span>
-place in Egypt, where it was found. It was obtained
-also in the island of Crete, and in Cyrene. It was
-said to be a combination of the froth of the sea consolidated
-with mud. It consisted probably of carbonate
-of lime. Six pounds of it cost only one
-denarius.</p>
-
-<p><i>Melinum</i> was also a white-coloured powder found
-in Melos and Samos in veins. It was most probably
-a carbonate of lime.</p>
-
-<p><i>Eretria</i> was named from the place where it was
-found. Pliny gives its medical properties, but does
-not inform us of its colour. It is impossible to say
-what it was.</p>
-
-<p><i>Auripigmentum</i> was yellow sulphuret of arsenic.
-It was probably but little used as a pigment by the
-ancient painters.</p>
-
-<p><i>Cerussa usta</i> was red lead.</p>
-
-<p><i>Sandaracha</i> was red sulphuret of arsenic. The
-pound of sandaracha cost 5 as.: it was imitated by
-red lead. Both it and <i>ochra</i> were found in the island
-Topazos in the Red Sea.</p>
-
-<p><i>Sandyx</i> was made by torrefying equal parts of true
-sandaracha and sinopis. It cost half the price of sandaracha.
-Virgil mistook this pigment for a plant, as is
-obvious from the following line:</p>
-
-<div class="poetry">
-<div class="poem"><div class="stanza">
-<span class="i0">Sponte sua sandix, pascentes vestiet agnos.<a id="FNanchor_70" href="#Footnote_70" class="fnanchor">70</a><br /></span>
-</div></div>
-</div>
-
-<p><i>Siricum</i> is made by mixing sinopis and sandyx.</p>
-
-<p><i>Atramentum</i> was obviously from Pliny’s account of
-it <i>lamp-black</i>. He mentions ivory-black as an invention
-of Apelles: it was called <i>elephantinum</i>.
-There was a native atramentum, which had the colour
-of sulphur, and got a black colour artificially. It is
-not unlikely that it contained sulphate of iron, and
-that it got its black colour from the admixture of some
-astringent substance.
-<span class="pagenum" id="Page_80">80</span></p>
-
-<p>The ink of the ancients was lamp-black mixed with
-water, containing gum or glue dissolved in it. <i>Atramentum
-indicum</i> was the same as our <i>China ink</i>.</p>
-
-<p>The <i>purpurissum</i> was a high-priced pigment. It
-was made by putting <i>creta argentaria</i> (a species of
-white clay) into the caldrons containing the ingredients
-for dying purple. The creta imbibed the purple
-colour and became <i>purpurissum</i>. The first portion of
-<i>creta</i> put in constituted the finest and highest-priced
-pigment. The portions put in afterwards became
-successively worse, and were, of consequence lower
-priced. We see, from this description, that it was a
-lake similar to our modern cochineal lakes.<a id="FNanchor_71" href="#Footnote_71" class="fnanchor">71</a></p>
-
-<p>That the purpurissum indicum was indigo is obvious
-from the statement of Pliny, that when thrown
-upon hot coals it gives out a beautiful purple flame.
-This constitutes the character of indigo. Its price in
-Pliny’s time was ten denarii, or six shillings and five-pence
-halfpenny the Roman pound; which is equivalent
-to 8<i>s.</i> 7⅓<i>d.</i> the avoirdupois.</p>
-
-<p>Though few or none of the ancient pictures have
-been preserved, yet several specimens of the colours
-used by them still remain in Rome and in the ruins of
-Herculaneum. Among others the fresco paintings,
-in the baths of Titus, still remain; and as these were
-made for a Roman emperor, we might expect to find
-the most beautiful and costly colours employed in
-them. These paints, and some others, were examined
-by Sir Humphrey Davy, in 1813, while he was in
-Rome. From his researches we derive some pretty
-accurate information respecting the colours employed
-by the painters of Greece and Rome.</p>
-
-<p>1. <i>Red paints.</i> Three different kinds of red were
-found in a chamber opened in 1811, in the baths of
-Titus, namely, a bright orange red, a dull red, and a
-brown red. The bright orange red was <i>minium</i>, or
-<span class="pagenum" id="Page_81">81</span>
-<i>red lead</i>; the other two were merely two varieties of
-iron ochres. Another still brighter red was observed
-on the walls; it proved, on examination, to be <i>vermilion</i>
-or <i>cinnabar</i>.</p>
-
-<p>2. <i>Yellow paints.</i> All the <i>yellows</i> examined by
-Davy proved to be <i>iron ochres</i>, sometimes mixed with
-a little <i>red lead</i>. Orpiment was undoubtedly employed,
-as is obvious from what Pliny says on the
-subject: but Davy found no traces of it among the
-yellow colours which he examined. A very deep
-yellow, approaching orange, which covered a piece of
-stucco in the ruins near the monument of Caius Cestius,
-proved to be protoxide of lead, or massicot,
-mixed with some red lead. The yellows in the Aldobrandini
-pictures were all ochres, and so were those
-in the pictures on the walls of the houses at Pompeii.</p>
-
-<p>3. <i>Blue paints.</i> Different shades of blues are used
-in the different apartments of the baths of Titus, which
-are darker or lighter, as they contain more or less
-carbonate of lime with which the blue pigment had been
-mixed by the painter. This blue pigment turned out,
-on examination, to be a frit composed of alkali and
-silica, fused together with a certain quantity of oxide of
-copper. This was the colour called χυανος (<i>kyanos</i>)
-by the Greeks, and <i>c&aelig;ruleum</i> by the Romans. Vitruvius
-gives the method of preparing it by heating
-strongly together sand, carbonate of soda, and filings
-of copper. Davy found that fifteen parts by weight
-of anhydrous carbonate of soda, twenty parts of powdered
-opaque flints, and three parts of copper filings,
-strongly heated together for two hours, gave a substance
-exactly similar to the blue pigment of the
-ancients, and which, when powdered, produced a fine
-deep blue colour. This c&aelig;ruleum has the advantage
-of remaining unaltered even when the painting is
-exposed to the actions of the air and sun.</p>
-
-<p>There is reason to suspect, from what Vitruvius and
-Pliny say, that glass rendered blue by means of cobalt
-<span class="pagenum" id="Page_82">82</span>
-constituted the basis of some of the blue pigments
-of the ancients; but all those examined by Davy consisted
-of glass tinged blue by copper, without any
-trace of cobalt whatever.</p>
-
-<p>4. <i>Green paints.</i> All the green paints examined by
-Davy proved to be carbonates of copper, more or less
-mixed with carbonate of lime. I have already mentioned
-that verdigris was known to the ancients. It
-was no doubt employed by them as a pigment, though
-it is not probable that the acetic acid would be able
-to withstand the action of the atmosphere for a couple
-of thousand years.</p>
-
-<p>5. <i>Purple paints.</i> Davy ascertained that the colouring
-matter of the ancient purple was combustible. It
-did not give out the smell of ammonia, at least perceptibly.
-There is little doubt that it was the <i>purpurissum</i>
-of the ancients, or a clay coloured by means
-of the purple of the buccinum employed by the Syrians
-in the celebrated purple dye.</p>
-
-<p>6. <i>Black and brown paints.</i> The black paints were
-lamp-black: the browns were some of them ochres and
-some of them oxides of manganese.</p>
-
-<p>7. <i>White paints.</i> All the ancient white paints examined
-by Davy were carbonates of lime.<a id="FNanchor_72" href="#Footnote_72" class="fnanchor">72</a> We know
-from Pliny that white lead was employed by the
-ancients as a pigment; but it might probably become
-altered in its nature by long-continued exposure to
-the weather.</p>
-
-<h3>III.&mdash;GLASS.</h3>
-
-<p>It is admitted by some that the word which in our
-English Bible is translated crystal, means glass, in
-the following passage of Job: “The gold and the
-crystal cannot equal it.”<a id="FNanchor_73" href="#Footnote_73" class="fnanchor">73</a> Now although the exact
-time when Job was written is not known, it is admitted
-on all hands to be one of the oldest of the books contained
-<span class="pagenum" id="Page_83">83</span>
-in the Old Testament. There are strong reasons
-for believing that it existed before the time of
-Moses; and some go so far as to affirm that there are
-several allusions to it in the writings of Moses. If
-therefore glass were known when the Book of Job was
-written, it is obvious that the discovery of it preceded
-the commencement of history. But even though the
-word used in Job should not refer to glass, there can
-be no doubt that it was known at a very early period;
-for glass beads are frequently found on the Egyptian
-mummies, and they are known to have been embalmed
-at a very remote period. The first Greek author who uses
-the word glass (ὑαλος, <i>hyalos</i>) is Aristophanes. In his
-comedy of The Clouds, act ii. scene 1, in the ridiculous
-dialogue between Socrates and Strepsiades, the
-latter announces a method which had occurred to him
-to pay his debts. “You know,” says he, “the beautiful
-transparent stone used for kindling fire.” “Do you
-mean glass (τον ὕαλον, <i>ton hyalon</i>)?” replied Socrates. “I
-do,” was the answer. He then describes how he would
-destroy the writings by means of it, and thus defraud
-his creditors. Now this comedy was acted about four
-hundred and twenty-three years before the beginning
-of the Christian era. The story related by Pliny, respecting
-the discovery of this beautiful and important
-substance, is well known. Some Phœnician merchants,
-in a ship loaded with carbonate of soda from Egypt,
-stopped, and went ashore on the banks of the river
-Belus: having nothing to support their kettles while
-they were dressing their food, they employed lumps of
-carbonate of soda for that purpose. The fire was
-strong enough to fuse some of this soda, and to unite
-it with the fine sand of the river Belus: the consequence
-of this was the formation of glass.<a id="FNanchor_74" href="#Footnote_74" class="fnanchor">74</a> Whether
-this story be entitled to credit or not, it is clear that
-<span class="pagenum" id="Page_84">84</span>
-the discovery must have originated in some such accident.
-Pliny’s account of the manufacture of glass, like
-his account of every other manufacture, is very imperfect:
-but we see from it that in his time they were in
-the habit of making coloured glasses; that colourless
-glasses were most highly prized, and that glass was
-rendered colourless then as it is at present, by the
-addition of a certain quantity of oxide of manganese.
-Colourless glass was very high priced in Pliny’s time.
-He relates, that for two moderate-sized colourless
-drinking-glasses the Emperor Nero paid 6000 sistertii,
-which is equivalent to 25<i>l.</i> of our money.</p>
-
-<p>Pliny relates the story of the man who brought a
-vessel of malleable glass to the Emperor Tiberius, and
-who, after dimpling it by dashing it against the floor,
-restored it to its original shape and beauty by means
-of a hammer; Tiberius, as a reward for this important
-discovery, ordered the artist to be executed, in order,
-as he alleged, to prevent gold and silver from becoming
-useless. But though Pliny relates this story, it is
-evident that he does not give credit to it; nor does it
-deserve credit. We can assign no reason why malleable
-substances may not be transparent; but all of
-them hitherto known are opaque. Chloride of silver,
-chloride of lead and iron constitute no exception, for
-they are not malleable, though by peculiar contrivances
-they may be extended; and their transparency is very
-imperfect.</p>
-
-<p>Many specimens of the coloured glasses made by
-the ancients still remain, particularly the beads employed
-as ornaments to the Egyptian mummies. Of
-these ancient glasses several have been examined chemically
-by Klaproth, Hatchett, and some other individuals,
-in order to ascertain the substances employed
-to give colour to the glass. The following are the
-facts that have been ascertained:</p>
-
-<p>1. <i>Red glass.</i> This glass was opaque, and of a
-<span class="pagenum" id="Page_85">85</span>
-lively copper-red colour. It was probably the kind of
-red glass to which Pliny gave the name of h&aelig;matinon.
-Klaproth analyzed it, and obtained from 100 grains
-of it the following constituents:
-
-<span class="table">
-<span class="trow">
-<span class="tcell">Silica</span>
-<span class="tcell tdr">71&middot;0</span>
-<span class="tcell">&nbsp;</span>
-</span>
-<span class="trow">
-<span class="tcell">Oxide of lead</span>
-<span class="tcell tdr">10&middot;0</span>
-<span class="tcell">&nbsp;</span>
-</span>
-<span class="trow">
-<span class="tcell">Oxide of copper</span>
-<span class="tcell tdr">7&middot;5</span>
-<span class="tcell">&nbsp;</span>
-</span>
-<span class="trow">
-<span class="tcell">Oxide of iron</span>
-<span class="tcell tdr">1&middot;0</span>
-<span class="tcell">&nbsp;</span>
-</span>
-<span class="trow">
-<span class="tcell">Alumina</span>
-<span class="tcell tdr">2&middot;5</span>
-<span class="tcell">&nbsp;</span>
-</span>
-<span class="trow">
-<span class="tcell">Lime</span>
-<span class="tcell tdr">1&middot;5</span>
-<span class="tcell">&nbsp;</span>
-</span>
-<span class="trow">
-<span class="tcell">&nbsp;</span>
-<span class="tcell tdr bt">93&middot;5</span>
-<span class="tcell"><a id="FNanchor_75" href="#Footnote_75" class="fnanchor">75</a></span>
-</span>
-</span>
-
-No doubt the deficiency was owing to the presence of
-an alkali. From this analysis we see that the colouring
-matter of this glass was <i>red oxide of copper</i>.</p>
-
-<p>2. <i>Green glass.</i> The colour was light verdigris-green,
-and the glass, like the preceding, was opaque.
-The constituents from 100 grains were,
-
-<span class="table">
-<span class="trow">
-<span class="tcell">Silica</span>
-<span class="tcell tdr">65&middot;0</span>
-<span class="tcell">&nbsp;</span>
-</span>
-<span class="trow">
-<span class="tcell">Black oxide of copper</span>
-<span class="tcell tdr">10&middot;0</span>
-<span class="tcell">&nbsp;</span>
-</span>
-<span class="trow">
-<span class="tcell">Oxide of lead</span>
-<span class="tcell tdr">7&middot;5</span>
-<span class="tcell">&nbsp;</span>
-</span>
-<span class="trow">
-<span class="tcell">Oxide of iron</span>
-<span class="tcell tdr">3&middot;5</span>
-<span class="tcell">&nbsp;</span>
-</span>
-<span class="trow">
-<span class="tcell">Lime</span>
-<span class="tcell tdr">6&middot;5</span>
-<span class="tcell">&nbsp;</span>
-</span>
-<span class="trow">
-<span class="tcell">Alumina</span>
-<span class="tcell tdr">5&middot;5</span>
-<span class="tcell">&nbsp;</span>
-</span>
-<span class="trow">
-<span class="tcell">&nbsp;</span>
-<span class="tcell tdr bt">98&middot;0</span>
-<span class="tcell"><a id="FNanchor_76" href="#Footnote_76" class="fnanchor">76</a></span>
-</span>
-</span>
-
-Thus it appears that both the red and green glass are
-composed of the same ingredients, though in different
-proportions. Both owe their colour to copper. The
-red glass is coloured by the red oxide of that metal;
-the green by the black oxide, which forms green-coloured
-compounds, with various acids, particularly
-with carbonic acid and with silica.</p>
-
-<p>3. <i>Blue glass.</i> The variety analyzed by Klaproth
-had a sapphire-blue colour, and was only translucent
-<span class="pagenum" id="Page_86">86</span>
-on the edges. The constituents from 100 grains of it
-were,
-
-<span class="table">
-<span class="trow">
-<span class="tcell">Silica</span>
-<span class="tcell tdr">81&middot;50</span>
-<span class="tcell">&nbsp;</span>
-</span>
-<span class="trow">
-<span class="tcell">Oxide of iron</span>
-<span class="tcell tdr">9&middot;50</span>
-<span class="tcell">&nbsp;</span>
-</span>
-<span class="trow">
-<span class="tcell">Alumina</span>
-<span class="tcell tdr">1&middot;50</span>
-<span class="tcell">&nbsp;</span>
-</span>
-<span class="trow">
-<span class="tcell">Oxide of copper</span>
-<span class="tcell tdr">0&middot;50</span>
-<span class="tcell">&nbsp;</span>
-</span>
-<span class="trow">
-<span class="tcell">Lime</span>
-<span class="tcell tdr">0&middot;25</span>
-<span class="tcell">&nbsp;</span>
-</span>
-<span class="trow">
-<span class="tcell">&nbsp;</span>
-<span class="tcell tdr bt">93&middot;25</span>
-<span class="tcell"><a id="FNanchor_77" href="#Footnote_77" class="fnanchor">77</a></span>
-</span>
-</span>
-
-From this analysis it appears that the colouring matter
-of this glass was oxide of iron: it was therefore analogous
-to the lapis lazuli, or ultramarine, in its nature.</p>
-
-<p>Davy, as has been formerly noticed, found another
-blue glass, or frit, coloured by means of copper; and
-he showed that the blue paint of the ancients was
-often made from this glass, simply by grinding it to
-powder.</p>
-
-<p>Klaproth could find no cobalt in the blue glass
-which he examined; but Davy found the transparent
-blue glass vessels, which are along with the vases, in
-the tombs of Magna Gr&aelig;cia, tinged with cobalt; and
-he found cobalt in all the transparent ancient blue
-glasses with which Mr. Millingen supplied him. The
-mere fusion of these glasses with alkali, and subsequent
-digestion of the product with muriatic acid, was
-sufficient to produce a sympathetic ink from them.<a id="FNanchor_78" href="#Footnote_78" class="fnanchor">78</a>
-The transparent blue beads which occasionally adorn
-the Egyptian mummies have also been examined, and
-found coloured by cobalt. The opaque glass beads
-are all tinged by means of oxide of copper. It is
-probable from this that all the transparent blue glasses
-of the ancients were coloured by cobalt; yet we find
-no allusion to cobalt in any of the ancient authors.
-Theophrastus says that copper (χαλκος, <i>chalcos</i>) was used
-to give glass a fine colour. Is it not likely that the impure
-<span class="pagenum" id="Page_87">87</span>
-oxide of cobalt, in the state in which they used
-it, was confounded by them with χαλκος (<i>chalcos</i>)?</p>
-
-<h3>IV.&mdash;VASA MURRHINA.</h3>
-
-<p>The Romans obtained from the east, and particularly
-from Egypt, a set of vessels which they distinguished
-by the name of <i>vasa murrhina</i>, and which
-were held by them in very high estimation. They
-were never larger than to be capable of containing
-from about thirty-six to forty cubic inches. One of
-the largest size cost, in the time of Pliny, about 7000<i>l.</i>
-Nero actually gave for one 3000<i>l.</i> They began to be
-known in Rome about the latter days of the republic.
-The first six ever seen in Rome were sent by Pompey
-from the treasures of Mithridates. They were deposited
-in the temple of Jupiter in the capitol. Augustus,
-after the battle of Actium, brought one of these
-vessels from Egypt, and dedicated it also to the gods.
-In Nero’s time they began to be used by private persons;
-and were so much coveted that Petronius, the
-favourite of that tyrant, being ordered for execution,
-and conceiving that his death was owing to a wish of
-Nero to get possession of a vessel of this kind which
-he had, broke the vessel in pieces in order to prevent
-Nero from gaining his object.</p>
-
-<p>There appear to have been two kinds of these vasa
-murrhina; those that came from Asia, and those that
-were made in Egypt. The latter were much more
-common, and much lower priced than the former, as
-appears from various passages in Martial and Propertius.</p>
-
-<p>Many attempts have been made, and much learning
-displayed by the moderns to determine the nature of
-these celebrated vessels; but in general these attempts
-were made by individuals too little acquainted with
-chemistry and with natural history in general to qualify
-them for researches of so difficult a nature. Some
-will have it that they consisted of a kind of gum;
-<span class="pagenum" id="Page_88">88</span>
-others that they were made of glass; others, of a particular
-kind of shell. Cardan and Scaliger assure us
-that they were <i>porcelain</i> vessels; and this opinion was
-adopted likewise by Whitaker, who supported it with
-his usual violence and arrogance. Many conceive
-them to have been made of some precious stone, some
-that they were of <i>obsidian</i>; Count de Veltheim thinks
-that they were made of the Chinese <i>agalmatolite</i>, or
-<i>figure stone</i>; and Dr. Hager conceives that they were
-made from the Chinese stone <i>yu</i>. Bruckmann was of
-opinion that these vessels were made of sardonyx, and
-the Abb&eacute; Winckelmann joins him in the same conclusion.</p>
-
-<p>Pliny informs us that these vasa murrhina were
-formed from a species of stone dug out of the earth in
-Parthia, and especially in Carimania, and also in other
-places but little known.<a id="FNanchor_79" href="#Footnote_79" class="fnanchor">79</a> They must have been very
-abundant at Rome in the time of Nero; for Pliny
-informs us that a man of consular rank, famous for
-his collection of vasa murrhina, having died, Nero
-forcibly deprived his children of these vessels, and they
-were so numerous that they filled the whole inside of
-a theatre, which Nero hoped to have seen filled with
-Romans when he came to it to sing in public.</p>
-
-<p>It is clear that the value of these vessels depended
-on their size. Small vessels bore but a small price, while
-that of large vessels was very high; this shows us that
-it must have been difficult to procure a block of the
-stone out of which they were cut, of a size sufficiently
-great to make a large vessel.</p>
-
-<p>These vessels were so soft that an impression might
-be made upon them with the teeth; for Pliny relates
-the story of a man of consular rank, who drank out of
-one, and was so enamoured with it that he bit pieces
-out of the lip of the cup: “Potavit ex eo ante hos
-annos consularis, ob amorem abraso ejus margine.”
-<span class="pagenum" id="Page_89">89</span>
-And what is singular, the value of the cup, so far from
-being injured by this abrasure, was augmented: “ut
-tamen injuria ilia pretium augeret; neque est hodie
-murrhini alterius pr&aelig;stantior indicatura.”<a id="FNanchor_80" href="#Footnote_80" class="fnanchor">80</a> It is clear
-from this that the matter of these vessels was neither
-rock crystal, agate, nor any precious stone whatever, all
-of which are too hard to admit of an impression from
-the teeth of a man.</p>
-
-<p>The lustre was vitreous to such a degree that the
-name <i>vitrum murrhinum</i> was given to the artificial
-fabric, in Egypt.</p>
-
-<p>The splendour was not very great, for Pliny observes,
-“Splendor his sine viribus nitorque verius
-quam splendor.”</p>
-
-<p>The colours, from their depth and richness, were what
-gave these vessels their value and excited admiration.
-The principal colours were purple and white, disposed
-in undulating bands, and usually separated by a third
-band, in which the two colours being mixed, assumed
-the tint of flame: “Sed in pretio varietas colorum,
-subinde circumagentibus se maculis in purpuram candoremque,
-et tertium ex utroque ignescentem, velut
-per transitum coloris, purpura rubescente, aut lacte
-candescente.”</p>
-
-<p>Perfect transparency was considered as a defect,
-they were merely translucent; this we learn not merely
-from Pliny, but from the following epigram of Martial:
-
-<span class="table">
-<span class="trow i0">Nos bibimus vitro, tu murra, Pontice: quare?<br /></span>
-<span class="trow i0">Prodat perspicuus ne duo vina calix.<br /></span>
-</span>
-
-Some specimens, and they were the most valued, exhibited
-a play of colour like the rainbow: Pliny says
-they were very commonly spotted with “sales, verruc&aelig;que
-non eminentes, sed ut in corpore etiam plerumque
-sessiles.” This, no doubt, refers to foreign bodies,
-such as grains of pyrites, antimony, galena, &amp;c.,
-<span class="pagenum" id="Page_90">90</span>
-which were often scattered through the substances
-of which the vessels were made.</p>
-
-<p>Such are all the facts respecting the vasa murrhina
-to be found in the writings of the ancients; they all
-apply to fluor spar, and to nothing else; but to it
-they apply so accurately as to leave little doubt that
-they were in reality vessels of fluor spar, similar to
-those at present made in Derbyshire.<a id="FNanchor_81" href="#Footnote_81" class="fnanchor">81</a></p>
-
-<p>The artificial vasa murrhina made at Thebes, in
-Egypt, were doubtless of glass, coloured to imitate
-fluor spar as much as possible, and having the
-semi-transparency which distinguishes that mineral.
-The imitations being imperfect, these factitious vessels
-were not much prized nor sought after by the Romans,
-they were rather distributed among the Arabians and
-Ethiopians, who were supplied with glass from Egypt.</p>
-
-<p>Rock crystal is compared by Pliny with the stone
-from which the vasa murrhina were made; the former,
-in his opinion, had been coagulated by cold, the latter
-by heat. Though the ancients, as we have seen, were
-acquainted with the method of colouring glass, yet
-they prized colourless glass highest on account of its
-resemblance to rock crystal; cups of it, in Pliny’s
-time, had supplanted those of silver and gold; Nero
-gave for a crystal cup 150,000 sistertii, or 625<i>l.</i></p>
-
-<h3>V.&mdash;DYEING AND CALICO-PRINTING.</h3>
-
-<p>Very little has been handed down by the ancients
-respecting the processes of dyeing. It is evident, from
-Pliny, that they were acquainted with madder, and
-that preparations of iron were used in the black dyes.
-The most celebrated dye of all, the <i>purple</i>, was discovered
-<span class="pagenum" id="Page_91">91</span>
-by the Tyrians about fifteen centuries before
-the Christian era. This colour was given by various
-kinds of shellfish which inhabit the Mediterranean.
-Pliny divides them into two genera; the first, comprehending
-the smaller species, he called <i>buccinum</i>, from
-their resemblance to a hunting-horn; the second, included
-those called <i>purpura</i>: Fabius Columna thinks
-that these were distinguished also by the name of
-<i>murex</i>.</p>
-
-<p>These shellfish yielded liquor of different shades of
-colour; they were often mixed in various proportions
-to produce particular shades of colour. One, or at
-most two drops of this liquor were obtained from each
-fish, by extracting and opening a little reservoir placed
-in the throat. To avoid this trouble, the smaller species
-were generally bruised whole, in a mortar; this
-was also frequently done with the large, though the
-other liquids of the fish must have in some degree injured
-the colour. The liquor, when extracted, was
-mixed with a considerable quantity of salt to keep it
-from putrifying; it was then diluted with five or six
-times as much water, and kept moderately hot in
-leaden or tin vessels, for eight or ten days, during
-which the liquor was often skimmed to separate all
-the impurities. After this, the wool to be dyed,
-being first well washed, was immersed and kept therein
-for five hours; then taken out, cooled, and again immersed,
-and continued in the liquor till all the colour
-was exhausted.<a id="FNanchor_82" href="#Footnote_82" class="fnanchor">82</a></p>
-
-<p>To produce particular shades of colour, carbonate
-of soda, urine, and a marine plant called <i>fucus</i>, were
-occasionally added: one of these colours was a very
-dark reddish violet&mdash;“Nigrantis ros&aelig; colore sublucens.”<a id="FNanchor_83" href="#Footnote_83" class="fnanchor">83</a>
-But the most esteemed, and that in which
-the Tyrians particularly excelled, resembled coagulated
-<span class="pagenum" id="Page_92">92</span>
-blood&mdash;“laus ei summa in colore sanguinis concreti,
-nigricans aspectu, idemque suspectu refulgens.”<a id="FNanchor_84" href="#Footnote_84" class="fnanchor">84</a></p>
-
-<p>Pliny says that the Tyrians first dyed their wool in
-the liquor of the purpura, and afterwards in that of
-the buccinum; and it is obvious from Moses that this
-purple was known to the Egyptians in his time.<a id="FNanchor_85" href="#Footnote_85" class="fnanchor">85</a> Wool
-which had received this double Tyrian dye (<i>dia bapha</i>)
-was so very costly that, in the reign of Augustus, it
-sold for about 36<i>l.</i> the pound. But lest this should
-not be sufficient to exclude all from the use of it but
-those invested with the very highest dignities of the
-state, laws were made inflicting severe penalties, and
-even death, upon all who should presume to wear it
-under the dignity of an emperor. The art of dyeing
-this colour came at length to be practised by a few individuals
-only, appointed by the emperors, and having
-been interrupted about the beginning of the twelfth
-century all knowledge of it died away, and during several
-ages this celebrated dye was considered and lamented
-as an irrecoverable loss.<a id="FNanchor_86" href="#Footnote_86" class="fnanchor">86</a> How it was afterwards
-recovered and made known by Mr. Cole, of Bristol,
-M. Jussieu, M. Reaumur, and M. Duhamel, would
-lead us too far from our present object, were we to
-relate it: those who are interested in the subject will
-find an historical detail in Bancroft’s work on Permanent
-Colours, just referred to.</p>
-
-<p>There is reason to suspect that the Hebrew word translated
-<i>fine linen</i> in the Old Testament, and so celebrated
-as a production of Egypt, was in reality <i>cotton</i>, and not
-linen. From a curious passage in Pliny, there is
-reason to believe that the Egyptians in his time, and
-probably long before, were acquainted with the method
-of calico-printing, such as is still practised in India
-<span class="pagenum" id="Page_93">93</span>
-and the east. The following is a literal translation of
-the passage in question:</p>
-
-<p>“There exists in Egypt a wonderful method of dyeing.
-The white cloth is stained in various places, not with
-dye stuffs, but with substances which have the property
-of absorbing (<i>fixing</i>) colours, these applications
-are not visible upon the cloth; but when they are dipped
-into a hot caldron of the dye they are drawn out an
-instant after dyed. The remarkable circumstance is,
-that though there be only one dye in the vat, yet different
-colours appear upon the cloth; nor can the
-colour be afterwards removed.”<a id="FNanchor_87" href="#Footnote_87" class="fnanchor">87</a></p>
-
-<p>It is evident enough that these substances applied
-were different mordants which served to fix the dye
-upon the cloth; the nature of these mordants cannot
-be discovered, as nothing specific seems to have been
-known to Pliny. The modern mordants are solutions
-of alumina; of the oxide of tin, oxide of iron, oxide of
-lead, &amp;c.: and doubtless these, or something equivalent
-to these, were the substances employed by the
-ancients. The purple dye required no mordant, it fixed
-itself to the cloth in consequence of the chemical
-affinity which existed between them. Whether indigo
-was used by the ancients as a dye does not appear,
-but there can be no doubt, at least, that its use
-was known to the Indians at a very remote period.</p>
-
-<p>From these facts, few as they are, there can be little
-doubt that dyeing, and even calico-printing, had made
-considerable progress among the ancients; and this
-could not have taken place without a considerable
-knowledge of colouring matters, and of the mordants
-by which these colouring matters were fixed. These
-facts, however, were probably but imperfectly understood,
-and could not be the means of furnishing the
-ancients with any accurate chemical knowledge.
-<span class="pagenum" id="Page_94">94</span></p>
-
-<h3>VI.&mdash;SOAP.</h3>
-
-<p>Soap, which constitutes so important and indispensable
-an article in the domestic economy of the
-moderns, was quite unknown to the ancient inhabitants
-of Asia, and even of Greece. No allusion to it occurs
-in the Old Testament. In Homer, we find Nausicaa,
-the daughter of the King of the Ph&aelig;acians, using
-nothing but water to wash her nuptial garments:</p>
-
-<div class="poetry">
-<div class="poem"><div class="stanza">
-<span class="i0">They seek the cisterns where Ph&aelig;acian dames<br /></span>
-<span class="i0">Wash their fair garments in the limped streams;<br /></span>
-<span class="i0">Where gathering into depth from falling rills,<br /></span>
-<span class="i0">The lucid wave a spacious bason fills.<br /></span>
-<span class="i0">The mules unharness’d range beside the main,<br /></span>
-<span class="i0">Or crop the verdant herbage of the plain.<br /></span>
-<span class="i0">Then emulous the royal robes they lave,<br /></span>
-<span class="i0">And plunge the vestures in the cleansing wave.<br /></span>
-<span class="i20"><i>Odyssey</i>, vi. 1. 99.<br /></span>
-</div></div>
-</div>
-
-<p>We find, in some of the comic poets, that the Greeks
-were in the habit of adding wood-ashes to water to
-make it a better detergent. Wood-ashes contain a
-certain portion of carbonate of potash, which of course
-would answer as a detergent; though, from its caustic
-qualities, it would be injurious to the hands of the
-washerwomen. There is no evidence that carbonate
-of soda, the <i>nitrum</i> of the ancients, was ever used as
-a detergent; this is the more surprising, because we
-know from Pliny that it was employed in dyeing, and
-one cannot see how a solution of it could be employed
-by the dyers in their processes without discovering that
-it acted powerfully as a detergent.</p>
-
-<p>The word <i>soap</i> (<i>sapo</i>) occurs first in Pliny. He informs
-us that it was an invention of the Gauls, who
-employed it to render their hair shining; that it was
-a compound of wood-ashes and tallow, that there were
-two kinds of it, <i>hard</i> and <i>soft</i> (<i>spissus et liquidus</i>);
-and that the best kind was made of the ashes of the
-beech and the fat of goats. Among the Germans
-<span class="pagenum" id="Page_95">95</span>
-it was more employed by the men than the women.<a id="FNanchor_88" href="#Footnote_88" class="fnanchor">88</a>
-It is curious that no allusion whatever is made by
-Pliny to the use of soap as a detergent; shall we conclude
-from this that the most important of all the uses
-of soap was unknown to the ancients?</p>
-
-<p>It was employed by the ancients as a pomatum;
-and, during the early part of the government of the
-emperors, it was imported into Rome from Germany,
-as a pomatum for the young Roman beaus. Beckmann
-is of opinion that the Latin word <i>sapo</i> is derived
-from the old German word <i>sepe</i>, a word still
-employed by the common people of Scotland.<a id="FNanchor_89" href="#Footnote_89" class="fnanchor">89</a></p>
-
-<p>It is well known that the state of soap depends upon
-the alkali employed in making it. <i>Soda</i> constitutes a
-<i>hard</i> soap, and <i>potash</i> a <i>soft</i> soap. The ancients being
-ignorant of the difference between the two alkalies,
-and using wood-ashes in the preparation of it,
-doubtless formed soft soap. The addition of some
-common salt, during the boiling of the soap, would
-convert the soft into hard soap. As Pliny informs us
-that the ancients were acquainted both with hard and
-soft soap, it is clear that they must have followed some
-such process.</p>
-
-<h3>VII.&mdash;STARCH.</h3>
-
-<p>The manufacture of starch was known to the ancients.
-Pliny informs us that it was made from wheat
-and from <i>siligo</i>, which was probably a variety or sub-species
-of wheat. The invention of starch is ascribed
-by Pliny to the inhabitants of the island of Chio, where
-in his time the best starch was still made. Pliny’s description
-of the method employed by the ancients of
-<span class="pagenum" id="Page_96">96</span>
-making starch is tolerably exact. Next to the China
-starch that of Crete was most celebrated; and next
-to it was the Egyptian. The qualities of starch were
-judged of by the weight; the lightest being always
-reckoned the best.</p>
-
-<h3>VIII.&mdash;BEER.</h3>
-
-<p>That the ancients were acquainted with wine is
-universally known. This knowledge must have been
-nearly coeval with the origin of society; for we are
-informed in Genesis that Noah, after the flood,
-planted a vineyard, and made wine, and got intoxicated
-by drinking the liquid which he had manufactured.<a id="FNanchor_90" href="#Footnote_90" class="fnanchor">90</a>
-Beer also is a very old manufacture. It
-was in common use among the Egyptians in the time
-of Herodotus, who informs us that they made use of a
-kind of wine made from barley, because no vines
-grew in their country.<a id="FNanchor_91" href="#Footnote_91" class="fnanchor">91</a> Tacitus informs us, that in
-his time it was the drink of the Germans.<a id="FNanchor_92" href="#Footnote_92" class="fnanchor">92</a> Pliny informs
-us that it was made by the Gauls, and by other
-nations. He gives it the name of <i>cerevisia</i> or <i>cervisia</i>;
-the name obviously alluding to the grain from which
-it was made.</p>
-
-<p>But though the ancients seem acquainted with both
-wine and beer, there is no evidence of their having
-ever subjected these liquids to distillation, and of
-having collected the products. This would have furnished
-them with ardent spirits or alcohol, of which
-there is every reason to believe they were entirely ignorant.
-Indeed, the method employed by Dioscorides
-to obtain mercury from cinnabar, is a sufficient proof
-that the true process of distillation was unknown to
-them. He mixed cinnabar with iron filings, put the
-<span class="pagenum" id="Page_97">97</span>
-mixture into a pot, to the top of which a cover of stoneware
-was luted. Heat was applied to the pot, and
-when the process was at an end, the mercury was
-found adhering to the inside of the cover. Had they
-been aware of the method of distilling the quicksilver
-ore into a receiver, this imperfect mode of collecting
-only a small portion of the quicksilver, separated from
-the cinnabar, would never have been practised. Besides,
-there is not the smallest allusion to ardent spirits,
-either in the writings of the poets, historians, naturalists,
-or medical men of ancient Greece; a circumstance
-not to be accounted for had ardent spirits
-been known, and applied even to one-tenth of the
-uses to which they are put by the moderns.</p>
-
-<h3>IX.&mdash;STONEWARE.</h3>
-
-<p>The manufacture of stoneware vessels was known at
-a very early period of society. Frequent allusions to
-the potter’s wheel occur in the Old Testament, showing
-that the manufacture must have been familiar to the
-Jewish nation. The porcelain of the Chinese boasts
-of a very high antiquity indeed. We cannot doubt
-that the processes of the ancients were similar to those of
-the moderns, though I am not aware of any tolerably accurate
-account of them in any ancient author whatever.</p>
-
-<p>Moulds of plaster of Paris were used by the ancients
-to take casts precisely as at present.<a id="FNanchor_93" href="#Footnote_93" class="fnanchor">93</a></p>
-
-<p>The sand of Puzzoli was used by the Romans, as
-it is by the moderns, to form a mortar capable of
-hardening under water.</p>
-
-<p>Pliny gives us some idea of the Roman bricks, which
-are known to have been of an excellent quality. There
-were three sizes of bricks used by the Romans.</p>
-
-<p>1. Lydian, which were 1&frac12; foot long and 1 foot
-broad.
-<span class="pagenum" id="Page_98">98</span></p>
-
-<p>2. Tetradoron, which was a square of 16 inches
-each side.</p>
-
-<p>3. Pentadoron, which was a square, each side of
-which was 20 inches long.</p>
-
-<p>Doron signifies the palm of the hand: of course it
-was equivalent to 4 inches.</p>
-
-<h3>X.&mdash;PRECIOUS STONES AND MINERALS.</h3>
-
-<p>Pliny has given a pretty detailed description of the
-precious stones of the ancients; but it is not very easy
-to determine the specific minerals to which he alludes.</p>
-
-<p>1. The description of the diamond is tolerably precise.
-It was found in Ethiopia, India, Arabia, and
-Macedonia. But the Macedonian diamond, as well
-as the adamas cyprius and siderites, were obviously
-not diamonds, but soft stones.</p>
-
-<p>2. The <i>emerald</i> of the ancients (<i>smaragdus</i>) must
-have varied in its nature. It was a green, transparent,
-hard stone; and, as colour was the criterion by which
-the ancients distinguished minerals and divided them
-into species, it is obvious that very different minerals
-must have been confounded together, under the name
-of emerald. Sapphire, beryl, doubtless fluor spar when
-green, and probably even serpentine, nephrite, and
-some ores of copper, seem to have occasionally got the
-same name. There is no reason to believe that the
-<i>emerald</i> of the moderns was known before the discovery
-of America. At least it has been only found in
-modern times in America. Some of the emeralds described
-by Pliny as losing their colour by exposure to
-the sun, must have been fluor spars. There is a remarkably
-deep and beautiful green fluor spar, met
-with some years ago in the county of Durham, in one
-of the Weredale mines that possesses this property.
-The emeralds of the ancients were of such a size (13&frac12;
-feet, large enough to be cut into a pillar), that we can
-<span class="pagenum" id="Page_99">99</span>
-consider them in no other light than as a species of
-rock.</p>
-
-<p>3. Topaz of the ancients had a green colour, which is
-never the case with the modern topaz. It was found in
-the island Topazios, in the Red Sea.<a id="FNanchor_94" href="#Footnote_94" class="fnanchor">94</a> It is generally
-supposed to have been the <i>chrysolite</i> of the moderns.
-But Pliny mentions a statue of it six feet long. Now
-chrysolite never occurs in such large masses. Bruce
-mentions a green substance in an emerald island in the
-Red Sea, not harder than glass. Might not this be
-the emerald of the ancients?</p>
-
-<p>4. <i>Calais</i>, from the locality and colour was probably
-the Persian turquoise, as it is generally supposed
-to be.</p>
-
-<p>5. Whether the <i>prasius</i> and <i>chrysoprasius</i> of Pliny
-were the modern stones to which these names are given,
-we have no means of determining. It is generally
-supposed that they are, and we have no evidence to
-the contrary.</p>
-
-<p>6. The <i>chrysolite</i> of Pliny is supposed to be our
-<i>topaz</i>: but we have no other evidence of this than
-the opinion of M. Du Tems.</p>
-
-<p>7. <i>Asteria</i> of Pliny is supposed by Saussure to be
-our sapphire. The lustre described by Pliny agrees
-with this opinion. The stone is said to have been very
-hard and colourless.</p>
-
-<p>8. <i>Opalus</i> seems to have been our <i>opal</i>. It is called,
-Pliny says, <i>p&aelig;deros</i> by many, on account of its beauty.
-The Indians called it <i>sangenon</i>.</p>
-
-<p>9. <i>Obsidian</i> was the same as the mineral to which
-we give that name. It was so called because a Roman
-named Obsidianus first brought it from Egypt. I have
-a piece of obsidian, which the late Mr. Salt brought
-from the locality specified by Pliny, and which possesses
-all the characters of that mineral in its purest state.
-<span class="pagenum" id="Page_100">100</span></p>
-
-<p>10. <i>Sarda</i> was the name of <i>carnelian</i>, so called because
-it was first found near Sardis. The <i>sardonyx</i>
-was also another name for <i>carnelian</i>.</p>
-
-<p>11. Onyx was a name sometimes given to a rock,
-<i>gypsum</i>; sometimes it was a light-coloured <i>chalcedony</i>.
-The Latin name for chalcedony was <i>carchedonius</i>, so
-called because Carthage was the place where this
-mineral was exposed to sale. The Greek name for
-Carthage was Καρχηδων (<i>carchedon</i>).</p>
-
-<p>12. <i>Carbunculus</i> was the garnet; and <i>anthrax</i> was
-a name for another variety of the same mineral.</p>
-
-<p>13. The <i>oriental amethyst</i> of Pliny was probably a
-sapphire. The fourth species of amethyst described by
-Pliny, seems to have been our amethyst. Pliny derives
-the name from α (<i>a</i>) and μυθη (<i>mythe</i>), <i>wine</i>, because it
-has not quite the colour of wine. But the common
-derivation is from α and μυθυω, <i>to intoxicate</i>, because
-it was used as an amulet to prevent intoxication.</p>
-
-<p>14. The <i>sapphire</i> is described by Pliny as always
-opaque, and as unfit for engraving on. We do not
-know what it was.</p>
-
-<p>15. The <i>hyacinth</i> of Pliny is equally unknown.
-From its name it was obviously of a blue colour. Our
-hyacinth has a reddish-brown colour, and a great deal
-of hardness and lustre.</p>
-
-<p>16. The <i>cyanus</i> of Pliny may have been our <i>cyanite</i>.</p>
-
-<p>17. <i>Astrios</i> agrees very well, as far as the description
-of Pliny goes, with the variety of felspar called <i>adularia</i>.</p>
-
-<p>18. <i>Belioculus</i> seems to have been our <i>catseye</i>.</p>
-
-<p>19. <i>Lychnites</i> was a violet-coloured stone, which
-became electric by heat. Unless it was a <i>blue tourmalin</i>,
-I do not know what it could be.</p>
-
-<p>20. The <i>jasper</i> of the ancients was probably the
-same as ours.</p>
-
-<p>21. <i>Molochites</i> may have been our <i>malachite</i>. The
-name comes from the Greek word μολοχη, <i>mallow</i>, or
-<i>marshmallow</i>.
-<span class="pagenum" id="Page_101">101</span></p>
-
-<p>22. Pliny considers <i>amber</i> as the juice of a tree
-concreted into a solid form. The largest piece of it
-that he had ever seen weighed 13 lbs. Roman weight,
-which is nearly equivalent to 9&frac34; lbs. avoirdupois. <i>Indian
-amber</i>, of which he speaks, was probably <i>copal</i>,
-or some transparent resin. It may be dyed, he says,
-by means of <i>anchusa</i> and the <i>fat of kids</i>.</p>
-
-<p>23. <i>Lapis specularis</i> was foliated sulphate of lime,
-or selenite.</p>
-
-<p>24. <i>Pyrites</i> had the same meaning among the ancients
-that it has among the moderns; at least as far
-as iron pyrites or bisulphuret of iron is concerned.
-Pliny describes two kind of pyrites; namely, the
-<i>white</i> (<i>arsenical pyrites</i>), and the <i>yellow</i> (iron pyrites).
-It was used for striking fire with steel, in order
-to kindle tinder. Hence the name <i>pyrites</i> or <i>firestone</i>.</p>
-
-<p>25. <i>Gagates</i>, from the account given of it by
-Pliny, was obviously pit-coal or jet.</p>
-
-<p>26. <i>Marble</i> had the same meaning among the ancients
-that it has among the moderns. It was sawed
-by the ancients into slabs, and the action of the saw
-was facilitated by a sand brought for the purpose from
-Ethiopia and the isle of Naxos. It is obvious that
-this sand was powdered corundum, or emery.</p>
-
-<p>27. <i>Creta</i> was a name applied by the ancients not
-only to chalk, but to <i>white clay</i>.</p>
-
-<p>28. <i>Melinum</i> was an <i>oxide of iron</i>. Pliny gives a
-list of one hundred and fifty-one species of stones in
-the order of the alphabet. Very few of the minerals
-contained in this list can be made out. He gives
-also a list of fifty-two species of stones, whose names
-are derived from a fancied resemblance which the
-stones are supposed to bear to certain parts of animals.
-Of these, also, very few can be made out.</p>
-
-<h3>XI.&mdash;MISCELLANEOUS OBSERVATIONS.</h3>
-
-<p>The ancients seem to have been ignorant of the nature
-and properties of air, and of all gaseous bodies.
-<span class="pagenum" id="Page_102">102</span>
-Pliny’s account of air consists of a single sentence:
-“A&euml;r densatur nubibus; furit procellis.” “Air is
-condensed in clouds, it rages in storms.” Nor is his
-description of water much more complete, since it consists
-only of the following phrases: “Aqu&aelig; subeunt
-in imbres, rigescunt in grandines, tumescunt in fluctus,
-pr&aelig;cipitantur in torrentes.”<a id="FNanchor_95" href="#Footnote_95" class="fnanchor">95</a> “Water falls in
-showers, congeals in hail, swells in waves, and rushes
-down in torrents.” In the thirty-eighth chapter of the
-second book, indeed, he professes to treat of <i>air</i>; but
-the chapter contains merely an enumeration of meteorological
-phenomena, without once touching upon
-the nature and properties of air.</p>
-
-<p>Pliny, with all the philosophers of antiquity, admitted
-the existence of the four elements, fire, air, water,
-and earth; but though he enumerates these in the fifth
-chapter of his first book, he never attempts to explain
-their nature or properties. Earth, among the ancients,
-had two meanings, namely, the planet on which we
-live, and the soil upon which vegetables grow. These
-two meanings still exist in common language. The
-meaning afterwards given to the <i>term</i>, earth, by the
-chemists, did not exist in the days of Pliny, or, at
-least, was unknown to him; a sufficient proof that
-chemistry, in his time, had made no progress as a
-science; for some notions respecting the properties and
-constituents of those supposed four elements must have
-constituted the very foundation of scientific chemistry.</p>
-
-<p>The ancients were acquainted with none of the acids
-which at present constitute so numerous a tribe, except
-<i>vinegar</i>, or <i>acetic acid</i>; and even this acid was
-not known to them in a state of purity. They knew
-none of the saline bases, except lime, soda, and potash,
-and these very imperfectly. Of course the whole
-tribe of salts was unknown to them, except a very few,
-which they found ready formed in the earth, or which
-<span class="pagenum" id="Page_103">103</span>
-they succeeded in forming by the action of vinegar on
-lead and copper. Hence all that extensive and most
-important branch of chemistry, consisting of the combinations
-of the acids and bases, on which scientific
-chemistry mainly depends, must have been unknown
-to them.</p>
-
-<p>Sulphur occurring native in large quantities, and
-being remarkable for its easy combustibility, and its
-disagreeable smell when burning, was known in the
-very earliest ages. Pliny describes four kinds of sulphur,
-differing from each other, probably, merely in
-their purity. These were
-
-<span class="table">
-<span class="trow">1. Sulphur vivum, or apyron. It was dug out of the
-earth solid, and was doubtless pure, or nearly so.
-It alone was used in medicine.</span>
-
-<span class="trow">2. Gleba&mdash;used only by fullers.</span>
-
-<span class="trow">3. Egula&mdash;used also by fullers.</span>
-
-<span class="trow">Pliny says, it renders woollen stuffs white and soft.
-It is obvious from this, that the ancients knew the
-method of bleaching flannel by the fumes of sulphur,
-as practised by the moderns.</span>
-
-<span class="trow">4. The fourth kind was used only for sulphuring
-matches.</span>
-</span></p>
-
-<p>Sulphur, in Pliny’s time, was found native in the
-&AElig;olian islands, and in Campania. It is curious that
-he never mentions Sicily, whence the great supply is
-drawn for modern manufacture.</p>
-
-<p>In medicine, it seems to have been only used externally
-by the ancients. It was considered as excellent
-for removing eruptions. It was used also for fumigating.</p>
-
-<p>The word <i>alumen</i>, which we translate <i>alum</i>, occurs
-often in Pliny; and is the same substance which the
-Greeks distinguished by the name of στυπτηρια (<i>stypteria</i>).
-It is described pretty minutely by Dioscorides, and also
-by Pliny. It was obviously a natural production, dug
-out of the earth, and consequently quite different from
-our alum, with which the ancients were unacquainted.
-<span class="pagenum" id="Page_104">104</span>
-Dioscorides says that it was found abundantly in
-Egypt; that it was of various kinds, but that the slaty
-variety was the best. He mentions also many other
-localities. He says that, for medical purposes, the
-most valued of all the varieties of alumen were the
-<i>slaty</i>, the <i>round</i>, and the <i>liquid</i>. The slaty alumen
-is very white, has an exceedingly astringent taste, a
-strong smell, is free from stony concretions, and
-gradually cracks and emits long capillary crystals from
-these rifts; on which account it is sometimes called
-<i>trichites</i>. This description obviously applies to a kind
-of slate-clay, which probably contained pyrites mixed
-with it of the decomposing kind. The capillary crystals
-were probably similar to those crystals at present
-called <i>hair-salt</i> by mineralogists, which exude pretty
-abundantly from the shale of the coal-beds, when it
-has been long exposed to the air. <i>Hair-salt</i> differs
-very much in its nature. Klaproth ascertained by
-analysis, that the <i>hair-salt</i> from the quicksilver-mines
-in Idria is sulphate of magnesia, mixed with a small
-quantity of sulphate of iron.<a id="FNanchor_96" href="#Footnote_96" class="fnanchor">96</a> The <i>hair-salt</i> from the
-abandoned coal-pits in the neighbourhood of Glasgow
-is a double salt, composed of sulphate of alumina, and
-sulphate of iron, in definite proportions; the composition
-being
-
-<span class="table">
-  <span class="trow">
-    <span class="tcell tdc">1</span>
-    <span class="tcell">atom protosulphate of iron,</span>
-  </span>
-  <span class="trow">
-    <span class="tcell tdc">1&frac12;</span>
-    <span class="tcell">atom sulphate of alumina,</span>
-  </span>
-  <span class="trow">
-    <span class="tcell tdc">15</span>
-    <span class="tcell">atoms water.</span>
-  </span>
-</span></p>
-
-<p>I suspect strongly that the capillary crystals from
-the schistose alumen of Dioscorides were nearly of the
-same nature.</p>
-
-<p>From Pliny’s account of the uses to which alumen
-was applied, it is quite obvious that it must have
-varied very much in its nature. <i>Alumen nigrum</i> was
-used to strike a black colour, and must therefore have
-contained iron. It was doubtless an impure native
-<span class="pagenum" id="Page_105">105</span>
-sulphate of iron, similar to many native productions of
-the same nature still met with in various parts of the
-world, but not employed; their use having been superseded
-by various artificial salts, more definite in
-their nature, and consequently more certain in their
-application, and at the same time cheaper and more
-abundant than the native.</p>
-
-<p>The alumen employed as a mordant by the dyers,
-must have been a sulphate of alumina more or less
-pure; at least it must have been free from all sulphate
-of iron, which would have affected the colour of the
-cloth, and prevented the dyer from accomplishing his
-object.<a id="FNanchor_97" href="#Footnote_97" class="fnanchor">97</a></p>
-
-<p>What the <i>alumen rotundum</i> was, is not easily conjectured.
-Dioscorides says, that it was sometimes
-made artificially; but that the artificial alumen rotundum
-was not much valued. The best, he says, was
-full of air-bubbles, nearly white, and of a very astringent
-taste. It had a slaty appearance, and was found
-in Egypt or the Island of Melos.</p>
-
-<p>The <i>liquid alumen</i> was limpid, milky, of an equal
-colour, free from hard concretions, and having a fiery
-shade of colour.<a id="FNanchor_98" href="#Footnote_98" class="fnanchor">98</a> In its nature, it was similar to the
-alumen candidum; it must therefore have consisted
-chiefly, at least, of sulphate of alumina.</p>
-
-<p>Bitumen and naphtha were known to the ancients,
-and used by them to give light instead of oil; they
-were employed also as external applications in cases
-of disease, and were considered as having the same
-virtues as sulphur. It is said, that the word translated
-<i>salt</i> in the New Testament&mdash;“Ye are the salt of
-the earth: but if the salt have lost his savour, wherewith
-shall it be salted? It is henceforth good for nothing,
-but to be cast out, and to be trodden under foot
-<span class="pagenum" id="Page_106">106</span>
-of men”<a id="FNanchor_99" href="#Footnote_99" class="fnanchor">99</a>&mdash;it is said, that the word salt in this passage
-refers to asphalt, or bitumen, which was used by the
-Jews in their sacrifices, and called <i>salt</i> by them. But
-I have not been able to find satisfactory evidence of
-the truth of this opinion. It is obvious from the context,
-that the word translated <i>salt</i> could not have had
-that meaning among the Jews; because salt never can
-be supposed to lose its savour. Bitumen, while liquid,
-has a strong taste and smell, which it loses gradually
-by exposure to the air, as it approaches more and more
-to a solid form.</p>
-
-<p>Asphalt was one of the great constituents of the
-Greek fire. A great bed of it still existing in Albania,
-supplied the Greeks with this substance. Concerning
-the nature of the Greek fire, it is clear that many exaggerated
-and even fabulous statements have been
-published. The obvious intention of the Greeks being,
-probably, to make their invention as much dreaded
-as possible by their enemies. Nitre was undoubtedly
-one of the most important of its constituents;
-though no allusion whatever is ever made. We do
-not know when <i>nitrate of potash</i>, the nitre of the
-moderns, became known in Europe. It was discovered
-in the east; and was undoubtedly known in China and
-India before the commencement of the Christian era.
-The property of nitre, as a supporter of combustion,
-could not have remained long unknown after the discovery
-of the salt. The first person who threw a piece
-of it upon a red-hot coal would observe it. Accordingly
-we find that its use in fireworks was known very
-early in China and India; though its prodigious expansive
-power, by which it propels bullets with so
-great and destructive velocity, is a European invention,
-posterior to the time of Roger Bacon.
-<span class="pagenum" id="Page_107">107</span></p>
-
-<p>The word <i>nitre</i> (רתנ) had been applied by the ancients
-to <i>carbonate of soda</i>, a production of Egypt,
-where it is still formed from sea-water, by some unknown
-process of nature in the marshes near Alexandria.
-This is evident, not merely from the account
-given of it by Dioscorides and Pliny; for the following
-passage, from the Old Testament, shows that it had
-the same meaning among the Jews: “As he that
-taketh away a garment in cold weather, is as vinegar
-upon nitre: so is he that singeth songs to a heavy
-heart.”<a id="FNanchor_100" href="#Footnote_100" class="fnanchor">100</a> Vinegar poured upon saltpetre produces no
-sensible effect whatever, but when poured upon carbonate
-of soda, it occasions an <i>effervescence</i>. When
-saltpetre came to be imported to Europe, it was natural
-to give it the same name as that applied to carbonate
-of soda, to which both in taste and appearance
-it bore some faint resemblance. Saltpetre possessing
-much more striking properties than carbonate of soda
-much more attention was drawn to it, and it gradually
-fixed upon itself the term <i>nitre</i>, at first applied to a
-different salt. When this change of nomenclature
-took place does not appear; but it was completed
-before the time of Roger Bacon, who always applies
-the term <i>nitrum</i> to our nitrate of potash and never to
-carbonate of soda.</p>
-
-<p>In the preceding history of the chemical facts known
-to the ancients, I have taken no notice of a well-known
-story related of Cleopatra. This magnificent
-and profligate queen boasted to Antony that she
-would herself consume a million of sistertii at a supper.
-Antony smiled at the proposal, and doubted
-the possibility of her performing it. Next evening
-a magnificent entertainment was provided, at which
-Antony, as usual, was present, and expressed his opinion
-that the cost of the feast, magnificent as it was,
-fell far short of the sum specified by the queen. She
-<span class="pagenum" id="Page_108">108</span>
-requested him to defer computing till the dessert was
-finished. A vessel filled with vinegar was placed before
-her, in which she threw two pearls, the finest in
-the world, and which were valued at ten millions of
-sistertii; these pearls were dissolved by the vinegar,<a id="FNanchor_101" href="#Footnote_101" class="fnanchor">101</a>
-and the liquid was immediately drunk by the queen.
-Thus she made good her boast, and destroyed the two
-finest pearls in the world.<a id="FNanchor_102" href="#Footnote_102" class="fnanchor">102</a> This story, supposing it
-true, shows that Cleopatra was aware that vinegar has
-the property of dissolving pearls. But not that she
-knew the nature of these beautiful productions of
-nature. We now know that pearls consist essentially
-of carbonate of lime, and that the beauty is owing to
-the thin concentric lamin&aelig;, of which they are composed.</p>
-
-<p>Nor have I taken any notice of lime with which the
-ancients were well acquainted, and which they applied
-to most of the uses to which the moderns put it. Thus
-it constituted the base of the Roman mortar, which
-is known to have been excellent. They employed it
-also as a manure for the fields, as the moderns do. It
-was known to have a corrosive nature when taken internally;
-but was much employed by the ancients externally,
-and in various ways as an application to
-ulcers. Whether they knew its solubility in water
-does not appear; though, from the circumstance of its
-being used for making mortar, this fact could hardly
-escape them. These facts, though of great importance,
-could scarcely be applied to the rearing of a chemical
-structure, as the ancients could have no notion of the
-action of acids upon lime, or of the numerous salts
-which it is capable of forming. Phenomena which
-must have remained unknown till the discovery of the
-acids enabled experimenters to try their effects upon
-limestone and quicklime. Not even a conjecture appears
-in any ancient writer that I have looked into,
-<span class="pagenum" id="Page_109">109</span>
-about the difference between quicklime and limestone.
-This difference is so great that it must have
-been remarked by them, yet nobody seems ever to
-have thought of attempting to account for it. Even
-the method of burning or calcining lime is not described
-by Pliny; though there can be no doubt that
-the ancients were acquainted with it.</p>
-
-<p>Nor have I taken any notice of leather or the method
-of tanning it. There are so many allusions to
-leather and its uses by the ancient poets and historians,
-that the acquaintance of the ancients with it is
-put out of doubt. But so far as I know, there is no
-description of the process of tanning in any ancient
-author whatever.
-<span class="pagenum" id="Page_110">110</span></p>
-
-<h2 id="CHAPTER_III">CHAPTER III.<br />
-
-<span class="large">CHEMISTRY OF THE ARABIANS.</span></h2>
-
-<p>Hitherto I have spoken of Alchymy, or of the chemical
-manufactures of the ancients. The people to
-whom scientific chemistry owes its origin are the
-Arabians. Not that they prosecuted scientific chemistry
-themselves; but they were the first persons who
-attempted to form chemical medicines. This they did
-by mixing various bodies with each other, and applying
-heat to the mixture in various ways. This led to the
-discovery of some of the mineral acids. These they
-applied to the metals, &amp;c., and ascertained the effects
-produced upon that most important class of bodies.
-Thus the Arabians began those researches which led
-gradually to the formation of scientific chemistry. We
-must therefore endeavour to ascertain the chemical
-facts for which we are indebted to the Arabians.</p>
-
-<p>When Mahomet first delivered his dogmas to his
-countrymen they were not altogether barbarous. Possessed
-of a copious and expressive language, and inhabiting
-a burning climate, their imaginations were
-lively and their passions violent. Poetry and fiction
-were cultivated by them with ardour, and with considerable
-success. But science and inductive philosophy,
-had made little or no progress among them.
-The fatalism introduced by Mahomet, and the blind
-enthusiasm which he inculcated, rendered them furious
-<span class="pagenum" id="Page_111">111</span>
-bigots and determined enemies to every kind of
-intellectual improvement. The rapidity with which
-they overran Asia, Africa, and even a portion of
-Europe, is universally known. At that period the
-western world, was sunk into extreme barbarism, and
-the Greeks, with whom the remains of civilization still
-lingered, were sadly degenerated from those sages
-who graced the classic ages. Bent to the earth under
-the most grinding but turbulent despotism that ever
-disgraced mankind, and having their understandings
-sealed up by the most subtle and absurd, and uncompromising
-superstition, all the energy of mind, all
-the powers of invention, all the industry and talent,
-which distinguished their ancestors, had completely
-forsaken them. Their writers aimed at nothing new
-or great, and were satisfied with repeating the scientific
-facts determined by their ancestors. The lamp of
-science fluttered in its socket, and was on the eve of
-being extinguished.</p>
-
-<p>Nothing good or great could be expected from such
-a state of society. It was, therefore, wisely determined
-by Providence that the Mussulman conquerors,
-should overrun the earth, sweep out those miserable
-governors, and free the wretched inhabitants from the
-trammels of despotism and superstition. As a despotism
-not less severe, and a superstition still more
-gloomy and uncompromising, was substituted in their
-place, it may seem at first sight, that the conquests of
-the Mahometans brought things into a worse state
-than they found them. But the listless inactivity, the
-almost deathlike torpor which had frozen the minds of
-mankind, were effectually roused. The Mussulmans
-displayed a degree of energy and activity which have
-few parallels in the history of the world: and after the
-conquests of the Mahometans were completed, and
-the Califs quietly seated upon the greatest and most
-powerful throne that the world had ever seen; after
-Almanzor, about the middle of the eighth century, had
-<span class="pagenum" id="Page_112">112</span>
-founded the city of Bagdad, and settled a permanent
-and flourishing peace, the arts and sciences, which
-usually accompany such a state of society, began to
-make their appearance.</p>
-
-<p>That calif founded an academy at Bagdad, which
-acquired much celebrity, and gradually raised itself
-above all the other academies in his dominions. A
-medical college was established there with powers to
-examine all those persons who intended to devote
-themselves to the medical profession. So many professors
-and pupils flocked to this celebrated college,
-from all parts of the world, that at one time their number
-amounted to no fewer than six thousand. Public
-hospitals and laboratories were established to facilitate
-a knowledge of diseases, and to make the students
-acquainted with the method of preparing medicines.
-It was this last establishment which originated with the
-califs that gave a first beginning to the science of
-chemistry.</p>
-
-<p>In the thirteenth century the calif Mostanser re-established
-the academy and the medical college at
-Bagdad: for both had fallen into decay, and had
-been replaced by an infinite number of Jewish seminaries.
-Mostanser gave large salaries to the professors,
-collected a magnificent library, and established a
-new school of pharmacy. He was himself often present
-at the public lectures.</p>
-
-<p>The successor of Mostanser was the calif Haroun-Al-Raschid,
-the perpetual hero of the Arabian tales.
-He not only carried his love for the sciences further
-than his predecessors, but displayed a liberality and a
-tolerance for religious opinions, which was not quite
-consistent with Mahometan bigotry and superstition.
-He drew round him the Syrian Christians, who translated
-the Greek classics, rewarded them liberally, and
-appointed them instructors of his Mahometan subjects,
-especially in medicine and pharmacy. He protected
-the Christian school of Dschondisabour, founded
-<span class="pagenum" id="Page_113">113</span>
-by the Nestorian Christians, before the time of Mahomet,
-and still continuing in a flourishing state: always
-surrounded by literary men, he frequently condescended
-to take a part in their discussions, and not
-unfrequently, as might have been expected from his
-rank, came off victorious.</p>
-
-<p>The most enlightened of all the califs was Almamon,
-who has rendered his name immortal by his
-exertions in favour of the sciences. It was during his
-reign that the Arabian schools came to be thoroughly
-acquainted with Greek science; he procured the
-translation of a great number of important works.
-This conduct inflamed the religious zeal of the faithful,
-who devoted him to destruction, and to the
-divine wrath, for favouring philosophy, and in that
-way diminishing the authority of the Koran. Almamon
-purchased the ancient classics, from all quarters,
-and recommended the care of doing so in a particular
-manner to his ambassadors at the court of the
-Greek emperors. To Leo, the philosopher, he made
-the most advantageous offers, to induce him to come
-to Bagdad; but that philosopher would not listen to
-his invitation. It was under the auspices of this enlightened
-prince, that the celebrated attempt was made
-to determine the size of the earth by measuring a
-degree of the meridian. The result of this attempt
-it does not belong to this work to relate.</p>
-
-<p>Almotassem and Motawakkel, who succeeded Almamon,
-followed his example, favoured the sciences,
-and extended their protection to men of science who
-were Christians. Motawakkel re-established the celebrated
-academy and library of Alexandria. But
-he acted with more severity than his predecessors with
-regard to the Christians, who may perhaps have
-abused the tolerance which they enjoyed.</p>
-
-<p>The other vicars of the prophet, in the different
-Mahometan states, followed the fine example set them
-by Almamon. Already in the eighth century the sovereigns
-<span class="pagenum" id="Page_114">114</span>
-of Mogreb and the western provinces of Africa
-showed themselves the zealous friends of the sciences.
-One of them called Abdallah-Ebn-Ibadschab rendered
-commerce and industry flourishing at Tunis.
-He himself cultivated poetry and drew numerous
-artists and men of science into his state. At Fez and
-in Morocco the sciences flourished, especially during
-the reign of the Edrisites, the last of whom, Jahiah, a
-prince possessed of genius, sweetness, and goodness,
-changed his court into an academy, and paid attention
-to those only who had distinguished themselves
-by their scientific knowledge.</p>
-
-<p>But Spain was the most fortunate of all the Mahometan
-states, and had arrived at such a degree of
-prosperity both in commerce, manufactures, population,
-and wealth, as is hardly to be credited. The
-three Abdalrahmans and Alhakem carried, from the
-eighth to the tenth century, the country subject to the
-Calif of Cordova to the highest degree of splendour.
-They protected the sciences, and governed with so
-much mildness, that Spain was probably never so
-happy under the dominion of any Christian prince.
-Alhakem established at Cordova an academy, which
-for several ages was the most celebrated in the whole
-world. All the Christians of Western Europe repaired
-to this academy in search of information. It
-contained, in the tenth century, a library of 280,000
-volumes. The catalogue of this library filled no less
-than forty-four volumes. Seville, Toledo, and Murcia,
-had likewise their schools of science and their libraries,
-which retained their celebrity as long as the dominion
-of the Moors lasted. In the twelfth century there
-were seventy public libraries in that part of Spain
-which belonged to the Mahometans. Cordova had
-produced one hundred and fifty authors, Almeria fifty-two,
-and Murcia sixty-two.</p>
-
-<p>The Mahometan states of the east continued also
-to favour the sciences. An emir of Irak, Adad-El-Daula
-<span class="pagenum" id="Page_115">115</span>
-by name, distinguished himself towards the
-end of the tenth century by the protection which he
-afforded to men of science. To him almost all the
-philosophers of the age dedicated their works. Another
-emir of Irak, Saif-Ed-Daula, established schools
-at Kufa and at Bussora, which soon acquired great celebrity.
-Abou-Mansor-Baharam, established a public
-library at Firuzabad in Curdistan, which at its very
-commencement contained 7000 volumes. In the
-thirteenth century there existed a celebrated school of
-medicine in Damascus. The calif Malek-Adel endowed
-it richly, and was often present at the lectures with a
-book under his arm.</p>
-
-<p>Had the progress of the sciences among the Arabians
-been proportional to the number of those who
-cultivated them, we might hail the Saracens as the
-saviours of literature during the dark and benighted
-ages of Christianity; but we must acknowledge with
-regret, that notwithstanding the enlightened views of
-the califs, notwithstanding the multiplicity of academies
-and libraries, and the prodigious number of
-writers, the sciences received but little improvement
-from the Arabians. There are very few Arabian
-writers in whose works we find either philosophical
-ideas, successful researches, new facts, or great and
-new and important truths. How, indeed, could such
-things be expected from a people naturally hostile to
-mental exertion; professing a religion which stigmatizes
-all exercise of the judgment as a crime, and
-weighed down by the heavy yoke of despotism? It
-was the religion of the Arabians, and the despotism
-of their princes, that opposed the greatest obstacles
-to the progress of the sciences, even during the most
-flourishing period of their civilization.<a id="FNanchor_103" href="#Footnote_103" class="fnanchor">103</a> Fortunately
-<span class="pagenum" id="Page_116">116</span>
-chemistry was the branch of science least obnoxious
-to the religious prejudices of the Mahometans. It was
-in it, therefore, that the greatest improvements were
-made: of these improvements it will be requisite now
-to endeavour to give the reader some idea. Astrology
-and alchymy, they both derived from the Greeks:
-neither of them were inconsistent with the taste of the
-nation&mdash;neither of them were anathematized by the
-Mahometan creed, though Islamism prohibited magic
-and all the arts of divination. Alchymy may have
-suggested the chemical processes&mdash;but the Arabians
-applied them to the preparation of medicines, and
-thus opened a new and most copious source of investigation.</p>
-
-<p>The chemical writings of the Arabians which I have
-had an opportunity of seeing and perusing in a Latin
-dress, being ignorant of the original language in which
-they were written, are those of Geber and Avicenna.</p>
-
-<p>Geber, whose real name was Abou-Moussah-Dschafar-Al-Soli,
-was a Sabean of Harran, in Mesopotamia,
-and lived during the eighth century. Very
-little is known respecting the history of this writer,
-who must be considered as the patriarch of chemistry.
-Golius, professor of the oriental languages in the
-University of Leyden, made a present of Geber’s work
-in manuscript to the public library. He translated it
-into Latin, and published it in the same city in folio,
-and afterwards in quarto, under the title of “Lapis
-Philosophorum.”<a id="FNanchor_104" href="#Footnote_104" class="fnanchor">104</a> It was translated into English by
-Richard Russel in 1678, under the title of, “The
-Works of Geber, the most famous Arabian Prince and
-Philosopher.”<a id="FNanchor_105" href="#Footnote_105" class="fnanchor">105</a> The works of Geber, so far as they
-<span class="pagenum" id="Page_117">117</span>
-appeared in Latin or English, consist of four tracts.
-The first is entitled, “Of the Investigation or Search
-of Perfection.” The second is entitled, “Of the Sum
-of Perfection, or of the perfect Magistery.” The
-third, “Of the Invention of Verity or Perfection.”
-And the last, “Of Furnaces, &amp;c.; with a Recapitulation
-of the Author’s Experiments.”</p>
-
-<p>The object of Geber’s work is to teach the method
-of making the philosopher’s stone, which he distinguishes
-usually by the name of <i>medicine of the third
-class</i>. The whole is in general written with so much
-plainness, that we can understand the nature of the
-substances which he employed, the processes which
-he followed, and the greater number of the products
-which he obtained. It is, therefore, a book of some
-importance, because it is the oldest chemical treatise
-in existence,<a id="FNanchor_106" href="#Footnote_106" class="fnanchor">106</a> and because it makes us acquainted
-with the processes followed by the Arabians, and the
-progress which they had made in chemical investigations.
-I shall therefore lay before the reader the most
-important facts contained in Geber’s work.</p>
-
-<p>1. He considered all the metals as compounds of
-mercury and sulphur: this opinion did not originate
-with him. It is evident from what he says, that the
-same notion had been adopted by his predecessors&mdash;men
-whom he speaks of under the title of the
-<i>ancients</i>.</p>
-
-<p>2. The metals with which he was acquainted were
-<i>gold</i>, <i>silver</i>, <i>copper</i>, <i>iron</i>, <i>tin</i>, and <i>lead</i>. These are
-usually distinguished by him under the names of <i>Sol</i>,
-<i>Luna</i>, <i>Venus</i>, <i>Mars</i>, <i>Jupiter</i>, and <i>Saturn</i>. Whether
-<span class="pagenum" id="Page_118">118</span>
-these names of the planets were applied to the metals
-by Geber, or only by his translators, I cannot say;
-but they were always employed by the alchymists,
-who never designated the metals by any other appellations.</p>
-
-<p>3. Gold and silver he considered as perfect metals;
-but the other four were imperfect metals. The difference
-between them depends, in his opinion, partly
-upon the proportions of mercury and sulphur in each,
-and partly upon the purity or impurity of the mercury
-and sulphur which enters into the composition of each.</p>
-
-<p>Gold, according to him, is created of the most
-subtile substance of mercury and of most clear fixture,
-and of a small substance of sulphur, clean and of pure
-redness, fixed, clear, and changed from its own nature,
-tinging that; and because there happens a diversity in
-the colours of that sulphur, the yellowness of gold
-must needs have a like diversity.<a id="FNanchor_107" href="#Footnote_107" class="fnanchor">107</a> His evidence that
-gold consisted chiefly of mercury, is the great ease
-with which mercury dissolves gold. For mercury, in
-his opinion, dissolves nothing that is not of its own
-nature. The lustre and splendour of gold is another
-proof of the great proportion of mercury which it contains.
-That it is a fixed substance, void of all burning
-sulphur, he thinks evident by every operation in
-the fire, for it is neither diminished nor inflamed.
-His other reasons are not so intelligible.<a id="FNanchor_108" href="#Footnote_108" class="fnanchor">108</a></p>
-
-<p>Silver, like gold, is composed of much mercury and
-a little sulphur; but in the gold the sulphur is red;
-whereas the sulphur that goes to the formation of
-silver is white. The sulphur in silver is also clean,
-fixed, and clear. Silver has a purity short of that of
-gold, and a more gross inspissation. The proof of
-this is, that its parts are not so condensed, nor is it
-so fixed as gold; for it may be diminished by fire,
-which is not the case with gold.<a id="FNanchor_109" href="#Footnote_109" class="fnanchor">109</a>
-<span class="pagenum" id="Page_119">119</span></p>
-
-<p>Iron is composed of earthy mercury and earthy
-sulphur, highly fixed, the latter in by far the greatest
-quantity. Sulphur, by the work of fixation, more easily
-destroys the easiness of liquefaction than mercury.
-Hence the reason why iron is not fusible, as is the
-case with the other metals.<a id="FNanchor_110" href="#Footnote_110" class="fnanchor">110</a></p>
-
-<p>Sulphur not fixed melts sooner than mercury; but
-fixed sulphur opposes fusion. What contains more
-fixed sulphur, more slowly admits of fusion than what
-partakes of burning sulphur, which more easily and
-sooner flows.<a id="FNanchor_111" href="#Footnote_111" class="fnanchor">111</a></p>
-
-<p>Copper is composed of sulphur unclean, gross and
-fixed as to its greater part; but as to its lesser part
-not fixed, red, and livid, in relation to the whole not
-overcoming nor overcome and of gross mercury.<a id="FNanchor_112" href="#Footnote_112" class="fnanchor">112</a></p>
-
-<p>When copper is exposed to ignition, you may discern
-a sulphureous flame to arise from it, which is a
-sign of sulphur not fixed; and the loss of the quantity
-of it by exhalation through the frequent combustion
-of it, shows that it has fixed sulphur. This last being
-in abundance, occasions the slowness of its fusion
-and the hardness of its substance. That copper
-contains red and unclean sulphur, united to unclean
-mercury, is, he thinks, evident, from its sensible
-qualities.<a id="FNanchor_113" href="#Footnote_113" class="fnanchor">113</a></p>
-
-<p>Tin consists of sulphur of small fixation, white with
-a whiteness not pure, not overcoming but overcome,
-mixed with mercury partly fixed and partly not fixed,
-white and impure.<a id="FNanchor_114" href="#Footnote_114" class="fnanchor">114</a> That this is the constitution of
-tin he thinks evident; for when calcined, it emits a
-sulphureous stench, which is a sign of sulphur not
-fixed: it yields no flame, not because the sulphur is
-fixed, but because it contains a great portion of mercury.
-In tin there is a twofold sulphur and also a
-twofold mercury. One sulphur is less fixed, because
-in calcining it gives out a stench as sulphur. The fixed
-<span class="pagenum" id="Page_120">120</span>
-sulphur continues in the tin after it is calcined. He
-thinks that the twofold mercury in tin is evident, from
-this, that before calcination it makes a crashing
-noise when bent, but after it has been thrice calcined,
-that crashing noise can no longer be perceived.<a id="FNanchor_115" href="#Footnote_115" class="fnanchor">115</a>
-Geber says, that if lead be washed with
-mercury, and after its washing melted in a fire not
-exceeding the fire of its fusion, a portion of the mercury
-will remain combined with the lead, and will
-give it the crashing noise and all the qualities of tin.
-On the other hand, you may convert tin into lead.
-By manifold repetition of its calcination, and the administration
-of fire convenient for its reduction, it is
-turned into lead.<a id="FNanchor_116" href="#Footnote_116" class="fnanchor">116</a></p>
-
-<p>Lead, in Geber’s opinion, differs from tin only in
-having a more unclean substance commixed of the
-two more gross substances, sulphur and mercury.
-The sulphur in it is burning and more adhesive to the
-substance of its own mercury, and it has more of the
-substance of fixed sulphur in its composition than tin
-has.<a id="FNanchor_117" href="#Footnote_117" class="fnanchor">117</a></p>
-
-<p>Such are the opinions which Geber entertained respecting
-the composition of the metals. I have been
-induced to state them as nearly in his own words as
-possible, and to give the reasons which he has assigned
-for them, even when his facts were not quite correct,
-because I thought that this was the most likely way of
-conveying to the reader an accurate notion of the sentiments
-of this father of the alchymists, upon the very
-foundation of the whole doctrine of the transmutation
-of metals. He was of opinion that all the imperfect
-metals might be transformed into gold and silver, by
-altering the proportions of the mercury and sulphur of
-which they are composed, and by changing the nature
-of the mercury and sulphur so as to make them the
-same with the mercury and sulphur which constitute
-<span class="pagenum" id="Page_121">121</span>
-gold and silver. The substance capable of producing
-these important changes he calls sometimes the <i>philosopher’s
-stone</i>, but generally the <i>medicine</i>. He gives
-the method of preparing this important <i>magistery</i>, as
-he calls it. But it is not worth while to state his process,
-because he leaves out several particulars, in
-order to prevent the foolish from reaping any benefit
-from his writings, while at the same time those readers
-who possess the proper degree of sagacity will be able,
-by studying the different parts of his writings, to divine
-the nature of the steps which he omits, and thus
-profit by his researches and explanations. But it
-will be worth while to notice the most important of
-his processes, because this will enable us to judge of
-the state of chemistry in his time.</p>
-
-<p>4. In his book on furnaces, he gives a description
-of a furnace proper for calcining metals, and from
-the fourteenth chapter of the fourth part of the first
-book of his Sum of Perfection, it is obvious that
-the method of calcining or oxidizing iron, copper,
-tin, and lead, and also mercury and arsenic were familiarly
-known to him.</p>
-
-<p>He gives a description of a furnace for distilling,
-and a pretty minute account of the glass or stoneware,
-or metallic aludel and alembic, by means of
-which the process was conducted. He was in the
-habit of distilling by surrounding his aludel with hot
-ashes, to prevent it from being broken. He was acquainted
-also with the water-bath. These processes were
-familiar to him. The description of the distillation of
-many bodies occurs in his work; but there is not the
-least evidence that he was acquainted with ardent
-spirits. The term <i>spirit</i> occurs frequently in his
-writings, but it was applied to volatile bodies in general,
-and in particular to sulphur and white arsenic,
-which he considered as substances very similar in their
-properties. Mercury also he considered as a spirit.</p>
-
-<p>The method of distilling <i>per descensum</i>, as is practised
-<span class="pagenum" id="Page_122">122</span>
-in the smelting of zinc, was also known to him.
-He describes an apparatus for the purpose, and gives
-several examples of such distillations in his writings.</p>
-
-<p>He gives also a description of a furnace for melting
-metals, and mentions the vessels in which such processes
-were conducted. He was acquainted with crucibles;
-and even describes the mode of making cupels,
-nearly similar to those used at present. The process
-of cupellating gold and silver, and purifying them by
-means of lead, is given by him pretty minutely and
-accurately: he calls it <i>cineritium</i>, or at least that is
-the term used by his Latin translator.</p>
-
-<p>He was in the habit of dissolving salts in water and
-acetic acid, and even the metals in different menstrua.
-Of these menstrua he nowhere gives any account; but
-from our knowledge of the properties of the different
-metals, and from some processes which he notices, it
-is easy to perceive what his solvents must have been;
-namely, the mineral acids which were known to him,
-and to which there is no allusion whatever in any
-preceding writer that I have had an opportunity of
-consulting. Whether Geber was the discoverer of these
-acids cannot be known, as he nowhere claims the discovery:
-indeed his object was to slur over these acids,
-as much as possible, that their existence, or at least
-their remarkable properties, might not be suspected by
-the uninitiated. It was this affectation of secrecy and
-mystery that has deprived the earliest chemists of that
-credit and reputation to which they would have been
-justly entitled, had their discoveries been made known
-to the public in a plain and intelligible manner.</p>
-
-<p>The mode of purifying liquids by filtration, and of
-separating precipitates from liquids by the same means,
-was known to Geber. He called the process <i>distillation
-through a filter</i>.</p>
-
-<p>Thus the greater number of chemical processes, such
-as they were practised almost to the end of the eighteenth
-century, were known to Geber. If we compare his
-<span class="pagenum" id="Page_123">123</span>
-works with those of Dioscorides and Pliny, we shall
-perceive the great progress which chemistry or rather
-pharmacy had made. It is more than probable that
-these improvements were made by the Arabian physicians,
-or at least by the physicians who filled the
-chairs in the medical schools, which were under the
-protection of the califs: for as no notice is taken of
-these processes by any of the Greek or Roman writers
-that have come down to us, and as we find them
-minutely described by the earliest chemical writers
-among the Arabians, we have no other alternative
-than to admit that they originated in the east.</p>
-
-<p>I shall now state the different chemical substances
-or preparations which were known to Geber, or which
-he describes the method of preparing in his works.</p>
-
-<p>1. Common salt. This substance occurring in such
-abundance in the earth, and being indispensable as a
-seasoner of food, was known from the earliest ages.
-But Geber describes the method which he adopted to
-free it from impurities. It was exposed to a red heat,
-then dissolved in water, filtered, crystallized by evaporation,
-and the crystals being exposed to a red heat,
-were put into a close vessel, and kept for use.<a id="FNanchor_118" href="#Footnote_118" class="fnanchor">118</a>
-Whether the identity of sal-gem (<i>native salt</i>) and
-common salt was known to Geber is nowhere said.
-Probably not, as he gives separate directions for
-purifying each.</p>
-
-<p>2. Geber gives an account of the two fixed alkalies,
-<i>potash</i> and <i>soda</i>, and gives processes for obtaining
-them. Potash was obtained by burning cream of tartar
-in a crucible, dissolving the residue in water, filtering
-the solution, and evaporating to dryness.<a id="FNanchor_119" href="#Footnote_119" class="fnanchor">119</a> This
-would yield a pure carbonate of potash.</p>
-
-<p>Carbonate of soda he calls <i>sagimen vitri</i>, and salt
-of soda. He mentions plants which yield it when
-burnt, points out the method of purifying it, and even
-<span class="pagenum" id="Page_124">124</span>
-describes the method of rendering it caustic by means
-of quicklime.<a id="FNanchor_120" href="#Footnote_120" class="fnanchor">120</a></p>
-
-<p>3. Saltpetre, or nitrate of potash, was known to
-him; and Geber is the first writer in whom we find an
-account of this salt. Nothing is said respecting its
-origin; but there can be little doubt that it came
-from India, where it was collected, and known long
-before Europeans were acquainted with it. The knowledge
-of this salt was probably one great cause of the
-superiority of the Arabians over Europeans in chemical
-knowledge; for it enabled them to procure <i>nitric acid</i>,
-by means of which they dissolved all the metals known
-in their time, and thus acquired a knowledge of various
-important saline compounds, which were of considerable
-importance.</p>
-
-<p>There is a process for preparing saltpetre artificially,
-in several of the Latin copies of Geber, though it does
-not appear in our English translation. The method
-was to dissolve sagimen vitri, or carbonate of soda, in
-aqua fortis, to filter and crystallize by evaporation.<a id="FNanchor_121" href="#Footnote_121" class="fnanchor">121</a>
-If this process be genuine, it is obvious that Geber
-must have been acquainted with nitrate of soda; but
-I have some doubts about the genuineness of the passage,
-because the term <i>aqua fortis</i> occurs in it. Now
-this term occurs nowhere else in Geber’s work: even
-when he gives the process for procuring nitric acid, he
-calls it simply water; but observes, that it is a water
-possessed of much virtue, and that it constitutes a
-precious instrument in the hands of the man who
-possesses sagacity to use it aright.</p>
-
-<p>4. Sal ammoniac was known to Geber, and seems
-to have been quite common in his time. There is no
-evidence that it was known to the Greeks or Romans,
-as neither Dioscorides nor Pliny make any allusion
-to it. The word in old books is sometimes <i>sal armoniac</i>,
-sometimes <i>sal ammoniac</i>. It is supposed to
-<span class="pagenum" id="Page_125">125</span>
-have been brought originally from the neighbourhood
-of the temple of Jupiter Ammon: but had this been
-the case, and had it occurred native, it could scarcely
-have been unknown to the Romans, under whose
-dominions that part of Africa fell. In the writings of
-the alchymists, sal ammoniac is mentioned under the
-following whimsical names:
-
-<span class="table">
-<span class="trow">Anima sensibilis,<br /></span>
-<span class="trow">Aqua duorum fratrum ex sorore,<br /></span>
-<span class="trow">Aquila,<br /></span>
-<span class="trow">Lapis aquilinis,<br /></span>
-<span class="trow">Cancer,<br /></span>
-<span class="trow">Lapis angeli conjungentis,<br /></span>
-<span class="trow">Sal lapidum,<br /></span>
-<span class="trow">Sal alocoph.<br /></span>
-</span>
-</p>
-
-<p>Geber not only knew sal ammoniac, but he was
-aware of its volatility; and gives various processes
-for subliming it, and uses it frequently to promote the
-sublimation of other bodies, as of oxides of iron and
-copper. He gives also a method of procuring it from
-urine, a liquid which, when allowed to run into putrefaction,
-is known to yield it in abundance. Sal
-ammoniac was much used by Geber, in his various
-processes to bring the inferior metals to a state of
-greater perfection. By adding it or common salt to
-aqua fortis, he was enabled to dissolve gold, which
-certainly could not be accomplished in the time of
-Dioscorides or Pliny. The description, indeed, of
-Geber’s process for dissolving gold is left on purpose
-in a defective state; but an attentive reader will find
-no great difficulty in supplying the defects, and thus
-understanding the whole of the process.</p>
-
-<p>5. Alum, precisely the same as the alum of the
-moderns, was familiarly known to Geber, and employed
-by him in his processes. The manufacture of
-this salt, therefore, had been discovered between the
-time when Pliny composed his Natural History and
-<span class="pagenum" id="Page_126">126</span>
-the eighth century, when Geber wrote; unless we
-admit that the mode of making it had been known to
-the Tyrian dyers, but that they had kept the secret
-so well, that no suspicion of its existence was entertained
-by the Greeks and Romans. That they employed
-<i>alumina</i> as a mordant in some of their dyes,
-is evident; but there is no proof whatever that <i>alum</i>,
-in the modern sense of the word, was known to them.</p>
-
-<p>Geber mentions three alums which he was in the
-habit of using; namely, icy alum, or Rocca alum;
-Jamenous alum, or alum of Jameni, and feather alum.
-<i>Rocca</i>, or <i>Edessa</i>, in Syria, is admitted to have been
-the place where the first manufactory of alum was
-established; but at what time, or by whom, is quite
-unknown: we know only that it must have been posterior
-to the commencement of the Christian era, and
-prior to the eighth century, when Geber wrote. Jameni
-must have been another locality where, at the
-time of Geber, a manufactory of alum existed. <i>Feather
-alum</i> was undoubtedly one of the native impure varieties
-of <i>alum</i>, known to the Greeks and Romans.
-Geber was in the habit of distilling alum by a strong
-heat, and of preserving the water which came over
-as a valuable menstruum. If alum be exposed to a
-red heat in glass vessels, it will give out a portion of
-sulphuric acid: hence water distilled from alum by
-Geber was probably a weak solution of sulphuric acid,
-which would undoubtedly act powerfully as a solvent
-of iron, and of the alkaline carbonates. It was probably
-in this way that he used it.</p>
-
-<p>6. Sulphate of iron or copperas, as it is called
-(<i>cuperosa</i>), in the state of a crystalline salt, was well
-known to Geber, and appears in his time to have been
-manufactured.</p>
-
-<p>7. Baurach, or borax, is mentioned by him, but
-without any description by which we can know whether
-or not it was our borax: the probability is that it was.
-<span class="pagenum" id="Page_127">127</span>
-Both glass and borax were used by him when the
-oxides of metals were reduced by him to the metallic
-state.</p>
-
-<p>8. Vinegar was purified by him by distilling it over,
-and it was used as a solvent in many of his processes.</p>
-
-<p>9. Nitric acid was known to him by the name of
-<i>dissolving water</i>. He prepared it by putting into an
-alembic one pound of sulphate of iron of Cyprus, half
-a pound of saltpetre, and a quarter of a pound of alum
-of Jameni: this mixture was distilled till every thing
-liquid was driven over. He mentions the red fumes
-which make their appearance in the alembic during
-the process.<a id="FNanchor_122" href="#Footnote_122" class="fnanchor">122</a> This process, though not an economical
-one, would certainly yield nitric acid; and it is
-remarkable, because it is here that we find the first
-hint of the knowledge of chemists of this most important
-acid, without which many chemical processes
-of the utmost importance could not be performed
-at all.</p>
-
-<p>10. This acid, thus prepared, he made use of to
-dissolve silver: the solution was concentrated till the
-nitrate of silver was obtained by him in a crystallized
-state. This process is thus described by him: “Dissolve
-silver calcined in solutive water (<i>nitric acid</i>), as
-before; which being done, coct it in a phial with a
-long neck, the orifice of which must be left unstopped,
-for one day only, until a third part of the water be
-consumed. This being effected, set it with its vessel
-in a cold place, and then it is converted into small
-fusible stones, like crystal.”<a id="FNanchor_123" href="#Footnote_123" class="fnanchor">123</a></p>
-
-<p>11. He was in the habit also of dissolving sal
-ammoniac in this nitric acid, and employing the solution,
-which was the aqua regia of the old chemists, to
-dissolve gold.<a id="FNanchor_124" href="#Footnote_124" class="fnanchor">124</a> He assures us that this aqua regia
-would dissolve likewise sulphur and silver. The latter
-assertion is erroneous. But sulphur is easily converted
-<span class="pagenum" id="Page_128">128</span>
-into sulphuric acid by the action of aqua regia, and of
-course it disappears or dissolves.</p>
-
-<p>12. Corrosive sublimate is likewise described by
-Geber in a very intelligible manner. His method of
-preparing it was as follows: “Take of mercury one
-pound, of dried sulphate of iron two pounds, of alum
-calcined one pound, of common salt half a pound,
-and of saltpetre a quarter of a pound: incorporate
-altogether by trituration and sublime; gather the
-white, dense, and ponderous portions which shall be
-found about the sides of the vessel. If in the first
-sublimation you find it turbid or unclean (which may
-happen by reason of your own negligence), sublime a
-second time with the same fuses.”<a id="FNanchor_125" href="#Footnote_125" class="fnanchor">125</a> Still more minute
-directions are given in other parts of the work: we
-have even some imperfect account of the properties of
-corrosive sublimate.</p>
-
-<p>13. Corrosive sublimate is not the only preparation
-of mercury mentioned by Geber. He informs
-us that when mercury is combined with sulphur
-it assumes a red colour, and becomes cinnabar.<a id="FNanchor_126" href="#Footnote_126" class="fnanchor">126</a> He
-describes the affinities of mercury for the different
-metals. It adheres easily to three metals; namely,
-lead, tin, and gold; to silver with more difficulty. To
-copper with still more difficulty than to silver; but to
-iron it unites in nowise unless by artifice.<a id="FNanchor_127" href="#Footnote_127" class="fnanchor">127</a> This is a
-tolerably accurate account of the matter. He says,
-that mercury is the heaviest body in nature except
-gold, which is the only metal that will sink in it.<a id="FNanchor_128" href="#Footnote_128" class="fnanchor">128</a>
-Now this was true, applied to all the substances known
-when Geber lived.</p>
-
-<p>He gives an account of the method of forming the
-peroxide of mercury by heat; that variety of it formerly
-distinguished by the name of <i>red precipitati
-per se</i>. “Mercury,” he says, “is also coagulated by
-<span class="pagenum" id="Page_129">129</span>
-long and constant retention in fire, in a glass vessel
-with a very long neck and round belly; the orifice of
-the neck being kept open, that the humidity may vanish
-thereby.”<a id="FNanchor_129" href="#Footnote_129" class="fnanchor">129</a> He gives another process for preparing
-this oxide, possible, perhaps, though certainly requiring
-very cautious regulation of the fire. “Take,”
-says he, “of mercury one pound, of vitriol (sulphate
-of iron) rubified two pounds, and of saltpetre one
-pound. Mortify the mercury with these, and then
-sublime it from rock alum and saltpetre in equal
-weights.”<a id="FNanchor_130" href="#Footnote_130" class="fnanchor">130</a></p>
-
-<p>14. Geber was acquainted with several of the compounds
-of metals with sulphur. He remarks that
-sulphur when fused with metals increases their weight.<a id="FNanchor_131" href="#Footnote_131" class="fnanchor">131</a>
-Copper combined with sulphur becomes yellow, and
-mercury red.<a id="FNanchor_132" href="#Footnote_132" class="fnanchor">132</a> He knew the method of dissolving
-sulphur in caustic potash, and again precipitating it
-by the addition of an acid. His process is as follows:
-“Grind clear and gummose sulphur to a most subtile
-powder, which boil in a lixivium made of ashes of
-<i>heartsease</i> and quicklime, gathering from off the
-surface its oleaginous combustibility, until it be discerned
-to be clear. This being done, stir the whole
-with a stick, and then warily take off that which
-passeth out with the lixivium, leaving the more gross
-parts in the bottom. Permit that extract to cool a
-little, and upon it pour a fourth part of its own
-quantity of distilled vinegar, and then will the whole
-suddenly be congealed as milk. Remove as much of
-the clear lixivium as you can; but dry the residue
-with a gentle fire and keep it.”<a id="FNanchor_133" href="#Footnote_133" class="fnanchor">133</a></p>
-
-<p>15. It would appear from various passages in
-Geber’s works that he was acquainted with arsenic in
-the metallic state. He frequently mentions its combustibility,
-<span class="pagenum" id="Page_130">130</span>
-and considers it as the <i>compeer</i> of sulphur.
-And in his book on <i>Furnaces</i>, chapter 25 (or 28 in
-some copies), he expressly mentions <i>metallic arsenic</i>
-(<i>arsenicum metallinum</i>), in a preparation not very intelligible,
-but which he considered of great importance.
-The white oxide of arsenic or arsenious acid, was obviously
-well known to him. He gives more than one
-process for obtaining it by sublimation.<a id="FNanchor_134" href="#Footnote_134" class="fnanchor">134</a> He observes
-in his Sum of Perfection, book i. part iv. chap. 2, which
-treats of sublimation, “Arsenic, which before its
-sublimation was evil and prone to adustion, after its
-sublimation, suffers not itself to be inflamed; but
-only resides without inflammation.”</p>
-
-<p>Geber states the fact, that when arsenic is heated
-with copper that metal becomes white.<a id="FNanchor_135" href="#Footnote_135" class="fnanchor">135</a> He gives
-also a process by which the white arseniate of iron is
-obviously made. “Grind one pound of iron filings
-with half a pound of sublimed arsenic (arsenious acid).
-Imbibe the mixture with the water of saltpetre, and
-salt-alkali, repeating this imbibation thrice. Then
-make it flow with a violent fire, and you will have
-your iron white. Repeat this labour till it flow sufficiently
-with peculiar dealbation.”<a id="FNanchor_136" href="#Footnote_136" class="fnanchor">136</a></p>
-
-<p>16. He mentions oxide of copper under the name
-of <i>&aelig;s ustum</i>, the red oxide of iron under the name of
-<i>crocus</i> of iron. He mentions also litharge and red
-lead.<a id="FNanchor_137" href="#Footnote_137" class="fnanchor">137</a> But as all these substances were known to the
-Greeks and Romans, it is needless to enter into any
-particular details.</p>
-
-<p>17. I am not sure what substance Geber understood
-by the word <i>marchasite</i>. It was a substance which
-must have been abundant, and in common use, for he
-refers to it frequently, and uses it in many of his processes;
-but he nowhere informs us what it is. I suspect
-<span class="pagenum" id="Page_131">131</span>
-it may have been sulphuret of antimony, which
-was certainly in common use in Asia long before the
-time of Geber. But he also makes mention of antimony
-by name, or at least the Latin translator has made
-use of the word <i>antimonium</i>. When speaking of the
-reduction of metals after heating them with sulphur,
-he says, “The reduction of tin is converted into clear
-antimony; but of lead, into a dark-coloured antimony,
-as we have found by proper experience.”<a id="FNanchor_138" href="#Footnote_138" class="fnanchor">138</a> It is not
-easy to conjecture what meaning the word antimony
-is intended to convey in this passage. In another
-passage he says, “Antimony is calcined, dissolved,
-clarified, congealed, and ground to powder, so it is
-prepared.”<a id="FNanchor_139" href="#Footnote_139" class="fnanchor">139</a></p>
-
-<p>18. Geber’s description of the metals is tolerably
-accurate, considering the time when he wrote. As an
-example I shall subjoin his account of gold. “Gold
-is a metallic body, yellow, ponderous, mute, fulged,
-equally digested in the bowels of the earth, and very
-long washed with mineral water; under the hammer
-extensible, fusible, and sustaining the trial of the cupel
-and cementation.”<a id="FNanchor_140" href="#Footnote_140" class="fnanchor">140</a> He gives an example of copper
-being changed into gold. “In copper-mines,” he
-says, “we see a certain water which flows out, and
-carries with it thin scales of copper, which (by a continual
-and long-continued course) it washes and
-cleanses. But after such water ceases to flow, we find
-these thin scales with the dry sand, in three years time
-to be digested with the heat of the sun; and among
-these scales the purest gold is found: therefore we
-judge those scales were cleansed by the benefit of the
-water, but were equally digested by heat of the sun,
-in the dryness of the sand, and so brought to equality.”<a id="FNanchor_141" href="#Footnote_141" class="fnanchor">141</a>
-Here we have an example of plausible reasoning from
-<span class="pagenum" id="Page_132">132</span>
-defective premises. The gold grains doubtless existed
-in the sand before, while the scales of copper in the
-course of three years would be oxidized and converted
-into powder, and disappear, or at least lose all their
-metallic lustre.</p>
-
-<p>Such are the most remarkable chemical facts which
-I have observed in the works of Geber. They are so
-numerous and important, as to entitle him with some
-justice to the appellation of the father and founder of
-chemistry. Besides the metals, sulphur and salt, with
-which the Greeks and Romans were acquainted, he
-knew the method of preparing sulphuric acid, nitric
-acid, and aqua regia. He knew the method of dissolving
-the metals by means of these acids, and actually prepared
-nitrate of silver and corrosive sublimate. He
-was acquainted with potash and soda, both in the state
-of carbonates and caustic. He was aware that these
-alkalies dissolve sulphur, and he employed the process
-to obtain sulphur in a state of purity.</p>
-
-<p>But notwithstanding the experimental merit of Geber,
-his spirit of philosophy did not much exceed that
-of his countrymen. He satisfied himself with accounting
-for phenomena by occult causes, as was the universal
-custom of the Arabians; a practice quite inconsistent
-with real scientific progress. That this was
-the case will appear from the following passage, in
-which Geber attempts to give an explanation of the
-properties of the <i>great elixir</i> or <i>philosopher’s stone</i>:
-“Therefore, let him attend to the properties and ways
-of action of the composition of the greater elixir. For
-we endeavour to make one substance, yet compounded
-and composed of many, so permanently fixed, that
-being put upon the fire, the fire cannot injure; and
-that it may be mixed with metals in flux and flow with
-them, and enter with that which in them is of an ingressible
-substance, and be fermented with that which
-in them is of a permixable substance; and be consolidated
-with that which in them is of a consolidable
-<span class="pagenum" id="Page_133">133</span>
-substance; and be fixed with that which in them is of
-a fixable substance; and not be burnt by those things
-which burn not gold and silver; and take away consolidation
-and weights with due ignition.”<a id="FNanchor_142" href="#Footnote_142" class="fnanchor">142</a></p>
-
-<p>The next Arabian whose name I shall introduce
-into this history, is Al-Hassain-Abou-Ali-Ben-Abdallah-Ebn-Sina,
-surnamed Scheik Reyes, or prince of
-physicians, vulgarly known by the name of <i>Avicenna</i>.
-Next to Aristotle and Galen, his reputation was the
-highest, and his authority the greatest of all medical
-practitioners; and he reigned paramount, or at least
-shared the medical sceptre till he was hurled from his
-throne by the rude hands of Paracelsus.</p>
-
-<p>Avicenna was born in the year 978, at Bokhara, to
-which place his father had retired during the emirate
-of the calif Nuhh, one of the sons of the celebrated
-Almansor. Ali, his father, had dwelt in Balkh, in
-the Chorazan. After the birth of Avicenna he went to
-Asschena in Bucharia, where he continued to live till
-his son had reached his fifteenth year. No labour nor
-expense was spared on the education of Avicenna,
-whose abilities were so extraordinary that he is said to
-have been able to repeat the whole Koran by heart
-at the age of ten years. Ali gave him for a master
-Abou-Abdallah-Annatholi, who taught him grammar,
-dialectics, the geometry of Euclid, and the astronomy
-of Ptolemy. But Avicenna quitted his tuition because
-he could not give him the solution of a problem
-in logic. He attached himself to a merchant, who
-taught him arithmetic, and made him acquainted with
-the Indian numerals from which our own are derived.
-He then undertook a journey to Bagdad, where he
-studied philosophy under the great Peripatician, Abou-Nasr-Alfarabi,
-a disciple of Mesue the elder. At the
-same time he applied himself to medicine, under the
-tuition of the Nestorian, Abou-Sahel-Masichi. He
-<span class="pagenum" id="Page_134">134</span>
-informs us himself that he applied with an extraordinary
-ardour to the study of the sciences. He was in
-the habit of drinking great quantities of liquids during
-the night, to prevent him from sleeping; and he often
-obtained in a dream a solution of those problems at
-which he had laboured in vain while he was awake.
-When the difficulties to be surmounted appeared to
-him too great, he prayed to God to communicate to
-him a share of his wisdom; and these prayers, he assures
-us, were never offered in vain. The metaphysics
-of Aristotle was the only book which he could not
-comprehend, and after reading them over forty times,
-he threw them aside with great anger at himself.</p>
-
-<p>Already, at the age of sixteen, he was a physician
-of eminence; and at eighteen he performed a brilliant
-cure on the calif Nuhh, which gave him such celebrity
-that Mohammed, Calif of Chorazan, invited him to
-his palace; but Avicenna rather chose to reside at
-Dschordschan, where he cured the nephew of the
-calif Kabus of a grievous distemper.</p>
-
-<p>Afterwards he went to Ray, where he was appointed
-physician to Prince Magd-Oddaula. Here he composed
-a dictionary of the sciences. Sometime after
-this he was raised to the dignity of vizier at Hamdan;
-but he was speedily deprived of his office and thrown
-into prison for having favoured a sedition. While incarcerated
-he wrote many works on medicine and
-philosophy. By-and-by he was set at liberty, and
-restored to his dignity; but after the death of his protector,
-Schems-Oddaula, being afraid of a new attempt
-to deprive him of his liberty, he took refuge in
-the house of an apothecary, where he remained long
-concealed and completely occupied with his literary
-labours. Being at last discovered he was thrown into
-the castle of Berdawa, where he was confined for four
-months. At the end of that time a fortunate accident
-enabled him to make his escape, in the disguise of a
-monk. He repaired to Ispahan, where he lived much
-<span class="pagenum" id="Page_135">135</span>
-respected at the court of the calif Ola-Oddaula. He
-did not live to a great age, because he had worn out
-his constitution by too free an indulgence of women
-and wine. Having been attacked by a violent colic,
-he caused eight injections, prepared from long pepper,
-to be thrown up in one day. This excessive use of so
-irritating a remedy, occasioned an excoriation of the
-intestines, which was followed by an attack of epilepsy.
-A journey to Hamdan, in company with the calif,
-and the use of mithridate, into which his servant by
-mistake had put too much opium, contributed still further
-to put an end to his life. He had scarcely arrived
-at the town when he died in the fifty-eighth year of
-his age, in the year 1036.</p>
-
-<p>Avicenna was the author of the immense work entitled
-“Canon,” which was translated into Latin, and
-for five centuries constituted the great standard, the infallible
-guide, the confession of faith of the medical
-world. All medical knowledge was contained in it;
-and nothing except what was contained in it was considered
-by medical men as of any importance. When
-we take a view of the Canon, and compare it with the
-writings of the Greeks, and even of the Arabians, that
-preceded it, we shall find some difficulty in accounting
-for the unbounded authority which he acquired over
-the medical world, and for the length of time during
-which that authority continued.</p>
-
-<p>But it must be remembered, that Avicenna’s reign
-occupies the darkest and most dreary period of the
-history of the human mind. The human race seems to
-have been asleep, and the mental faculties in a state
-of complete torpor. Mankind, accustomed in their
-religious opinions to obey blindly the infallible decisions
-of the church, and to think precisely as the
-church enjoined them to think, would naturally look
-for some means to save them the trouble of thinking
-on medical subjects; and this means they found fortunately
-in the canons of Avicenna. These canons,
-<span class="pagenum" id="Page_136">136</span>
-in their opinion, were equally infallible with the decisions
-of the holy father, and required to be as implicitly
-obeyed. The whole science of medicine was
-reduced to a simple perusal of Avicenna’s Canon, and
-an implicit adherence to his rules and directions.</p>
-
-<p>When we compare this celebrated work with the
-medical writings of the Greeks, and even of the
-Arabians, the predecessors of Avicenna, we shall be
-surprised that it contains little or nothing which can
-be considered as original; the whole is borrowed from
-the writings of Galen, or &AElig;tius, or Rhazes: scarcely
-ever does he venture to trust his own wings, but rests
-entirely on the sagacity of his Greek and Arabian
-predecessors. Galen is his great guide; or, if he ever
-forsake him, it is to place himself under the direction
-of Aristotle.</p>
-
-<p>The Canon contains a collection of most of the
-valuable information contained in the writings of the
-ancient Greek physicians, arranged, it must be allowed,
-with great clearness. The Hhawi of Razes is almost
-as complete; but it wants the <i>lucidus ordo</i> which
-distinguishes the Canon of Avicenna. I conceive that
-the high reputation which Avicenna acquired, was
-owing to the care which he bestowed upon his arrangement.
-He was undoubtedly a man of abilities, but
-not of inventive genius. There is little original matter
-in the Canon. But the physicians in the west, while
-Avicenna occupied the medical sceptre, had no opportunity
-of judging of the originality of their oracle,
-because they were unacquainted with the Greek language,
-and could not therefore consult the writings of
-Galen or &AElig;tius, except through the corrupt medium
-of an Arabian version.</p>
-
-<p>But it is not the medical reputation of Avicenna that
-induced me to mention his name here. Like all the
-Arabian physicians, he was also a chemist; and his
-chemical tracts having been translated into Latin, and
-published in Western Europe, we are enabled to judge
-<span class="pagenum" id="Page_137">137</span>
-of their merit, and to estimate the effect which they may
-have had upon the progress of chemistry. The first
-Latin translation of the chemical writings of Avicenna
-was published at Basil in 1572; they consist of two
-separate books; the first, under the name of “Porta
-Elementorum,” consists of a dialogue between a master
-and his pupil, respecting the mysteries of Alchymy.
-He gives an account of the four elements, fire, air,
-water, earth, and gives them their usual qualities of
-dry, moist, hot, and cold. He then treats of air, which,
-he says, is the food of fire, of water, of honey, of the
-mutual conversion of the elements into each other; of
-milk and cheese, of the mixture of fire and water, and
-that all things are composed of the four elements.
-There is nothing in this tract which has any pretension
-to novelty; he merely retails the opinions of the Greek
-philosophers.</p>
-
-<p>The other treatise is much larger, and professes to
-teach the whole art of alchymy; it is divided into ten
-parts, entitled “Dictiones.” The first diction treats of
-the philosopher’s stone in general; the second diction
-treats of the method of converting light things into
-heavy, hard things into soft; of the mutation of the
-elements; and of some other particulars of a nature not
-very intelligible. The third diction treats of the formation
-of the elixir; and the same subject is continued
-in the fourth.</p>
-
-<p>The fifth diction is one of the most important in the
-whole treatise; it is in general intelligible, which is
-more than can be said of those that precede it. This
-diction is divided into twenty-eight chapters: the first
-chapter treats of copper, which, he says, is of three
-kinds; permenian copper, natural copper, and Navarre
-copper. But of these three varieties he gives no account
-whatever; though he enlarges a good deal on the
-qualities of copper&mdash;not its properties, but its supposed
-medicinal action. It is hot and dry, he says,
-<span class="pagenum" id="Page_138">138</span>
-but in the calx of it there is humidity. His account
-of the composition of copper is the same with that of
-Geber.</p>
-
-<p>The second chapter treats of lead, the third of tin,
-and in the remaining chapters he treats successively
-of brass, iron, gold, silver, marcasite, sulphuret of
-antimony, which is distinguished by the name of
-alcohol; of soda, which he says is the juice of a plant
-called <i>sosa</i>. And he gives an unintelligible process
-by which it is extracted from that plant, without mentioning
-a syllable about the combustion to which it is
-obvious that it must have been subjected.</p>
-
-<p>In the twelfth chapter he treats of saltpetre, which,
-he says, is brought from Sicily, from India, from
-Egypt, and from Herminia. He describes several
-varieties of it, but mentions nothing about its characteristic
-property of deflagrating upon burning coals.
-He then treats successively of common salt, of sal-gem,
-of vitriol, of sulphur, of orpiment, and of sal ammoniac,
-which, he says, comes from Egypt, from India, and
-from Forperia. In the nineteenth and subsequent
-chapters he treats of aurum vivum, of hair, of urine, of
-eggs, of blood, of glass, of white linen, of horse-dung,
-and of vinegar.</p>
-
-<p>The sixth diction, in thirty-three chapters, treats of
-the calcination of the metals, of sublimation, and of
-some other processes. I think it unnecessary to be
-more particular, because I cannot perceive any thing
-in it that had not been previously treated of by Geber.</p>
-
-<p>The seventh diction treats of the preparation of
-blood and eggs, and the method of dividing them into
-their four elements. It treats also of the elixir of silver,
-and the elixir of gold; but it contains no chemical
-fact of any importance.</p>
-
-<p>The eighth diction treats of the preparation of the
-ferment of silver, and of gold. The ninth diction treats
-of the whole magistery, and of the nuptials of the sun
-<span class="pagenum" id="Page_139">139</span>
-and moon; that is, of gold and silver. The tenth diction
-treats of weights.</p>
-
-<p>The chemical writings of Avicenna are of little
-value, and apply chemistry rather to the supposed
-medical qualities of the different substances treated of,
-than to the advancement of the science. All the
-chemical knowledge which he possesses is obviously
-drawn from Geber. Geber, then, may be looked upon
-as the only chemist among the Arabians to whom we
-are indebted for any real improvements and new facts.
-It is true that the Arabian physicians improved considerably
-the materia medica of the Greeks, and introduced
-many valuable medicines into common use
-which were unknown before their time. It is enough
-to mention corrosive sublimate, manna, opium, asafœtida.
-It would be difficult to make out many of
-the vegetable substances used by the Arabian chemists;
-because the plants which they designated by
-particular names, can very seldom be identified.
-Botany at that time had made so little progress, that
-no method was known of describing plants so as to
-enable other persons to determine what they were.
-<span class="pagenum" id="Page_140">140</span></p>
-
-<hr class="chap" />
-<h2 id="CHAPTER_IV">CHAPTER IV<br />
-
-<span class="large">OF THE PROGRESS OF CHEMISTRY UNDER PARACELSUS AND
-HIS DISCIPLES.</span></h2>
-
-<p>Hitherto we have witnessed only the first rude
-beginnings, or, as it were, the early dawn of the chemical
-day. It is from the time of Paracelsus that the
-true commencement of chemical investigations is to be
-dated. Not that Paracelsus or his followers understood
-the nature of the science, or undertook any
-regular or successful investigation. But Paracelsus
-shook the medical throne of Galen and Avicenna to
-its very foundation; he roused the latent energies of
-the human mind, which had for so long a period lain
-torpid; he freed medical men from those trammels,
-and put an end to that despotism which had existed
-for five centuries. He pointed out the importance of
-chemical medicines, and of chemical investigations, to
-the physician. This led many laborious men to turn
-their attention to the subject. Those metals which
-were considered as likely to afford useful medicines,
-mercury for example, and antimony, were exposed to
-the action of an infinite number of reagents, and a
-prodigious collection of new products obtained and
-introduced into medicine. Some of these were better,
-and some worse, than the preparations formerly employed;
-but all of them led to an increase of the
-stock of chemical knowledge, which now began to
-accumulate with considerable rapidity. It will be
-<span class="pagenum" id="Page_141">141</span>
-proper, therefore, to give a somewhat particular account
-of the life and opinions of Paracelsus, so far as
-they can be made out from his writings, because,
-though he was not himself a scientific chemist, he may
-be truly considered as the man through whose means
-the stock of chemical knowledge was accumulated,
-which was afterwards, by the ingenuity of Beccher,
-and Stahl, moulded into a scientific form.</p>
-
-<p>Philippus Aureolus Theophrastus Paracelsus Bombast
-ab Hohenheim (as he denominates himself) was
-born at Einsideln, two German miles from Zurich.
-His father was called William Bombast von Hohenheim.
-He was a very near relation of George Bombast von
-Hohenheim, who became afterwards grand master of
-the order of Johannites. William Bombast von Hohenheim
-practised medicine at Einsideln.<a id="FNanchor_143" href="#Footnote_143" class="fnanchor">143</a> After
-receiving the first rudiments of his education in his
-native city, he became a wandering scholastic, as was
-then the custom with poor scholars. He wandered
-from province to province, predicting the future by
-the position of the stars, and the lines on the hand,
-and exhibiting all the chemical processes which he had
-learned from founders and alchymists. For his initiation
-in alchymy, astrology, and medicine, he was indebted
-to his father, who was much devoted to these
-three sciences. Paracelsus mentions also the names
-of several ecclesiastics from whom he received chemical
-information; among others, Tritheimius, abbot of
-Spanheim; Bishop Scheit, of Stettbach; Bishop Erhart,
-of Laventall; Bishop Nicolas, of Hippon; and Bishop
-Matthew Schacht. He seems also to have served
-some years as an army surgeon, for he mentions many
-cures which he performed in the Low Countries, in the
-States of the Church, in the kingdom of Naples, and
-during the wars against the Venetians, the Danes, and
-the Dutch.
-<span class="pagenum" id="Page_142">142</span></p>
-
-<p>There is some uncertainty whether he received a
-regular college education, as was then the practice
-with all medical men. He acknowledges himself that
-his medical antagonists reproached him with never
-having frequented their schools; and he is perpetually
-affirming, that a physician should receive all his
-knowledge from God, and not from man. But if we
-can trust his own assertions, there can be no doubt
-that he took a regular medical degree, which implies
-a regular college education. He tells us, in his preface
-to his Chirurgia Magna, that he visited the universities
-of Germany, France, and Italy. He assures
-his readers, that he was the ornament of the schools
-where he studied. He even speaks of the oath which
-he was obliged to take when he received his medical
-degree; but where he studied, or where and when he
-received his medical degree, are questions which neither
-Paracelsus nor his disciples, nor his biographers,
-have enabled us to solve. If he ever attended a
-university, he must have neglected his studies, otherwise
-he could not have been ignorant, as he confessedly
-was, of the very first elements of the most common
-kinds of knowledge. But if he neglected the universities,
-he laboured long and assiduously with the rich
-Sigismond Fuggerus, of Schwartz, in order to learn
-the true secret of forming the philosopher’s stone.</p>
-
-<p>He gives us some details of the numerous journeys
-that he made, as was customary with the alchymists
-of the time, into the mountains of Bohemia, the East,
-and Sweden, to inspect the mines, to get himself initiated
-into the mysteries of the eastern adepts, to
-inspect the wonders of nature, and to view the celebrated
-diamond mountain, the position of which, however,
-he unfortunately forgets to specify.</p>
-
-<p>In the preface to his Chirurgia Magna, he informs
-us that he traversed Spain, Portugal, England, Prussia,
-Poland, and Transylvania; where he not only
-profited by the information of the medical men with
-<span class="pagenum" id="Page_143">143</span>
-whom he became acquainted, but that he drew much
-precious information from old women, gipsies, conjurors,
-and chemists.<a id="FNanchor_144" href="#Footnote_144" class="fnanchor">144</a> He spent several years in
-Hungary; and informs us that at Weissenburg, in
-Croatia, and in Stockholm, he was taught by several
-old women to prepare drinks capable of curing ulcers.
-He is said also to have made a voyage into Egypt,
-and even into Tartary; and he accompanied the son
-of the Kan of the Tartars to Constantinople, in order
-to learn the secret of the philosopher’s stone from
-Trismogin, who inhabited that capital. This prodigious
-activity, this constant motion from place to place,
-left him but little leisure for reading: accordingly he
-informs us himself, that during the space of ten years
-he never opened a book, and that his whole library
-consisted only of six sheets. The inventory of his
-books, drawn up after his death, confirms this recital;
-for they consisted only of the Bible, the Concordance
-to the Bible, the New Testament, and the Commentaries
-of St. Jerome on the Evangelists.</p>
-
-<p>We know not at what period he returned back to
-Germany; but at the age of thirty-three the great
-number of fortunate cures which he had performed
-rendered him an object of admiration to the people,
-and of jealousy to the rival physicians of the time.
-He assures us that he cured eighteen princes whose
-diseases had been aggravated by the practitioners devoted
-to the system of Galen. Among others he cured
-Philip, Margrave of Baden, of a dysentery, who promised
-him a great reward, but did not keep his promise,
-and even treated him in a way unworthy of that
-<span class="pagenum" id="Page_144">144</span>
-prince. This cure, however, and others of a similar
-nature, added greatly to his celebrity; and in order
-to raise his reputation to the highest possible pitch, he
-announced publicly that he was able to cure all the
-diseases hitherto reckoned incurable; and that he had
-discovered an elixir, by means of which the life of
-man might be prolonged at pleasure to any extent
-whatever. He began the practice, which has since
-been so successfully followed in this country, of dispensing
-medicines gratuitously to the poor, in order to
-induce the rich to apply to him for assistance when
-they were overtaken with diseases.</p>
-
-<p>In the year 1526 Paracelsus was appointed professor
-of physic and surgery in the University of
-Basil. This appointment was given him, it is said,
-by the recommendation of Œcolampadius. He introduced
-the custom of lecturing in the common language
-of the country, as is at present the universal
-practice: but during the time of Paracelsus, and long
-after indeed, all lectures were delivered in Latin. The
-new method which he followed in explaining the theory
-and practice of the art; the numerous fortunate cures
-which he stated in confirmation of his method of treatment;
-the emphasis with which he spoke of his secrets
-for prolonging life, and for curing every kind of disease
-without distinction, but still more his lecturing in
-a language which was understood by the whole population,
-drew to B&acirc;le an immense crowd of idle, enthusiastic,
-and credulous hearers.</p>
-
-<p>The lectures which he delivered on Practical Medicine
-still remain, written in a confused mixture of
-German and barbarous Latin, and containing little or
-nothing except a farrago of empirical remedies, advanced
-with the greatest confidence. They have a
-much greater resemblance to a collection of quack
-advertisements than to the sober lectures of a professor
-in a university. In the month of November,
-1526, he wrote to Christopher Clauser, a physician in
-<span class="pagenum" id="Page_145">145</span>
-Zurich, that as Hippocrates was the first physician
-among the Greeks, Avicenna among the Arabians,
-Galen among the Pergamenians, and Marsilius among
-the Italians, so he was beyond dispute the greatest
-physician among the Germans. Every country produces
-an illustrious physician, whose medicines are
-adapted to the climate in which he lived, but not
-suited to other countries. The remedies of Hippocrates
-were good to the Greeks, but not suitable to
-the Germans; thus it was necessary that an inspired
-physician should spring up in every country, and that
-he was the person destined to teach the Germans the
-art of curing all diseases.<a id="FNanchor_145" href="#Footnote_145" class="fnanchor">145</a></p>
-
-<p>Paracelsus began his professorial career by burning
-publicly, in his class-room, and in the presence of his
-pupils, the works of Galen and Avicenna, assuring his
-hearers that the strings of his shoes possessed more
-knowledge than those two celebrated physicians. All
-the universities united had not, he assured them, as
-much knowledge as was contained in his own beard,
-and the hairs upon his neck were better informed than
-all the writers that ever existed put together. To
-give the reader an idea of the arrogant absurdity of
-his pretensions, I shall translate a few sentences of the
-preface to his tract, entitled “Paragranum,” where he
-indulges in his usual strain of rodomontade: “Me,
-me you shall follow, you Avicenna, you Galen, you
-Rhazes, you Montagnana, you Mesue. I shall not
-follow you, but you shall follow me. You, I say, you
-inhabitants of Paris, you inhabitants of Montpelier,
-you Suevi, you Misnians, you inhabitants of Cologne,
-you inhabitants of Vienna; all you whom the Rhine
-and the Danube nourish, you who inhabit the islands
-<span class="pagenum" id="Page_146">146</span>
-of the sea; you also Italy, you Dalmatia, you Athens,
-you Greek, you Arabian, you Israelite&mdash;I shall not
-follow you, but you shall follow me. Nor shall any
-one lurk in the darkest and most remote corner whom
-the dogs shall not piss upon. I shall be the monarch,
-the monarchy shall be mine. If I administer, and I
-bind up your loins, is he with whom you are at present
-delighted a Cacophrastus? This ordure must be eaten
-by you.”</p>
-
-<p>“What will your opinion be when you see your
-Cacophrastus constituted the chief of the monarchy?
-What will you think when you see the sect of Theophrastus
-leading on a solemn triumph, if I make you
-pass under the yoke of my philosophy? your Pliny
-will you call Cacopliny, and your Aristotle, Cacoaristotle?
-If I plunge them together with your Porphyry,
-Albertus, &amp;c., and the whole of their compatriots
-into my <i>necessary</i>.” But the terms become
-now so coarse and indelicate, that I cannot bring
-myself to proceed further with the translation. Enough
-has been given to show the extreme arrogance and
-folly of Paracelsus.</p>
-
-<p>So far, however, was this impudence and grossness
-from injuring the interest of Paracelsus, that we are
-assured by Ramus and Urstisius that it contributed still
-further to increase it. The coarseness of his language
-was well suited to the vulgarity of the age; and his arrogance
-and boasting were considered, as usual, as a
-proof of superior merit. The cure which he performed
-on Frobenius, drew the attention of Erasmus himself,
-who consulted him about the diseases with which he
-was afflicted; and the letters that passed between
-them are still preserved. The epistle of Paracelsus is
-short, enigmatical, and unintelligible; that of Erasmus
-is distinguished by that clearness and elegance
-which characterize his writings.<a id="FNanchor_146" href="#Footnote_146" class="fnanchor">146</a> But Frobenius died
-<span class="pagenum" id="Page_147">147</span>
-in the month of October, 1527, and the antagonists
-of Paracelsus attributed his death (and probably with
-justice) to the violent remedies which had been administered
-to a man whose constitution had been
-destroyed by the gout.</p>
-
-<p>His death contributed not a little to tarnish the
-glory of Paracelsus: but he suffered the greatest
-injury from the habits of intoxication in which he indulged,
-and from the vulgarity of the way in which
-he spent his time. He hardly ever went into his
-class-room to deliver a lecture till he was half intoxicated,
-and scarcely ever dictated to his secretaries
-till he had lost the use of his reason by a too liberal
-indulgence in wine. If he was summoned to visit a
-patient, he scarcely ever went but in a state of intoxication.
-Not unfrequently he passed the whole
-night in the alehouse, in the company of peasants, and
-when morning came, was quite incapable of performing
-the duties of his station. On one occasion, after
-a debauch, which lasted the whole night, he was called
-next morning to visit a patient; on entering the room,
-he inquired if the sick person had taken any thing:
-“Nothing,” was the answer, “except the body of our
-Lord.” “Since you have already,” says he, “provided
-yourself with another physician, my presence here is unnecessary,”
-and he left the apartment instantly. When
-Albertus Basa, physician to the king of Poland, visited
-Paracelsus in the city of Basel, he carried him to see
-a patient whose strength was completely exhausted,
-and which, in his opinion, it was impossible to restore;
-but Paracelsus, wishing to make a parade of his skill,
-administered to him three drops of his laudanum, and
-invited him to dine with him next day.<a id="FNanchor_147" href="#Footnote_147" class="fnanchor">147</a> The invitation
-<span class="pagenum" id="Page_148">148</span>
-was accepted, and the sick man dined next day
-with his physician.</p>
-
-<p>Towards the end of the year 1527 a disgraceful
-dispute into which he entered brought his career, as
-a professor, to a sudden termination. The canon
-Cornelius, of Lichtenfels, who had been long a martyr
-to the gout, employed him as his physician, and promised
-him one hundred florins if he could cure him.
-Paracelsus made him take three pills of laudanum,
-and having thus freed him from pain, demanded the
-sum agreed upon; but Lichtenfels refused to pay him
-the whole of it. Paracelsus summoned him before
-the court, and the magistrate of Basle decided that
-the canon was bound to pay only the regular price of
-the medicine administered. Irritated at this decision,
-our intoxicated professor uttered a most violent invective
-against the magistrate, who threatened to
-punish him for his outrageous conduct. His friends
-advised him to save himself by flight. He took their
-advice, and thus abdicated his professorship. But, by
-this time, his celebrity as a teacher had been so completely
-destroyed by his foolish and immoral conduct,
-that he had lost all his hearers. In consequence of
-this state of things, his flight from Basle produced no
-sensation whatever in that university.</p>
-
-<p>Paracelsus betook himself, in the first place, to
-Alsace, and sent for his faithful follower, the bookseller,
-Operinus, together with the whole of his chemical
-apparatus. In 1528 we find him at Colmar,
-where he recommenced his ambulating life of a theosophist,
-which he had led during his youth. His book
-upon syphilis, known at that time by the name of
-Morbus Gallicus, was dedicated at Colmar, to the chief
-magistrate of Colmar, Hieronymus Bonerus.<a id="FNanchor_148" href="#Footnote_148" class="fnanchor">148</a> In 1531
-he was at Saint-Gallen; in 1535, at Pfeffersbade, and
-in 1536, at Augsburg, where he dedicated his Chirurgia
-<span class="pagenum" id="Page_149">149</span>
-Magna to Malhausen. At the request of John de
-Leippa, Marshal of Bohemia, he undertook a journey
-into Moravia; as that nobleman, having been informed
-that Paracelsus understood the method of curing the
-gout radically, was anxious to put himself under his
-care. Paracelsus lived for a long time at Kroman,
-and its environs. John de Leippa, instead of receiving
-any benefit from the medicines administered to
-him, became daily worse, and at last died. This was
-the fate also of the lady of Zerotin, in whom the
-remedies of Paracelsus produced no fewer than twenty-four
-epileptic fits in one day. Paracelsus, instead of
-waiting the disgrace with which the death of this lady
-would have overwhelmed him, announced his intention
-of going to Vienna, that he might see how they would
-treat him in that capital.</p>
-
-<p>It is said, that from Vienna he went into Hungary;
-but in 1538, we find him in Villach, where he dedicated
-his Chronica et Origo Carinthi&aelig; to the states of
-Carinthia.<a id="FNanchor_149" href="#Footnote_149" class="fnanchor">149</a> His book, De Natura Rerum, had been
-dedicated to Winkelstein, and the dedication is dated
-also at Villach, in the year 1537.<a id="FNanchor_150" href="#Footnote_150" class="fnanchor">150</a> In 1540 he was
-at Mindelheim, and in 1541, at Strasburg, where he
-died, in St. Stephen’s hospital, in the forty-eighth
-year of his age.</p>
-
-<p>To form an accurate idea of this most extraordinary
-man, we must attend to his habits, and to the situation
-in which he was placed. He had acquired such
-a habit of moving about, that he assures us himself he
-found it impossible for him to continue for any length
-of time in one place. He was always surrounded by
-a number of followers, whom neither his habits of intoxication,
-nor the foolish and immoral conduct in
-which he was accustomed to indulge, could induce
-to forsake him. The most celebrated of these was
-Operinus, a printer at Basle, on whom Paracelsus
-<span class="pagenum" id="Page_150">150</span>
-lavishes the most excessive praises, in his book De
-Morbo Gallico. But Operinus loaded his master with
-obloquy, being provoked at him because he had not
-made him acquainted with the secret of the philosopher’s
-stone, as he had promised to do. We must
-therefore be cautious in believing the stories that he
-relates to the discredit of his master. We know the
-names of two others of his followers; Francis, who
-assures us that Paracelsus was devoted to the transmutation
-of metals; and George Vetter, who considered
-him as a magician; as was the opinion also of
-Operinus. Paracelsus himself, speaks of Dr. Cornelius,
-whom he calls his secretary, and in honour of
-whom he wrote several of his libels. Other libels are
-dedicated to Doctors Peter, Andrew, and Ursinus, to
-the licentiate Pancrace, and to Mr. Raphael. On
-this occasion he complains bitterly of the infidelity of
-his servants, who, he says, had succeeded in stealing
-from him several of his secrets; and had by this means
-been enabled to establish their reputation. He accuses
-equally the barbers and bathers that followed him, and
-is no less severe upon the physicians of every country
-through which he travelled.</p>
-
-<p>When we attempt to form an accurate conception of
-the medical and philosophical opinions of this singular
-man, we find ourselves beset with almost insurmountable
-difficulties. His statements are so much at
-variance with each other, in his different pieces, and
-so much confusion reigns with respect to the order of
-publication, that we know not what to fix on as his last
-and maturest opinions. His style is execrable; filled
-with new words of his own coining, and of mysticisms
-either introduced to excite the admiration of the ignorant,
-or from the fanaticism and credulity of the
-writer, who was undoubtedly, to a considerable extent,
-the dupe of his own impostures. That he was in possession
-of the philosopher’s stone, or of a medicine
-capable of prolonging life to an indefinite length, as
-<span class="pagenum" id="Page_151">151</span>
-he all along asserted, he could not himself believe;
-but he had boasted so long and so loudly of his wonderful
-cures, and of the efficacy of his medicines, that
-there can be no doubt that he ultimately placed implicit
-faith in them. The blunders of the transcribers
-whom he employed to copy his works, may perhaps
-account for some of the contradictions which they
-contain. But how can we look for a regular system
-of opinions from a man who generally dictated his
-works when in a state of intoxication, and thus laboured
-under an almost constant deprivation of reason.</p>
-
-<p>His obscurity was partly the effect of design, and
-no doubt was intended to exalt the notions entertained
-of his profundity. He uses common words in new
-significations, without giving any indication of the
-change which he introduced. Thus <i>anatomy</i>, in the
-writings of Paracelsus, signifies not the dissection of
-dead animals to determine their structure, but it
-means the nature, force, and magical designation of
-a thing. And as, according to the Platonic and
-Cabalistic theory, every earthly body is formed after
-the model of a heavenly body, Paracelsus calls <i>anatomy</i>
-the knowledge of that model, of that ideal, or of
-that paradigm after which all things are created. He
-terms the fundamental force of a thing <i>a star</i>, and
-defines alchymy the art of drawing out the stars of
-metals. The star is the source of all knowledge.
-When we eat, we introduce into our bodies <i>the star</i>,
-which is then modified, and favours nutrition.</p>
-
-<p>It is probable that many of his obscure and unintelligible
-expressions are the fruit of ignorance. Thus
-he uses the term <i>pagoyus</i>, instead of <i>paganus</i>. He
-gives the name of <i>pagoy&aelig;</i> to the four <i>entities</i>, or causes
-of diseases, founded on the influence of the stars, to
-the elementary qualities; to the occult qualities, and
-to the influence of spirits; because these had been
-already admitted by the <i>Pagans</i>. But the fifth <i>entity</i>,
-or cause of disease, which has God immediately for
-<span class="pagenum" id="Page_152">152</span>
-its author, is <i>non pagoya</i>. The <i>undimia</i> of Paracelsus
-is our <i>œdema</i>; only he applies the name to every kind
-of dropsy. The Latin word <i>tonitru</i>, we find is declined
-by Paracelsus. Thus he says, <i>lapis tonitrui</i>. The
-well-known line of Ovid,
-
-<span class="table">
-<span class="trow">Tollere nodosam nescit medicina podagram,<br /></span>
-</span>
-
-He travestied into
-
-<span class="table">
-<span class="trow">Nescit tartaream Roades curare podagram.<a id="FNanchor_151" href="#Footnote_151" class="fnanchor">151</a><br /></span>
-</span>
-
-<i>Roades</i>, he says, means medicines for horses; and
-if any person wishes a more elegant verse, he may
-make it for himself.<a id="FNanchor_152" href="#Footnote_152" class="fnanchor">152</a> He employs, also, a great number
-of words to which no meaning whatever can be
-attached; and to which, in all probability, he himself
-had affixed none.</p>
-
-<p>As is the case with all fanatics, he treated with contempt
-every kind of knowledge acquired by labour
-and application; and boasted that his wisdom was
-communicated to him directly by God Almighty. The
-theosophist who is worthy of partaking of the divine
-light, has no occasion for adopting a positive religion,
-nor of subjecting himself to any kind of religious ceremony.
-The divine light within, which assimilates him
-to the Deity, more than compensates for all these vulgar
-usages, and raises the illuminated votary far above the
-beggarly elements of external worship. Accordingly,
-Paracelsus has been accused of treating the public
-worship of the Deity with contempt. Not satisfied
-with the plain sense of the book, he attempted to explain
-in a mystical manner the words and syllables of
-the Bible. He accused Luther of not going far enough.
-“Luther,” says he, “is not worthy of untying the
-strings of my shoes: should I undertake a reformation,
-I would begin by sending the pope and the reformers
-themselves to school.” God, says Paracelsus, is the
-<span class="pagenum" id="Page_153">153</span>
-first and most excellent of writers. The Holy Scripture
-conducts us to all truth, and teaches us all
-things. But medicine, philosophy, and astronomy,
-are among the number of things. Therefore, when we
-want to know what magical medicine is, we must consult
-the Apocalypse. The Bible, with its paraphrases,
-is the key to the theory of diseases. It puts it in our
-power to understand St. John, who, like Daniel, Ezekiel,
-Moses, &amp;c., was a magician, a cabalist, a diviner.
-The first duty of a physician is to study the Cabala,
-without which he must every moment commit a thousand
-blunders. “Learn,” says he, “the cabalistic
-art, which includes under it all the others.” “Man
-invents nothing, the devil invents nothing; it is God
-alone who unveils to us the light of nature.” “God
-honoured at first with his illumination the blind pagans,
-Apollo, &AElig;sculapius, Machaon, Podalirius, and Hippocrates,
-and imparted to them the genius of medicine;
-their successors were the sophists.” One would suppose,
-from this passage, that Paracelsus had read and
-studied Hippocrates, and that he held him in high estimation.
-But the commentaries which he has left on
-some of the aphorisms, show evidently that he did
-not even understand the Greek physician. “The
-compassion of God,” says he, “is the only foundation
-of medical science, and not a knowledge of the great
-masters, or of the writings which they have left in Greek
-and Latin.” “God often acts in dreams by the light
-of nature, and points out to man the manner of curing
-diseases.” “This knowledge renders all those objects
-visible which would otherwise escape the sight; and
-when faith is joined with it, nothing is then impossible
-to the theosophist, who may transport the ocean to
-the top of Mount &AElig;tna, and Olympus into the Red
-Sea.” Paracelsus predicts that by the year 1590
-Christian theosophy would be generally spread over
-the world, and that the Galenical schools would be
-almost or entirely overthrown.
-<span class="pagenum" id="Page_154">154</span></p>
-
-<p>We find in Paracelsus some traces of the opinions
-of the Gnostics and Arians, who considered Christ as
-the first emanation of the Deity. He calls the first
-man <i>parens hominis</i>; and makes all spirits emanate
-from him. He is the <i>limbus minor</i>, or the last creature,
-into whom enters the great <i>limbus</i>, or the seed
-of all the creatures, the infinite being. All the sciences,
-and all the arts of man, are derived from this
-great <i>limbus</i>; and he who can sink himself in the little
-<i>limbus</i>, that is to say, in Adam, and who can communicate
-by faith with Jesus Christ, may invoke all
-<i>spirits</i>. Those who owe their science to this <i>limbus</i>,
-are the best informed; those who derive it from the
-stars, occupy the last rank; and those who owe it to
-the light of nature, are intermediate between the preceding.
-Jesus Christ, in his capacity of <i>limbus minor</i>
-and first man, being always an emanation of the Divinity;
-and, consequently, a subordinate personage.
-These ideas explain to us why Paracelsus passed for
-an Arian, and was supposed not to believe in the Divinity
-of Jesus Christ. He was of opinion that the
-faithful performed miracles, and operated magical
-cures by their simple confidence in God the Father,
-and not by their faith in Christ; but he adds, however,
-that we ought to pray to Jesus, in order to obtain his
-intercession.</p>
-
-<p>From the preceding attempt to explain the opinions
-of Paracelsus, it will be evident to the reader that he
-was both a fanatic and impostor, and that his theory
-(if such a name can be given to the reveries of a
-drunkard), consisted in uniting medicine with the doctrines
-of the Cabala. A few more observations will
-be necessary to develop his dogmas still further.</p>
-
-<p>Every body, in his opinion, and man in particular,
-is double, consisting of a material and spiritual
-substance.<a id="FNanchor_153" href="#Footnote_153" class="fnanchor">153</a> The spiritual, which may be called the
-<span class="pagenum" id="Page_155">155</span>
-<i>sideric</i>, results from the celestial influences; and we
-may trace after it a figure capable of producing all
-kinds of magical effects. When we can act upon the
-body itself, we act at the same time upon the spiritual
-form by characters and conjurations.<a id="FNanchor_154" href="#Footnote_154" class="fnanchor">154</a> Yet, in another
-passage, he blames all magical ceremonies, and ascribes
-them to want of faith. The celestial intelligences
-impress upon material bodies certain signs,
-which manifest their influence. The perfection of
-art consists in understanding the meaning of these
-signs, and in determining from them the nature, qualities,
-and essence of a body. Adam, the first man,
-had a perfect knowledge of the Cabala; he could interpret
-the signatures of all things. It was this which
-enabled him to assign to the animals names which
-suited them best. A man who renounces all sensuality,
-and is blindly obedient to the will of God, is capable
-of taking a share in the actions which celestial intelligences
-perform; and consequently is possessed of
-the philosopher’s stone. Never does he want any
-thing; all creatures in earth and in heaven are obedient
-to him; he can cure all diseases, and prolong
-his life as long as he pleases; because he possesses
-the tincture which Adam and the patriarch’s before
-the flood employed to prolong the term of their existence.<a id="FNanchor_155" href="#Footnote_155" class="fnanchor">155</a>
-Beelzebub, the chief of the demons, is also
-subject to the power of magic: and who can blame
-the theosophist for believing in the devil? He ought,
-however, to take care to prevent this malignant spirit
-from commanding him. Paracelsus was often wont
-to say, “If God does not aid me, the devil will help
-me.”
-<span class="pagenum" id="Page_156">156</span></p>
-
-<p>Pantheism was one of the principal dogmas of the
-Cabala; and Paracelsus adopts it in all its grossness.
-He affirms perpetually that every thing is animated in
-the universe; that every thing which exists, eats,
-drinks, and voids excrements: even minerals and
-liquids take food and void the digested remains of
-their nourishment.<a id="FNanchor_156" href="#Footnote_156" class="fnanchor">156</a> This opinion leads necessarily to
-the admission of a great number of spiritual substances,
-intermediate between material and immaterial in every
-part of the sublunary world, in water, air, earth, and
-fire; who, as well as man, eat, drink, converse, beget
-children; but which approach pure spirits in this, that
-they are more transparent, and infinitely more agile
-than all other animal bodies. Man possesses a soul,
-of which these pure spirits are destitute. Hence it
-happens that these spiritual substances are at once
-body and spirit without a soul. When they die (for
-like the human race they are subject to death), no
-soul remains. Like us they are exposed to diseases.
-Their names vary according to the places that they
-occupy. When they inhabit the air, they are called
-<i>sylphs</i>; when the water, <i>nymphs</i>; when the earth,
-<i>pigmies</i>; when the fire, <i>salamanders</i>.<a id="FNanchor_157" href="#Footnote_157" class="fnanchor">157</a> The inhabitants
-of the waters are also called <i>undin&aelig;</i>, and those
-of the fire <i>vulcani</i>. The sylphs approach nearest to
-our nature, as they live in the air like us. The sylphs,
-nymphs, and pigmies, sometimes obtain permission
-from God to make themselves visible, to converse
-with men, to indulge in carnal pleasures, and to produce
-children. But the salamanders have no relation
-to man. These spiritual beings are acquainted with
-the future, and capable of revealing it to man. They
-appear under the form of <i>ignes fatui</i>. We have also
-<span class="pagenum" id="Page_157">157</span>
-the history of the fairies and the giants; and are told
-how these spiritual beings are the guardians of concealed
-treasures; and how these sylphs, nymphs, pigmies,
-and salamanders, may be charmed, and their
-treasures taken from them.</p>
-
-<p>This division of man into body and spirit, and of
-the things of nature into visible and invisible, has in
-all ages of the world, been adopted by fanatics, because
-it enabled them to explain the history of ghosts,
-and a thousand similar prejudices. Hence the distinction
-between soul and spirit, which is so very ancient;
-and hence the three following harmonies to
-which the successors of Paracelsus paid a particular
-attention:
-
-<span class="table">
-<span class="trow">
-<span class="tcell"><i>Soul</i>,</span>
-<span class="tcell"><i>Spirit</i>,</span>
-<span class="tcell"><i>Body</i>,</span>
-</span>
-<span class="trow">
-<span class="tcell"><i>Mercury</i>,</span>
-<span class="tcell"><i>Sulphur</i>,</span>
-<span class="tcell"><i>Salt</i>,</span>
-</span>
-<span class="trow">
-<span class="tcell"><i>Water</i>,</span>
-<span class="tcell"><i>Air</i>,</span>
-<span class="tcell"><i>Earth</i>.</span>
-</span>
-</span>
-
-The will and the imagination of man acts principally
-by means of the spirit. Hence the reason of the
-efficacy of sorcery and magic. The <i>n&aelig;vi materni</i> are
-the impressions of these <i>vice-men</i>, and Paracelsus
-calls them <i>cocomica signa</i>. The <i>sideric</i> body of man
-draws to him, by imagination, all that surrounds him,
-and particularly the stars, on which it acts like a magnet.
-In this manner, women with child, and during
-the regular period of monthly evacuation, having a
-diseased imagination, are not only capable of poisoning
-a mirror by their breath, but of injuring the infants
-in their wombs, and even also of poisoning the
-moon. But it seems needless to continue this disagreeable
-detail of the absurd and ridiculous opinions
-which Paracelsus has consigned to us in his different
-tracts.</p>
-
-<p>The Physiology of Paracelsus (if such a name can
-be applied to his reveries) is nothing else than an application
-of the laws of the Cabala to the explanation
-of the functions of the body. There exists, he assures
-us, an intimate connexion between the sun and the
-<span class="pagenum" id="Page_158">158</span>
-heart, the moon and the brain, Jupiter and the liver,
-Saturn and the spleen, Mercury and the lungs, Mars
-and the bile, Venus and the kidneys. In another
-part of his works, he informs us that the sun acts on
-the umbilicus and the middle parts of the abdomen,
-the moon on the spine, Mercury on the bowels, Venus
-on the organs of generation, Mars on the face, Jupiter
-on the head, and Saturn on the extremities. The
-pulse is nothing else than the measure of the temperature
-of the body, according to the space of the six
-places which are in relation to the planets. Two pulses
-under the sole of the feet belong to Saturn and Jupiter,
-two at the elbow to Mars and Venus, two in the
-temples to the moon and mercury. The pulse of the
-sun is found under the heart. The <i>macrocosm</i> has
-also seven pulses, which are the revolutions of the
-seven planets, and the irregularity or intermittence of
-these pulses, is represented by the eclipses. The moon
-and Saturn are charged in the macrocosm with thickening
-the water, which causes it to congeal. In like
-manner the moon of the microcosm, that is to say the
-brain, coagulates the blood. Hence <i>melancholy persons</i>,
-whom Paracelsus calls <i>lunatics</i>, have a thick
-blood. We ought not to say of a man that he has
-such and such a complexion; but that it is Mars,
-Venus, &amp;c., so that a physician ought to know the
-planets of the microcosm, the arctic and antarctic
-pole, the meridian, the zodiac, the east and the west,
-before trying to explain the functions or cure the diseases.<a id="FNanchor_158" href="#Footnote_158" class="fnanchor">158</a>
-This knowledge is acquired by a continual
-comparison of the macrocosm with the microcosm.
-What must have been the state of medicine at the
-time when Paracelsus wrote, when the propagator of
-<span class="pagenum" id="Page_159">159</span>
-such opinions could be reckoned one of the greatest
-of its reformers?</p>
-
-<p>The system of Galen had for its principal basis the
-doctrine of the four elements, <i>fire</i>, <i>air</i>, <i>water</i>, and
-<i>earth</i>. Paracelsus neglected these elements, and
-multiplied the substances of the disease itself. He
-admits, strictly speaking, three or four elements;
-namely, the <i>star</i>, the <i>root</i>, the <i>element</i>, the <i>sperm</i>,
-which he distinguishes by the name of the <i>true seed</i>.
-All these elements were originally confounded together
-in the <i>chaos</i> or <i>yliados</i>. The <i>star</i> is the active force
-which gives form to matter. The <i>stars</i> are reasonable
-beings addicted to sodomy and adultery, like other
-creatures. Each of them draws at pleasure out of
-the <i>chaos</i>, the plant and the metal to which it has
-an affinity, and gives a <i>sideric</i> form to their <i>root</i>.
-There are two kinds of <i>seed</i>; the <i>sperm</i> is the vehicle
-of the true seed. It is engendered by speculation, by
-imagination, by the power of the <i>star</i>. The occult, invisible,
-<i>sideric</i> body produces the <i>true seed</i>, and the
-Adamic man secretes only the visible envelope of it.
-Putrefaction cannot give birth to a new body: the
-seed must pre-exist, and it is developed during putrefaction
-by the power of the stars. The generation of
-animals is produced by the concourse of the infinite
-number of seeds which detach themselves from all
-parts of the body. Thus the seed of the nose reproduces
-a nose, that of the eye the eye, and so on.</p>
-
-<p>With respect to the elements themselves, Paracelsus
-admits occasionally their influence on the functions of
-the body, and the theory of diseases; but he deduces
-the faculties which they possess from the <i>stars</i>. It
-was he that first shook the doctrine of the four elements,
-originally contrived by Empedocles. Alchymy
-had introduced another set of elements, and the alchymists
-maintained that salt, sulphur, and mercury,
-were the true elements of things. Paracelsus endeavoured
-to reconcile these chemical elements with his
-<span class="pagenum" id="Page_160">160</span>
-cabalistic ideas, and to show more clearly their utility
-in the theory of medicine. He invented a <i>sideric
-salt</i>, which can only be perceived by the exquisite
-senses of a theosophist, elevated by the abnegation of
-all gross sensuality to a level with pure and spiritual
-demons. This <i>salt</i> is the cause of the consistence of
-bodies, and it is it which gives them the faculty of
-being reproduced from their ashes.</p>
-
-<p>Paracelsus imagined also a <i>sideric sulphur</i>, which
-being vivified by the influence of the stars, gives bodies
-the property of growing, and of being combustible.
-He admits also a <i>sideric mercury</i>, the foundation of
-fluidity and volatilization. The concourse of these
-three substances forms the body. In different parts of
-his works, Paracelsus says, that the <i>elements</i> are composed
-of these three principles. In plants he calls the
-salt <i>balsam</i>, the sulphur <i>resin</i> and the mercury <i>gotaronium</i>.
-In other passages he opposes the assertion of
-the Galenists, that <i>fire</i> is <i>dry</i> and <i>hot</i>, <i>air cold</i> and
-<i>moist</i>, <i>earth dry</i> and <i>cold</i>, <i>water moist</i> and <i>cold</i>. Each
-of these elements, he says, is capable of admitting all
-qualities, so that in reality there exists a <i>dry water</i>, a
-<i>cold fire</i>, &amp;c.</p>
-
-<p>I must not omit another remarkable physiological
-doctrine of Paracelsus, namely, that there exists in the
-stomach a demon called <i>Arch&aelig;us</i>, who presides over
-the chemical operations which take place in it, separating
-the poisonous from the nutritive part of food,
-and furnishing the alimentary substances with the
-tincture, in consequence of which they become capable
-of being assimilated. This <i>ruler of the stomach</i>, who
-changes bread into blood, is the type of the physician,
-who ought to keep up a good understanding with him,
-and lend him his assistance. To produce a change in
-the humours ought never to be the object of the true
-physician, he should endeavour to concentrate all his
-operations on the stomach and the ruler who reigns in it.
-This Arch&aelig;us to whom the name of <i>Nature</i> may also
-<span class="pagenum" id="Page_161">161</span>
-be given, produces all the changes by his own power.
-It is he alone who cures diseases. He has a <i>head</i> and
-<i>hands</i>, and is nothing else than the <i>spirit of life</i>, the
-<i>sideric body</i> of man, and no other spirit besides exists
-in the body. Each part of the body has also a peculiar
-stomach in which the secretions are elaborated.</p>
-
-<p>There are, he informs us, five different causes of
-diseases. The first is the <i>ens astrorum</i>. The constellations
-do not immediately induce diseases, but they
-alter and infect the air. This is what, properly speaking
-constitutes the <i>entity of the stars</i>. Some constellations
-<i>sulphurize</i> the atmosphere, others communicate
-to it <i>arsenical</i>, <i>saline</i>, or <i>mercurial</i> qualities.
-The arsenical astral entities injure the blood, the mercurial
-the head, the saline the bones and the vessels.
-Orpiment occasions tumours and dropsies, and the
-<i>bitter stars</i> induce fever.</p>
-
-<p>The second morbific cause is the <i>ens veneni</i>, which
-proceeds from alimentary substances: when the archeus
-is languid putrefaction ensues, either <i>localiter</i> or
-<i>emuncturaliter</i>. This last takes place when those evacuations,
-which ought to be expelled by the nose, the
-intestines, or the bladder, are retained in the body.
-Dissolved mercury escapes through the pores of the
-skin, white sulphur by the nose, arsenic by the ears,
-sulphur diluted with water by the eyes, salt in solution
-by the urine, and sulphur deliquesced by the intestines.</p>
-
-<p>The third morbific cause of disease is the <i>ens naturale</i>;
-but Paracelsus subjects to the ens astrorum
-the principles which the schools are in the habit of arranging
-among the number of natural causes. The
-<i>ens spirituale</i> forms the fourth species and the <i>ens
-deale</i> or <i>Christian entity</i> the fifth. This last class
-comprehends all the immediate effects of divine predestination.</p>
-
-<p>It would lead us too far if I were to point out the
-strange methods which he takes to discover the cause
-<span class="pagenum" id="Page_162">162</span>
-of diseases. But his doctrine concerning <i>tartar</i> is too
-important, and does our fanatic too much credit to be
-omitted. It is without doubt the most useful of all
-the innovations which he introduced. <i>Tartar</i> according
-to him, is the principle of all the maladies proceeding
-from the thickening of the humours, the
-rigidity of the solids, or the accumulation of earthy
-matter. Paracelsus thought the term <i>stone</i> not suitable
-to indicate that matter, because it applies only to
-one species of it. Frequently the principle proceeds
-from mucilage, and mucilage is tartar. He calls this
-principle <i>tartar</i> (<i>tartarus</i>) because it burns like hellfire,
-and occasions the most dreadful diseases. As
-<i>tartar</i> (<i>bitartrate of potash</i>) is deposited at the bottom
-of the wine-cask, in the same way <i>tartar</i> in the living
-body is deposited on the surface of the teeth. It is
-deposited on the internal parts of the body when the
-arch&aelig;us acts with too great impetuosity and in an irregular
-manner, and when it separates the nutritive
-principle with too much impetuosity. Then the saline
-spirit unites itself to it and coagulates the earthy
-principle, which is always present, but often in the
-state of <i>materia prima</i> without being coagulated.</p>
-
-<p>In this manner tartar, in the state of <i>materia prima</i>,
-may be transmitted from father to son. But it is not
-hereditary and transmittable when it has already assumed
-the form of gout, of renal calculus, or of obstruction.
-The saline spirit which gives it its form,
-and causes its coagulation, is seldom pure and free
-from mixture; usually it contains alum, vitriol, or
-common salt; and this mixture contributes also to
-modify the tartarous diseases. The tartar may be
-likewise distinguished according as it comes from the
-blood itself, or from foreign matters accumulated in
-the humours. The great number of calculi which have
-been found in every part of the body, and the obstructions,
-confirm the generality of this morbific cause,
-to which are due most of the diseases of the liver.
-<span class="pagenum" id="Page_163">163</span>
-When the tartarous matter is increased by certain articles
-of food, renal calculi are engendered, a calculous
-paroxysm is induced, and violent pain is occasioned.
-It acts as an emetic, and may even give occasion to
-death, when the saline spirit becomes corrosive; and
-when the tartar coagulated by it becomes too irritating.</p>
-
-<p>Tartar, then, is always an excrementitious substance,
-which in many cases results from the too great
-activity of the digestive forces. It may make its appearance
-in all parts of the body, from the irregularity
-and the activity, too energetic or too indolent, of the
-archeus; and then it occasions particular accidents relative
-to each of the functions. Paracelsus enumerates
-a great number of diseases of the organs, which may
-be explained by that one cause; and affirms, that the
-profession of medicine would be infinitely more useful,
-if medical men would endeavour to discover the tartar
-before they tried to explain the affections.</p>
-
-<p>Paracelsus points out, also, the means by which we
-can distinguish the presence of tartar in urine. For
-this it is necessary, not merely to inspect the urine,
-but to subject it to a chemical analysis. He declaims
-violently against the ordinary ouroscopy. He divides
-urine into internal and external; the internal comes
-from the blood, and the external announces the nature
-of the food and drink which has been employed.
-To the sediment of urine he gives the new name of
-<i>alcola</i>, and admits three species of it, namely, <i>hypostasis</i>,
-<i>divulsio</i>, and <i>sedimen</i>. The first is connected
-with the stomach, the second with the liver, and the
-third with the kidneys; and tartar predominates in all
-the three.</p>
-
-<p>The Cabala constantly directs Paracelsus in his
-therapeutics and materia medica. As all terrestrial
-things have their image in the region of the stars, and
-as diseases depend also on the influence of the stars,
-we have nothing more to do, in order to obtain a certain
-<span class="pagenum" id="Page_164">164</span>
-cure for these diseases, than to discover, by means
-of the Cabala, the harmony of the constellations.
-<i>Gold</i> is a specific against all diseases of the <i>heart</i>, because,
-in the mystic scale, it is in harmony with that
-viscus. The <i>liquor of the moon</i> and crystal cure the
-diseases of the <i>brain</i>. The liquor <i>alkahest</i> and <i>cheiri</i>
-are efficacious against those of the <i>liver</i>. When we
-employ vegetable substances, we must consider their
-harmony with the constellations, and their magical
-harmony with the parts of the body and the diseases,
-each star drawing, by a sort of magical virtue, the
-plant for which it has an affinity, and imparting to it
-its activity. So that plants are a kind of sublunary
-stars. To discover the virtues of plants, we must study
-their anatomy and cheiromancy; for the leaves are
-their hands, and the lines observable on them enable
-us to appreciate the virtues which they possess. Thus
-the anatomy of the <i>chelidonium</i> shows us that it is a
-remedy for jaundice. These are the celebrated <i>signatures</i>
-by means of which we deduce the virtues of
-vegetables, and the medicines of analogy which they
-present in relation to their form. Medicines, like women,
-are known by the forms which they affect. He
-who calls in question this principle, accuses the
-Divinity of falsehood, the infinite wisdom of whom has
-contrived these external characters to bring the study
-of them more upon a level with the weakness of the
-human understanding. On the corolla of the euphrasia
-there is a black dot; from this we may conclude that
-it furnishes an excellent remedy against all diseases of
-the eye. The lizard has the colour of malignant ulcers,
-and of the carbuncle; this points out the efficacy
-which that animal possesses as a remedy.</p>
-
-<p>These signatures were exceedingly convenient for
-the fanatics, since they saved them the trouble of
-studying the medical virtues of plants, but enabled
-them to decide the subject <i>&agrave; priori</i>. Paracelsus acted
-very considerately, when he ascribed these virtues
-<span class="pagenum" id="Page_165">165</span>
-principally to the stars, and affirmed that the observation
-of favourable constellations is an indispensable
-condition in the employment of these medicines. “The
-remedies are subjected to the will of the stars, and
-directed by them; you ought therefore to wait till
-heaven is favourable, before ordering a medicine.”</p>
-
-<p>Paracelsus considered all the effects of plants as
-specifics, and the use of them as secrets. The same
-notions explain the eulogy which he bestowed on the
-<i>elixir of long life</i>, and upon all the means which he
-employed to prolong the term of existence. He believed
-that these methods, which contained the <i>materia
-prima</i>, served to repair the constant waste of that matter
-in the human body. He was acquainted, he says,
-with four of these arcana, to which he applied the
-mystic terms, <i>mercury of life</i>, <i>philosopher’s stone</i>,
-&amp;c. The <i>polygonum persicaria</i> was an infallible
-specific against all the effects of magic. The method
-of using it is, to apply it to the suffering part, and then
-to bury it in the earth. It draws out the malignant
-spirits like a magnet, and it is buried to prevent these
-malignant spirits from making their escape.</p>
-
-<p>The reformation of Paracelsus had the great advantage
-of representing <i>chemistry</i> as an indispensable art
-in the preparation of medicines. The disgusting decoctions
-and useless syrups gave place to <i>tinctures</i>,
-<i>essences</i>, and <i>extracts</i>. Paracelsus says, expressly,
-that the true use of chemistry is to prepare medicines,
-and not to make gold. He takes that opportunity of
-declaiming against cooks and innkeepers, who drown
-medicines in soup, and thus destroy all their properties.
-He blames medical men for prescribing simples,
-or mixtures of simples, and affirms that the object
-should always be to extract the quintessence of each
-substance; and he describes at length the method of
-extracting this quintessence. But he was very little
-scrupulous about the substances from which this quintessence
-<span class="pagenum" id="Page_166">166</span>
-was to be extracted. The heart of a hare, the
-bones of a hare, the bone of the heart of a stag, mother-of-pearl,
-coral, and various other bodies may, he
-says, be used indiscriminately to furnish a quintessence
-capable of curing some of the most grievous diseases.</p>
-
-<p>Paracelsus combats with peculiar energy the method
-of cure employed by the disciples of Galen, directed
-solely against the predominating humours, and the
-elementary qualities. He blames them for attempting
-to correct the action of their medicines, by the addition
-of useless ingredients. Fire and chemistry, he affirmed,
-are the sole correctives. It was Paracelsus that first
-introduced <i>tin</i> as a remedy for worms, though his mode
-of employing it was not good.</p>
-
-<p>I have been thus particular in pointing out the philosophical
-and medical opinions of Paracelsus, because
-they were productive of such important consequences,
-by setting medical men free from the slavish deference
-which they had been accustomed to pay to the dogmas
-of Galen and Avicenna. But it was the high rank to
-which he raised chemistry, by making a knowledge of
-it indispensable to all medical men; and by insisting
-that the great importance of chemistry did not consist
-in the formation of gold, but in the preparation of
-medicines, that rendered the era of Paracelsus so
-important in the history of chemistry; for after his
-time the art of chemistry was cultivated by medical
-men in general&mdash;it became a necessary part of their
-education, and began to be taught in colleges and
-medical schools. The object of chemistry came to
-be, not to discover the philosopher’s stone, but to
-prepare medicines; and a great number of new medicines,
-both from the mineral and vegetable kingdom&mdash;some
-of more, some of less, consequence,
-soon issued from the laboratories of the chemical
-physicians.</p>
-
-<p>There can be little doubt that many chemical preparations
-<span class="pagenum" id="Page_167">167</span>
-were either first introduced into medicine by
-Paracelsus, or at least were first openly prescribed by
-him: though from the nature of his writings, and the
-secrecy in which he endeavoured to keep his most
-valuable remedies, it is not easy to point out what
-these remedies were. Mercury is said to have been
-employed in medicine by Basil Valentine; but it was
-Paracelsus who first used it openly as a cure for the
-venereal disease, and who drew general attention to it
-by his encomiums on its medical virtues, and by the
-eclat of the cures which he performed by means of it,
-after all the Galenical prescriptions of the schools had
-been tried in vain.</p>
-
-<p>He ascertained that alum contains, united to an
-acid, not a metallic oxide, but an earth. He mentions
-metallic arsenic; but there is some reason for believing
-that this metal was known to Geber and the
-Arabian physicians. Zinc is mentioned by him, and
-likewise bismuth, as substances not truly metallic, but
-approaching to metals in their properties: for malleability
-and ductility were considered by him as essential
-to the metals.<a id="FNanchor_159" href="#Footnote_159" class="fnanchor">159</a> I cannot be sure of any other chemical
-fact which appears in Paracelsus, and which was not
-known before his time. The use of sal ammoniac in
-subliming several metallic calces, was familiar to him,
-but it had long ago been explained by Geber. It is
-clear also that Geber was acquainted with aqua regia,
-and that he employed it to dissolve gold. Paracelsus’s
-reputation as a chemist, therefore, depends not upon
-<span class="pagenum" id="Page_168">168</span>
-any discoveries which he actually made, but upon the
-great importance which he attached to the knowledge
-of it, and to his making an acquaintance with chemistry
-an indispensable requisite of a medical education.</p>
-
-<p>Paracelsus, as the founder of a new system of
-medicine, the object of which was to draw chemistry
-out of that state of obscurity and degradation into
-which it had been plunged, and to give it the charge
-of the preparation of medicine, and presiding over the
-whole healing art, deserved a particular notice; and
-I have even endeavoured, at some length, to lay his
-system of opinions, absurd as it is, before the reader.
-But the same attention is not due to the herd of followers
-who adopted his absurdities, and even carried
-them, if possible, still further than their master: at
-the same time there are one or two particulars connected
-with the Paracelsian sect which it would be
-improper to omit.</p>
-
-<p>The most celebrated of his followers was Leonhard
-Thurneysser-zum-Thurn, who was born in 1530, at
-Basle, where his father was a goldsmith. His life,
-like that of his master, was checkered with very extraordinary
-vicissitudes. In 1560 he was sent to Scotland
-to examine the lead-mines in that country. In
-1558 he commenced miner and sulphur extractor at
-Tarenz on the Inn, and was so successful, that he
-acquired a great reputation. He had turned his attention
-to medicine on the Paracelsian plan, and in 1568
-made himself distinguished by several important cures
-which he performed. In 1570 he published his Quinta
-Essentia, with wooden cuts, in Munster; from thence
-he went to Frankfort on the Oder, and published his
-Piso, a work which treats of <i>waters</i>, <i>rivers</i>, and
-<i>springs</i>. John George, Elector of Brandenburg, was
-at that time in Frankfort, and was informed that the
-treatise of Thurneysser pointed out the existence of a
-great deal of riches in the March of Brandenburg, till
-that time unknown. His courtiers, who were anxious
-<span class="pagenum" id="Page_169">169</span>
-to establish mines in their possessions, united in recommending
-the author. He was consulted about a
-disease under which the wife of the elector was labouring,
-and having performed a cure, he was immediately
-named physician to this prince.</p>
-
-<p>He turned this situation to the best account. He
-sold Spanish white, and other cosmetics, to the ladies
-of the court; and instead of the disgusting decoctions
-of the Galenists, he administered the remedies of
-Paracelsus under the pompous titles of <i>tincture of
-gold</i>, <i>magistery of the sun</i>, <i>potable gold</i>, &amp;c. By
-these methods he succeeded in amassing a prodigious
-fortune, but was not fortunate enough to be able to
-keep it. Gaspard Hoffmann, professor at Frankfort,
-a well-informed and enlightened man, published a
-treatise, the object of which was to expose the extravagant
-pretensions and ridiculous ignorance of Thurneysser.
-This book drew the attention of the courtiers,
-and opened the eyes of the elector. Thurneysser
-lost much of his reputation; and the methods
-by which he attempted to bolster himself up, served
-only to sink him still lower in the estimation of
-men of sense. Among other things, he gave out that
-he was the possessor of a devil, which he carried about
-with him in a bottle. This pretended devil was nothing
-else than a scorpion, preserved in a phial of oil.
-The trick was discovered, and the usual consequences
-followed. He lost a process with his wife, from whom
-he was separated; this deprived him of the greatest
-part of his fortune. In 1584 he fled to Italy, where
-he occupied himself with the transmutation of metals,
-and he died at Cologne in 1595.</p>
-
-<p>Thurneysser extols Paracelsus as the only true physician
-that ever existed. His Quintessence is written
-in verse. In the first book <i>The Secret</i> is the speaker.
-He is represented with a padlock in his mouth, a key
-in his hand, and seated on a coffer in a chamber, the
-windows of which are shut. This personage teaches that
-<span class="pagenum" id="Page_170">170</span>
-all things are composed of salt, sulphur, and mercury,
-or of earth, air, and water; and consequently that
-<i>fire</i> is excluded from the number of the elements. We
-must search for the secret in the <i>Bible</i>, and then in
-the <i>stars</i> and the <i>spirits</i>. In the second book, <i>Alchymy</i>
-is the speaker. She points out the mode of performing
-the processes; and says that to endeavour to fix
-volatile substances, is the same thing as to endeavour
-to trace white letters on a wall with a piece of charcoal.
-She prohibits all long processes, because God
-created the world in six days.</p>
-
-<p>His method of judging of the diseases from the
-urine of the patient deserves to be mentioned. He
-distilled the urine, and fixed to the receiver a tube
-furnished with a scale, the degrees of which consisted
-of all the parts of the body. The phenomena which
-he observed during the distillation of the urine, enabled
-him to draw inferences respecting the state of all these
-different organs.</p>
-
-<p>I pass over Bodenstein, Taxites, and Dorn, who
-distinguished themselves as partisans of Paracelsus.
-Dorn derived the whole of chemistry from the first
-chapter of Genesis, the words of which he explained
-in an alchymistical sense. These words in particular,
-“And God made the firmament, and divided the
-waters which were under the firmament from the
-waters which were above the firmament,” appeared to
-him to be an account of the <i>great work</i>. Severinus,
-physician to the King of Denmark, and canon of Roskild,
-was also a celebrated partisan of Paracelsus;
-but his writings do not show either that knowledge or
-stretch of thought which would enable us to account
-for the reputation which he acquired and enjoyed.</p>
-
-<p>There were very few partisans of Paracelsus out of
-Germany. The most celebrated of his followers among
-the French, was Joseph du Chesne, better known by
-the name of Quercitanus, who was physician to
-Henry IV. He was a native of Gascony, and drew
-<span class="pagenum" id="Page_171">171</span>
-many enemies upon himself by his arrogant and overbearing
-conduct. He pretended to be acquainted
-with the method of making gold. He was a thorough-going
-Paracelsian. He affirmed that diseases, like
-plants, spring from seeds. The word alchymy, according
-to him, is composed of the two Greek words
-ἁλς (salt) and χημεια, because the <i>great secret</i> is concealed
-in salt. All bodies are composed of three
-principles, as God is of three substances. These
-principles are contained in saltpetre, the salts of sulphur
-solid and volatile, and the volatile mercurial
-salt. He who possesses <i>sal generalis</i> may easily produce
-philosophical gold, and draw potable gold from the
-three kingdoms of nature. To prove the possibility
-of this transmutation, he cites an experiment very
-often repeated after him, and which some theologians
-have even employed as analogous to the resurrection of
-the dead; namely, the faculty which plants have of
-being produced from their ashes. His materia medica is
-founded on the <i>signatures</i> of plants, which he carries
-so far as to assert that male plants are more suitable
-to men, and female plants to women. Sulphuric acid,
-he says, has a magnetic virtue, in consequence of
-which it is capable of curing the epilepsy. He recommends
-the <i>magisterium cranii humani</i> as an excellent
-medicine, and boasts much of the virtues of
-antimony.</p>
-
-<p>Du Chesne was opposed by Riolanus, who attacked
-chemical remedies with much bitterness. The medical
-faculty of Paris took up the cause of the Galenists
-with much zeal, and prohibited their fellows and
-licentiates from using any chemical medicines whatever.
-He had to sustain a dispute with Aubert relative
-to the origin and the transmutation of metals. Fenot
-came to the assistance of Aubert, and affirmed that
-gold possesses no medical properties whatever, that
-<i>crabs’ eyes</i> are of no use when administered in intermittents,
-and that the laudanum of Paracelsus (being
-<span class="pagenum" id="Page_172">172</span>
-an opiate) is in reality hurtful instead of being beneficial.</p>
-
-<p>The decree of the medical faculty of Paris which
-placed antimony among the poisons, and which occasioned
-that of the Parliament of Paris, was composed
-by Simon Pietre, the elder, a man of great erudition
-and the most unimpeachable probity. Had it been
-literally obeyed it would have occasioned very violent
-proceedings; because chemical remedies, as they act
-more promptly and with greater energy, were getting
-daily into more general use. In 1603 the celebrated
-Theodore Turquet de Mayenne was prosecuted, because,
-in spite of the prohibition, he had sold antimonial
-preparations. The decree of the faculty against
-him exhibits a remarkable proof of the bigotry and
-intolerance of the times.<a id="FNanchor_160" href="#Footnote_160" class="fnanchor">160</a> However Turquet does
-not seem to have been molested notwithstanding this
-decree. He ceased indeed to be professor of chemistry,
-but continued to practise medicine as formerly;
-and two members of the faculty, Seguin and Akakia,
-even wrote an apology for him. At last he went to
-England, whither he had been invited, to accept an
-honourable appointment.
-<span class="pagenum" id="Page_173">173</span></p>
-
-<p>The mystical doctrines of Paracelsus are supposed
-to have given origin to the sect of Rosecrucians, concerning
-which so much has been written and so little
-certain is known. It is not at all unlikely that the
-greatest part, if not the whole that has been stated
-about the antiquity, and extent, and importance of
-this sect, is mere fiction, and that the origin of the
-whole was nothing else than a ludicrous performance
-of Valentine Andre&aelig;, an ecclesiastic of Calwe, in the
-country of Wirtemburg, a man of much learning,
-genius, and philanthropy. From his life, written by
-himself, and preserved in the library of Wolfenbuttel,
-we learn that in the year 1603 he drew up the celebrated
-Noce Chimique of Christian Rosenkreuz, in order
-to counteract the alchymistical and the theosophistical
-dogmas so common at that period. He was unable to
-restrain his risible faculties when he saw this <i>ludibrium
-juvenilis ingenii</i> adopted as a true history, while he
-meant it merely as a satire. It is believed that the
-Fama Fraternitatis is a production of this ecclesiastic,
-and that he published it in order to correct the chemists
-and enthusiasts of the time. He himself was
-called Andre&aelig;, Knight of the Rose-cross (<i>ros&aelig; crucis</i>)
-because he had engraven on his seal a cross with four
-roses.</p>
-
-<p>It is true that Andre&aelig; instituted, in 1620, a <i>fraternitas
-christiana</i>, but with quite other views than those
-which are supposed to have actuated the Rosecrucians.
-His object was to correct the religious opinions of
-the times, and to separate Christian theology from
-scholastic controversies, with which it had been unhappily
-intermixed. He himself, in different parts of his
-writings, distinguishes carefully between the Rosecrucians
-and his own society, and amuses himself with
-the credulity of the German theosophists, who adopted
-so readily his fiction for a series of truths. It would
-appear, therefore, that this secret order of Rosecrucians,
-notwithstanding the brilliant origin assigned to
-<span class="pagenum" id="Page_174">174</span>
-it, really owes its birth to the pleasantry of a clergyman
-of Wirtemburg, who endeavoured by that means to
-set bounds to the chimeras of theosophy, but who unfortunately
-only increased still more the adherents of
-this absurd science.</p>
-
-<p>A crowd of enthusiasts found it too advantageous
-to propagate the principles of the <i>rosa crux</i> not to
-endeavour to unite them into a sect. Valentine Weigel,
-a fanatical preacher at Tschoppau, near Chemnitz,
-left at his death a prodigious number of followers, who
-were already Rosecrucians, without bearing the name.
-Egidius Gutmann, of Suabia, was equally a Rosecrucian,
-without bearing the name; he condemned all
-pagan medicines, and affirmed that he possessed the
-universal remedy which ennobles man, cures all diseases,
-and gives man the power of fabricating gold.
-“To fly in the air, to transmute metals, and to know
-all the sciences,” says he, “nothing more is requisite
-than faith.”</p>
-
-<p>Oswald Crollius, of Hesse, must also take his station
-in this honourable fraternity of enthusiasts. He
-was physician to the Prince of Anhalt, and afterwards
-a counsellor of the Emperor Rodolphus II. The introduction
-to his Basilica Chymica, contains a short
-but exact epitome of the opinions of Paracelsus. It is
-not worth while to give the reader a notion of his own
-opinions, which are quite as absurd and unintelligible
-as those of Paracelsus and his followers. As a preparer
-of chemical medicines he deserves more credit;
-<i>antimonium diaphoreticum</i> was a favourite preparation
-of his, and so was sulphate of potash, which was
-known at the time by the name of <i>specificum purgans
-Paracelsi</i>: he knew chloride of silver well, and first
-gave it the name of <i>luna cornea</i>, or <i>horn silver</i>: fulminating
-gold was known to him, and called by him
-<i>aurum volatile</i>.</p>
-
-<p>This is the place to mention Andrew Libavius, of
-Halle, in Saxony, where he was a physician, and a
-<span class="pagenum" id="Page_175">175</span>
-professor in the gymnasium of Coburg, who was one of
-the most successful opponents of the school of Paracelsus,
-and whose writings do him much credit. As
-a chemist, he deserves perhaps to occupy a higher
-rank than any of his contemporaries: he was, it is
-true, a believer in the possibility of transmuting metals,
-and boasted of the wonderful powers of <i>aurum potabile</i>;
-but he always distinguishes between rational
-alchymy and the <i>mental</i> alchymy of Paracelsus. He
-separated, with great care, <i>chemistry</i> from the reveries
-of the theosophists, and stands at the head of those
-who opposed most successfully the progress of superstition
-and fanaticism, which was making such an
-overwhelming progress in his time. His writings are
-very numerous and various, and were collected and
-published at Frankfort, in 1615, in three folio volumes,
-under the title of “Opera omnia Medico-chymica.”
-Libavius himself died in 1616. It would occupy more
-space than we have room for, to attempt an abstract of
-his very multifarious works. A few observations will
-be sufficient: he wrote no fewer than five different
-tracts to expose the quackery of George Amwald,
-who had boasted that he was in possession of a panacea,
-by means of which he was enabled to perform the most
-wonderful cures, and which he was in the habit of
-selling to his patients at an enormous price; Libavius
-showed that this boasted panacea was nothing
-else than <i>cinnabar</i>, which neither possessed the virtues
-ascribed to it by Amwald, nor deserved to be purchased
-at so high a price. He entered also into a controversy
-with Crollius, and exposed his fanatical and absurd
-opinions. He engaged likewise in a dispute with Henning
-Scheunemann, a physician in Bamberg, who was
-a Rosecrucian, and, like the rest of his brethren, profoundly
-ignorant not merely of all science, but even
-of philology. The expressions of Scheunemann are
-so obscure, that we learn more of his opinions from
-Libavius than from his own writings. He divides the
-<span class="pagenum" id="Page_176">176</span>
-internal nature of man into seven different degrees, from
-the seven changes it undergoes: these are, combustion,
-sublimation, dissolution, putrefaction, distillation,
-coagulation, and tincture. He gives us likewise an
-account of ten modifications which the three elements
-undergo; but as they are quite unintelligible, it is not
-worth while to state them. Libavius had the patience
-to analyze and expose all these gallimatias.</p>
-
-<p>Libavius’s system of chemistry, entitled “Alchymia
-&egrave; dispersis passim optimorum auctorum, veterum et
-recentiorum exemplis potissimum, tum etiam preceptis
-quibusdam operose collecta, adhibitisque ratione et
-experientia quanta potuit esse methodo accurate explicata
-et in integrum corpus redacta. Accesserunt
-tractati nonnulli physici chymici item methodistici.”
-Frankfort, 1595, folio, 1597, 4to.&mdash;is really an excellent
-book, considering the period in which it was
-written, and deserves the attention of every person
-who is interested in the history of chemistry. I shall
-notice some of the most remarkable chemical facts
-which occur in Libavius, and which I have not observed
-in any preceding writer; who the actual discoverer of
-these facts really was, it is impossible to say, in consequence
-of the secrecy which at that time was affected,
-and the obscure terms in which chemical facts are
-in general stated.</p>
-
-<p>He was aware that the fumes of sulphur have the
-property of blackening white lead. He was in the
-habit of purifying cinnabar by means of arsenic and
-oxide of lead. He knew the method of giving glass a
-red colour by means of gold or its oxide, and was
-aware of the method of making artificial gems, such
-as ruby, topaz, hyacinth, garnet, balass, by tinging
-glass by means of metallic oxides. He points out
-fluor spar as an excellent flux for various metals and
-their oxides. He knew that when metals were fused
-along with alkaline bodies, a certain portion of them
-was converted into slags, and this portion he endeavoured to
-<span class="pagenum" id="Page_177">177</span>
-recover by the addition of iron filings.
-He was aware of the mode of acidifying sulphur by
-means of nitric acid. He knew that camphor is soluble
-in nitric acid, and forms with it a kind of oil.
-Of the perchloride of tin he was undoubtedly the discoverer,
-as it has continued ever since his time to
-pass by his name; namely, <i>fuming liquor of Libavius</i>.
-He was aware, that alcohol or spirits could be obtained
-by distilling the fermented juice of a great variety
-of sweet fruits. He procured sulphuric acid by
-the distillation of alum and sulphate of iron, as Geber
-had done long before his time; but he determined
-the nature of the acid with more care than had been
-done, and showed, that it was the same as that obtained
-by the combustion of sulphur along with saltpetre.
-To him, therefore, in some measure, are we
-indebted for the process of preparing sulphuric acid
-which is at present practised by manufacturers.</p>
-
-<p>Libavius found a successor in Angelus Sala, of
-Vicenza, physician to the Duke of Mecklenburg-Schwerin,
-worthy of his enlightened views and indefatigable
-exertions to oppose the torrent of fanaticism
-which threatened to overwhelm all Europe. Sala was
-still more addicted to chemical remedies than Libavius
-himself; but he had abjured a multitude of prejudices
-which had distinguished the school of Paracelsus.
-He discarded <i>aurum potabile</i>, and considered fulminating
-gold as the only remedy of that metal that
-deserved to be prescribed by medical men. He treated
-the notion of the existence of a universal remedy
-with contempt. He described sulphuret of gold and
-glass of antimony with a good deal of precision. He
-recommended sulphuric acid as an excellent remedy,
-and showed that it might be formed indifferently from
-sulphur, or by distilling blue vitriol or green vitriol.
-He affirmed, that the essential salts obtained from
-plants had not the same virtues as the plants from
-which they are obtained. He showed that sal ammoniac
-<span class="pagenum" id="Page_178">178</span>
-is a compound of muriatic acid and ammonia.
-To him, therefore, we are indebted for the first accurate
-mention of ammonia. It could not but have
-been noticed before by chemists, as it is procured with
-so much ease by the distillation of animal substances;
-but Sala is the first person who seems to have examined
-it with attention, and to have recognised its
-peculiar properties, and the readiness with which it
-saturates the different acids. He showed that iron
-has the property of precipitating copper from acid solutions:
-he pointed out also various precipitations of
-metals by other metals. He seems to have been acquainted
-with calomel, and to have been aware of
-at least some of its medical properties. He says,
-that fulminating gold loses its fulminating property
-when mixed with its own weight of sulphur, and the
-sulphur is burnt off it. Many other curious chemical
-facts occur in his writings, which it would be too tedious
-to particularize here. His works were collected
-and published in a quarto volume at Frankfort, in
-1647, under the title of “Opera Medico-chymica, qu&aelig;
-extant omnia.” There was another edition in the
-same place in 1682, and an edition was published at
-Rome in 1650.
-<span class="pagenum" id="Page_179">179</span></p>
-
-<hr class="chap" />
-<h2 id="CHAPTER_V">CHAPTER V.<br />
-
-<span class="large">OF VAN HELMONT AND THE IATRO-CHEMISTS.</span></h2>
-
-<p>Paracelsus first raised the dignity of chemistry,
-by pointing out the necessity of it for medical men,
-and by showing the superiority of chemical medicines
-over the disgusting decoctions of the Galenists. Libavius
-and Angelus Sala had carefully separated chemistry
-from the fanatical opinions of the followers of
-Paracelsus and the Rosecrucians. But matters were
-not doomed to remain in this state. Chemistry underwent
-a new revolution at this period, which shook the
-Spagirical system to its foundation; substituted other
-principles, and gave to medicine an aspect entirely
-new. This revolution was in a great measure due to
-the labours of Van Helmont.</p>
-
-<p>John Baptist Van Helmont was a gentleman of
-Brabant, and Lord of Merode, of Royenboch, of
-Oorschot, and of Pellines. He was born in Brussels
-in 1577, and studied scholastic philosophy in Louvain
-till the age of seventeen. After having finished his
-<i>humanity</i> (as it was termed), he ought, according to
-the usage of the place, to have taken his degree of
-master of arts; but, having reflected on the futility of
-these ceremonies, he resolved never to solicit any academical
-honour. He next associated himself to the
-Jesuits, who then delivered courses of philosophy at
-Louvain, to the great displeasure of the professors of
-<span class="pagenum" id="Page_180">180</span>
-that city. One of the most celebrated of the Jesuits,
-Martin del Rio, even taught him magic. But Van
-Helmont was disappointed in his expectations: instead
-of that true wisdom which he hoped to acquire,
-he met with nothing but scholastic dialectics,
-with all its usual subtilties. He was no better satisfied
-with the doctrines of the Stoics, who taught him his
-own weakness and misery.</p>
-
-<p>At last the works of Thomas &agrave; Kempis, and John
-Taulerus fell into his hands. These sacred books of
-mysticism attracted his attention: he thought that he
-perceived that wisdom is the gift of the Supreme
-Being; that it must be obtained by prayer; and that
-we must renounce our own will, if we wish to participate
-in the influence of the divine grace. From this
-moment he imitated Jesus Christ, in his humility. He
-abandoned all his property to his sister, renouncing
-the privileges of his birth, and laying aside the rank
-which he had hitherto occupied in society. It was
-not long before he reaped the fruit of these abnegations.
-A genius appeared to him in all the important
-circumstances of his life. In the year 1633 his own
-soul appeared to him under the figure of a resplendent
-crystal.</p>
-
-<p>The desire which he had of imitating in every
-respect the conduct of Christ, suggested to him the
-idea of practising medicine as a work of charity and
-benevolence. He began, as was then the custom of
-the time, by studying the art of healing in the writings
-of the ancients. He read the works of Hippocrates
-and Galen with avidity; and made himself so
-well acquainted with their opinions, that he astonished
-all the medical men by the profundity of his knowledge.
-But as his taste for mysticism was insatiable,
-he soon became disgusted with the writings of the
-Greeks; an accident led him to abandon them for
-ever. Happening to take up the glove of a young
-girl afflicted with the <i>itch</i>, he caught that disagreeable
-<span class="pagenum" id="Page_181">181</span>
-disease. The Galenists whom he consulted, attributed
-it to the combustion of the bile, and the saline state of
-the phlegm. They prescribed a course of purgatives
-which weakened him considerably, without effecting a
-cure. This circumstance disgusted him with the system
-of the humorists, and led him to form the resolution
-of reforming medicine, as Paracelsus had done.
-The works of this reformer, which he read with attention,
-awakened in him a spirit of reformation, but did
-not satisfy him; because his knowledge, being much
-greater than that of Paracelsus, he could not avoid
-despising the disgusting egotism, and the ridiculous
-ignorance of that fanatic. Though he had already
-refused a canonicate, he took the degree of doctor of
-medicine, in 1599, and afterwards travelled through
-the greatest part of France and Italy; and he assures
-us, that during his travels, he performed a great number
-of cures. On his return, he married a rich Brabantine
-lady, by whom he had several children; among
-others a son, afterwards celebrated under the name of
-Francis Mercurius, who edited his father’s works, and
-who went a good deal further than his father had done,
-in all the branches of theosophy. Van Helmont passed
-the rest of his life on his estate at Vilvorde, almost
-constantly occupied with the processes of his laboratory.
-He died in the year 1644, on the 13th of December,
-at six o’clock in the evening, after having nearly
-reached the age of sixty-seven years.</p>
-
-<p>The system of Van Helmont has for its basis the
-opinions of the spiritualists. He arranged even the
-influence of evil genii, the efforts of sorcerers, and the
-power of magicians among the causes which produce
-diseases. The archeus of Paracelsus constituted one
-of the capital points of his theory; but he ascribed to
-it a more substantial nature than Paracelsus had done.
-This archeus is independent of the elements; it has
-no form; for form constitutes the object of generation,
-<span class="pagenum" id="Page_182">182</span>
-or of production. These ideas are obviously borrowed
-from the ancients. The <i>form</i> of Aristotle is not the
-μορφη, but the ενεργεια (<i>the power of acting</i>) which
-matter does not possess.</p>
-
-<p>The archeus draws all the corpuscles of matter to
-the aid of <i>fermentation</i>. There are, properly speaking,
-only two causes of things; the cause <i>ex qua</i>, and
-the cause <i>per quam</i>. The first of these causes is
-<i>water</i>. Van Helmont considered water as the true
-principle of every thing which exists; and he brought
-forward very specious arguments in favour of his opinion,
-drawn both from the animal and vegetable
-kingdom. The reader will find his arguments on the
-subject, in his treatise entitled “Complexionum atque
-Mistionum elementalium Figmentum.”<a id="FNanchor_161" href="#Footnote_161" class="fnanchor">161</a> The only one
-of his experiments that, in the present state of our
-knowledge, possesses much plausibility, is the following:
-He took a large earthen vessel, and put into it
-200 lbs. of earth, previously dried in an oven. This
-earth he moistened with rain-water, and planted in it
-a willow which weighed five pounds. After an interval
-of five years, he pulled up his willow and found
-that its weight amounted to 169 pounds, and about
-three ounces. During these five years, the earth in
-the pot was duly watered with rain or distilled water.
-To prevent the earth in which the willow grew from
-being mixed with new earth blown upon it by the
-winds, the pot was covered with tin plate, pierced with
-a great number of holes to admit the air freely. The
-leaves which fell every autumn during the vegetation
-of the willow in the pot, were not reckoned in the
-169 lbs. 3 oz. The earth in the pot being again dried
-in the oven, was found to have lost about two ounces
-of its original weight. Thus 164 lbs. of wood, bark,
-<span class="pagenum" id="Page_183">183</span>
-roots, &amp;c., were produced from water alone.<a id="FNanchor_162" href="#Footnote_162" class="fnanchor">162</a> This,
-and several other experiments which it is needless to
-state, satisfied him that all vegetable substances are
-produced from water alone. He takes it for granted
-that fish live (ultimately at least) on water alone; but
-they contain almost all the peculiar animal substances
-that exist in the animal kingdom. Hence he concludes
-that animal substances are derived also from pure
-water.<a id="FNanchor_163" href="#Footnote_163" class="fnanchor">163</a> His reasoning with respect to sulphur, glass,
-stone, metals, &amp;c., all of which he thinks may ultimately
-be resolved into water, is not so satisfactory.</p>
-
-<p>Water produces elementary earth, or pure quartz;
-but this elementary earth does not enter into the composition
-of organic bodies. Van Helmont excludes
-<i>fire</i> from the number of elements, because it is not a
-substance, nor even the essential form of a substance.
-The matter of fire is compound, and differs entirely
-from the matter of light. Water gives origin also to
-the three chemical principles, salt, sulphur, and mercury,
-which cannot be considered as elements or active
-principles. I do not see clearly how he gets rid of
-<i>air</i>; for he says, that though water may be elevated in
-the form of vapour, yet that these vapours are no more
-air than the dust of marble is water.</p>
-
-<p>According to Van Helmont, a particular disposition
-of matter, or a particular mixture of that matter is not
-necessary for the formation of a body. The archeus,
-by its sole power, draws all bodies from water, when
-the <i>ferment</i> exists. This <i>ferment</i>, in its quality of a
-mean which determines the action of the archeus, is
-not a formal being; it can neither be called a <i>substance</i>,
-nor an <i>accident</i>. It pre-exists in the seed which
-is developed by it, and which contains in itself a second
-ferment of the seed, the product of the first. The
-ferment exhales an odour, which attracts the generating
-spirit of the archeus. This spirit consists in an
-<span class="pagenum" id="Page_184">184</span>
-<i>aura vitalis</i>, and it creates the bodies of nature in its
-own image, after its own <i>idea</i>. It is the true foundation
-of life, and of all the functions of organized
-bodies; it disappears only at the instant of death to
-produce a new creation of the body, which enters then,
-for the second time, into fermentation. The seed, then,
-is not indispensable to enable an animal to propagate
-its species; it is merely necessary that the archeus
-should act upon a suitable ferment. Animals produced
-in this manner are as perfect as those which
-spring from eggs.</p>
-
-<p>When water, as an element, ferments, it develops
-a vapour, to which Van Helmont gave the name of
-<i>gas</i>, and which he endeavours to distinguish from <i>air</i>.
-This gas contains the chemical principles of the body
-from which it escapes in an aerial form by the impulse
-of the archeus. It is a substance intermediate between
-spirit and matter, the principle of action of life, and of
-generation of all bodies; for its production is the first
-result of the action of the vital spirit on the torpid
-ferment, and it may be compared to the <i>chaos</i> of the
-ancients.</p>
-
-<p>The term <i>gas</i>, now in common use among chemists,
-and applied by them to all elastic fluids which differ in
-their properties from common air, was first employed
-by Van Helmont: and it is evident, from different
-parts of his writings, that he was aware that different
-species of gas exist. His <i>gas sylvestre</i> was evidently
-our <i>carbonic acid gas</i>, for he says, that it is evolved
-during the fermentation of wine and beer; that it is
-formed when charcoal is burnt in air; and that it exists
-in the Grotto del Cane. He was aware that this gas
-extinguishes a lighted candle. But he says that the
-gases from dung, and those formed in the large intestines,
-when passed through a candle, catch fire, and
-exhibit a variety of colours, like the rainbow.<a id="FNanchor_164" href="#Footnote_164" class="fnanchor">164</a> To
-<span class="pagenum" id="Page_185">185</span>
-these combustible gases he gave the names of <i>gas
-pingue</i>, <i>gas siccum</i>, <i>gas fuliginosum</i>, or <i>endimicum</i>.</p>
-
-<p>Sal ammoniac, he says, may be distilled alone, without
-danger, and so may aqua fortis (<i>aqua chrysulca</i>),
-but if they be mixed together so much gas sylvestre
-is produced, that the vessels employed, however
-strong, will burst asunder, unless an opening be left
-for the escape of this gas.<a id="FNanchor_165" href="#Footnote_165" class="fnanchor">165</a> In the same way cream
-of tartar cannot be distilled in close vessels without
-breaking them in pieces, an opening must be left
-for the escape of the <i>gas sylvestre</i>, which is generated
-in such abundance.<a id="FNanchor_166" href="#Footnote_166" class="fnanchor">166</a> He says, also, that when
-carbonate of lime is dissolved in distilled vinegar, or
-silver in nitric acid, abundance of gas sylvestre is
-extricated. From these, and many other passages
-which might be quoted, it is evident that Van Helmont
-was aware of the evolution of gas during the
-solution of carbonates and metals in acids, and during
-the distillation of various animal and vegetable substances,
-that he had anticipated the experiments made
-so many years after by Dr. Hales, and for which that
-philosopher got so much credit. But it would be
-going too far to say, as some have done, that Van
-Helmont knew accurately the differences which characterize
-the different gases which he produced, or
-indeed that he distinguished accurately between them.
-For it is evident, from the passages quoted and from
-many others which occur in his treatise, De Flatibus,
-that carbonic acid, protoxide of azote, and deutoxide
-of azote, and probably also muriatic acid gas were
-all considered by him as constituting one and the
-same gas. How, indeed, could he distinguish between
-different gases when he was not acquainted
-with the method of collecting them, or of determining
-their properties? These observations of Van Helmont,
-then, though they do him much credit, and
-<span class="pagenum" id="Page_186">186</span>
-show how far his chemical knowledge was superior
-to that of the age in which he lived, take nothing
-from the merit or the credit of those illustrious chemists
-who, in the latter half of the eighteenth century,
-devoted themselves to the investigation of this part
-of chemistry, at that time attended with much difficulty,
-but intimately connected with the subsequent
-progress which the science has made.</p>
-
-<p>Van Helmont was aware, also, that the bulk of
-air is diminished when bodies are burnt in it. He
-considered respiration to be necessary in this way:
-the air was drawn into the blood by the pulmonary
-arteries and veins, and occasioned a fermentation in
-it requisite for the continuance of life.</p>
-
-<p>Gas, according to Van Helmont, has an affinity
-with the principle of the movement of the stars, to
-which he gave the name of <i>blas</i>. It had, he supposed,
-much influence on all sublunary bodies. He
-admitted in the ferment which gives birth to plants,
-a substance which, after the example of Paracelsus,
-he called <i>pessas</i>, and to the metallic ferment he gave
-the name of <i>bur</i>.<a id="FNanchor_167" href="#Footnote_167" class="fnanchor">167</a></p>
-
-<p>The archeus of Van Helmont, like that of Paracelsus,
-has its seat in the stomach. It is the same
-thing as the sentient soul. This notion of the nature
-and seat of the archeus was founded on the following
-experiment: He swallowed a quantity of <i>aconitum</i>
-(<i>henbane</i>). In two hours he experienced the most
-disagreeable sensation in his stomach. His feeling
-and understanding seemed to be concentrated in that
-organ, for he had no longer the free use of his mental
-faculties. This feeling induced him to place the seat
-of understanding in the stomach, of volition in the
-<span class="pagenum" id="Page_187">187</span>
-heart, and of memory in the brain. The faculty of
-desire, to which the ancients had assigned the liver
-as its organ, he placed in the spleen. What confirmed
-him still more in the idea that the stomach is
-the seat of the soul, is the fact, that life sometimes
-continues after the destruction of the brain, but never,
-he alleges, after that of the stomach. The sentient
-soul acts constantly by means of the <i>vital spirits</i>,
-which are of a resplendent nature, and the nerves
-serve merely to moisten these spirits which constitute
-the mediums of sensation. By virtue of the archeus
-man is much nearer to the realm of spirits and the
-father of all the genii, than to the world. He thinks
-that Paracelsus’s constant comparison of the human
-body with the world is absurd. Yet Van Helmont,
-at least in his youth, was a believer in magnetism,
-which he employed as a method of explaining the
-effect of sympathy.</p>
-
-<p>The archeus exercises the greatest influence on
-digestion, and he has chiefly the stomach and spleen
-under his superintendence. These two organs form a
-duumvirate in the body; for the stomach cannot act
-alone and without the concurrence of the spleen.
-Digestion is produced by means of an acid liquor,
-which dissolves the food, under the superintendence
-of the archeus. Van Helmont assures us that he had
-himself tasted this acid liquor in the stomach of birds.
-Heat, strictly speaking, does not favour digestion;
-for we see no increase of the digestive powers
-during the most ardent fever. Nor are the powers
-of digestion wanting in fishes, although they want
-the animal heat which is requisite for mammiferous
-animals. Certain birds even digest fragments of glass,
-which, certainly, simple heat would not enable them
-to do. The pylorus is, in some measure, the director
-of digestion. It acts by a peculiar and immaterial
-power, in virtue of a <i>blas</i>, and not as a muscle. It
-opens and shuts the stomach according to the orders
-<span class="pagenum" id="Page_188">188</span>
-of the archeus. It is in it, therefore, that the causes
-of derangement of digestion must be sought for.</p>
-
-<p>The duumvirate just spoken of is the cause of
-natural sleep, which does not belong to the soul,
-as far as it resides in the stomach. Sleep is a natural
-action, and one of the first vital actions. Hence the
-reason why the embryo sleeps without ceasing. At
-any rate it is not true that sleep is owing to vapours
-which mount to the brain. During sleep the soul
-is naturally occupied, and it is then that the deity
-approaches most intimately to man. Accordingly,
-Van Helmont informs us, that he received in dreams
-the revelation of several secrets, which he could not
-have learnt otherwise.</p>
-
-<p>The duumvirate operates the <i>first</i> digestion, of
-which, Van Helmont enumerates six different species.
-When the acid, which is prepared for digestion,
-passes into the duodenum it is neutralized by the
-bile of the gall-bladder. This constitutes the second
-digestion. To the bile of the gall-bladder, Van Helmont
-gave the name of <i>fel</i>, and he carefully distinguished
-it from the biliary principle in the mass
-of the blood. This last he called <i>bile</i>. The <i>fel</i> is
-not an excrementitious matter, but a humour necessary
-to life, a true vital balsam. Van Helmont
-endeavoured to show by various experiments that it
-is not <i>bitter</i>.</p>
-
-<p>The <i>third</i> digestion takes place in the vessels of
-the mesentery, into which the gall-bladder sends the
-prepared fluid. The <i>fourth</i> digestion is operated in
-the heart, where the red blood becomes more yellow
-and more volatile by the addition of the vital spirits.
-This is owing to the passage of the vital spirit from
-the posterior to the anterior ventricle, through the
-pores of the septum. At the same time the pulse
-is produced, which of itself develops heat; but does
-not regulate it in any manner, as the ancients pretended
-that it did. The <i>fifth</i> digestion consists in the
-<span class="pagenum" id="Page_189">189</span>
-conversion of the arterial blood into vital spirit. It
-takes place principally in the brain, but is produced
-also throughout all the body. The <i>sixth</i> digestion
-consists in the elaboration of the nutritive principle
-in each member, where the archeus prepares its own
-nourishment by means of the vital spirits. Thus,
-there are six digestions: the number seven has been
-chosen by nature for a state of repose.</p>
-
-<p>From the preceding sketch of the physiology of
-Van Helmont, it is evident that he paid little or no
-regard to the structure of the parts in explaining
-the functions. In his pathology we find the same
-passion for spiritualism. He admitted, indeed, the
-importance of anatomy, but he regretted that the
-pathological part of that science had been so little
-cultivated. As the archeus is the foundation of life
-and of all the functions, it is plain that the diseases
-can neither be derived from the four cardinal
-humours, nor from the disposition or the action of
-opposite things; the proximate cause of diseases must
-be sought for in the sufferings, the anger, the fear,
-and the other affections of the archeus, and their
-remote cause may be considered as the ideal seed
-of the archeus. Disease, in his opinion, is not a
-negative state or a mere absence of health, it is a
-substantial and active thing as well as a state of
-health. Most of the diseases which attack certain
-parts or members of the body result from an error
-in the archeus, who sends his ferment from the
-stomach in which he resides into the other parts of
-the body. Van Helmont explained in this way not
-only the epilepsy and madness, but likewise the <i>gout</i>,
-which does not proceed from a flux, and has not
-its seat in the limb in which the pain resides, but
-is always owing to an error in the vital spirit. It
-is true that the character of the gout acts upon the
-semen in which the vital spirit principally manifests
-its action, and that in this way diseases are propagated
-<span class="pagenum" id="Page_190">190</span>
-in the act of generation; but if, during life
-instead of altering the semen it is carried to the
-liquid of the articulations, this is a proof of the
-prudence of nature, which lavishes all her cares on
-the preservation of the species, and loves better to
-alter the humours of the articulations than the semen
-itself. The gout acidifies the liquors of the articulations,
-which is then coagulated by the acids. The
-duumvirate is the cause of apoplexy, vertigo, and
-particularly of a species of asthma, which Van Helmont
-calls <i>caducus pulmonalis</i>. Pleurisy is produced
-in a similar way. The archeus, in a movement
-of rage, sends acrid acids to the lungs, which occasion
-an inflammation. Dropsy is also owing to the
-anger of the archeus, who prevents the secretions of
-the kidneys from going on in the usual way.</p>
-
-<p>Of all the diseases, fever appeared to him most conformable
-to his notions of the unlimited power of the
-archeus. The causes of fever are all much more
-proper to offend the archeus, than to alter the structure
-of parts and the mixture of humours. The cold
-fit is owing to a state of fear and consternation, into
-which the archeus is thrown, and the hot stage results
-from his disordered movements. All fevers have their
-peculiar seat in the duumvirate.</p>
-
-<p>Van Helmont was in general much more successful
-in refuting the scholastic opinions by which the practice
-of medicine was regulated in his time, than in establishing
-his own. We are struck with the force of his arguments
-against the Galenical doctrine of fever, and
-against the influence of the cardinal humours on the
-different kinds of fever. He refuted no less vehemently
-the idea of the putridity of the blood, while that liquid
-circulates in the vessels. Perhaps he carried the opposite
-doctrine too far; but his opinions have had a
-good effect upon subsequent medical theory, and medical
-men learned from them to make less use of the
-term putridity. The phrase <i>mixture of humours</i>, not
-<span class="pagenum" id="Page_191">191</span>
-more intelligible, however, came to be substituted
-for it.</p>
-
-<p>Van Helmont’s theory of urinary calculi deserves
-peculiar attention, because it exhibits the germ of a
-more rational explanation of these concretions than
-had been previously attempted by physiologists. Van
-Helmont was aware that Paracelsus, who ascribed
-these concretions to tartar, had formed an idea of
-their nature, which a careful chemical analysis would
-immediately refute. He satisfied himself that urinary
-calculi differ completely from common stones, and
-that they do not exist in the food or drink which the
-calculous person had taken. Tartar, he says, precipitates
-from wine, not as an earth, but as a crystallized
-salt. In like manner, the natural salt of urine
-precipitates from that liquid, and gives origin to calculi.
-We may imitate this natural process by mixing
-spirit of urine with rectified alcohol. Immediately an
-<i>offa alba</i> is precipitated.</p>
-
-<p>It is needless to observe that Van Helmont was
-mistaken, in supposing that this <i>offa</i> was the matter
-of calculus. Spirit of urine was a strong solution of
-carbonate of ammonia. The alcohol precipitated this
-salt; so that his <i>offa</i> was merely <i>carbonate of ammonia</i>.
-Nor is there the shadow of evidence that alcohol,
-as Van Helmont thought it did, ever makes its way
-into the mass of humours; yet his notion of the origin
-of calculi is not less accurate, though of course he
-was ignorant of the chemical nature of the various
-substances which constitute these calculi. From this
-reasoning Van Helmont was induced to reject the
-term <i>tartar</i>, employed by Paracelsus. To avoid all
-false interpretations he substitutes the word <i>duelech</i>,
-to denote the state in which the spirit of urine precipitates
-and gives origin to these calculous concretions.</p>
-
-<p>As all diseases proceeded in his opinion from the
-archeus, the object of his treatment was to calm the
-archeus, to stimulate it, and to regulate its movements.
-<span class="pagenum" id="Page_192">192</span>
-To accomplish these objects he relied upon dietetics,
-and upon acting on the imaginations of his patients.
-He considered <i>certain words</i> as very efficacious in
-curing the diseases of the archeus. He admitted the
-existence of the universal medicine, to which he gave
-the names of <i>liquor alkahest</i>, <i>ens primum salium</i>,
-<i>primus metallus</i>. Mercurials, antimonials, opium,
-and wine, are particularly agreeable to the archeus,
-when in a state of delirium from fever.</p>
-
-<p>Among the mercurial preparations, he praises what
-he calls <i>mercurius diaphoreticus</i> as the best. He
-gives no account of the mode of preparing it; but
-from some circumstances I think it must have been
-<i>calomel</i>. He considers it as a sovereign remedy
-in fevers, dropsies, diseases of the liver, and ulcers of
-the lungs. He employed the red oxide of mercury
-as an external application to ulcers. The principal
-antimonial preparations which he employed were the
-hydrosulphuret, or <i>golden sulphur</i>, and the deutoxide,
-or <i>antimonium diaphoreticum</i>. This last medicine
-was used in scruple doses&mdash;a proof of its great inertness
-compared with the protoxide of antimony.</p>
-
-<p>Opium he considered as a fortifying and calming
-medicine. It contains an acrid salt and a bitter oil,
-which give it the virtue of putting a stop to the errors
-of the archeus, when it was sending its acid ferment
-into other acid parts of the body. Van Helmont assures
-us that he wrought many important cures by the
-employment of wine.</p>
-
-<p>Such is a very short statement of the opinions of a
-man, who, notwithstanding his attachment to the fanatical
-opinions which distinguished the time in which
-he lived, had the merit of overturning a vast number
-of errors, both theoretical and practical; and of laying
-down many principles, which, for want of erudition,
-have been frequently assigned to modern writers. Van
-Helmont has been frequently placed on the same level
-with Paracelsus, and treated like him with contempt.
-<span class="pagenum" id="Page_193">193</span>
-But his claims upon the medical world are much
-higher, and his merits infinitely greater. His notions,
-it is true, were fanatical; but his erudition was great,
-his understanding excellent, and his industry indefatigable.
-His writings did not become known till rather
-a late period; for, with the exception of a single tract,
-they were not published till 1648, by his son, after his
-death.</p>
-
-<p>The decided preference given to chemical medicines
-by Van Helmont, and the uses to which he applies
-chemical theory, had a natural tendency to raise chemistry
-to a higher rank in the eyes of medical men
-than it had yet reached. But the man to whom the
-credit of founding the iatro-chemical sect is due, is
-Francis de le Bo&eacute; Sylvius, who was born in the year
-1614. While a practitioner of medicine at Amsterdam,
-he studied with profound attention the system of Van
-Helmont, and the rival and much more popular theory
-of Descartes: upon these he founded his own theory,
-which, in reality, contains little entitled to the name
-of original, notwithstanding the tone in which he
-speaks of it, and his repeated declarations that he had
-borrowed from no one. He was appointed professor
-of the theory and practice of medicine in the University
-of Leyden, where he taught with such eclat, and drew
-after him so great a number of pupils, that Boerhaave
-alone surpassed him in this respect. It was he that
-first introduced the practice of giving clinical lectures
-in the hospitals, on the cases treated in the presence
-of the pupils. This admirable innovation has been
-productive of much benefit to medicine. He greatly
-promoted anatomical studies, and inspected, himself, a
-vast number of dead bodies. This is the more remarkable,
-because his own system, like that of Van
-Helmont, from whom it was borrowed, was quite independent
-of the structure of the parts.</p>
-
-<p>Every thing was explained by him according to the
-principles of chemistry, as they were then understood.
-<span class="pagenum" id="Page_194">194</span>
-The celebrity of the university in which he taught,
-and the vast number of his pupils, contributed to
-spread this theory into every part of the world, and to
-give it an eclat which is really surprising, when we
-consider it with attention. But he possessed the
-talents just suited for securing the reception of his
-opinions by his pupils as infallible oracles, and of
-being the idol of the university. Yet it is melancholy
-to be obliged to add, that few persons ever more
-abused the favours of nature, or the advantages of
-situation and elocution.</p>
-
-<p>To form a clear idea of the principles of this founder
-of iatro-chemistry, we have only to call to mind the
-ferments of Van Helmont, which constitute the foundation-stone
-of the whole system. We cannot, says
-he, conceive a single change in the mixture of the
-humours, which is not the consequence of fermentation;
-and yet he assigns to this fermentation conditions
-which are scarcely to be found united in the
-living body. Digestion, in his opinion, is a true fermentation
-produced by the application of a ferment.
-Like Van Helmont, he admits a <i>triumvirate</i>; but places
-it in the humours; the effervescence or fermentation of
-which enabled him to explain most of the functions
-of the body. Digestion is the result of the mixture of
-the saliva with the pancreatic juice and the bile, and
-the fermentation of these humours. The saliva, as
-well as the pancreatic juice, contains an acidulous
-salt easily recognised by the taste. Here Sylvius derives
-advantage from the experiments of Regnier de
-Graaf on the pancreatic juice, which he had constantly
-found acid.</p>
-
-<p>Sylvius, who affirmed that the bile contained an
-alkali, united with an oil and a volatile spirit, supposes
-an effervescence from the union of the alkali of the
-bile with the acid of the pancreatic juice, and this <i>fermentation</i>
-he considered as the cause of digestion.
-By this fermentation the <i>chyle</i> is produced, which is
-<span class="pagenum" id="Page_195">195</span>
-nothing else than the <i>volatile spirit</i> of the food accompanied
-by an <i>oil</i> and an alkali, neutralized by a weak
-acid. The blood is more than completed (<i>plus quam
-perficitur</i>) in the spleen. It acquires its highest
-perfection by the addition of a certain quantity of
-vital spirits. The <i>bile</i> is not drawn from the blood
-in the liver, but pre-exists in the circulating fluid.
-It mixes with that fluid anew to be carried to the
-heart together with the <i>lymph</i>, equally mixed with the
-blood, and there it gives origin to a vital fermentation.
-In this way the blood becomes the centre of reunion
-of all the humours of the secretions, which mix together
-or separate, without the solids taking the smallest
-share in the operations. Indeed, so completely
-are the solids banished from the system of Sylvius that
-he attends to nothing whatever except the humours.</p>
-
-<p>The formation and motion of the blood is explained
-by the fermentation of the oily volatile salt of the bile,
-and the dulcified acid of the lymph, which develops
-the vital heat, by which the blood is attenuated and
-becomes capable of circulating. This vital fire, quite
-different from ordinary fire is kept up in its turn by
-the uniform mixture of the blood. It attenuates the
-humours, not because it is <i>heat</i> but because it is composed
-of <i>pyramids</i>. This last notion is obviously
-borrowed from Descartes, just as the fermentation
-in the heart, as the cause of the motion of the blood,
-reminds us of the opinions of Van Helmont.</p>
-
-<p>Sylvius explains the preparation of the vital spirits
-in the encephalos by distillation, and he finds a great
-resemblance between their properties and those of
-spirit of wine. The nerves conduct these spirits to
-the different parts, and they spread themselves in
-the substance of the organs to render them sensible.
-When they insinuate themselves into the glands the
-addition of the acid of the blood produces a liquid
-analogous to naphtha, which constitutes the <i>lymph</i>.
-Lymph, then, is a compound of the vital spirit and
-<span class="pagenum" id="Page_196">196</span>
-the acid of the blood. <i>Milk</i> is formed in the mamm&aelig;
-by the afflux of a very mild acid, which gives a white
-colour to the red humour of the blood.</p>
-
-<p>The theory of the natural functions was no less
-chemical. Even the diseases themselves were explained
-upon chemical principles. Sylvius first introduced
-the word <i>acridity</i> to denote a predominance of
-the chemical elements of the humours, and he looked
-upon these <i>acridities</i> as the proximate cause of all
-diseases. But as every thing acrid may be referred to
-one or other of two classes, acids and alkalies, there
-are only two great classes of diseases; namely, those
-proceeding from an <i>acid acridity</i>, and those proceeding
-from an <i>alkaline</i>.</p>
-
-<p>Sylvius was not altogether ignorant of the constituent
-parts of the animal humours; but it is obvious,
-from the account of his opinions just given, that this
-knowledge was very incomplete; indeed the whole of
-his chemical science resolves itself into a comparison
-of the humours of the living body with chemical
-liquids. Perhaps his notions respecting such of the
-<i>gases</i>, as he had occasion to observe, were somewhat
-clearer than those of Van Helmont. He called them
-<i>halitus</i>, and takes some notice of their different chemical
-properties, and states the influence which he
-supposes them to exert in certain diseases.</p>
-
-<p>In the human body he saw nothing but a magna of
-humours continually in fermentation, distillation, effervescence,
-or precipitation; and the physician was degraded
-by him to the rank of a distiller or a brewer.</p>
-
-<p>Bile acquires different acridities, when bad food,
-altered air, or other similar causes act apon the body.
-It becomes <i>acid</i> or <i>alkaline</i>. In the former case it
-thickens and occasions obstructions; in the latter it
-excites febrile heat; and the viscid vapours elevated
-from it are the cause of the cold fit with which fever
-commences. All acute and continued fevers have
-their origin in this acridity of the bile. The vicious
-<span class="pagenum" id="Page_197">197</span>
-mixture of the bile with the blood, or its specific acridity,
-produces <i>jaundice</i>, which is far from being always
-owing to obstructions in the liver. The vicious
-effervescence of the bile with the pancreatic juice produces
-almost all other diseases. But all these assertions
-of Sylvius are unsupported by evidence.</p>
-
-<p>The acid acridity of the pancreatic juice, and the
-obstruction of the pancreatic ducts, which are produced
-by it, are considered by him as the cause of
-intermittent fevers. When the acid of the pancreatic
-juice acquires still more acridity, hypochondriasis and
-hysteria are the consequences of it. If, during the
-morbid effervescence of the pancreatic juice with the
-bile an acid and viscid humour arise, the vital spirits
-of the heart are overwhelmed during a certain time.
-This occasions syncope, palpitation of the heart, and
-other nervous affections.</p>
-
-<p>When the acid acridity of the pancreatic juice or of
-the lymph (for both are similar) is deposited on the
-nerves, the consequence is spasms or convulsions;
-epilepsy in particular depends upon the acrid vapours
-produced by the morbid effervescence of the pancreatic
-juice with acrid bile. Gout has the same origin
-as intermittent fevers, for we must look for it in the
-obstruction of the pancreas and the lymphatic glands,
-accompanied with an acid acridity of the lymph.
-Rheumatism is owing to the acrid acid, deprived of
-the oil which dulcifies it. The smallpox is occasioned
-by an acid acridity in the lymph, which gives origin
-to the pustules. Indeed all suppuration in general
-is owing to a coagulating acid in the lymph. Syphilis
-results from a caustic acid in the lymph. The itch is
-produced by an acid acridity of the lymph. Dropsies
-are produced by the same acid acridity of the lymph.
-Urinary calculi are the consequences of a coagulating
-acid existing in the lymph and the pancreatic juice.
-Corrosive acids, and the loss of volatile spirits,
-occasion leucorrhœa.
-<span class="pagenum" id="Page_198">198</span></p>
-
-<p>From the preceding statement it would appear that
-almost all diseases proceed from acids. However,
-Sylvius informs us that malignant fevers are owing to
-a superabundance of volatile salts and to a too great
-tenuity of the blood. The vital spirits themselves give
-occasion to diseases. They are sometimes too aqueous,
-sometimes they effervesce too violently, and sometimes
-not at all. Hence all the nervous diseases, which
-Sylvius never considers as existing by themselves;
-but as always derived from the acid, acrid, or alkaline
-vapours which trouble the vital spirits.</p>
-
-<p>The method of cure which Sylvius deduced from
-these absurd and contemptible hypotheses, was worthy
-of the hypotheses themselves; and certainly constitute
-the most detestable mode of treatment that ever has
-disgraced medical science. To diseases produced by
-the effervescence of the bile he opposed purgatives;
-because in his opinion emetics produced injurious
-effects. The reason was, that the emetics which he
-employed were too violent, consisting of antimonial
-preparations, particularly <i>powder of Algerotti</i>, or an
-impure protoxide of antimony. For though <i>emetic
-tartar</i> had been discovered in 1630, it does not seem
-to have come into use till a much later period. We
-do not find any notice of it in the <i>praxis chymiatrica</i>
-of Hartmann published in 1647, at Geneva.</p>
-
-<p>He endeavoured to moderate the acridity of the bile
-by opiates and other narcotics. It will scarcely be
-believed, though it was a natural consequence of his
-opinions, when we state that he recommended ammoniacal
-preparations, particularly his oleaginous volatile
-salt, and spirit of hartshorn, &amp;c., as cures for almost
-all diseases. Sometimes they were employed to correct
-the acidity of the lymph, sometimes to destroy the
-acid acridity of the pancreatic juice, sometimes to
-correct the inertness of the vital spirits, sometimes to
-promote the secretions, and to induce a flow of the
-menses. Volatile spirit of amber and opium were
-<span class="pagenum" id="Page_199">199</span>
-prescribed by him in intermittent fevers; and volatile
-salts in almost all acute diseases. He united them
-with antivenomous potions, angelica, contrayerva, bezoard,
-crabs’ eyes, and other similar substances. These
-absorbents seemed to him very necessary to correct
-the acidity of the pancreatic juice, and the acridity of
-the bile. In administering them he paid no attention
-to the regular course which acute diseases usually
-run; he neither inquired into the remote nor proximate
-causes of disease, nor to the symptoms: every thing
-was neglected connected with induction, and his
-whole proceedings regulated by wild speculations and
-absurd theories, quite inconsistent with the phenomena
-of nature.</p>
-
-<p>To attempt to refute these wild notions of Sylvius
-would be loss of time. It is extraordinary, and almost
-incredible, that he could have regulated his practice
-by them: and it is a still more incredible thing, and
-exhibits a very humiliating view of human nature,
-that these crudities and absurdities were swallowed
-with avidity by crowds of students, who placed a blind
-reliance on the dogmas of their master, and were
-initiated by him into a method of treating their patients,
-better calculated than any other that could easily have
-been devised, to aggravate all their diseases, and put
-an end to their lives. If any of the patients of the
-iatro-chemists ever recovered their health, well might
-it be said that their recovery was not the consequence
-of the prescriptions of their physicians, but that it took
-place in spite of them.<a id="FNanchor_168" href="#Footnote_168" class="fnanchor">168</a>
-<span class="pagenum" id="Page_200">200</span></p>
-
-<p>It is a very remarkable circumstance, and shows
-clearly that mankind in general had become disgusted
-with the dogmas of the Galenists, that iatro-chemistry
-was adopted more or less completely by almost
-all physicians. There were, indeed, a few individuals
-who raised their voices against it; but, what
-is curious and inexplicable, they never attempted to
-start objections against the principles of the iatro-chemists,
-or to point out the futility of their hypothesis,
-and their inconsistency with fact. They combated
-them by arguments not more solid than those of
-their antagonists.</p>
-
-<p>During the presidency of Riolan over the Medical
-College of Paris, that learned body set itself against
-all innovations. Guy Patin, who was a medical professor
-in the University of Paris, and a man of great
-celebrity, opposed the chemical system of medicine
-with much zeal. In his Martyrologium Antimonii he
-collects all the cases in which the use of antimony, as
-a medicine, had proved injurious to the patient. But
-in the year 1666, the dispute relative to antimony,
-and particularly relative to tartar emetic, became so
-violent, that all the doctors of the faculty of Paris
-were assembled by an order of the parliament, under
-the presidency of Dean Vignon, and after a long
-deliberation, it was concluded by a majority of
-ninety-two votes, that tartar emetic, and other antimonials,
-should not only be permitted, but even recommended.
-Patin after this decision pretended no
-longer to combat chemical medicine; but he did not
-remain inactive. One of his friends, Francis Blondel,
-demanded the resolution to be cancelled; but his exertions
-were unsuccessful; nor were the writings of
-Guillemeau and Menjot, who were also keen partisans
-of the views of Patin, attended with better success.</p>
-
-<p>In England iatro-chemistry assumed a direction
-quite peculiar. It was embraced by a set of men who
-had cultivated anatomy with the most marked success,
-<span class="pagenum" id="Page_201">201</span>
-and who were quite familiar with the experimental
-method of investigating nature. The most eminent
-of all the English supporters of iatro-chemistry was
-Thomas Willis, who was a contemporary of Sylvius.</p>
-
-<p>Dr. Willis was born at Great Bodmin, in Wiltshire,
-in 1621. He was a student at Christchurch College,
-in Oxford, when that city was garrisoned for King
-Charles I. Like the other students, he bore arms for
-his Majesty, and devoted his leisure hours to the study
-of physic. After the surrender of Oxford to the parliament,
-he devoted himself to the practice of medicine,
-and soon acquired reputation. He appropriated
-a room as an oratory for divine service, according to
-the forms of the church of England, to which most of
-the loyalists of Oxford daily resorted. In 1660, he
-became Sedleian professor of natural philosophy, and
-the same year he took the degree of doctor of physic.
-He settled ultimately in London, and soon acquired
-a higher reputation, and a more extensive practice,
-than any of his contemporaries. He died in 1675,
-and was buried in Westminster Abbey. He was a
-first-rate anatomist. To him we are indebted for the
-first accurate description of the brain and nerves.</p>
-
-<p>But it is as an iatro-chemist that he claims a place
-in this work. His notions approach nearer to those
-of Paracelsus than to the hypotheses of Van Helmont
-and Sylvius. He admits the three chemical elements
-of Paracelsus, salt, sulphur, and mercury, in all the
-bodies in nature, and employs them to explain their
-properties and changes; but he gives the name of
-<i>spirit</i> to the <i>mercury</i> of Paracelsus. He ascribes to
-it the virtue of volatilizing all the constituent parts of
-bodies: salt, on the other hand, is the cause of fixity
-in bodies; <i>sulphur</i> produces colour and heat, and
-unites the <i>spirit</i> to the <i>salt</i>. In the stomach there
-occurs an acid ferment, which forms the chyle with
-the sulphur of the aliments: this chyle enters into
-effervescence in the heart, because the salt and sulphur
-<span class="pagenum" id="Page_202">202</span>
-take fire together. From this results the vital
-flame, which penetrates every thing. The vital spirits
-are secreted in the brain by a real distillation. The
-vessels of the testes draw an elixir from the constituent
-parts of the blood; but the spleen retains the earthy
-part, and communicates a new igneous ferment to the
-circulating fluid. On this account the blood must be
-considered as a humour, constantly disposed to fermentation,
-and in this respect it may be compared to
-wine. Every humour in which salt, sulphur, and
-spirit predominates in a certain manner, may be converted
-into a <i>ferment</i>. All diseases proceed from a
-morbid state or action of this ferment; and a physician
-may be compared to a wine-merchant; for, like
-him, he has nothing to do but to watch that the necessary
-fermentations take place with regularity, and
-that no foreign substance come to derange the operation.</p>
-
-<p>At this period the mania of explaining every thing
-had proceeded to such a length, that no distinction
-was made between dead and living bodies. The chemical
-facts which were at that time known, were applied
-without hesitation to explain all the functions
-and all the diseases of the living body. According to
-Willis, fever is the simple result of a violent and preternatural
-effervescence of the blood and the other
-humours of the body, either produced by external
-causes, or by internal ferments, into which the chyle
-is converted when it mixes with the blood. The effervescence
-of the vital spirits is the source of quotidians;
-that of salt and sulphur produces continued fever;
-and external ferments of a malignant nature produce
-malignant fevers. Thus the smallpox is owing to the
-seeds of fermentation set in activity by an external
-principle of contagion. Spasms and convulsions are
-produced by an explosion of the salt and sulphur
-with the animal spirits. Hypochondriacal affections
-and hysteria depend originally on the morbid putrifaction
-<span class="pagenum" id="Page_203">203</span>
-of the blood in the spleen, or on a bad fermentescible
-principle, loaded with salt and sulphur, which
-unites with the vital spirits and deranges them. Scurvy
-is owing to an alteration of the blood, which may then
-be compared to vapid or stale wine. The gout is
-merely the coagulation of the nutritive juices altered
-by the acidified animal spirits; just as sulphuric acid
-forms a coagulum with carbonate of potash.</p>
-
-<p>The action of medicines is easily explained by the
-effects which they produce on the nourishing principles.
-Sudorifics are considered as cordials, because they
-augment the sulphur of the blood, which is the true
-food of the vital flame. Cordials purify the animal
-spirits, and fix the too volatile blood. Willis disagrees
-with the other iatro-chemists of his time in one
-thing: he recommends bleeding in the greater number
-of diseases, as an excellent method of diminishing
-unnatural fermentation.</p>
-
-<p>Dr. Croone, a celebrated Fellow of the Royal Society,
-was another English iatro-chemist, who attempted
-to explain muscular motion by the effervescence of
-the nervous fluid, or animal spirits.</p>
-
-<p>It is not worth while to notice the host of writers&mdash;English,
-French, Italian, Dutch, and German, who
-exerted themselves to maintain, improve, and defend,
-the chemical doctrines of medicine. The first person
-who attempted to overturn these absurd doctrines,
-and to introduce something more satisfactory in their
-place, was Mr. Boyle, at that time in the height of
-his celebrity.</p>
-
-<p>Robert Boyle was born at Youghall, in the province
-of Munster, on the 25th of January, 1627. He
-was the seventh son, and the fourteenth child of
-Richard, Earl of Cork. He was partly educated at
-home, and partly at Eton, where he was under the
-tuition of Sir Henry Wotton. At the age of eleven,
-he travelled with his brother and a French tutor
-through France to Geneva, where he pursued his
-<span class="pagenum" id="Page_204">204</span>
-studies for twenty-one months, and then went to
-Italy. During this period, he acquired the French
-and Italian languages; and, indeed, talked in the former
-with so much fluency and correctness, that he
-passed, when he thought proper, for a Frenchman. In
-1642, his father’s finances were deranged, by the
-breaking out of the great Irish rebellion. His tutor,
-who was a Genevese, was obliged to borrow, on his
-own credit, a sum of money sufficient to carry him
-home. On his arrival, he found his father dead; and,
-though two estates had been left to him, such was the
-state of the times, that several years elapsed before he
-could command the requisite sum of money to supply
-his exigencies. He retired to an estate at Stalbridge,
-in Dorsetshire.</p>
-
-<p>In 1654 he went to Oxford, where he associated
-himself with a number of eminent men (Dr. Willis
-among others), who had constituted themselves into a
-combination for experimental investigations, distinguished
-by the name of the <i>Philosophical College</i>.
-This society was transferred to London; and, in 1663,
-was incorporated by Charles II. under the name of the
-<i>Royal Society</i>. In 1668 Mr. Boyle took up his residence
-in London, where he continued till the last day
-of December, 1691, assiduously occupied in experimental
-investigations, on which day he died, in the
-sixty-fifth year of his age.</p>
-
-<p>We are indebted to Mr. Boyle for the first introduction
-of the air-pump and the thermometer into
-Britain, and for contributing so much, by means of
-Dr. Hooke, to the improvement of both. His hydrostatical
-and pneumatical investigations and experiments
-constitute the foundation of these two sciences.
-The thermometer was first made an accurate instrument
-of investigation by Sir Isaac Newton, in 1701.
-This he did by selecting as two fixed points the temperatures
-at which water freezes and boils; marking
-these upon the stem of the thermometer, and dividing
-<span class="pagenum" id="Page_205">205</span>
-the interval between them into a certain number of degrees.
-All thermometers made in this way will stand at
-the same point when plunged into bodies of the same
-temperature. The number of divisions between the freezing
-and boiling points constitute the cause of the differences
-between different thermometers. In Fahrenheit’s
-thermometer, which is used in Great Britain, the number
-of degrees, between the freezing and boiling points
-of water, is 180; in Reaumur’s it is 80; in Celsius’s, or
-the centigrade, it is 100; and in De Lisle’s it is 150.</p>
-
-<p>But my reason for mentioning Mr. Boyle here was,
-the attempt which he made in 1661, by the publication
-of his Sceptical Chemist, to overturn the absurd
-opinions of the iatro-chemists. He raises doubts, not
-only respecting the existence of the elements of the
-Peripatetics, but even of those of the chemists. The
-first elements of bodies, in his opinion, are <i>atoms</i>, of
-different shapes and sizes; the union of which gives
-origin to what we vulgarly call <i>elements</i>. We cannot
-restrain the number of these to four, as the Peripatetics
-do; nor to three, with the chemists: neither are they
-immutable, but convertible into each other. Fire is
-not the means that ought to be employed to obtain
-them; for the <i>salt</i> and <i>sulphur</i> are formed during its
-action by the union of different simple bodies.</p>
-
-<p>Boyle shows, besides, that the chemical theory of
-qualities is exceedingly inaccurate and uncertain; because
-it takes for granted things which are very doubtful,
-and in many cases directly contrary to the phenomena
-of nature. He endeavours to prove the truth of
-these ideas, and particularly the production of the
-chemical principles, by a great number of convincing
-and conclusive experiments.</p>
-
-<p>In another treatise, entitled “The Imperfections of
-the Chemical Doctrine of Qualities,”<a id="FNanchor_169" href="#Footnote_169" class="fnanchor">169</a> he points out, in
-the second section, the insufficiency of the hypotheses of
-<span class="pagenum" id="Page_206">206</span>
-Sylvius relative to the generality of acids and alkalies.
-He shows that the offices ascribed to them are arbitrary,
-and the notions respecting them unsettled; that the
-hypotheses respecting them are needless, and insufficient,
-and afford but an unsatisfactory solution of the
-phenomena.</p>
-
-<p>These arguments of Boyle did not immediately shake
-the credit of the chemical system. In the year 1691,
-a chemical academy was founded at Paris by Nicolas
-de Blegny, the express object of which was to examine
-these objections of Boyle, which by this time had attracted
-great attention. Boyle’s experiments were repeated
-and confirmed; but the academicians, notwithstanding,
-came to the conclusion, that it is unnecessary
-to have recourse to the true elements of
-bodies; and that the phenomena which occur in the
-animal economy may be explained by the predominance
-of acids or alkalies. Various other publications
-appeared, all on the same side.</p>
-
-<p>In Germany, Hermann Conringius, the most skilful
-physician of his time, opposed the chemical theory;
-and his opinions were impugned by Olaus Borrichius,
-who defended not only alchymy, but the chemical
-theory of medicine, with equal erudition and zeal.<a id="FNanchor_170" href="#Footnote_170" class="fnanchor">170</a></p>
-
-<p>Towards the end of the sixteenth century, the chemists
-thought of examining the liquids of the living
-body, to ascertain whether they really contained the
-acids and alkalies which had been assigned them, and
-considered as the cause of all diseases. But at that
-time chemistry had made so little progress, and such
-was the want of skill of those who undertook these investigations,
-that they readily obtained every thing
-that was wanted to confirm their previous notions.
-John Viridet, a physician of Geneva, announced that
-he had found an acid in the saliva and the pancreatic
-juice, and an alkali in the gastric juice and the bile.
-<span class="pagenum" id="Page_207">207</span>
-But the most celebrated experiments of that period
-were those of Raimond Vieussens, undertaken in 1698,
-in order to discover the presence of an acid spirit in
-the blood. His method was, to mix blood with a
-species of clay, called <i>bole</i>, and to subject the mixture
-to distillation. He found that the liquid distilled over
-was acid. Charmed with this discovery, which he considered
-as of first-rate importance, he announced it by
-letter to the different academies and colleges in Europe.
-Some doubts being raised about the accuracy
-of his experiment, it having been alleged that the acid
-came from the clay which he had mixed with the
-blood, and not from the blood itself, Vieussens purified
-the <i>bole</i> from all the acid which it could contain,
-and repeated his experiment again. The result was
-the same&mdash;the acrid salt of the fluid yielded an acid
-spirit.</p>
-
-<p>It would be needless in the present state of our
-knowledge to point out the inaccuracy of such an
-experiment, or how little it contributed to prove that
-blood contains a free acid. It is now well known to
-chemists, that blood is remarkably free from acids;
-and, that if we except a little common salt, which exists
-in all the liquids of the human body, there is neither
-any acid nor salt whatever in that liquid.</p>
-
-<p>Michael Ettmuller, at Leipsic, who was a chemist
-of some eminence in his day, and published a small
-treatise on the science, which was much sought after,
-was also a zealous iatro-chemist; but his opinions
-were obviously regulated by the researches of Boyle.
-He denies the existence of acids and alkalies in certain
-bodies, and distinguishes carefully between acid
-and putrid fermentation.</p>
-
-<p>One of the most formidable antagonists to the iatro-chemical
-doctrines was Dr. Archibald Pitcairne, first
-a professor of medicine in the University of Leyden,
-and afterwards of Edinburgh, and one of the most
-eminent physicians of his time. He was born in Edinburgh,
-<span class="pagenum" id="Page_208">208</span>
-on the 25th of December, 1652. After finishing
-his school education in Dalkeith, he went to the
-University of Edinburgh, where he improved himself in
-classical learning, and completed a regular course of
-philosophy. He turned his attention to the law, and
-prosecuted his studies with so much ardour and intensity
-that his health began to suffer. He was advised
-to travel, and set out accordingly for the South of
-France: by the time he reached Paris he was so far
-recovered that he determined to renew his studies;
-but as there was no eminent professor of law in that
-city, and as several gentlemen of his acquaintance
-were engaged in the study of medicine, he went with
-them to the lectures and hospitals, and employed himself
-in this way for several months, till his affairs called
-him home.</p>
-
-<p>On his return he applied himself chiefly to mathematics,
-in which, under the auspices of his friend, the
-celebrated Dr. David Gregory, he made uncommon
-progress. Struck with the charms of this science, and
-hoping by the application of it to medicine to reduce
-the healing art under the rigid rules of mathematical
-demonstration, he formed the resolution of devoting
-himself to the study of medicine. There was at that
-time no medical school in Edinburgh, and no hospital
-at which he could improve himself; he therefore repaired
-to Paris, and devoted himself to his studies with
-a degree of ardour that ensured an almost unparalleled
-success. In 1680 he received from the faculty
-of Rheims the degree of doctor of medicine, a degree
-also conferred on him in 1699 by the University of
-Aberdeen.</p>
-
-<p>In the year 1691 his reputation was so high that
-the University of Leyden solicited him to fill the medical
-chair, at that time vacant; he accepted the invitation,
-and delivered a course of lectures at Leyden, which
-was greatly admired by all his auditors, among whom
-were Boerhaave and Mead. At the close of the session
-<span class="pagenum" id="Page_209">209</span>
-he set out for Scotland, to marry the daughter
-of Sir Archibald Stevenson: his friends in his own
-country would not consent to part with him, and thus
-he was reluctantly obliged to resign his chair in the
-University of Leyden.</p>
-
-<p>He settled as a physician in Edinburgh, where he
-was appointed titular professor of medicine. His
-practice extended beyond example, and he was more
-consulted by foreigners than any Edinburgh physician
-either before or after his time. He died in October,
-1713, admired and regretted by the whole country.
-He was a zealous supporter of iatro-mathematics, and
-as such a professed antagonist of the iatro-chemists.
-He refuted their opinions with much strength of reasoning,
-while his high reputation gave his opinions an
-uncommon effect; so that he contributed perhaps as
-much as any one, to put a period to the most disgraceful,
-as well as dangerous, set of opinions that
-ever overspread the medical horizon.</p>
-
-<p>Into the merits of the iatro-mathematicians it is not
-the business of this work to enter; they at least display
-science, and labour, and erudition, and in all
-these respects are far before the iatro-chemists. Perhaps
-their own opinions were not more agreeable to
-the real structure of the human body, nor their practice
-more conformable to reason, or more successful
-than those of the chemists. Probably the most valuable
-of all Dr. Pitcairne’s writings, is his vindication
-of the claims of Hervey to the great discovery of the
-circulation.</p>
-
-<p>Boerhaave, the pupil of Pitcairne, and afterwards a
-professor in Leyden, was a no less zealous or successful
-opponent of the iatro-chemists.</p>
-
-<p>Herman Boerhaave, perhaps the most celebrated
-physician that ever existed, if we except Hippocrates,
-was born at Voorhout, a village near Leyden, in 1668,
-<span class="pagenum" id="Page_210">210</span>
-where his father was the parish clergyman. At the
-age of sixteen he was left without parents, protection,
-advice, or fortune. He had already studied theology,
-and the other branches of knowledge that are considered
-as requisite for a clergyman, to which situation
-he aspired; and while occupied with these studies
-he supported himself at Leyden by teaching mathematics
-to the students&mdash;a branch of knowledge to
-which he had devoted himself with considerable ardour
-while living in his father’s house. But, a report being
-raised that he was attached to the doctrines of Spinoza,
-the clamour against him was so loud that he
-thought it requisite to renounce his intention of going
-into <i>orders</i>.<a id="FNanchor_171" href="#Footnote_171" class="fnanchor">171</a> He turned his studies to medicine, and
-the branches of science connected with that pursuit,
-and these delightful subjects soon engrossed the whole
-of his attention. In 1693 he was created doctor of
-medicine, and began to practise. He continued to
-teach mathematics for some time, till his practice increased
-sufficiently to enable him to live by his fees.
-His spare money was chiefly laid out upon books; he
-also erected a chemical laboratory, and though he had
-no garden he paid great attention to the study of
-plants. His reputation increased with considerable
-rapidity; but his fortune rather slowly. He was invited
-to the Hague by a nobleman, who stood high in
-the favour of William III., King of Great Britain; but
-he declined the invitation. His three great friends,
-to whom he was in some measure indebted for his
-success, were James Trigland, professor of theology,
-<span class="pagenum" id="Page_211">211</span>
-Daniel Alphen, and John Van den Berg, both of them
-successively chief magistrates of Leyden, and men of
-great influence.</p>
-
-<p>Van den Berg recommended him to the situation of
-professor of medicine in the University of Leyden, to
-which chair he was raised, fortunately for the reputation
-of the university, on the death of Drelincourt, in 1702.
-He not only gave public lectures on medicine, but
-was in the habit also of giving private instructions to
-his pupils. His success as a teacher was so great, that
-a report having been spread of his intention to quit
-Leyden, the curators of the university added considerably
-to his salary on condition that he would not
-leave them.</p>
-
-<p>This first step towards fortune and eminence having
-been made, others followed with great rapidity. He
-was appointed successively professor of botany and of
-chemistry, while rectorships and deanships were showered
-upon him with an unsparing hand. And such
-was the activity, the zeal, and the ability with which
-he filled all these chairs, that he raised the University
-of Leyden to the very highest rank of all the universities
-of Europe. Students flocked to him from all
-quarters&mdash;every country of Europe furnished him with
-pupils; Leyden was filled and enriched by an unusual
-crowd of strangers. Though his class-rooms were
-large, yet so great was the number of students, that it
-was customary for them to keep places, just as is done
-in a theatre when a first-rate actor is expected to perform.
-He died in the year 1738, while still filling the
-three different chairs with undiminished reputation.</p>
-
-<p>It is not our object here to speak of Boerhaave as a
-physician, or as a teacher of medicine, or of botany;
-though in all these capacities he is entitled to the very
-highest eulogium; his practice was as unexampled as
-his success as a teacher. It is solely as a chemist that
-he claims our attention here. His system of chemistry,
-published in two quarto volumes in 1732, and of which
-<span class="pagenum" id="Page_212">212</span>
-we have an excellent English translation by Dr. Shaw,
-printed in 1741, was undoubtedly the most learned
-and most luminous treatise on chemistry that the world
-had yet seen; it is nothing less than a complete collection
-of all the chemical facts and processes which
-were known in Boerhaave’s time, collected from a
-thousand different sources, and from writings equally
-disgusting from their obscurity and their mysticism.
-Every thing is stated in the plainest way, stripped of
-all mystery, and chemistry is shown as a science
-and an art of the first importance, not merely to
-medicine, but to mankind in general. The processes
-given by him are too numerous and too tedious to have
-been all repeated by one man, how laborious soever he
-may have been: many of them have been taken upon
-trust, and, as no distinction is made in the book, between
-those which are stated upon his own authority
-and those which are merely copied from others, this
-treatise has been accused, and with some justice, as
-not always to be depended on. But the real information
-which it communicates is prodigious, and when
-we compare it with any other system of chemistry that
-preceded it, the superiority of Boerhaave’s information
-will appear in a very conspicuous point of view.</p>
-
-<p>After a short but valuable historical introduction
-he divides his work into two parts; the first treats of
-the <i>theory of chemistry</i>, the second of the <i>practical
-processes</i>.</p>
-
-<p>He defines chemistry as follows: “Chemistry is an
-art which teaches the manner of performing certain
-physical operations, whereby bodies cognizable to the
-senses, or capable of being rendered cognizable, and
-of being contained in vessels, are so changed by means
-of proper instruments, as to produce certain determinate
-effects; and at the same time discover the causes
-thereof; for the service of various arts.”</p>
-
-<p>This definition is not calculated to throw much
-light on chemistry to those who are unacquainted with
-<span class="pagenum" id="Page_213">213</span>
-its nature and object. Neither is it conformable to
-the modern notions entertained of chemistry; but it
-is requisite to keep in mind Boerhaave’s definition of
-chemistry, when we examine his system, that we may
-not accuse him of omissions and imperfections, which
-are owing merely to the state of the science when he
-gave his system to the world.</p>
-
-<p>In his theory of chemistry he begins with the
-metals, which he treats of in the following order:
-Gold, mercury, lead, silver, copper, iron, tin. The
-account of them, though imperfect, is much fuller
-and more satisfactory than any that preceded it. He
-then treats of the salts, which are, common salt, saltpetre,
-borax, sal ammoniac and alum. This it will be
-admitted is but a meagre list. However other salts
-occur in different parts of the book which are not described
-here. He next gives an account of sulphur.
-Here he introduces <i>white arsenic</i>, obtained, he says,
-from cobalt, and not known for more than two hundred
-years. He considers it as a real sulphur, and
-takes no notice of metallic arsenic, though it had been
-already alluded to by Paracelsus. He then treats of
-bitumens, including under the name not merely bitumens
-liquid and solid, but likewise pit-coal, amber,
-and ambergris. An account of stones and earths
-comes next, and constitutes the most defective part of
-the book. It is very surprising that in this part of
-his work he takes no notice of <i>lime</i>. The semi-metals
-come next: they are, antimony, bismuth, zinc.
-Here he gives an account of the three vitriols or sulphates
-of iron, copper, and zinc. He knew the composition
-of sulphate of iron; but was ignorant of that
-of sulphate of copper and sulphate of zinc. He considers
-semi-metals as compounds of a true metal and
-sulphur, and therefore enumerates cinnabar among
-the semi-metals. Lastly he treats of vegetables and
-animals; and it is needless to say that his account is
-very imperfect.
-<span class="pagenum" id="Page_214">214</span></p>
-
-<p>He next treats of the utility of chemistry, and
-shows its importance in natural philosophy, medicine,
-and the arts. Afterwards he describes the instruments
-of chemistry. This constitutes the longest and the most
-important part of the whole work. He first treats of
-fire at great length. Here we have an account of the
-thermometer, of the expansion produced by heat, of
-steam, and in fact the germ of many of the most important
-parts of the science of heat, which have since
-been expanded and applied to the improvement, not
-merely of chemistry, but of the arts and resources of
-human industry. The experiments of Fahrenheit related
-by him, on the change of temperature induced
-by agitating water and mercury together at different
-degrees of heat, gave origin to the whole doctrine of
-specific heats. Though Boerhaave himself seemed not
-aware of the importance of these experiments, or indeed
-even to have considered them with any attention.
-But when afterwards analyzed by Dr. Black, these
-experiments gave origin to one of the most important
-parts of the whole science of heat.</p>
-
-<p>He next treats at great length on <i>fuel</i>. Here his
-opinions are often very erroneous, from his ignorance
-of a vast number of facts which have since come to
-light. It is curious that during the whole of his very
-long account of combustion he makes no allusion to
-the peculiar opinions of Stahl on the subject; though
-they were known to the public, and had been admitted
-by chemists in general, before his work was
-published. To what are we to ascribe this omission?
-It could scarcely have been owing to ignorance,
-Stahl’s reputation being too high to allow his opinions
-to be treated with neglect. We must suppose, I think,
-that Boerhaave did not adopt Stahl’s doctrine of combustion;
-but at the same time did not think it proper
-to enter into any controversy on the subject.</p>
-
-<p>He next treats of the heat produced when different
-liquids are mixed, as alcohol and water, &amp;c. He
-<span class="pagenum" id="Page_215">215</span>
-gives many examples of such increase of temperature,
-and describes the phenomena very correctly. But he
-was unable to assign the cause of the evolution of
-this heat. The subject was elucidated many years
-after by Dr. Irvine, who showed that it was owing to
-a diminution of the specific heat which takes place
-when liquids combine chemically together. It is in
-this part of his work that he gives an account of phosphorus,
-of the action of nitric acid on volatile oils,
-and he concludes, from all the facts which he states,
-that elementary fire is a corporeal body. His explanation
-of the combustion of Homberg’s pyrophorus
-and of common phosphorus, shows clearly that he had
-no correct notion of the reason why air is necessary
-to maintain combustion, nor of the way in which that
-elastic fluid performs its part in the great phenomena
-of nature.</p>
-
-<p>He next treats of the mode of regulating fire for
-chemical purposes: then he treats of <i>air</i>, his account
-being chiefly taken from Boyle. He ascribes the discovery
-of the law of the elasticity of air both to Boyle
-and Mariotte. Boyle, I believe, was the first discoverer
-of it. The French are in the habit of calling it the
-law of Mariotte. He then treats of <i>water</i>, and lastly
-of <i>earth</i>; but even here no mention whatever is made
-of lime. In the last part of the theory of chemistry
-he treats at great length of menstruums. These are
-water, oils, alcohol, alkalies, acids, and neutral salts.
-He mentions potash and ammonia, but takes no notice
-of soda; the difference between potash and soda not
-being accurately known. Nor can we expect any
-particular account of the difference between the properties
-of mild and caustic potash; as this subject
-was not understood till the time of Dr. Black. The
-only acids which he mentions are the <i>acetic</i>, <i>sulphuric</i>,
-<i>nitric</i>, <i>muriatic</i>, and <i>aqua regia</i>. He subjoins
-a disquisition on the alcahest or universal solvent,
-which it is obvious enough, however, from the
-<span class="pagenum" id="Page_216">216</span>
-way in which he speaks of it, that he was not a believer
-in. The object of his practical part is to teach
-the method of making all the different chemical substances
-known when he wrote. This he does in two
-hundred and twenty-seven processes, in which all the
-manipulations are described with considerable minuteness.
-This part of the work must have been long
-considered as of great utility, and must have been
-long resorted to by the student as a mine of practical
-information upon almost every subject that could arrest
-his attention. So immense is the progress that
-chemistry has made since the days of Boerhaave, and
-so different are the researches that at present occupy
-chemists, and so much greater the degree of precision
-requisite to be attained, that his processes and directions
-are now of little or no use to a practical student
-of chemistry, as they convey little or none of the
-knowledge which it is requisite for him to possess.</p>
-
-<p>Boerhaave made a set of most elaborate experiments,
-to refute the ideas of the alchymists respecting
-the possibility of fixing mercury. He put a quantity
-of pure mercury into a glass vessel, and kept it for
-fifteen years at a temperature rather higher than 100&deg;.
-It underwent no alteration whatever, excepting that a
-small portion of it was converted into a black powder.
-But this black powder was restored to the state of
-running mercury by trituration in a mortar. In this
-experiment the air had free access to the mercury. It
-was repeated in a close vessel with the same result,
-excepting that the mercury was kept hot for only six
-months instead of fifteen years.</p>
-
-<p>To show that mercury cannot be obtained from metals
-by the processes recommended by the alchymists,
-he dissolved pure nitrate of lead in water, and, mixing
-the solution with sal ammoniac, chloride of lead precipitated.
-Of this chloride he put a quantity into a retort,
-and poured over it a strong lixivium of caustic
-potash, The whole was digested at the temperature
-<span class="pagenum" id="Page_217">217</span>
-of 96&deg; for six months and six days. It was then distilled
-in a glass retort, by a temperature gradually
-raised to redness, but not a particle of mercury was
-evaporated, as it had been alleged by the alchymists
-would be the case.</p>
-
-<p>Isaac Hollandus had stated that mercury could be
-easily obtained from the salt of lead made by means
-of distilled vinegar. To prove this he calcined a
-quantity of acetate of lead, ground the residue to
-powder, and triturated it with a very strong alkaline
-lixivium, and kept the lixivium over it covered with
-paper for months, taking care to add water in proportion
-as it evaporated. The calx was then distilled in
-a heat gradually raised to redness; but not a particle
-of mercury was obtained.<a id="FNanchor_172" href="#Footnote_172" class="fnanchor">172</a></p>
-
-<p>These were not the only laborious experiments which
-he made with this metal. He distilled it above five
-hundred times, and found that it underwent no alteration.
-When long agitated in a glass bottle it is convertible
-into a black acrid powder, obviously protoxide
-of mercury. This black powder, when distilled, is
-converted into running mercury. Exposure of mercury
-for some months in a heat of 180&deg;, converts it
-also into protoxide; and if the heat be higher than
-this, the mercury is converted into a red acrid substance,
-obviously peroxide of mercury. But this
-peroxide, by simple distillation, is again reduced into
-the state of running mercury.<a id="FNanchor_173" href="#Footnote_173" class="fnanchor">173</a></p>
-
-<p>Boerhaave combated the opinions of the iatro-chemists
-with great eloquence, and with a weight derived
-from his high reputation, and the extraordinary veneration
-in which his opinions were held by his disciples.
-His efforts were assisted by those of Bohn, who combated
-the medical opinions by arguments drawn both from
-experience and observation, and perfectly irresistible;
-<span class="pagenum" id="Page_218">218</span>
-and the ruin of the chemical sect was consummated
-by the exertions of the celebrated Frederick Hoffmann,
-the founder of the most perfect and satisfactory system
-of medicine that has ever appeared. His efforts
-were probably roused into action by a visit which he
-paid to England in 1683, during which he got acquainted
-with Boyle and with Sydenham; the former
-the greatest experimentalist, and the latter the greatest
-physician of the time; and both of whom were declared
-enemies to iatro-chemistry.
-<span class="pagenum" id="Page_219">219</span></p>
-
-<hr class="chap" />
-<h2 id="CHAPTER_VI">CHAPTER VI.<br />
-
-<span class="large">OF AGRICOLA AND METALLURGY.</span></h2>
-
-<p>I have been induced by a wish to prosecute the
-history of the opinions first supported by Paracelsus,
-and carried so much further by Van Helmont and
-Sylvius, to give a connected view of their effects
-upon medical practice and medical theory; and I
-have come to the commencement of the eighteenth
-century, without taking notice of one of the most extraordinary
-men, and one of the greatest promoters of
-chemistry that ever existed: I mean George Agricola.
-I shall consecrate the whole of this chapter to his labours,
-and those of his immediate successors.</p>
-
-<p>George Agricola was born at Glaucha, in Misnia,
-in the year 1494. When a young man he acquired such
-a passion for mining and minerals, by frequenting the
-mountains of Bohemia, that he could not be persuaded to
-relinquish the study. He settled, indeed, as a physician,
-at Joachimstal; but his favourite study engrossed
-so much of his attention, that he succeeded
-but ill in his medical capacity. This induced him to
-withdraw to Chemnitz, where he devoted himself to his
-favourite pursuits. He studied the mineralogical
-writings of the ancients with the most minute accuracy;
-but not satisfied with this, he visited the mines
-in person, examined the processes followed by the
-<span class="pagenum" id="Page_220">220</span>
-miners in extracting the different ores, and in washing
-and sorting them. He made collections of all the
-different ores, and studied their nature and properties
-attentively: he likewise collected information about
-the methods of smelting them, and extracting from
-them the metals in a state of purity. The information
-which he collected, respecting the mines wrought in
-the different countries of Europe, is quite wonderful,
-if we consider the period in which he lived, the little
-intercourse which existed between nations, and the
-total want of all those newspapers and journals which
-now carry every new scientific fact with such rapidity
-to every part of the world.</p>
-
-<p>Agricola died at Chemnitz in the year 1555, after he
-had reached the sixty-first year of his age. Maurice, the
-celebrated Elector of Saxony, settled on him a pension,
-the whole of which he devoted to his metallurgic pursuits.
-To him we find him dedicating the edition of his works
-which he published in the year of his death, and which
-is dated the fourteenth before the calends of April, 1555.
-He even spent a considerable proportion of his own
-estate in following out his favourite investigations. In
-the earlier part of his life he had expressed himself
-rather favourable to the protestant opinions; but in
-his latter days he had attacked the reformed religion.
-This rendered him so odious to the Lutherans, at that
-time predominant in Chemnitz, that they suffered his
-body to remain unburied for five days together; so
-that it was necessary to remove it from Chemnitz to
-Zeitz, where it was interred in the principal church.</p>
-
-<p>His great work is his treatise De Re Metallica, in
-twelve books. In this work he gives an account of
-the instruments and machines, and every thing connected
-with mining and metallurgy; and even gives
-figures of all the different pieces of apparatus employed
-in his time. He has also exhibited the Latin
-and German names for all these different utensils.
-This work may be considered as a very complete treatise
-<span class="pagenum" id="Page_221">221</span>
-on metallurgy, as it existed in the sixteenth century.
-The first six books are occupied with an account
-of mining and smelting. In the seventh book he
-treats of <i>docimasy</i>, or the method of determining the
-quantity of metal which can be extracted from every
-particular ore. This he does so completely, that most
-of his processes are still followed by miners and
-smelters. He gives a minute and accurate account of
-the furnaces, muffles, crucibles, &amp;c., almost such as
-are still employed, with minute directions for preparing
-the ores which are to be subjected to examination,
-the fluxes with which they must be mixed, and
-the precautions necessary in order to obtain a satisfactory
-result. In short, this book may be considered
-as a complete manual of docimasy. How much of
-the methods given originated with Agricola it is impossible
-to say. He probably did little more than
-collect the scattered processes employed by the
-smelters of metals, in different parts of the world, and
-reduce the whole to a regular system. But this was
-a great deal. Perhaps it is not saying too much, that
-the great progress made in the chemical investigation
-of the metals, was owing in a great measure to the
-labours of Agricola. Certainly the progress made by
-the moderns, in the difficult arts of mining and metallurgy,
-must in a great measure be ascribed to the
-labours of Agricola.</p>
-
-<p>In the eighth book he describes the mechanical preparation
-of the ores, and the mode of roasting them,
-either in the open air or in furnaces. The ninth book
-is occupied with an account of smelting-furnaces. It
-contains also a description of the processes for obtaining
-mercury, antimony, and bismuth, from their ores.
-The tenth book treats of the separation of silver and
-gold from each other, by means of nitric acid and aqua
-regia: minute directions for the preparation of which
-are given. The modes of purifying the precious metals
-by means of sulphur, antimony, and cementations,
-<span class="pagenum" id="Page_222">222</span>
-are also described. In the eleventh book he treats of
-the method of purifying silver from copper and iron,
-by means of lead. He gives an account also of the
-processes employed for smelting and purifying copper.
-In the twelfth book he treats of the methods of preparing
-common salt, saltpetre, alum, and green vitriol,
-or sulphate of iron: of the preparation and purification
-of sulphur, and of the mode of manufacturing glass.
-In short, Agricola’s work De Re Metallica is beyond
-comparison the most valuable chemical work which
-the sixteenth century produced, and places the author
-very high indeed among the list of the improvers of
-chemistry.</p>
-
-<p>The other works of Agricola are his treatise De
-Natura Fossilium, in ten books; De Ortu et Causis
-Subterraneorum, in five books; De Natura eorum qu&aelig;
-effluunt ex Terra, in four books; De veteribus et novis
-Metallis, in two books; and his Bermannus sive de
-re metallica Dialogus. The treatise De veteribus et
-novis Metallis is amusing. He not only collects together
-all the historical facts on record, respecting the
-first discoverers of the different metals and the first
-workers of mines, but he gives many amusing anecdotes
-nowhere else to be found, respecting the way in
-which some of the most celebrated German mines
-were discovered. In the second book he takes a geographical
-view of every part of the known world, and
-states the mines wrought and the metals found in each.
-We must not suppose that all his statements in this
-historical sketch are accurate: to admit it would be
-to allow him a greater share of information than could
-possibly belong to any one man. He frequently gives
-us the authority upon which his statements are founded;
-but he often makes statements without any authority
-whatever. Thus he says, that a mine of quicksilver
-had been recently discovered in Scotland: the fact
-however, is, that no quicksilver-mine ever existed in
-any part of Britain. There was, indeed, a foolish
-<span class="pagenum" id="Page_223">223</span>
-story circulated about thirty years ago, about a vein of
-quicksilver found under the town of Berwick-upon-Tweed;
-but it was an assertion unsupported by any
-authentic evidence.</p>
-
-<p>Many years elapsed before much addition was
-made to the processes described by Agricola. In the
-year 1566, Pedro Fernandes de Velasco introduced a
-method of extracting gold and silver from their ores in
-Mexico and Peru by means of quicksilver. But I
-have never seen a description of his process. Alonzo
-Barba claims for himself, and seemingly with justice,
-the method of amalgamating the ores of gold and
-silver by boiling. Barba was a Spanish priest, who
-lived about the year 1609, at Tarabuco, a market-town
-in the province of Charcso, eight miles from
-Plata, in South America. In the year 1615 he was
-curate at Tiaguacano, in the Province of Pacayes, and
-in 1617, he lived at Lepas in Peru. He is said to have
-been a native of Lepe, a small township in Andalusia,
-and had for many years the living of the church of St.
-Bernard at Potosi. His work on the amalgamation of
-gold and silver ores appeared at Madrid in the year
-1640, in quarto.<a id="FNanchor_174" href="#Footnote_174" class="fnanchor">174</a> In the year 1629 a new edition of
-it appeared with an appendix, under the title of
-“Trattado de las Antiquas Minas de Espa&ntilde;a de Alonzo
-Carillo Lasso.” The English minister at the Court of
-Madrid, the Earl of Sandwich, published the first
-part of it in an English translation at London, in
-1674, under the title of “The First Book of the Art
-of Metals, in which is declared the manner of their
-generation, and the concomitants of them, written
-in Spanish by Albaro Alonzo Barba. By E. Earl of
-Sandwich.”</p>
-
-<p>The next improver of metallurgic processes was
-Lazarus Erckern, who was upper bar-master at Kuttenberg,
-<span class="pagenum" id="Page_224">224</span>
-in the year 1588, and was superintendent of
-the mines in Germany, Hungary, Transylvania, the
-Tyrol, &amp;c., to three successive emperors. His work has
-been translated into English under the title of “Heta
-Minor; or the laws of art and nature in knowing,
-judging, assaying, fining, refining, and enlarging the
-bodies of confined metals. To which are added essays
-on metallic words, illustrated with sculptures. By Sir
-J. Pettus. London, 1683, folio.” But this translation
-is a very bad one. Erckern gives a plain account
-of all the processes employed in his time without a
-word of theory or reasoning. It is an excellent practical
-book; though it is obvious enough that the
-author was inferior in point of abilities to Agricola.
-His treatment of Don Juan de Corduba, who offered,
-in 1588, to put the Court of Vienna in possession of
-the Spanish method of extracting gold and silver from
-the ores by amalgamation, as related by Baron Born in
-his work on amalgamation, shows very clearly that
-Erckern was a very illiberal-minded man, and puffed
-up with an undue conceit of his own superior knowledge.<a id="FNanchor_175" href="#Footnote_175" class="fnanchor">175</a>
-Had he condescended to assist the Spaniard,
-and to furnish him with proper materials to work upon,
-the Austrians might have been in possession of the process
-of amalgamation with all its advantages a couple
-of centuries before its actual introduction.</p>
-
-<p>I need not take any notice of the docimastic treatises
-of Schindlers and Schlutter, which are of a much
-later date, and both of which have been translated into
-French, the former by Geoffroy, junior; the latter by
-Hellot. This last translation, in two large quartos,
-published in 1764, constitutes a very valuable book,
-and exhibits all the docimastic and metallurgic processes
-known at that period with much fidelity and minuteness.
-Very great improvements have taken place
-<span class="pagenum" id="Page_225">225</span>
-since that period, but I am not aware of any work
-published in any of the European languages, that is
-calculated to give us an exact idea of the present state
-of the various mining and metallurgic processes&mdash;important
-as they are to civilized society.</p>
-
-<p>Gellert’s Metallurgic Chemistry, so far as it goes, is
-an excellent book.
-<span class="pagenum" id="Page_226">226</span></p>
-
-<hr class="chap" />
-<h2 id="CHAPTER_VII">CHAPTER VII.<br />
-
-<span class="large">OF GLAUBER, LEMERY, AND SOME OTHER CHEMISTS OF THE
-END OF THE SEVENTEENTH CENTURY.</span></h2>
-
-<p>Hitherto I have treated of the alchymists, or
-iatro-chemists, and have brought the history of chemistry
-down to the beginning of the eighteenth century.
-But during the seventeenth century there
-existed several laborious chemists, who contributed
-very materially by their exertions, either to extend the
-bounds of the science, or to increase its popularity and
-respectability in the eyes of the world. Of some of
-the most eminent of these it is my intention to give an
-account in this chapter.</p>
-
-<p>Of John Rudolf Glauber, the first of these meritorious
-men in point of time, I know very few particulars.
-He was a German and a medical man, and
-spent most of his time at Salzburg, Ritzingen, Frankfort
-on the Maine, and at Cologne. Towards the end
-of his life he went to Holland, but during the greatest
-part of his residence in that country he was confined
-to a sick-bed. He died at Amsterdam in 1668, after
-having reached a very advanced age. Like Paracelsus,
-whom he held in high estimation, he was in open hostility
-with the Galenical physicians of his time. This
-led him into various controversies, and induced him
-to publish various apologies; most of which still remain
-among his writings. One of the most curious of
-these apologies is the one against Farmer. To this
-man Glauber had communicated certain secrets of his
-<span class="pagenum" id="Page_227">227</span>
-own, which were at that time considered as of great
-value; Farrner binding himself not to communicate
-them to any person. This obligation he not only
-broke, but publicly deprecated the skill and integrity
-of Glauber, and offered to communicate to
-others, for stipulated sums, a set of secrets of his own,
-which he vaunted of as particularly valuable. Glauber
-examines these secrets, and shows that every one of
-them possessed of any value, had been communicated
-by himself to Farrner, and to put an end to Farrner’s
-unfair attempt to make money by selling Glauber’s
-secrets, he in this apology communicates the whole
-processes to the public.</p>
-
-<p>Glauber’s works were published in Amsterdam,
-partly in Latin, and partly in the German language.
-In the year 1689 an English translation of them was
-published in London by Mr. Christopher Packe, in one
-large folio volume. Glauber was an alchymist and a
-believer in the universal medicine. But he did not
-confine his researches to these two particulars, but endeavoured
-to improve medicine and the arts by the
-application of chemical processes to them. In his
-treatise of <i>philosophical furnaces</i> he does not confine
-himself to a description of the method of constructing
-furnaces, and explaining the use of them, but gives
-an account of a vast many processes, and medicinal
-and chemical preparations, which he made by means
-of these furnaces. One of the most important of
-these preparations was muriatic acid, which he obtained
-by distilling a mixture of common salt, sulphate of
-iron, and alum, in one of the furnaces which he
-describes.</p>
-
-<p>He makes known the method of dissolving most of
-the metals in muriatic acid, and the resulting chlorides,
-which he denominates oils of the respective metals,
-constitute in his opinion valuable medicines. He
-mentions particularly the chloride of gold, and from
-the mode of preparing it, the solution must have been
-<span class="pagenum" id="Page_228">228</span>
-strong. Yet he recommends it as an internal medicine,
-which he says may be taken with safety, and is
-a sovereign remedy in old ulcers of the mouth, tongue,
-and throat, arising from the French pox, leprosy,
-scorbute, &amp;c. Thus we see the use of gold as a remedy
-for the venereal disease did not originate with M.
-Chretiens, of Montpelier. This chloride of gold is so
-violent a poison that it is remarkable that Glauber does
-not specify the dose that patients labouring under the
-diseases for which he recommends it ought to take.&mdash;The
-sesqui-chloride of iron he recommends as a most
-excellent application to ill-conditioned ulcers and cancers.
-We see from this that the use of iron in cancers,
-lately recommended, is not so new a remedy as has
-been supposed.</p>
-
-<p>He mentions the violent action of chloride of mercury
-(obviously corrosive sublimate), and says that
-he saw a woman suddenly killed by it, being administered
-internally by a surgeon. Butter of antimony he
-first recognised as nothing else than a combination of
-chlorine and antimony; before his time it had been
-always supposed to contain mercury.</p>
-
-<p>He describes the method of obtaining sulphuric
-acid by distilling sulphate of iron; gives an account of
-the mode of obtaining sulphate of iron and sulphate
-of copper, in crystals: the method of obtaining nitric
-acid from nitre by means of alum, was much improved
-by him. He gives a particular detail of the
-way of obtaining fulminating gold. This fulminating
-gold he says is of little use in medicine; but he gives
-a method of preparing from it a red tincture of gold,
-which he considers as one of the most useful and efficacious
-of all medicines: this tincture is nothing else
-than chloride of gold. It would take up too much
-space to attempt an analysis of all the curious facts
-and preparations described in this treatise on philosophical
-furnaces; but it will repay the perusal of any
-person who will take the trouble to look into it. All
-<span class="pagenum" id="Page_229">229</span>
-the different pharmacopœias of the seventeenth century
-borrowed from it largely. The third part of this
-treatise is peculiarly interesting. It will be seen that
-Glauber had already thought of the peculiar efficacy
-of applying solutions of sulphur, &amp;c. to the skin, and
-had anticipated the various vapour and gaseous baths
-which have been introduced in Vienna and other
-places, during the course of the present century, and
-considered as new, and as constituting an important
-era in the healing art. In the fourth part he not only
-treats of the docimastic processes, so well described
-by Agricola and Erckern, but gives us the method of
-making glass, and of imitating the precious stones by
-means of coloured glasses. The fifth part is peculiarly
-valuable; in it he treats of the methods of preparing
-lutes for glass vessels, of the construction and qualities
-of crucibles, and of the vitrification of earthen vessels.</p>
-
-<p>Another of his tracts is called “The Mineral Work;”
-the object of which is to show the method of separating
-gold from flints, sand, clay, and other minerals,
-by the spirit of salt (<i>muriatic acid</i>), which otherwise
-cannot be purged; also a panacea, or universal antimonial
-medicine. This panacea was a solution of
-deutoxide of antimony in pyrotartaric acid; Glauber
-gives a most flattering account of its efficacy in
-removing the most virulent diseases, particularly all
-kinds of cutaneous eruptions. The second and third
-parts of The Mineral Work are entirely alchymistical.
-In the treatise called “Miraculum Mundi,” his chief
-object is to write a panegyric on <i>sulphate of soda</i>, of
-which he was the discoverer, and to which he gave the
-name of <i>sal mirabile</i>. The high terms in which he
-speaks of this innocent salt are highly amusing, and
-serve well to show the spirit of the age, and the dreams
-which still continued to haunt the most laborious
-and sober-minded chemists. The <i>sal mirabile</i> was
-not merely a purgative, a virtue which it certainly
-possesses in a high degree, being as mild a purgative,
-<span class="pagenum" id="Page_230">230</span>
-perhaps the very best, of all the saline preparations
-yet tried; but it was a universal medicine, a
-panacea, a cure for all diseases: nor was Glauber
-contented with this, but pointed out many uses in the
-various arts and manufactures for which in his opinion
-it was admirably fitted. But by far the fullest account
-of this <i>sal mirabile</i> is given by him in his treatise
-on the nature of salts.</p>
-
-<p>I shall satisfy myself with giving the titles of his
-other tracts. Every one of them contains facts of considerable
-importance, not to be found in any chemical
-writings that preceded him; but to attempt to connect
-these facts into one point of view would be needless,
-because they are not such as would be likely to interest
-the general reader.</p>
-
-<p>1. The Consolation of Navigators. This gives an
-account of a method by which sailors may carry with
-them a great deal of nourishment in very small bulk.
-The method consists in evaporating the wort of malt
-to dryness, and carrying the dry extract to sea. This
-method has been had recourse to in modern times, and
-has been found to furnish an effectual remedy against
-the scurvy. He recommends also the use of muriatic
-acid as a remedy for thirst, and a cure for the scurvy.</p>
-
-<p>2. A true and perfect Description of the extracting
-good Tartar from the Lees of Wine.</p>
-
-<p>3. The first part of the Prosperity of Germany; in
-which is treated of the concentration of wine, corn,
-and wood, and the more profitable use of them than
-has hitherto been.</p>
-
-<p>4. The second part of the Prosperity of Germany;
-wherein is shown by what means minerals may be
-concentrated by nitre, and turned into metallic and
-better bodies.</p>
-
-<p>5. The third part of the Prosperity of Germany;
-in which is delivered the way of most easily and plentifully
-extracting saltpetre out of various subjects,
-every where obvious and at hand. Together with a
-<span class="pagenum" id="Page_231">231</span>
-succinct explanation of Paracelsus’s prophecy; that is
-to say, in what manner it is to be understood the
-northern lion will institute or plant his political or civil
-monarchy; and that Paracelsus himself will not abide
-in his grave; and that a vast quantity of riches will
-offer itself. Likewise who the artist Elias is, of whose
-coming in the last days, and his disclosing abundance
-of secrets, Paracelsus and others have predicted.</p>
-
-<p>6. The fourth part of the Prosperity of Germany;
-in which are revealed many excellent, useful secrets,
-and such as are serviceable to the country; and withal
-several preparations of efficacious cates extracted out
-of the metals and appointed to physical uses; as also
-various confections of golden potions. To which is
-also adjoined a small treatise which maketh mention
-of my laboratory; in which there shall be taught and
-demonstrated (for the public good and benefit of mankind)
-wonderful secrets, and unto every body most
-profitable but hitherto unknown.</p>
-
-<p>7. The fifth part of the Prosperity of Germany;
-clearly and solidly demonstrating and as it were showing
-with the fingers, what alchymy is, and what benefit
-may, by the help thereof, be gotten every where and
-in most places of Germany. Written and published
-to the honour of God, the giver of all good things, primarily;
-and to the honour of all the great ones of the
-country; and for the health, profit, and assistance
-against foreign invasions, of all their inhabitants that
-are by due right and obedience subject unto them.</p>
-
-<p>8. The sixth and last part of the Prosperity of Germany;
-in which the arcanas already revealed in the
-fifth part, are not only illustrated and with a clear elucidation,
-but also such are manifested as are most
-highly necessary to be known for the defence of the
-country against the Turks. Together with an evident
-demonstration adjoined, showing, that both a
-particular and universal transmutation of the imperfect
-metals into more perfect ones by salt and fire, is
-<span class="pagenum" id="Page_232">232</span>
-most true; and withal, by what means any one, that is
-endued with but a mean knowledge in managing the
-fire, may experimentally try the truth hereof in twenty-four
-hours’ space.</p>
-
-<p>9. The first century of Glauber’s wealthy Storehouse
-of Treasures.&mdash;Many of the processes given in this
-treatise are mystically stated, or even concealed.</p>
-
-<p>10. The second, third, fourth, and fifth century of
-Glauber’s wealthy Storehouse of Treasures.</p>
-
-<p>11. New chemical Light; being a revelation of a
-certain new invented secret, never before manifested
-to the world.&mdash;This was a method of extracting gold
-from stones. Probably the gold found by Glauber in
-his processes existed in some of the reagents employed;
-this, at least, is the most natural way of accounting
-for the result of Glauber’s trials.</p>
-
-<p>15. The spagyrical Pharmacopœia, or Dispensatory.&mdash;In
-this book he treats chiefly of medicines peculiarly
-his own; one of those, on which he bestows the greatest
-praise, is <i>secret sal ammoniac</i>, or sulphate of ammonia.
-He describes the method of preparing this salt,
-by saturating sulphuric acid with ammonia. He informs
-us that it was much employed by Paracelsus
-and Van Helmont, who distinguished it by the name
-of <i>alkahest</i>.</p>
-
-<p>13. Book of Fires.&mdash;Full of enigmas.</p>
-
-<p>14. Treatise of the three Principles of Metals; viz.
-sulphur, mercury, and salt of philosophers; how they
-may be profitably used in medicine, alchymy, and
-other arts.</p>
-
-<p>15. A short Book of Dialogues. Chiefly relating
-to alchymy.</p>
-
-<p>16. Proserpine, or the Goddess of Riches.</p>
-
-<p>17. Of Elias the Artist.</p>
-
-<p>18. Of the three most noble Stones generated by
-three Fires.</p>
-
-<p>19. Of the Purgatory of Philosophers.</p>
-
-<p>20. Of the secret Fire of Philosophers.
-<span class="pagenum" id="Page_233">233</span></p>
-
-<p>21. A Treatise concerning the Animal Stone.</p>
-
-<p>John Kunkel, who acquired a high reputation as a
-chemist, was born in the Duchy of Sleswick; in the
-year 1630: his father was a trading chemist, or apothecary;
-and Kunkel himself had, in his younger years,
-paid great attention to the business of an apothecary:
-he had also diligently studied the different processes
-of glass-making; and had paid particular attention to
-the assaying of metals. In the year 1659, he was
-chamberlain, chemist, and superintendent of apothecaries
-to the dukes Francis Charles and Julius Henry,
-of Lauenburg. While in this situation, he examined
-many pretended transmutations of metals, and undertook
-other researches of importance. From this situation
-he was invited, by John George II., Elector of
-Saxony, on the recommendation of Dr. Langelott and
-Counsellor Vogt, as chamberlain and superintendent
-of the elector’s laboratory, with a considerable salary.
-From this situation he went to Berlin, where he was
-chemist to the elector Frederick William; after whose
-death, his laboratory and glass-house were accidentally
-burnt. From Berlin he was invited to Stockholm by
-Charles XI., King of Sweden, who gave him the title
-of counsellor of metals, and raised him to the rank
-of a nobleman: here he died, in 1702, in the seventy-second
-year of his age. Kunkel’s greatest discovery
-was, the method of extracting phosphorus from urine.
-This curious substance had been originally discovered
-by Brandt, a chemist, of Hamburg, in the year 1669, as
-he was attempting to extract from human urine a liquid
-capable of converting silver into gold. He showed a
-specimen of it to Kunkel, with whom he was acquainted:
-Kunkel mentioned the fact as a piece of news to
-one Kraft, a friend of his in Dresden, where he then
-resided: Kraft immediately repaired to Hamburg,
-and purchased the secret from Brandt for 200 rix-dollars,
-doubtless exacting from him, at the same time,
-a promise not to reveal it to any other person. Soon
-<span class="pagenum" id="Page_234">234</span>
-after, he exhibited the phosphorus publicly in Britain
-and in France; whether for money, or not, does not
-appear. Kunkel, who had mentioned to his friend his
-intention of getting possession of the process, being
-vexed at the treacherous conduct of Kraft, attempted
-to discover it himself, and, after three or four years
-labour, he succeeded, though all that he knew from
-Brandt was, that urine was the substance from which
-the phosphorus was procured. In consequence of this
-success, phosphorus was at first distinguished by the
-epithet of <i>Kunkel</i> added to the name.</p>
-
-<p>Kunkel published, in 1678, a treatise on phosphorus,
-in which he describes the properties of this substance,
-at that time a subject of great wonder and curiosity.
-In this treatise, he proposes phosphorus as a remedy
-of some efficacy, and gives a formula for preparing
-pills of it, to be taken internally. It is therefore erroneous
-to suppose, as has been done, that the introduction
-of this dangerous remedy into medicine is a
-modern discovery. Kunkel appears to have been acquainted
-with nitric ether. One of the most valuable
-of his books, is his treatise on glass-making, which
-was translated into French; and which, till nearly
-the end of the eighteenth century, constituted by far
-the best account of glass-making in existence. The
-following is a list of the most important of his works:</p>
-
-<p>1. Observations on fixed and volatile Salts, potable
-Gold and Silver, Spiritus Mundi, &amp;c.; also of the
-colour and smell of metals, minerals, and bitumens.&mdash;This
-tract was published at Hamburg, in 1678, and
-has been several times reprinted since.</p>
-
-<p>2. Chemical Remarks on the chemical Principles,
-acid, fixed and volatile alkaline Salts, in the three
-kingdoms of nature, the mineral, vegetable, and animal;
-likewise concerning their colour and smell, &amp;c.;
-with a chemical appendix against non-entia chymica.</p>
-
-<p>3. Treatise of the Phosphorus mirabilis, and its
-wonderful shining Pills; together with a discourse on
-<span class="pagenum" id="Page_235">235</span>
-what was formerly rightly named nitre, but is now
-called the <i>blood of nature</i>.</p>
-
-<p>4. An Epistle against Spirit of Wine without an acid.</p>
-
-<p>5. Touchstone de Acido et Urinoso, Sale calido et
-frigido.</p>
-
-<p>6. Ars Vitraria experimentalis.</p>
-
-<p>7. Collegium Physico-chymicum experimentale, <i>or</i>
-Laboratorium chymicum.<a id="FNanchor_176" href="#Footnote_176" class="fnanchor">176</a></p>
-
-<p>Nicolas Lemery, the first Frenchman who completely
-stripped chemistry of its mysticism, and presented it to
-the world in all its native simplicity, deserves our particular
-attention, in consequence of the celebrity which
-he acquired, and the benefits which he conferred on
-the science. He was born at Rouen on the 17th of
-November, 1645. His father, Julian Lemery, was
-<i>procureur</i> of the Parliament of Normandy, and a protestant.
-His son, when very young, showed a decided
-partiality for chemistry, and repaired to an apothecary
-in Rouen, a relation of his own, in hopes of being
-initiated into the science; but finding that little information
-could be procured from him, young Lemery
-left him in 1666, and went to Paris, where he boarded
-himself with M. Glaser, at that time demonstrator of
-chemistry at the Jardin du Roi.</p>
-
-<p>Glaser was a <i>true chemist</i>, according to the meaning
-at that time affixed to the term&mdash;full of obscure
-notions&mdash;unwilling to communicate what knowledge
-he possessed&mdash;and not at all sociable. In two months
-Lemery quitted his house in disgust, and set out with a
-resolution to travel through France, and pick up chemical
-information as he best could, from those who
-were capable of giving him information on the subject.
-He first went to Montpelier, where he boarded in the
-house of M. Vershant, an apothecary in that town.
-<span class="pagenum" id="Page_236">236</span>
-With his situation there he was so much pleased, that
-he continued in it for three years: he employed himself
-assiduously in the laboratory, and in teaching
-chemistry to a number of young students who boarded
-with his host. Here his reputation gradually increased
-so much, that he drew round him the professors of the
-faculty of medicine of Montpelier, and all the curious
-of the place, to witness his experiments. Here, too,
-he practised medicine with considerable success.</p>
-
-<p>After travelling through all France, he returned to
-Paris in 1672. Here he frequented the different
-scientific meetings at that time held in that capital,
-and soon distinguished himself by his chemical knowledge.
-In a few years he got a laboratory of his own,
-commenced apothecary, and began to give public lectures
-on chemistry, which were speedily attended by
-great crowds of students from foreign countries. For
-example, we are told that on one occasion forty Scotchmen
-repaired to Paris on purpose to hear his lectures,
-and those of M. Du Verney on anatomy. The medicines
-which he prepared in his laboratory became
-fashionable, and brought him a great deal of money.
-The magistery of bismuth (or pearl-white), which he
-prepared as a cosmetic, was sufficient, we are told, to
-support the whole expense of his house. In the year
-1675 he published his Cours de Chimie, certainly one
-of the most successful chemical books that ever appeared;
-it ran through a vast number of editions in a
-few years, and was translated into Latin, German,
-Spanish, and English.</p>
-
-<p>In 1681 he began to be troubled in consequence of
-his religious opinions. Louis XIV. was at that time in
-the height of his glory, entirely under the control of
-his priests, and zealously bent upon putting an end to
-the reformed religion in his dominions. Indeed, from
-the infamous conduct of Charles II. of England, and
-the bigotry of his successor, a prospect was opened to
-him, and of which he was anxious to avail himself, of
-<span class="pagenum" id="Page_237">237</span>
-annihilating the reformed religion altogether, and of
-plunging Europe a second time into the darkness of
-Roman Catholicism.</p>
-
-<p>Lemery found it expedient, in 1683, to pass over into
-England. Here he was well received by Charles II.:
-but England was at that time convulsed with those
-religious and political struggles, which terminated five
-years afterwards in the revolution. Lemery, in consequence
-of this state of things, found it expedient to
-leave England, and return to France. He took a doctor’s
-degree at Caen, in Normandy; and, returning to
-Paris, he commenced all at once practitioner in medicine
-and surgery, apothecary, and lecturer on chemistry.
-The edict of Nantes was revoked in 1685, when
-James II. had assured Louis of his intention to overturn
-the established religion, and bring Great Britain
-again under the dominion of the pope. Lemery was
-obliged to give up practice and conceal himself, in
-order to avoid persecution. Finding his success hopeless,
-as long as he continued a protestant, he changed
-his religion in 1686, and declared himself a Roman
-catholic. This step secured his fortune: he was now
-as much caressed and protected by the court and the
-clergy, as he had been formerly persecuted by them.
-In 1699 when the Academy of Sciences was new
-modelled, he was appointed associated chemist, and,
-on the death of Bourdelin, before the end of that year,
-he became a pensioner. He died on the 19th of June,
-1715, at the age of seventy, in consequence of an attack
-of palsy, which terminated in apoplexy.</p>
-
-<p>Besides his System of Chemistry, which has been
-already mentioned, he published the following works:</p>
-
-<p>1. Pharmacop&eacute;e universelle, contenant toutes les
-Operations de Pharmacie qui sont en usage dans la
-M&eacute;dicine.</p>
-
-<p>2. Trait&eacute; universelle des Drogues simples mis en
-ordre alphab&eacute;tique.
-<span class="pagenum" id="Page_238">238</span></p>
-
-<p>3. Trait&eacute; de l’Antimoine, contenant l’analyse chimique
-de ce mineral.</p>
-
-<p>Besides these works, five different papers by Lemery
-were printed in the Memoirs of the French Academy,
-between 1700 and 1709 inclusive. These are
-as follow:</p>
-
-<p>1. Explication physique et chimique des Feux souterrains,
-des tremblemens de Terre, des Ouragans, des
-Eclairs et du Tonnere.&mdash;This explanation is founded
-on the heat and combustion produced by the mutual
-action of iron filings and sulphur on each other, when
-mixed in large quantities.</p>
-
-<p>2. Du Camphre.</p>
-
-<p>3. Du Miel et de son analyse chimique.</p>
-
-<p>4. De l’Urine de Vache, de ses effets en m&eacute;dicine
-et de son analyse chimique.</p>
-
-<p>5. Reflexions et Experiences sur le Sublim&eacute; Corrosive.&mdash;It
-appears from this paper, that in 1709, when
-Lemery wrote, corrosive sublimate was considered as
-a compound of mercury with the sulphuric and muriatic
-acids. Lemery’s statement, that he made corrosive
-sublimate simply by heating a mixture of mercury
-and decrepitated salt, is not easily explained.
-Probably the salt which he had employed was impure.
-This is the more likely, because, from his account of
-the matter which remained at the bottom of the matrass
-after sublimation, it must have either contained
-peroxide of iron or peroxide of mercury, for its colour
-he says was red.</p>
-
-<p>M. Lemery left a son, who was also a member of
-the French Academy; an active chemist, and author
-of various papers, in which he endeavours to give a
-mechanical explanation of chemical phenomena.</p>
-
-<p>Another very active member of the French Academy,
-at the same time with Lemery, was M. William
-Homberg, who was born on the 8th of January, 1652,
-at Batavia, in the island of Java. His father, John
-<span class="pagenum" id="Page_239">239</span>
-Homberg, was a Saxon gentleman, who had been
-stripped of all his property during the thirty years
-war. After receiving some education by the care of
-a relation, he went into the service of the Dutch East
-India Company, and got the command of the arsenal
-at Batavia. There he married the widow of an officer,
-by whom he had four children, of whom William was
-the second.</p>
-
-<p>His father quitted the service of the India Company
-and repaired to Amsterdam with his family.
-Young Homberg studied with avidity: he devoted
-himself to the law, and in 1674 was admitted advocate
-of Magdeburg; but his taste for natural history
-and science was great. He collected plants in the
-neighbourhood, and made himself acquainted with
-their names and uses. At night he studied the stars,
-and learned the names and positions of the different
-constellations. Thus he became a self-taught botanist
-and astronomer. He constructed a hollow
-transparent celestial globe, on which, by means of a
-light placed within, the principal fixed stars were seen
-in the same relative positions as in the heavens.</p>
-
-<p>Otto Guericke was at that time burgomaster of
-Magdeburg. His experiments on a vacuum, and his
-invention of the air-pump, are universally known.
-Homberg attached himself to Otto Guericke, and this
-philosopher, though fond of mystery, either explained
-to him his secrets, in consequence of his admiration
-of his genius, or was unable to conceal them from
-his penetration. At last Homberg, quite tired of his
-profession of advocate, left Magdeburg and went to
-Italy. He sojourned for some time at Padua, where
-he devoted himself to the study of medicine, anatomy,
-and botany. At Bologna he examined the famous Bologna
-stone, the nature of which had been almost
-forgotten, and succeeded in making a pyrophorus
-out of it. At Rome he associated particularly with
-Marc-Antony Celio, famous for the large glasses
-<span class="pagenum" id="Page_240">240</span>
-for telescopes which he was able to grind. Nor
-did he neglect painting, sculpture, and music; pursuits
-in which, at that time, the Italians excelled all
-other nations.</p>
-
-<p>From Italy he went to France, and thence passed
-into England, where he wrought for some time in the
-laboratory of Mr. Boyle, at that time one of the most
-eminent schools of science in Europe. He then
-passed into Holland, studied anatomy under De
-Graaf, and after visiting his family, went to Wittemberg,
-where he took the degree of doctor of medicine.</p>
-
-<p>After this he visited Baldwin and Kunkel, to get
-more accurate information respecting the phosphorus
-which each had respectively discovered. He purchased
-a knowledge of Kunkel’s phosphorus, by
-giving in exchange a meteorological toy of Otto
-Guericke, now familiarly known, by which the moisture
-or dryness of the air was indicated&mdash;a little man
-came out of his house and stood at the door in dry
-weather, but retired under cover in moist weather. He
-next visited the mines of Saxony, Bohemia, and
-Hungary: he even went to Sweden, to visit the copper-mines
-of that country. At Stockholm he wrought
-in the chemical laboratory, lately established by the
-king, along with Hjerna, and contributed considerably
-to the success of that new establishment.</p>
-
-<p>He repaired a second time to France, where he
-spent some time, actively engaged with the men of
-science in Paris. His father strongly pressed him to
-return to Holland and settle as a physician: he at
-last consented, and the day of his departure was
-come, when, just as he was going into his carriage, he
-was stopped by a message from M. Colbert on the
-part of the king. Offers of so advantageous a nature
-were made him if he would consent to remain in
-France, that, after some consideration, he was induced
-to embrace them.
-<span class="pagenum" id="Page_241">241</span></p>
-
-<p>In 1682 he changed his religion and became Roman
-catholic: this induced his father to disinherit
-him. In 1688 he went to Rome, where he practised
-medicine with considerable success. A few years
-after he returned to Paris, where his knowledge and
-discoveries gave him a very high reputation. In 1691
-he became a member of the Academy of Sciences,
-and got the direction of the laboratory belonging to the
-academy: this enabled him to devote his undivided
-attention to chemical investigations. In 1702 he was
-taken into the service of the Duke of Orleans, who
-gave him a pension, and put him in possession of the
-most splendid and complete laboratory that had ever
-been seen. He was presented with the celebrated
-burning-glass of M. Tchirnhaus, by the Duke of Orleans,
-and was enabled by means of it to determine
-many points that had hitherto been only conjectural.</p>
-
-<p>In 1704 he was made first physician to the Duke
-of Orleans, who honoured him with his particular
-esteem. This appointment obliging him to reside out
-of Paris, would have made it necessary for him to resign
-his seat in the academy, had not the king made
-a special exemption in his favour. In 1708 he married
-a daughter of the famous M. Dodart, to whom
-he had been long attached. Some years after he was
-attacked by a dysentery, which was cured, but returned
-from time to time. In 1715 it returned with
-great violence, and Homberg died on the 24th of
-September.</p>
-
-<p>His knowledge was uncommonly great in almost
-every department of science. His chemical papers
-were very numerous; though there are few of them,
-in this advanced period of the science, that are likely
-to claim much attention from the chemical world.
-His pyrophorus, of which he has given a description
-in the M&eacute;moires de l’Acad&eacute;mie,<a id="FNanchor_177" href="#Footnote_177" class="fnanchor">177</a> was made by mixing
-<span class="pagenum" id="Page_242">242</span>
-together human f&aelig;ces and alum, and roasting the
-mixture till it was reduced to a dry powder. It was
-then exposed in a matrass to a red heat, till every
-thing combustible was driven off. Any combustible
-will do as a substitute for human f&aelig;ces&mdash;gum, flour,
-sugar, charcoal, may be used. When a little of this
-phosphorus is poured upon paper, it speedily catches
-fire and kindles the paper. Davy first explained the
-nature of this phosphorus. The potash of the alum
-is converted into potassium, which, by its absorption
-of oxygen from the atmosphere, generates heat, and
-sets fire to the charcoal contained in the powder.</p>
-
-<p>Homberg’s papers printed in the Memoirs of the
-French Academy amount to thirty-one. They are to
-be found in the volumes for 1699 to 1714 inclusive.</p>
-
-<p>M. Geoffroy, who was a member of the academy
-about the same time with Lemery and Homberg,
-though he outlived them both, and who was an active
-chemist for a considerable number of years, deserves
-also to be mentioned here.</p>
-
-<p>Stephen Francis Geoffroy was born in Paris on the
-13th of February, 1672, where his father was an
-apothecary. While a young man, regular meetings
-of the most eminent scientific men of Paris were held
-in his father’s house, at which he was always present.
-This contributed very much to increase his taste for
-scientific pursuits. After this he studied botany,
-chemistry, and anatomy in Paris. In 1692 his father
-sent him to Montpelier, to study pharmacy in the
-house of a skilful apothecary, who at the same time
-sent his son to Paris, to acquire the same art in the
-house of M. Geoffroy, senior. Here he attended the
-different classes in the university, and his name began
-to be known as a chemist. After spending some time
-in Montpelier, he travelled round the coast to see the
-principal seaports, and was at St. Malo’s in 1693,
-when it was bombarded by the British fleet.</p>
-
-<p>In 1698 Count Tallard being appointed ambassador
-<span class="pagenum" id="Page_243">243</span>
-extraordinary to London, made choice of M. Geoffroy
-as his physician, though he had not taken a medical
-degree. Here he made many valuable acquaintances,
-and was elected a fellow of the Royal Society. From
-London he went to Holland, and thence into Italy, in
-1700, where he went in the capacity of physician to
-M. de Louvois. The great object of M. Geoffroy was
-always natural history, and materia medica. In 1693
-he had subjected himself to an examination, and he
-had been declared qualified to act as an apothecary;
-but his own object was to be a physician, while that
-of his father was that he should succeed himself as an
-apothecary: this in some measure regulated his
-education. At last he declared his intentions, and
-his father agreed to them; he became bachelor of
-medicine in 1702, and doctor of medicine in 1704.</p>
-
-<p>In 1709 he was made professor of medicine in the
-Royal College. In 1707 he began to lecture on
-chemistry, at the Jardin du Roi, in place of M. Fagan,
-and continued to teach this important class during
-the remainder of his life. In 1726 he was chosen
-dean of the faculty of medicine; and, after the two
-years for which he was elected was finished, he was
-again chosen to fill the same situation. There existed
-at that time a lawsuit between the physicians and
-surgeons in Paris; a kind of civil war very injurious
-to both; and the mildness and suavity of his manners
-fitted him particularly for being at the head of the
-body of physicians during its continuance. He became
-a member of the academy in 1699, and died on the
-6th of January, 1731.</p>
-
-<p>The most important of all his chemical labours, and
-for which he will always be remembered in the annals
-of the science, was the contrivance which he fell upon,
-in 1718, of exhibiting the order of chemical decompositions
-under the form of a table.<a id="FNanchor_178" href="#Footnote_178" class="fnanchor">178</a> This method
-<span class="pagenum" id="Page_244">244</span>
-was afterwards much enlarged and improved. Such
-tables are now usually known by the name of <i>tables
-of affinity</i>; and, though they have been of late years
-somewhat neglected, there can be but one opinion of
-their importance when properly constructed.</p>
-
-<p>M. Geoffroy first communicated to the French chemists
-the mode of making Prussian blue, as Dr.
-Woodward did to the English.</p>
-
-<p>Claude Joseph Geoffroy, the younger brother of the
-preceding, was also a member of the Academy of
-Sciences, and a zealous cultivator of chemistry. Many
-of his chemical papers are to be found in the memoirs
-of the French Academy. He demonstrated the composition
-of sal ammoniac, which however was known
-to Glauber. He made many experiments upon the
-combustion of the volatile oils, by pouring nitric acid
-on them. He explained the pretended property which
-certain waters have of converting iron into copper, by
-showing that in such cases copper was held in solution
-in the water by an acid, and that the iron merely
-precipitated the copper, and was dissolved and combined
-with the acid in its place. He pointed out the
-constituents of the three vitriols, the green, the blue,
-and the white; showing that the two former were
-combinations of sulphuric acid with oxides of iron and
-copper, and the latter a solution of lapis calaminaris
-(<i>carbonate of zinc</i>) in the same acid. He has also a
-memoir on the emeticity of antimony, tartar emetic,
-and kermes mineral; but it is rather medical than
-chemical. He determined experimentally the nature
-of the salt of Seignette, or Rochelle salt, and showed
-that it was obtained by saturating cream of tartar with
-carbonate of soda, and crystallizing. It is curious that
-this discovery was made about the same time by M.
-Boulduc. I have noticed only a few of the papers of
-M. Geoffroy, junior; because, though they all do him
-credit, and contributed to the improvement of chemistry,
-yet none of them contain any of those great
-<span class="pagenum" id="Page_245">245</span>
-discoveries, which stand as landmarks in the progress
-of science, and constitute an era in the history of
-mankind. For the same reason I omit several other
-names that, in a more minute history of chemistry,
-would deserve to be particularized.
-<span class="pagenum" id="Page_246">246</span></p>
-
-<hr class="chap" />
-<h2 id="CHAPTER_VIII">CHAPTER VIII.<br />
-
-<span class="large">OF THE ATTEMPTS TO ESTABLISH A THEORY IN CHEMISTRY.</span></h2>
-
-<p>Bacon, Lord Verulam, as early as the commencement
-of the 17th century, had pointed out the importance
-of chemical investigations, and had predicted
-the immense advantages which would result from the
-science, when it came to be properly cultivated and
-extended; but he did not himself attempt either to
-construct a theory of chemistry, or even to extend it
-beyond the bounds which it had reached before he
-began to write. Neither did Boyle, notwithstanding
-the importance of his investigations, and his comparative
-freedom from the prejudices of the alchymists,
-attempt any thing like a theory of chemistry; though
-the observations which he made in his Sceptical Chemist,
-had considerable effect in overturning, or at least
-in hastening the downfall of the absurd chemical opinions
-which at that time prevailed, and the puerile
-hypotheses respecting the animal functions, and the
-pathology and treatment of diseases founded on these
-opinions. The first person who can with propriety be
-said to have attempted to construct a theory of chemistry,
-was Beccher.</p>
-
-<p>John Joachim Beccher, one of the most extraordinary
-men of the age in which he lived, was born at
-Spires, in Germany, in the year 1635. His father, as
-<span class="pagenum" id="Page_247">247</span>
-Beccher himself informs us, was a very learned Lutheran
-preacher. As he lost his father when he was very
-young, and as that part of Germany where he lived
-had been ruined by the thirty years’ war, his family
-was reduced to great poverty. However, his passion
-for information was so great, that he contrived to
-educate himself by studying what books he could
-procure, and in this way acquired a great deal of
-knowledge. Afterwards he travelled through the
-greatest part of Germany, Italy, Sweden, and Holland.</p>
-
-<p>In the year 1666 he was appointed public professor
-of medicine in the University of Mentz, and soon after
-chief physician to the elector. In that capacity he
-took up his residence in Munich, where he was furnished
-by the elector with an excellent laboratory:
-but he soon fell into difficulties, the nature of which
-does not appear, and was obliged to leave the place.
-He took refuge in Vienna, where, from his knowledge
-of finance, he was appointed chamberlain to Count
-Zinzendorf, and through him acquired so much importance
-in the eyes of the court, that he was named
-a member of the newly-erected College of Commerce,
-and obtained the title of imperial commercial counsellor
-and chamberlain. But here also he speedily
-raised up so many enemies against himself, that he
-found it necessary to leave Vienna, and to carry with
-him his wife and children. He repaired to Holland,
-and settled at Haerlem in 1678. Here he was likely to
-have been successful; but his enemies from Vienna
-followed him, and obliged him to leave Holland. In
-1680 we find him in Great Britain, where he examined
-the Scottish lead-mines, and smelting-works; and in
-1681, and 1682, he traversed Cornwall, and studied
-the mines and smelting-works of that great mining
-county; here he suggested several improvements
-and ameliorations. Soon after this an advantageous
-proposal was made to him by the Duke of Mecklenburg
-Gustrow, by means of Count Zinzendorf; but all
-<span class="pagenum" id="Page_248">248</span>
-his projects were arrested by his death, which took
-place in the year 1682. It is said that he died in
-London, but I have not been able to find any evidence
-of this.</p>
-
-<p>It would be a difficult task to particularize his
-various discoveries, which are scattered through a multiplicity
-of writings. He was undoubtedly the first
-discoverer of boracic acid, though the credit of the
-discovery has usually been given to Homberg.<a id="FNanchor_179" href="#Footnote_179" class="fnanchor">179</a> But
-then he gives no account of boracic acid, nor does he
-seem to have attended to its qualities. The following
-is a list of Beccher’s writings:</p>
-
-<p>1. Metallurgia, or the Natural Science of Metals.</p>
-
-<p>2. Institutiones Chymic&aelig;.</p>
-
-<p>3. Parnassus Medicinalis illustrata.</p>
-
-<p>4. Œdipus Chymicus seu Institutiones Chymic&aelig;.</p>
-
-<p>5. Acta laboratorii Chymici Monacensis seu Physica
-Subterranea.&mdash;This, which is the most important of all
-his works, is usually known by the name of “Physica
-Subterranea.” This is the sole title affixed to it in the
-edition published at Leipsic, in 1703, to which Stahl
-has prefixed a long introduction. It is divided into
-seven sections. In the first he treats of the creation
-of the world; in the second he gives a chemical account
-of the motions and changes which are constantly
-going on in the earth; in the third he treats of the
-three principles of all bodies, which he calls <i>earths</i>.
-The first of these principles of metals and stones is the
-<i>fusible</i> or <i>stony earth</i>; the second principle of minerals
-is the <i>fat earth</i>, improperly called <i>sulphur</i>; the
-third principle is the <i>fluid earth</i>, improperly called
-<i>mercury</i>; in the fourth section he treats of the action
-<span class="pagenum" id="Page_249">249</span>
-of subterraneous principles, or the formation of <i>mixts</i>;
-in the fifth he treats of the solution of the three
-classes of mixts, animals, vegetables, and metals;
-in the sixth he treats of <i>mixts</i>, in which he gives their
-chemical constituents. This section is very curious,
-because it gives Beccher’s views of the constitution of
-compound bodies. It will be seen from it that he
-had much more correct notions of the real objects of
-chemistry, than any of his contemporaries. In the
-seventh and last section he treats of the accidents and
-physical affections of subterraneous bodies.</p>
-
-<p>6. Experimentum Chymicum novum quo artificialis
-et instantanea metallorum generatio et transmutatio,
-ad oculum demonstratur.&mdash;This constitutes the first
-supplement to the Physica Subterranea.</p>
-
-<p>7. Supplementum secundum in Physicam subterraneam,
-demonstratio philosophica seu Theses Chymic&aelig;,
-veritatem et possibilitatem transmutationis metallorum
-in aurum evincentes.</p>
-
-<p>8. Trifolium Beccherianum Hollandicum.</p>
-
-<p>9. Experimentum novum et curiosum de Minera
-arenaria perpetua, sive prodromus histori&aelig; seu propositionis
-Pr&aelig;p. D.D. Hollandi&aelig; ordinibus ab authore
-fact&aelig;, circa auri extractionem mediante arena littorali
-per modum miner&aelig; perpetu&aelig; seu operationis magn&aelig;
-fusori&aelig; cum emolumento. Loco supplementi tertii in
-Physicam suam subterraneam.</p>
-
-<p>10. Chemical Luckpot, or great chemical agreement;
-in a collection of one thousand five hundred chemical
-processes.</p>
-
-<p>11. Foolish Wisdom and wise Folly.</p>
-
-<p>12. Magnalia Natur&aelig;.</p>
-
-<p>13. Tripus Hermeticus fatidicus pandens oracula
-chemica; seu I. Laboratorium portatile, cum methodo
-vere spagyric&aelig; seu juxta exigentiam natur&aelig; laborandi.
-Accessit pro praxi et exemplo; II. Centrum mundi
-concatenatum seu Duumviratus hermeticus s. magnorum
-duorum productorum nitri et salis textura et anatomia
-<span class="pagenum" id="Page_250">250</span>
-atque in omnium pr&aelig;cedentium confirmationem
-adjunctum est; III. Alphabetum Minerale seu viginti
-quatuor theses de subterraneorum mineralium genesi,
-textura et analysi; his accessit concordantia mercurii
-lun&aelig; et menstruorum.</p>
-
-<p>14. Chemical Rose-garden.</p>
-
-<p>15. Pantaleon delarvatus.</p>
-
-<p>16. Beccheri, Lancelotti, etc. Epistol&aelig; quatuor Chemic&aelig;.</p>
-
-<p>Beccher’s great merit was the contrivance of a chemical
-theory, by which all the known facts were connected
-together and deduced from one general principle.
-But as this theory was adopted and considerably
-modified by Stahl, it will be better to lay a sketch of
-it before the reader, after mentioning a few particulars
-of the life and labours of one of the most extraordinary
-men whom Germany has produced; a man who, in
-spite of the moroseness and haughtiness of his character,
-and in spite of the barbarity of his style, raised
-himself to the very first rank as a man of science;
-and had the rare or almost unique fortune of giving
-laws at the same time to two different and important
-sciences, which he cultivated together, without letting
-his opinions respecting the one influence him with
-regard to the other. These sciences were chemistry
-and medicine.</p>
-
-<p>George Ernest Stahl was born at Anspach, in the
-year 1660. He studied medicine at Jena under
-George Wolfgang Wedel; and got his doctor’s degree
-at the age of twenty-three. Immediately after this he
-began his career as a public lecturer. In 1687 the
-Duke of Weimar gave him the title of physician to
-the court. In 1694 he was named, at the solicitation
-of Frederick Hoffmann, second professor of medicine
-in the University of Halle, which had just been established.
-Hoffmann and he were at that time great
-friends, though they afterwards quarrelled. Both of
-them were men of the very highest talents and both
-<span class="pagenum" id="Page_251">251</span>
-were the founders of medical systems which, of course,
-each was anxious to support. Hoffmann had greatly
-the superiority in elegance and clearness of style,
-and in all the amenities of polite manners. But perhaps
-the moroseness of Stahl, and the obscurity, or
-rather mysticism of his style, contributed equally with
-the more amiable qualities of Hoffmann to excite the
-attention and produce the veneration with which he
-was viewed by his pupils, and, indeed, by the world
-at large.</p>
-
-<p>At Halle he continued as a teacher of medicine for
-twenty-two years. In 1716 he was appointed physician
-to the King of Prussia. In consequence of this
-appointment he left Halle, and resided in Berlin,
-where he died in the year 1734, in the seventy-fifth
-year of his age. Notwithstanding the great figure
-that Stahl made as a chemist, there is no evidence
-that he ever taught that science in any public school.
-The Berlin Academy had been founded under the superintendence
-of Leibnitz, who was its first president;
-and therefore existed when Stahl was in Berlin: but,
-till it was renovated in 1745 by Frederick the Great,
-this academy possessed but little activity, and could
-scarcely, therefore, have stimulated Stahl to attend
-to chemical science. However, his Chymia rationalis
-et experimentalis was published in 1720, while he resided
-in Berlin. The same date is appended to the
-preface of his Fundamenta Chymi&aelig;; but, from some
-expressions in that preface, it must, I should think,
-have been written, not by Stahl, but by some other
-person.<a id="FNanchor_180" href="#Footnote_180" class="fnanchor">180</a> I suspect that the book had been written by
-some of his pupils, from the lectures of the author
-while at Halle. If this was really the case, it is obvious
-<span class="pagenum" id="Page_252">252</span>
-that Stahl must have taught chemistry as well as
-medicine in the University of Halle.</p>
-
-<p>Stahl’s medical theory is not less deserving of notice
-than his chemical. But it is not the object of this
-work to enter into medical speculations. Like Van
-Helmont, he resolved all diseases into the actions of
-the <i>soul</i>, which was not merely the former of the body,
-but its ruler and regulator. When any of the functions
-are deranged, the soul exerts itself to restore
-them again to their healthy state; and she accomplishes
-this by what in common language is called
-disease. The business of a medical man, then, is not
-to prevent diseases, or to stop them short when they
-appear; because they are the efforts of the soul, the
-<i>vis medicatrix natur&aelig;</i>, to restore the deranged state of
-the functions: but he must watch these diseases, and
-prevent the symptoms from becoming too violent. He
-must assist nature to produce the intended effect, and
-check her exertions when they become abnormal. It
-was a kind of modification of this theory, or rather a
-mixture of the Stahlian and Hoffmannian theories, that
-Dr. Cullen afterwards taught in Edinburgh with so
-much eclat. And these opinions, so far as medical
-theories have any influence on practice, still continue
-in some measure prevalent. Indeed, much of the
-vulgar practice followed by medical men, chiefly in
-consequence of the education which they have received,
-is deduced from these two theories. But
-it would be too great a digression from the object
-of this work to enter into any details: suffice it to
-say, that the rival theories of Hoffmann and Stahl for
-many years divided the medical world in Germany, if
-not in the greater part of Europe. It was no small
-matter of exultation to so young a medical school as
-Halle, to have at once within its walls two such eminent
-teachers as Hoffmann and Stahl.</p>
-
-<p>Let us turn our attention to the chemical writings of
-Stahl. Of these the most important is his Fundamenta
-<span class="pagenum" id="Page_253">253</span>
-Chymi&aelig; dogmatic&aelig; et experimentalis. It is divided,
-like the chemistry of Boerhaave, into a theoretical and
-practical part. The perusal of it is very disagreeable,
-as it is full of German words and phrases, and symbols
-are almost constantly substituted for words, as was at
-that time the custom.</p>
-
-<p>His definition of chemistry is much more exact
-than Boerhaave’s. It is, according to him, the art of
-resolving compound bodies into their constituents, and
-of again forming them by uniting these constituents
-together.</p>
-
-<p>He is inclined to believe with Beccher, that the
-simple principles are four in number. The <i>mixts</i> are
-compounds of these principles; and he shows by the
-doctrine of permutations that if we suppose the simple
-principles four, then the number of mixts will be
-40,340. He treats in the first place of <i>mixts</i>, <i>compounds</i>,
-and <i>aggregates</i>.</p>
-
-<p>The first object of chemistry is <i>corruption</i>, the second
-<i>generation</i>. Of these he treats at considerable
-length, giving an account of the different chemical
-processes, and of the apparatus employed.</p>
-
-<p>He next treats of <i>salts</i>, which he defines mixts
-composed of water and earth, both simple and pure,
-and intimately united. The salts are vitriol, alum,
-nitre, common salt, and sal ammoniac. He next treats
-of more compound salts. These are sugar, tartar, salts
-from the animal and salts from the mineral kingdom,
-and quicklime.</p>
-
-<p>After this comes sulphur, cinnabar, antimony, the
-sulphur of vitriol, the sulphur of nitre, resins, and
-distilled oils. Then he treats of water, which he divides
-into aqua <i>humida</i> or common water, and aqua
-<i>sicca</i> or mercury. Next he treats of earths, which
-are of two kinds, viz., <i>friable earths</i>, such as <i>clay</i>,
-<i>loam</i>, sand, &amp;c., and metallic earths constituting the
-bases of the metals.</p>
-
-<p>He next treats of the metals; and, as a preliminary,
-<span class="pagenum" id="Page_254">254</span>
-we have a description of the method of smelting, and
-operating upon the different metals. The metals are
-then described successively in the following order:
-Gold, silver, copper, iron, tin, lead, bismuth, zinc,
-antimony.</p>
-
-<p>To this part of the system are added three sections.
-The first treats of mercuries, the second of the philosopher’s
-stone, and the third of the universal medicine.
-We must not suppose that Stahl was a believer in these
-ideal compositions; his object is merely to give a
-history of the different processes which had been recommended
-by the alchymists.</p>
-
-<p>The second part of his work is divided into two
-<i>tracts</i>. The first tract contains three sections. The first
-of these treats of the nature of solids and fluids, of solutions
-and menstrua, of the effects of heat and fire,
-of effervescence and boiling, of volatilization, of fusion
-and liquefaction, of distillation, of precipitation,
-of calcination and incineration, of detonation, of
-amalgamation, of crystallization and inspissation, and
-of the fixity and firmness of bodies. In the second
-section we have an account of salts, and of their
-generation and transmutation, of sulphur and inflammability,
-of phosphorus, of colours, and of the
-nature of metals and minerals. In this article he
-gives short definitions of these bodies, and shows how
-they may be known. The bodies thus defined are
-gold, silver, iron, copper, lead, tin, mercury, antimony,
-sulphur, arsenic, vitriol, common salt, nitre,
-alum, sal ammoniac, alkalies, and salts; viz., muriatic
-acid, sulphuric, nitric, and sulphurous.</p>
-
-<p>In the third section he treats of the method of reducing
-metallic calces, of the mode of separating metals
-from their scori&aelig;, of the mode of making artificial
-gems, and finally of the mode of giving copper a
-golden colour.</p>
-
-<p>The second tract is divided into two parts. The first
-part is subdivided into four sections. In the first
-<span class="pagenum" id="Page_255">255</span>
-section he treats of the instruments of chemical motion,
-of fire, of air, of water, of the most subtile earth or
-salt. In the second section he treats <i>de subjectis</i>, under
-the several heads of dissolving aggregates, of triturations
-and solutions, and of calcinations and combustions.
-In the third section he treats of the object of
-chemistry under the following heads: Of chemical
-corruption, consisting of compounds from liquids, of
-the separation of solids and fluids, of mixts, of the
-solution of compounds from solids. In the fourth
-section he treats of fermentation.</p>
-
-<p>The second part of this second tract treats of chemical
-generation, and is divided into two sections. In
-the first section he treats of the aggregate collection
-of bodies into fluids and solids. The section treats of
-compositions under the heads of volatile and solid
-bodies. He gives in the last article an account of the
-combination of mixts.</p>
-
-<p>The third and last part of this elaborate work discusses
-three subjects; viz. <i>zymotechnia</i> or <i>fermentation</i>,
-<i>halotechnia</i>, or the production and properties of salts,
-and <i>pyrotechnia</i>, in which the whole of the Stahlian
-doctrine of <i>phlogiston</i> is developed. This third part
-has all the appearance of having been notes written
-down by some person during the lectures of Stahl: for
-it consists of alternate sentences of Latin and German.
-It is not at all likely that Stahl himself would
-have produced such a piebald work; but if he lectured
-in Latin, as was at that time the universal custom,
-it was natural for a person occupied in taking
-down the lectures, to write as far as was possible in
-Latin, but when any of the Latin phrases were lost, or
-did not immediately occur to memory, it were equally
-natural to write down the meaning of what the professor
-stated in the language most familiar to the
-writer, which was undoubtedly the German.</p>
-
-<p>Another of Stahl’s works is entitled “Opusculum
-Chymico-physico-medicum,” published at Halle in a
-<span class="pagenum" id="Page_256">256</span>
-thick quarto volume, in the year 1715. It contains a
-great number of tracts, partly chemical and partly
-medical, which it is needless to specify. Perhaps the
-most curious of them all is his dissertation to show the
-way in which Moses ground the golden calf to powder,
-dissolved it in water, and obliged the children of Israel
-to drink it. He shows that a solution of hepar sulphuris
-(<i>sulphuret of potassium</i>), has the property of
-dissolving gold, and he draws as a conclusion from his
-experiments that this was the artifice employed by
-Moses. We have in the same volume a pretty detailed
-treatise on metallurgic pyrotechny and docimasy. This
-is the more curious, because Stahl never appears to
-have frequented the mines and smelting-houses of
-Germany. He must, therefore, have drawn his information
-from books and from experiment.</p>
-
-<p>Another of his books is entitled “Experimenta, Observationes,
-Animadversiones, CCC. Numero.” An
-octavo volume, printed at Berlin in 1731. Another of
-his books is entitled “Specimen Beccherianum.” There
-are also two chemical books of Stahl, which I have
-seen only in a French translation, viz., <i>Trait&eacute; de
-Soufre</i> and <i>Trait&eacute; de Sels</i>. These are the only chemical
-writings of Stahl that I have seen. There are
-probably others; indeed I have seen the titles of several
-other chemical works ascribed to him. But as it
-is doubtful whether he really wrote them or not, I
-think it unnecessary to specify them here.</p>
-
-<p>Stahl’s writings evince the great progress which
-chemistry had made even since the time of Beccher.
-But it is difficult to say what particular new facts,
-which appear first in his writings were discovered by
-himself, and what by others. I shall not, therefore,
-attempt any enumeration of them. His reasoning is
-more subtile, and his views much more extensive and
-profound than those of his predecessors. The great
-improvement which he introduced into chemistry was
-the employment of <i>phlogiston</i>, to explain the phenomena
-<span class="pagenum" id="Page_257">257</span>
-of combustion and calcination. This theory
-had been originally broached by Beccher, from whom
-Stahl evidently borrowed it, but he improved and simplified
-it so much that the whole credit of it was given
-to him. It was called the Stahlian theory, and raised
-him to the highest rank among chemists. The sole
-objects of chemists for thirty or forty years after his
-time was to illucidate and extend his theory. It applied
-so happily to all the known facts, and was supported
-by experiments, which appeared so decisive that nobody
-thought of calling it in question, or of interrogating
-nature in any other way than he had pointed
-out. It will be requisite, therefore, before proceeding
-further with this historical sketch, to lay the outlines
-of the phlogistic theory before the reader.</p>
-
-<p>It was conceived by Beccher and Stahl that all
-<i>combustible</i> bodies are compounds. One of the constituents
-they supposed to be dissipated during the
-combustion, while the other constituent remained behind.
-Now when combustible bodies are subjected to
-combustion, some of them leave an acid behind them;
-while others leave a fixed powdery matter, possessing
-the properties of an <i>earth</i>, and called usually the
-<i>calx</i> of the combustible body. The metals are the
-substances which leave a calx behind them when
-burnt, and sulphur and phosphorus leave an acid.
-With respect to those bodies that would not burn,
-chemists did not speculate much at first; but afterwards
-they came to think that they consisted of the
-fixed substance that remained after combustion.
-Hence the conclusion was natural, that they had
-already undergone combustion. Thus quicklime
-possessed properties very similar to the calces of metals.
-It was natural, therefore, to consider it as a calx, and
-to believe that if the matter dissipated during combustion
-could be again restored, lime would be converted
-into a substance similar to the metals.</p>
-
-<p>Combustibility then, according to this view of the
-<span class="pagenum" id="Page_258">258</span>
-subject, depends upon a principle or material substance,
-existing in every combustible body, and dissipated
-during the combustion. This substance was
-considered to be absolutely the same in all combustible
-bodies whatever; hence the difference between
-combustible bodies proceeded from the other principle
-or number of principles with which this common substance
-is combined. In consequence of this identity
-Stahl invented the term <i>phlogiston</i>, by which he denoted
-this common principle of combustible bodies.
-Inflammation, with the several phenomena that attend
-it, depended on the gradual separation of this principle,
-which being once separated, what remained of
-the body could no longer be an inflammable substance,
-but must be similar to the other kinds of matter. It
-was this opinion that combustibility is owing to the
-presence of phlogiston, and inflammation to its escape,
-that constituted the peculiar theory of Beccher, and
-which was afterwards illustrated by Stahl with so much
-clearness, and experiments to prove its truth were advanced
-by him of so much force, that it came to be
-distinguished by the name of the Stahlian theory.</p>
-
-<p>The identity of phlogiston in all combustible bodies
-was founded upon observations and experiments of so
-decisive a nature, that after the existence of the principle
-itself was admitted, they could not fail to be
-satisfactory. When phosphorus is made to burn it gives
-out a strong flame, much heat is evolved, and the phosphorus
-is dissipated in a white smoke: but if the combustion
-be conducted within a glass vessel of a proper
-shape, this white smoke will be deposited on the inside
-of the glass; it quickly absorbs moisture from the atmosphere,
-and runs into an acid liquid, known by the name
-of phosphoric acid. If this liquid be put into a platinum
-crucible, and gradually heated to redness, the water
-is dissipated, and a substance remains which, on cooling,
-congeals into a transparent colourless body like
-glass: this is dry <i>phosphoric</i> acid. If now we mix
-<span class="pagenum" id="Page_259">259</span>
-phosphoric acid with a quantity of charcoal powder,
-and heat it sufficiently in a glass retort, taking care to
-exclude the external air, a <i>portion</i> or the <i>whole</i> of the
-charcoal will disappear, and phosphorus will be formed
-possessed of the same properties that it had before
-it was subjected to combustion. The conclusion deduced
-from this process appeared irresistible; the
-charcoal, or a portion of it, had combined with the
-phosphoric acid, and both together had constituted
-phosphorus.</p>
-
-<p>Now, in changing phosphoric acid into phosphorus,
-we may employ almost any kind of combustible substance
-that we please, provided it be capable of bearing
-the requisite heat; they will all equally answer,
-and will all convert the acid into phosphorus. Instead
-of charcoal we may take lamp-black, or sugar, or resin,
-or even several of the metals. Hence it was concluded
-that all of these bodies contain a common principle
-which they communicate to the phosphoric acid;
-and since the new body formed is in all cases identical,
-the principle communicated must also be identical.
-Hence combustible bodies contain an identical principle,
-and this principle is phlogiston.</p>
-
-<p>Sulphur by burning is converted into sulphuric acid;
-and if sulphuric acid be heated with charcoal, or phosphorus,
-or even sulphur, it is again converted into
-sulphur. Several of the metals produce the same
-effect. The reasoning here was the same as with
-regard to phosphoric acid, and the conclusion was
-similar.</p>
-
-<p>When lead is kept nearly at a red heat in the open
-air for some time, being constantly stirred to expose
-new surfaces to the air, it is converted into the beautiful
-pigment called <i>red lead</i>; this is a calx of lead.
-To restore this calx again to the state of metallic lead,
-we have only to heat it in contact with almost any combustible
-matter whatever. Pit-coal, peat, charcoal,
-sugar, flour, iron, zinc, &amp;c., all these bodies then must
-<span class="pagenum" id="Page_260">260</span>
-contain one common principle, which they communicate
-to red lead, and by so doing convert it into lead.
-This common principle is phlogiston.</p>
-
-<p>These examples are sufficient to show the reader the
-way in which Stahl proved the identity of phlogiston
-in all combustible bodies. And the demonstration
-was considered as so complete that the opinion was
-adopted by every chemist without exception.</p>
-
-<p>When we inquire further, and endeavour to learn
-what qualities phlogiston was supposed to have in its
-separate state, we find this part of the subject very
-unsatisfactory, and the opinions very unsettled. Beccher
-and Stahl represented phlogiston as a dry substance,
-or of an earthy nature, the particles of which
-are exquisitely subtile, and very much disposed to be
-agitated and set in motion with inconceivable velocity.
-This was called by Stahl <i>motus verticillaris</i>. When
-the particles of any body are agitated with this kind of
-motion, the body exhibits the phenomena of heat
-or ignition, or inflammation, according to the violence
-and rapidity of the motion.</p>
-
-<p>This very crude opinion of the earthy nature of
-phlogiston, appears to have been deduced from the
-insolubility of most combustible substances in water.
-If we except alcohol, and ether, and gums, very few
-of them are capable of being dissolved in that liquid.
-Thus the metals, sulphur, phosphorus, oils, resins, bitumens,
-charcoal, &amp;c., are well known to be insoluble.
-Now, at the time that Beccher and Stahl lived, insolubility
-in water was considered as a character peculiar
-to earthy bodies; and as those bodies which contain
-a great deal of phlogiston are insoluble in water,
-though the other constituents be very soluble in that
-liquid, it was natural enough to conclude that phlogiston
-itself was of an earthy nature.</p>
-
-<p>But though the opinions of chemists about the nature
-and properties of phlogiston in a separate state
-were unsettled, no doubts were entertained respecting
-<span class="pagenum" id="Page_261">261</span>
-its existence, and respecting its identity in all combustible
-bodies. Its presence or its absence produced
-almost all the changes which bodies undergo. Hence
-chemistry and combustion came to be in some measure
-identified, and a theory of combustion was considered
-as the same thing with a theory of chemistry.</p>
-
-<p>Metals were compounds of <i>calces</i> and phlogiston.
-The different species of metals depend upon the different
-species of calx which each contains; for there
-are as many <i>calces</i> (each simple and peculiar) as there
-are metals. These calces are capable of uniting with
-phlogiston in indefinite proportions. The calx united
-to a little phlogiston still retains its earthy appearance&mdash;a
-certain additional portion restores the calx to the
-state of a metal. An enormous quantity of phlogiston
-with which some calces, as calx of manganese, are
-capable of combining, destroys the metallic appearance
-of the body, and renders it incapable of dissolving
-in acids.</p>
-
-<p>The affinity between a metallic calx and phlogiston
-is strong; but the facility of union is greatly promoted
-when the calx still retains a little phlogiston. If we
-drive off the whole phlogiston we can scarcely unite
-the calx with phlogiston again, or bring it back to the
-state of a metal: hence the extreme difficulty of reducing
-the calx of zinc, and even the red calx of iron.</p>
-
-<p>The various colours of bodies are owing to phlogiston,
-and these colours vary with every alteration in the
-proportion of phlogiston present.</p>
-
-<p>It was observed very early that when a metal was
-converted into a calx its weight was increased. But
-this, though known to Beecher and Stahl, does not
-seem to have had any effect on their opinions. Boyle,
-who does not seem to have been aware of the phlogistic
-theory, though it had been broached before his
-death, relates an experiment on tin which he made.
-He put a given weight of it into an open glass vessel,
-and kept it melted on the fire till a certain portion of
-<span class="pagenum" id="Page_262">262</span>
-it was converted into a calx: it was now found to
-have increased considerably in weight. This experiment
-he relates in order to prove the materiality of
-heat: in his opinion a certain quantity of heat had
-united to the tin and occasioned the increase of weight.
-This opinion of Boyle was incompatible with the Stahlian
-theory: for the tin had not only increased in
-weight, but had been converted into a calx. It was
-therefore the opinion of Boyle that calx of tin was a
-combination of <i>tin</i> and <i>heat</i>. It could not consequently
-be true that calx of tin was tin deprived of phlogiston.</p>
-
-<p>When this difficulty struck the phlogistians, which
-was not till long after the time of Stahl, they endeavoured
-to evade it by assigning new properties to
-phlogiston. According to them it is not only destitute
-of weight, but endowed with a principle of levity.
-In consequence of this property, a body containing
-phlogiston is always lighter than it would otherwise be,
-and it becomes heavier when the phlogiston makes its
-escape: hence the reason why calx of tin is heavier
-than the same tin in the metallic state. The increase
-of weight is not owing, as Boyle believed, to the
-fixation of heat in the tin, but to the escape of phlogiston
-from it.</p>
-
-<p>Those philosophic chemists, who thus refined upon
-the properties of phlogiston, did not perceive that by
-endowing it with a principle of levity, they destroyed
-all the other characters which they had assigned to it.
-What is gravity? Is it not an attraction by means of
-which bodies are drawn towards each other, and remain
-united? And is there any reason for supposing that
-chemical attraction differs in its nature from the other
-kinds of attraction which matter possesses? If, then,
-phlogiston be destitute of gravity, it cannot possess
-any attraction for other bodies; if it be endowed with
-a principle of levity, it must have the property of
-repelling other bodies, for that is the only meaning
-that can be attached to the term. But if phlogiston
-<span class="pagenum" id="Page_263">263</span>
-has the property of repelling all other substances, how
-comes it to be fixed in combustible bodies? It must
-be united to the calces or the acids, which constitute
-the other principle of these bodies; and it could not
-be united, and remain united, unless a principle of
-attraction existed between it and these bases; that is
-to say, unless it possessed a principle the very opposite
-of levity.</p>
-
-<p>Thus the fact, that calces are heavier than the metals
-from which they are formed, in reality overturned the
-whole doctrine of phlogiston; and the only reason
-why the doctrine continued to be admitted after the
-fact was known is, that in these early days of chemistry,
-the balance was scarcely ever employed in
-experimenting: hence alterations in weight were little
-attended to or entirely overlooked. We shall see
-afterwards, that when Lavoisier introduced a more
-accurate mode of experimenting, and rendered it necessary
-to compare the original weights of the substances
-employed, with the weights of the products,
-he made use of this very experiment of Boyle, and a
-similar one made with mercury, to overturn the whole
-doctrine of phlogiston.</p>
-
-<p>The phlogistic school being thus founded by Stahl,
-in Berlin, a race of chemists succeeded him in that
-capital, who contributed in no ordinary degree to the
-improvement of the science. The most deservedly
-celebrated of these were Neumann, Pott, Margraaf, and
-Eller.</p>
-
-<p>Caspar Neumann was born at Zullichau, in Germany,
-in 1682. He was early received into favour by
-the King of Prussia, and travelled at the expense of
-that monarch into Holland, England, France, and
-Italy. During these travels he had an opportunity of
-making a personal acquaintance with the most eminent
-men of science in all the different countries which he
-visited. On his return home, in 1724, he was appointed
-professor of chemistry in the Royal College of Physic
-<span class="pagenum" id="Page_264">264</span>
-and Surgery at Berlin, where he delivered a course of
-lectures annually. During the remainder of his life
-he enjoyed the situation of superintendent of the Royal
-Laboratory, and apothecary to the King of Prussia.
-He died in 1737. He was a Fellow of the Royal
-Society, and several papers of his appeared in the
-Transactions of that learned body. The following is
-a list of these papers, all of which were written in
-Latin:</p>
-
-<p>1. Disquisitio de camphora.</p>
-
-<p>2. De experimento probandi spiritum vini Gallici,
-per quam usitato, sed revera falso et fallaci.</p>
-
-<p>Some merchants in Holland, England, Hamburg,
-and Dantzic, were in possession of what they considered
-an infallible test to distinguish French brandy
-from every other kind of spirit. It was a dusky yellowish
-liquid. When one or two drops of it were let
-fall into a glass of French brandy, a beautiful blue
-colour appeared at the bottom of the glass, and when
-the brandy is stirred, the whole liquid becomes azure.
-But if the spirit tried be malt spirit, no such colour
-appears in the glass. Neumann ascertained that the
-test liquid was merely a solution of sulphate of iron
-in water, and that the blue colour was the consequence
-of the brandy having been kept in oak casks, and thus
-having dissolved a portion of tannin. Every spirit
-will exhibit the same colour, if it has been kept in oak
-casks.</p>
-
-<p>3. De salibus alkalino-fixis.</p>
-
-<p>4. De camphora thymi.</p>
-
-<p>5. De ambragrysea.</p>
-
-<p>His other papers, published in Germany, are the following:</p>
-
-<h3>In the Ephemerides.</h3>
-
-<p>1. De oleo distillato formicorum &aelig;thereo.</p>
-
-<p>2. De albumine ovi succino simili.</p>
-
-<h3>In the Miscellania Berolinensia.</h3>
-
-<p>1. Meditationes in binas observationes de aqua per
-<span class="pagenum" id="Page_265">265</span>
-putrefactionem rubra, vulgo pro tali in sanguinem
-versa habita.</p>
-
-<p>2. Succincta relatio exactis Pomeraniis de prodigio
-sanguinis in palude viso.</p>
-
-<p>3. De prodigio sanguinis ex Pomeranio nunciato.</p>
-
-<p>4. Disquisitio de camphora.</p>
-
-<p>5. De experimento probandi spiritum vini Gallicum.</p>
-
-<p>6. De spiritu urinoso caustico.</p>
-
-<p>7. Demonstratio syrupum violarum ad probanda
-liquida non sufficere.</p>
-
-<p>8. Examen correctionis olei raparum.</p>
-
-<p>9. De vi caustica et conversione salium alkalino-fixorum
-a&euml;ri expositorum in salia neutra.</p>
-
-<h3>He published separately,</h3>
-
-<p>1. De salibus alkalino-fixis et camphora.</p>
-
-<p>2. De succino, opio, caryophyllis aromaticis et
-castoreo.</p>
-
-<p>3. On saltpetre, sulphur, antimony, and iron.</p>
-
-<p>4. On tea, coffee, beer, and wine.</p>
-
-<p>5. Disquisitio de ambragrysea.</p>
-
-<p>6. On common salt, tartar, sal ammoniac and ants.</p>
-
-<p>After Neumann’s death, two copies of his chemical
-lectures were published. The first consisting of notes
-taken by one of his pupils, intermixed with incoherent
-compilations from other authors, was printed at Berlin
-in 1740. The other was printed by the booksellers of
-the Orphan Hospital of Zullichau (the place of Neumann’s
-birth), and is said to have been taken from the
-original papers in the author’s handwriting. Of this
-last an excellent translation, with many additions and
-corrections, was published by Dr. Lewis, in London,
-in the year 1759; it was entitled, “The Chemical
-Works of Caspar Neumann, M.D., Professor of Chemistry
-at Berlin, F.R.S., &amp;c. Abridged and methodized;
-with large additions, containing the later
-discoveries and improvements made in Chemistry, and
-the arts depending thereon. By William Lewis, M.B.,
-<span class="pagenum" id="Page_266">266</span>
-F.R.S. London, 1759.” This is an excellent book,
-and contains many things that still retain their value,
-notwithstanding the improvements which have been
-made since in every department of chemistry.</p>
-
-<p>I have reason to believe that the laborious part of
-this translation and compilation was made by Mr.
-Chicholm, whom Dr. Lewis employed as his assistant.
-Mr. Chicholm, when a young man, went to London
-from Aberdeen, where he had studied at the university,
-and acquired a competent knowledge of Greek
-and Latin, but no means of supporting himself. On
-his arrival in London, one of the first things that struck
-his attention was a Greek book, placed open against
-the pane of a bookseller’s window. Chicholm went up
-to the window, at which he continued standing till he
-had perused the whole Greek page thus exposed to
-his view. Dr. Lewis happened to be in the shop: he
-had been looking out for a young man whom he could
-employ to take charge of his laboratory, and manage
-his processes, and who should possess sufficient intelligence
-to read chemical works for him, and collect
-out of each whatever deserved to be known, either
-from its novelty or ingenuity. The appearance and
-manners of Chicholm struck him, and made him think
-of him as a man likely to answer the purposes which
-he had in view. He called him into the shop, and
-after some conversation with him, took him home,
-and kept him all his life as his assistant and operator.
-Chicholm was a laborious and painstaking man, and
-by continually working in Lewis’s laboratory, soon
-acquired a competent knowledge of chemistry. He
-compiled several manuscript volumes, partly consisting
-of his own experiments, and partly of collections from
-other authors. At Dr. Lewis’s death, all his books
-were sold by auction, and these manuscript volumes
-among the rest. They were purchased by Mr. Wedgewood,
-senior, who at the same time took Mr. Chicholm
-into his service, and gave him the charge of his own
-<span class="pagenum" id="Page_267">267</span>
-laboratory. It was Mr. Chicholm that was the constructor
-of the well-known piece of apparatus known
-by the name of Wedgewood’s pyrometer. After his
-death the instrument continued still to be constructed
-for some time; but so many complaints were made of
-the unequal contraction of the pieces, that Mr. Wedgewood,
-junior, who had succeeded to the pottery in consequence
-of the death of his father, put an end to the
-manufacture of them altogether.</p>
-
-<p>John Henry Pott was born at Halberstadt, in the
-year 1692. He was a scholar of Hoffmann and Stahl,
-and from this last he seems to have imbibed his taste
-for chemistry. He settled at Berlin, where he became
-assessor of the Royal College of Medicine and Surgery,
-inspector of medicines, superintendent of the Royal
-Laboratory, and dean of the Academy of Sciences of
-Berlin. He was chosen professor of theoretical chemistry
-at Berlin; and on the death of Neumann, in
-1737, he succeeded him as professor of practical chemistry.
-He was beyond question the most learned
-and laborious chemist of his day. His erudition, indeed,
-was very great; and his historical introductions
-to his dissertation displays the extent of his reading
-on every subject of which he had occasion to treat.
-It has often struck me that the historical introductions
-which Bergmann has prefixed to his papers, are several
-of them borrowed from Pott. The Lithogeognosia of
-Pott is one of the most extraordinary productions of
-the age in which he lived. It was the result of a request
-of the King of Prussia, to discover the ingredients
-of which Saxon porcelain was made. Mr. Pott, not
-being able to procure any satisfactory information relative
-to the nature of the substances employed at
-Dresden, resolved to undertake a chemical examination
-of all the substances that were likely to be employed
-in such a manufacture. He tried the effect of
-fire upon all the stones, earths, and minerals, that he
-could procure, both separately and mixed together in
-<span class="pagenum" id="Page_268">268</span>
-various proportions. He made at least thirty thousand
-experiments in six years, and laid the foundation for a
-chemical knowledge of these bodies.<a id="FNanchor_181" href="#Footnote_181" class="fnanchor">181</a> It is to this work
-of Pott that we are indebted for our knowledge of the
-effects of heat upon various earthy bodies, and upon
-mixtures of them. Thus he found that pure white
-clay, or mixtures of pure clay and quartz-sand, would
-not fuse at any temperature which he could produce;
-but clay, mixed with lime or with oxide of iron, enters
-speedily into fusion. Clay also fuses with its own weight
-of borax; it forms a compact mass with half its weight,
-and does not concrete into a hard body when mixed with
-a third of its weight of that salt. Clay fuses easily
-with fluor spar; it fuses, also, with twice its weight of
-protoxide of lead, and with its own weight of sulphate of
-lime, but with no other proportion tried. It was a knowledge
-of these mutual actions of bodies on each other,
-when exposed to heat, that gradually led to the methods
-of examining minerals by the blowpipe. These
-methods were brought to the present state of perfection
-by Assessor Gahn, of Fahlun, the result of whose labours
-has been published by Berzelius, in his treatise
-on the blowpipe. Pott died in 1777, in the eighty-fifth
-year of his age.</p>
-
-<p>His different chemical works (his Lithogeognosia excepted)
-were collected and translated into French by
-M. Demachy, in the year 1759, and published in four
-small octavo volumes. The chemical papers contained
-in these volumes are thirty-two in number. Some of
-these papers cannot but appear somewhat extraordinary
-to a modern chemist: for example, M. Duhamel had
-<span class="pagenum" id="Page_269">269</span>
-published in the memoirs of the French Academy, in
-the year 1737, a set of experiments on common salt,
-from which he deduced that its basis was a fixed alkali,
-which possessed properties different from those
-of potash, and which of course required to be distinguished
-by a peculiar name. It is sufficiently known
-that the term <i>soda</i> was afterwards applied to this alkali;
-by which name it is known at present. Pott,
-in a very elaborate and long dissertation on the base
-of common salt, endeavours to refute these opinions
-of Duhamel. The subject was afterwards taken up
-by Margraaf, who demonstrated, by decisive experiments,
-that the base of common salt is <i>soda</i>; and that
-soda differs essentially in its properties from potash.</p>
-
-<p>Pott’s dissertation on <i>bismuth</i> is of considerable
-value. He collects in it the statements and opinions
-of all preceding writers on this metal, and describes
-its properties with considerable accuracy and minuteness.
-The same observations apply to his dissertation
-on zinc.</p>
-
-<p>John Theodore Eller, of Brockuser, was born on
-the 29th of November, 1689, at Pletzkau, in the principality
-of Anhalt Bernburg. He was the fourth
-son of Jobst Hermann Eller, a man of a respectable
-family, whose ancestors were proprietors of considerable
-estates in Westphalia and the Netherlands.
-Young Eller received the rudiments of his education
-in his father’s house, from which he went to the University
-of Quedlinburg; and from thence to the
-University of Jena, in 1709. He was sent thither to
-study law; but his passion was for natural philosophy,
-which led him to devote himself to the study of medicine.
-From Jena he went to Halle, and finally to
-Leyden, attracted by the reputation of the older Albinus,
-of Professor Sengerd and the celebrated Boerhaave,
-at that time in the height of his reputation.
-The only practical anatomist then in Leyden, was
-M. Bidloo, an old man of eighty, and of course
-<span class="pagenum" id="Page_270">270</span>
-unfit for teaching. This induced Eller to repair to
-Amsterdam, to study under Rau, and to inspect the
-anatomical museum of Ruysch. Bidloo soon dying,
-Rau was appointed his successor at Leyden, whither
-Eller followed him, and dissected under him till the
-year 1716. After taking his degree at Leyden, Eller
-returned to Germany, and devoted a considerable
-time to the study and examination of the mines of
-Saxony and the Hartz, and of the metallurgic processes
-connected with these mines. From these mines
-he repaired to France, and resumed his anatomical
-studies under Du Verney and Winslow. Chemistry
-also attracted a good deal of his attention, and he frequented
-the laboratories of Grosse, Lemery, Bolduc,
-and Homberg, at that time the most eminent chemists
-in Paris.</p>
-
-<p>From Paris he repaired to London, where he formed
-an acquaintance with the numerous medical men of
-eminence who at that time adorned this capital. On
-returning to Germany in 1721, he was appointed physician
-to Prince Victor Frederick of Anhalt Bernburg.
-From Bernburg he went to Magdeburg; and the
-King of Prussia called him to Berlin in 1724, to teach
-anatomy in the great anatomic theatre which had been
-just erected. Soon after he was appointed physician
-to the king, a counsellor and professor in the Royal
-Medico-Chirurgical College, which had been just
-founded in Berlin. He was also appointed dean of
-the Superior College of Medicine, and physician to
-the army and to the great Hospital of Frederick. In
-the year 1755 Frederick the Great made him a privy-counsellor,
-which is the highest rank that a medical
-man can attain in Prussia. The same year he was
-made director of the Royal Academy of Sciences of
-Berlin. He died in the year 1760, in the seventy-first
-year of his age. He was twice married, and his second
-wife survived him.</p>
-
-<p>Many chemical papers of Eller are to be found in
-<span class="pagenum" id="Page_271">271</span>
-the memoirs of the Berlin Academy. They were of
-sufficient importance, at the time when he published
-them, to add considerably to his reputation, though
-not sufficiently so to induce me to give a catalogue of
-them here. I am not aware of any chemical discovery
-for which we are indebted to him; but have been induced
-to give this brief notice of him, because he is
-usually associated with Pott and Margraaf, making
-with them the three celebrated chemists who adorned
-Berlin, during the splendid reign of Frederick the
-Great.</p>
-
-<p>Andrew Sigismund Margraaf was born in Berlin,
-in the year 1709, and acquired the first principles
-of chemistry from his father, who was an apothecary
-in that city. He afterwards studied under Neumann,
-and travelling in quest of information to Frankfort,
-Strasburg, Halle, and Freyburg, he returned to Berlin
-enriched with all the knowledge of his favourite
-science which at that time existed. In 1760, on the
-death of Eller, he was made director of the physical
-class of the Berlin Academy of Sciences. He died
-in the year 1782, in the seventy-third year of his
-age. He gradually acquired a brilliant reputation
-in consequence of the numerous chemical papers
-which he successively published, each of which usually
-contained a new chemical fact, of more or less importance,
-deduced from a set of experiments generally
-satisfactory and convincing. His papers have a greater
-resemblance to those of Scheele than of any other
-chemist to whom we can compare them. He may
-be considered as in some measure the beginner of
-chemical analysis; for, before his time, the chemical
-analysis of bodies had hardly been attempted. His
-methods, as might have been expected, were not very
-perfect; nor did he attempt numerical results. His
-experiments on phosphorus and on the method of
-extracting it from urine are valuable; they communicated
-the first accurate notions relative to this
-<span class="pagenum" id="Page_272">272</span>
-substance and to phosphoric acid. He first determined
-the properties of the earth of alum, now known
-by the name of <i>alumina</i>; showed that it differed from
-every other, and that it existed in clay, and gave
-to that substance its peculiar properties. He demonstrated
-the peculiar nature of soda, the base of
-common salt, which Pott had called in question, and
-thus verified the conclusions of Duhamel. He gives
-an easy process for obtaining pure silver from the
-chloride of that metal: his method is to dissolve
-the pure chloride of silver in a solution of caustic
-ammonia, and to put into the liquid a sufficient
-quantity of pure mercury; the silver is speedily reduced
-and converted into an amalgam, and when this
-amalgam is exposed to a red heat the mercury is
-driven off and pure silver remains. The usual method
-of reducing the chloride of silver is to heat it in a
-crucible with a sufficient quantity of carbonate of
-potash, a process which was first recommended by
-Kunkel. But it is scarcely possible to prevent the
-loss of a portion of the silver when the chloride is
-reduced in this way. The modern process is undoubtedly
-the simplest and the best, to reduce it
-by means of hydrogen. If a few pieces of zinc be
-put into the bottom of a beer-glass and some dilute
-sulphuric acid be poured over it an effervescence
-takes place, and hydrogen gas is disengaged. Chloride
-of silver, placed above the zinc in the same
-glass, is speedily reduced by this hydrogen and converted
-into metallic silver.</p>
-
-<p>Margraaf’s chemical papers, down to the time of
-publication, were collected together, translated into
-French and published at Paris in the year 1762,
-in two very small octavo volumes, they consist of
-twenty-six different papers: some of the most curious
-and important of which are those that have been
-just particularized. Several other papers written by
-him appeared in the memoirs of the Berlin Academy,
-<span class="pagenum" id="Page_273">273</span>
-after this collection of his works was published, particularly
-“A demonstration of the possibility of drawing
-fixed alkaline salts from tartar by means of acids,
-without employing the action of a violent fire.” It
-was this paper, probably, that led Scheele, a few
-years after, to his well-known method of obtaining
-tartaric acid, a modification of which is still followed
-by manufacturers.</p>
-
-<p>“Observations concerning a remarkable volatilization
-of a portion of a kind of stone known by the
-names of flosse, flusse, fluor spar, and likewise by that
-of hesperos: which volatilization was effectuated by
-means of acids.” Pott had already shown the value
-of fluor spar as a flux. Three years after the appearance
-of Margraaf’s paper, Scheele discovered the
-nature of fluor spar, and first drew the attention of
-chemists to the peculiar properties of fluoric acid.</p>
-
-<p>In France, in consequence chiefly of the regulations
-established in the Academy of Sciences, in the
-year 1699, a race of chemists always existed, whose
-specific object was to cultivate chemistry, and extend
-and improve it. The most eminent of these chemical
-labourers, after the Stahlian theory was fully admitted
-in France till its credit began to be shaken,
-were Reaumur, Hellot, Duhamel, Rouelle, and Macquer.
-Besides these, who were the chief chemists
-in the academy, there were a few others to whom
-we are indebted for chemical discoveries that deserve
-to be recorded.</p>
-
-<p>Ren&eacute; Antoine Ferchault, Esq., Seigneur de Reaumur,
-certainly one of the most extraordinary men
-of his age, was born at Rochelle, in 1683. He went
-to the school of Rochelle, and afterwards studied
-philosophy under the Jesuits at Poitiers. Hence he
-went to Bourges, to which one of his uncles, canon
-of the holy chapel in that city, had invited him. At
-this time he was only seventeen years of age, yet
-his parents ventured to intrust a younger brother
-<span class="pagenum" id="Page_274">274</span>
-to his care, and this care he discharged with all the
-fidelity and sagacity of a much older man. Here
-he devoted himself to mathematics and physics, and
-he soon after went to Paris to improve the happy
-talents which he had received from nature. He was
-fortunate enough to meet with a friend and relation
-in the president, Henault, equally devoted to study
-with himself, equally eager for information, and
-possessed of equal honour and integrity, and equally
-promising talents.</p>
-
-<p>He came to Paris in 1703. In 1708 he was admitted
-into the Academy of Sciences, in the situation
-of <i>&eacute;l&egrave;ve</i> of M. Varignon, vacant by the promotion of
-M. Saurin to the rank of associate.</p>
-
-<p>The first papers of his which were inserted in the
-Memoirs of the Academy were geometrical: he gave
-a general method of finding an infinity of curves,
-described by the extremity of a straight line, the
-other extremity of which, passing along the surface
-of a given curve, is always obliged to pass through the
-same point. Next year he gave a geometrical work on
-Developes; but this was the last of his mathematical
-tracts. He was charged by the academy with the task
-of giving a description of the arts, and his taste for
-natural history began to draw to that study the greatest
-part of his attention. His first work as a naturalist
-was his observations on the formation of shells. It was
-unknown whether shells increase by intussusception,
-like animal bodies, or by the exterior and successive
-addition of new parts. By a set of delicate observations
-he showed that shells are formed by the addition
-of new parts, and that this was the cause of the
-variety of colour, shape, and size which they usually
-affect. His observations on snails, with a view to
-the way in which their shells are formed, led him
-to the discovery of a singular insect, which not only
-lives on snails, but in the inside of their bodies, from
-which it never stirs till driven out by the snail.
-<span class="pagenum" id="Page_275">275</span></p>
-
-<p>During the same year, he wrote his curious paper
-on the silk of spiders. The experiments of M. Bohn
-had shown that spiders could spin a silk that might
-be usefully employed. But it remained to be seen
-whether these creatures could be fed with profit, and
-in sufficiently great numbers to produce a sufficient
-quantity of silk to be of use. Reaumur undertook
-this disagreeable task, and showed that spiders could
-not be fed together without attacking and destroying
-one another.</p>
-
-<p>The next research which he undertook, was to discover
-in what way certain sea-animals are capable
-of attaching themselves to fixed bodies, and again
-disengaging themselves at pleasure. He discovered
-the various threads and pinn&aelig; which some of them
-possess for this purpose, and the prodigious number of
-limbs by which the sea-star is enabled to attach itself
-to solid bodies. Other animals employ a kind of
-cement to glue themselves to those substances to
-which they are attached, while some fix themselves
-by forming a vacuum in the interval between themselves
-and the solid substances to which they are
-attached.</p>
-
-<p>It was at this period that he found great quantities
-of the buccinum, which yielded the purple dye of
-the ancients, upon the coast of Poitou. He observed,
-also, that the stones and little sandy ridges round
-which the shellfish had collected were covered with
-a kind of oval grains, some of which were white, and
-others of a yellowish colour, and having collected
-and squeezed some of these upon the sleeve of his
-shirt, so as to wet it with the liquid which they contained,
-he was agreeably surprised in about half an
-hour to find the wetted spot assume a beautiful purple
-colour, which was not discharged by washing. He
-collected a number of these grains, and carrying them
-to his apartment, bruised and squeezed different parcels
-of them upon bits of linen; but to his great
-<span class="pagenum" id="Page_276">276</span>
-surprise, after two or three hours, no colour appeared
-on the wetted part; but, at the same time, two or three
-spots of the plaster at the window, on which drops of
-the liquid had fallen, had become purple; though the
-day was cloudy. On carrying the pieces of linen to
-the window, and leaving them there, they also acquired
-a purple colour. It was the action of light, then, on
-the liquor, that caused it to tinge the linen. He found,
-likewise, that when the colouring matter was put into
-a phial, which filled it completely, it remained unchanged;
-but when the phial was not full, and was
-badly corked, it acquired colour. From these facts
-it is evident, that the purple colour is owing to the
-joint action of the light and the oxygen of the atmosphere
-upon the liquor of the shellfish.</p>
-
-<p>About this time, likewise, he made experiments
-upon a subject which attracted the attention of mechanicians&mdash;to
-determine whether the strength of a
-cord was greater, or less, or equal to the joint strength
-of all the fibres which compose it. The result of
-Reaumur’s experiments was, that the strength of the
-cord is less than that of all the fibres of which it is composed.
-Hence it follows, that the less that a cord
-differs from an assemblage of straight fibres, the
-stronger it is. This, at that time considered as a singular
-mechanical paradox, was afterwards elucidated
-by M. Duhamel.</p>
-
-<p>It was a popular opinion of all the inhabitants of the
-sea-shore, that when the claws of crabs, lobsters, &amp;c.,
-are lost by any means, they are gradually replaced
-by others, and the animal in a short time becomes
-as perfect as at first. This opinion was ridiculed by
-men of science as inconsistent with all our notions of
-true philosophy. Reaumur subjected it to the test
-of experiment, by removing the claws of these animals,
-and keeping them alone for the requisite time
-in sea-water: new claws soon sprang out, and perfectly
-replaced those that had been removed. Thus
-<span class="pagenum" id="Page_277">277</span>
-the common opinion was verified,and the contemptuous
-smile of the half-learned man of science was shown to
-be the result of ignorance, not of knowledge.</p>
-
-<p>Reaumur was not so fortunate in his attempts to explain
-the nature of the shock given by the torpedo;
-which we now know to be an electric shock produced
-by a peculiar apparatus within the animal. Reaumur
-endeavoured to prove, from dissection, that the shock
-was owing to the prodigious rapidity of the blow given
-by the animal in consequence of a peculiar structure
-of its muscles.</p>
-
-<p>The turquoise was at that time, as it still is, considerably
-admired in consequence of the beauty of its
-colour. Persia was the country from which this precious
-stone came, and it was at that time considered as
-the only country in the universe where it occurred.
-Reaumur made a set of experiments on the subject
-and showed that the fossil bones found in Languedoc,
-when exposed to a certain heat, assume the same
-beautiful green colour, and become turquoises equally
-beautiful with the Persian. It is now known, that the
-true Persian turquoise, the <i>calamite</i> of mineralogists, is
-quite different from fossil bones coloured with copper.
-So far, therefore, Reaumur deceived himself by these
-experiments; but at that time chemical knowledge
-was too imperfect to enable him to subject Persian
-turquoise to an analysis, and determine its constitution.</p>
-
-<p>About the same period, he undertook an investigation
-of the nature of imitation pearls, which resemble the
-true pearls so closely, that it is very difficult, from appearances,
-to distinguish the true from the false. He
-showed that the substance which gave the false pearls
-their colour and lustre, was taken from a small fish
-called by the French <i>able</i>, or <i>ablette</i>. He likewise
-undertook an investigation of the origin of true
-pearls, and showed that they were indebted for their
-production to a disease of the animal. It is now known,
-that the introduction of any solid body, as a grain of
-<span class="pagenum" id="Page_278">278</span>
-sand, within the shell of the living pearl-shellfish, gives
-occasion to the formation of pearl. Linn&aelig;us boasted
-that he knew a method of forming artificial pearls; and
-doubtless his process was merely introducing some
-solid particle of matter into the living shell. Pearls
-consist of alternate layers of carbonate of lime and
-animal membrane; and the colour and lustre to which
-they owe their value depends upon the thinness of the
-alternate coats.</p>
-
-<p>The next paper of Reaumur was an account of the
-rivers in France whose sand yielded gold-dust, and the
-method employed to extract the gold. This paper will
-well repay the labour of a perusal; it owes its interest
-in a great measure to the way in which the facts are
-laid before the reader.</p>
-
-<p>His paper on the prodigious bank of fossil shells at
-Touraine, from which the inhabitants draw manure in
-such quantities for their fields, deserves attention in a
-geological point of view. But his paper on flints and
-stones is not so valuable; it consists in speculations,
-which, from the infant state of chemical analysis when
-he wrote, could not be expected to lead to correct conclusions.</p>
-
-<p>I pass over many of the papers of this most indefatigable
-man, because they are not connected with
-chemistry; but his history of insects constitutes a
-charming book, and contains a prodigious number of
-facts of the most curious and important nature. This
-book alone, supposing Reaumur had done nothing
-else, would have been sufficient to have immortalized
-the author.</p>
-
-<p>In the year 1722 he published his work on the <i>art
-of converting iron into steel, and of softening cast-iron</i>.
-At that time no steel whatever was made in
-France; the nation was supplied with that indispensable
-article from foreign countries, chiefly from Germany.
-The object of Reaumur’s book was to teach
-his countrymen the art of making steel, and, if possible,
-<span class="pagenum" id="Page_279">279</span>
-to explain the nature of the process by which iron is
-changed into steel. Reaumur concluded from his experiments,
-that steel is iron impregnated with <i>sulphureous</i>
-and <i>saline</i> matters. The word <i>sulphureous</i>,
-as at that time used, was nearly synonymous with our
-present term <i>combustible</i>. The process which he found
-to answer, and which he recommends to be followed,
-was to mix together
-
-<span class="table">
-  <span class="trow">
-    <span class="tcell">4</span>
-    <span class="tcell">parts of soot</span>
-  </span>
-  <span class="trow">
-    <span class="tcell">2</span>
-    <span class="tcell">parts of charcoal-powder</span>
-  </span>
-  <span class="trow">
-    <span class="tcell">2</span>
-    <span class="tcell">parts of wood-ashes</span>
-  </span>
-  <span class="trow">
-    <span class="tcell">1&frac12;</span>
-    <span class="tcell">parts of common salt.</span>
-  </span>
-</span></p>
-
-<p>The iron bars to be converted into steel were surrounded
-with this mixture, and kept red-hot till converted
-into steel. Reaumur’s notion of the difference between
-iron and steel was an approximation to the
-truth. The saline matters which he added do not
-enter into the composition of steel; and if they did, so
-far from improving, they would injure its qualities.
-But the charcoal and soot, which consist chiefly of
-carbon, really produce the desired effect; for steel is
-a combination of <i>iron</i> and <i>carbon</i>.</p>
-
-<p>In consequence of these experiments of Reaumur, it
-came to be an opinion entertained by chemists, that
-steel differed from iron merely by containing a greater
-proportion of phlogiston; for the charcoal and soot
-with which the iron bars were surrounded was considered
-as consisting almost entirely of phlogiston; and
-the only useful purpose which they could serve, was
-supposed to be to furnish phlogiston. This opinion
-continued prevalent till it was overturned towards the
-end of the last century, first by the experiments of
-Bergmann, and afterwards by those of Berthollet,
-Vandermond, and Monge, published in the Memoirs of
-the French Academy for 1786 (page 132). In this
-elaborate memoir the authors take a view of all the
-different processes followed in bringing iron from the
-ore to the state of steel: they then give an account of
-<span class="pagenum" id="Page_280">280</span>
-the researches of Reaumur and of Bergmann; and lastly
-relate their own experiments, from which they finally
-draw, as a conclusion, that steel is a compound of iron
-and carbon.</p>
-
-<p>The regent Orleans, who at that time administered
-the affairs of France, thought that this work of Reaumur
-was deserving a reward, and accordingly offered
-him a pension of 12,000 livres. Reaumur requested
-of the regent that this pension should be given in the
-name of the academy, and that after his death it should
-continue, and be devoted to defray the necessary expenses
-towards bringing the arts into a state of perfection.
-The request was granted, and the letters patent
-made out on the 22d of December, 1722.</p>
-
-<p>At that time tin-plate, as well as steel, was not made
-in France; but all the tin-plates wanted were brought
-from Germany, where the processes followed were
-kept profoundly secret. Reaumur undertook to discover
-a method of tinning iron sufficiently cheap to
-admit the article to be manufactured in France&mdash;and
-he succeeded. The difficulty consisted in removing
-the scales with which the iron plates, as prepared, were
-always covered. These scales consist of a vitrified
-oxide of iron, to which the tin will not unite. Reaumur
-found, that when these plates are steeped in water
-acidulated by means of bran, and then allowed to rust in
-stoves, the scales become loose, and are easily detached
-by rubbing the plates with sand. If after being thus
-cleansed they are plunged into melted tin, covered with
-a little tallow to prevent oxidizement, they are easily
-tinned. In consequence of this explanation of the
-process by Reaumur, tin-plate manufactories were
-speedily established in different parts of France. It
-was about the same time, or only a little before it,
-that tin-plate manufactories were first started in England.
-The English tin-plate was much more beautiful
-than the German, and therefore immediately preferred
-to it; because in Germany the iron was converted into
-<span class="pagenum" id="Page_281">281</span>
-plates by hammering, whereas in England it was rolled
-out. This made it much smoother, and consequently
-more beautiful.</p>
-
-<p>Another art, at that time unknown in France, and
-indeed in every part of Europe except Saxony, was
-the art of making porcelain, a name given to the
-beautiful translucent stoneware which is brought from
-China and Japan. Reaumur undertook to discover
-the process employed in making it. He procured
-specimens of porcelain from China and Japan, and
-also of the imitations of those vessels at that time
-made in various parts of France and other European
-countries. The true porcelain remained unaltered,
-though exposed to the most violent heat which he was
-capable of producing; but the imitations, in a furnace
-heated by no means violently, melted into a
-perfect glass. Hence he concluded, that the imitation-porcelains
-were merely glass, not heated sufficiently
-to be brought into fusion; but true porcelain
-he conceived to be composed of two different ingredients,
-one of which is capable of resisting the most
-violent heat which can be raised, but the other, when
-heated sufficiently, melts into a glass. It is this last
-ingredient that gives porcelain its translucency, while
-the other makes it refractory in the fire. This opinion
-of Reaumur was soon after confirmed by Father
-d’Entrecolles, a French missionary in China, who
-sent some time after a memoir to the academy, describing
-the mode followed by the Chinese in the manufactory
-of their porcelain. Two substances are
-employed by them, the one called <i>kaolin</i> and the
-other <i>petunse</i>. It is now known that <i>kaolin</i> is what
-we call porcelain-clay, and that <i>petunse</i> is a fine
-white felspar. Felspar is fusible in a violent heat, but
-porcelain-clay is refractory in the highest temperatures
-that we have it in our power to produce in furnaces.</p>
-
-<p>Reaumur made another curious observation on
-glass, which has been, since his time, employed very
-<span class="pagenum" id="Page_282">282</span>
-successfully to explain the appearances of many of
-our trap-rocks. If a glass vessel, properly secured in
-sand, be raised to a red heat, and then allowed to
-cool very slowly, it puts off the appearance of glass
-and assumes that of stoneware, or porcelain. Vessels
-thus altered have received the name of <i>Reaumur’s
-porcelain</i>. They are much more refractory than glass,
-and therefore may be exposed to a pretty strong red
-heat without any danger of softening or losing their
-shape. This change is occasioned by the glass being
-kept long in a soft state: the various substances of
-which it is composed are at liberty to exercise their
-affinities and to crystallize. This makes the vessel lose
-its glassy structure altogether. In like manner it was
-found by Sir James Hall and Mr. Gregory Watt, that
-when common greenstone was heated sufficiently,
-and then rapidly cooled, it melted and concreted into
-a glass; but if after having been melted it was allowed
-to cool exceedingly slowly, the constituents again
-crystallized and arranged themselves as at first&mdash;so
-that a true greenstone was again formed. In the same
-way lavas from a volcano either assume the appearance
-of slag or of stone, according as they have cooled rapidly
-or slowly. Many of the lavas from Vesuvius
-cannot be distinguished from our <i>greenstones</i>.</p>
-
-<p>Reaumur’s labours upon the thermometer must not
-be omitted here; because he gave his name to a thermometer,
-which was long used in France and in other
-parts of Europe. The first person that brought thermometers
-into a state capable of being compared with
-each other was Sir Isaac Newton, in a paper published
-in the Philosophical Transactions for 1701. Fahrenheit,
-of Amsterdam, was the first person that put
-Newton’s method in practice, by fixing two points on
-his scale, the freezing-water point and the boiling-water
-point, and dividing the interval between them
-into one hundred and eighty degrees.</p>
-
-<p>But no fixed point existed in the thermometers employed
-<span class="pagenum" id="Page_283">283</span>
-in France, every one graduating them according
-to his fancy; so that no two thermometers could
-be compared together. Reaumur graduated his thermometers
-by plunging them into freezing water or a
-mixture of snow and water. This point was marked
-zero, and was called the freezing-water point. The
-liquid used in his thermometers was spirit of wine:
-he took care that it should be always of the same
-strength, and the interval between the point of freezing
-and boiling water was divided into eighty degrees.
-Deluc afterwards rectified this thermometer, by substituting
-mercury for spirit of wine. This not only enabled
-the thermometer to be used to measure higher
-temperatures, but corrected an obvious error which
-existed in all the thermometers constructed upon
-Reaumur’s principle: for spirit of wine cannot bear a
-temperature of eighty degrees Reaumur without being
-dissipated into vapour&mdash;absolute alcohol boiling at a
-hundred and sixty-two degrees two-thirds. It is obvious
-from this, that the boiling point in Reaumur’s
-thermometer could not be accurate, and that it would
-vary, according to the quantity of empty space left
-above the alcohol.</p>
-
-<p>Finally, he contrived a method of hatching chickens
-by means of artificial heat, as is practised in Egypt.</p>
-
-<p>We are indebted to him also for a set of important
-observations on the organs of digestion in birds. He
-showed, that in birds of prey, which live wholly upon
-animal food, digestion is performed by solvents in the
-stomach, as is the case with digestion in man: while
-those birds that live upon vegetable food have a very
-powerful stomach or gizzard, capable of triturating
-the seeds which they swallow. To facilitate this triturating
-process, these fowls are in the habit of swallowing
-small pebbles.</p>
-
-<p>The moral qualities of M. Reaumur seem not to have
-been inferior to the extent and variety of his acquirements.
-He was kind and benevolent, and remarkably
-<span class="pagenum" id="Page_284">284</span>
-disinterested. He performed the duties of intendant
-of the order of St. Louis from the year 1735 till his
-death, without accepting any of the emoluments of
-the office, all of which were most religiously given to
-the person to whom they belonged, had she been capable
-of performing the duties of the place. M.
-Reaumur died on the 17th of October, 1756, after
-having lived very nearly seventy-five years.</p>
-
-<p>John Hellot was born in Paris in the year 1685, on
-the 20th of November. His father, Michael Hellot,
-was of a respectable family, and the early part of his
-son’s education was at home: it seems to have been
-excellent, as young Hellot acquired the difficult art
-of writing on all manner of subjects in a precise, clear,
-and elegant style. His father intended him for the
-church; but his own taste led him decidedly to the
-study of chemistry. He had an uncle a physician,
-some of whose papers on chemical subjects fell into
-his hands. This circumstance kindled his natural taste
-into a flame: he formed an acquaintance with M.
-Geoffroy, whose reputation as a chemist was at that
-time high, and this friendship was afterwards cemented
-by Geoffroy marrying the niece of M. Hellot.</p>
-
-<p>His circumstances being easy, he went over to
-England, to form a personal acquaintance with the
-many eminent philosophers who at that time adorned
-that country. His fortune was considerably deranged
-by Law’s celebrated scheme during the regency of the
-Duke of Orleans. This obliged him to look out for
-some resource: he became editor of the Gazette de
-France, and continued in this employment from 1718
-to 1732. During these fourteen years, however, he
-did not neglect chemistry, though his progress was
-not so rapid as it would have been, could he have devoted
-to that science his undivided attention. In 1732
-he was put forward by his friends as a candidate for a
-place in the Academy of Sciences; and in the year
-1735 he was chosen adjunct chemist, vacant by the
-<span class="pagenum" id="Page_285">285</span>
-promotion of M. de la Condamine to the place of associate.
-Three years after he was declared a supernumerary
-pensioner, without passing through the step
-of associate. His reputation as a chemist was already
-considerable, and after he became a member of the
-academy, he devoted himself to the investigations
-connected with his favourite science.</p>
-
-<p>His first labours were on zinc; in two successive
-papers he endeavoured to decompose this metal, and
-to ascertain the nature of its constituents. Though
-his labour was unsuccessful, yet he pointed out many
-new properties of this metal, and various new compounds
-into which it enters. Neither was he more
-successful in his attempt to account for the origin of
-the red vapours which are exhaled from nitre in
-certain circumstances. He ascribed them to the
-presence of ferruginous matters in the nitre; whereas
-they are owing to the expulsion and partial decomposition
-of the nitric acid of the nitre, in consequence of
-the action of some more powerful acid.</p>
-
-<p>His paper on sympathetic ink is of more importance.
-A German chemist had shown him a saline solution of
-a red colour which became blue when heated: this
-led him to form a sympathetic ink, which was pale
-red, while the paper was moist, but became blue upon
-drying it by holding it to the fire. This sympathetic
-ink was a solution of cobalt in muriatic acid. It does
-not appear from Hellot’s paper that he was exactly
-aware of the chemical constitution of the liquid which
-constituted his sympathetic ink; though it is clear he
-knew that cobalt constitutes an essential part of it.</p>
-
-<p>Kunkel’s phosphorus, though it had been originally
-discovered in Germany, could not be prepared by any
-of the processes which had been given to the public.
-Boyle had taught his operator, Godfrey Hankwitz, the
-method of making it. This man had, after Boyle’s
-death, opened a chemist’s shop in London, and it was
-he that supplied all Europe with this curious article:
-<span class="pagenum" id="Page_286">286</span>
-on that account it was usually distinguished by the
-name of <i>English phosphorus</i>. But in the year 1737
-a stranger appeared in Paris, who offered for a stipulated
-reward to communicate the method of manufacturing
-this substance to the Academy of Sciences.
-The offer was accepted by the French government,
-and a committee of the academy, at the head of which
-was Hellot, was appointed to witness the process, and
-ascertain all its steps. The process was repeated with
-success; and Hellot drew up a minute detail of the
-whole, which was inserted in the Memoirs of the Academy,
-for the year 1737. The publication of this
-paper constitutes an era in the preparation of phosphorus:
-it was henceforward in the power of every
-chemist to prepare it for himself. A few years after
-the process was much improved by Margraaf; and,
-within little more than twenty years after, the very
-convenient process still in use was suggested by Scheele.
-Hellot’s experiments on the comparative merits of the
-salts of Peyrac, and of Pecais were of importance,
-because they decided a dispute&mdash;they may also perhaps
-be considered as curiosities in an historical point
-of view; because we see from them the methods which
-Hellot had recourse to at that early period in order to
-determine the purity of common salt. They are not
-entitled, however, to a more particular notice here.</p>
-
-<p>In the year 1740 M. Hellot was charged with the
-general inspection of dyeing; a situation which
-M. du Foy had held till the time of his death in 1739.
-It was this appointment, doubtless, which turned his
-attention to the theory of dyeing, which he tried to
-explain in two memoirs read to the academy in 1740
-and 1741. The subject was afterwards prosecuted by
-him in subsequent memoirs which were published by
-the academy.</p>
-
-<p>In 1745 he was named to go to Lyons in order to
-examine with care the processes followed for refining
-gold and silver. Before his return he took care to
-<span class="pagenum" id="Page_287">287</span>
-give to these processes the requisite precision and exactness.
-Immediately after his return to Paris he was
-appointed to examine the different mines and assay
-the different ores in France; this appointment led him
-to turn his thoughts to the subject. The result of this
-was the publication of an excellent work on assaying
-and metallurgy, entitled “De la Fonte des Mines, des
-Fonderies, &amp;c. Traduit de l’Allemand de Christophe-Andr&eacute;
-Schlutter.” The first volume of this book
-appeared in 1750, and the second in 1753. Though
-this book is called by Hellot a translation, it contains
-in fact a great deal of original matter; the arrangement
-is quite altered; many processes not noticed by
-Schlutter are given, and many essential articles are
-introduced, which had been totally omitted in the
-original work. He begins with an introduction, in
-which he gives a short sketch of all the mines existing
-in every part of France, together with some notice of
-the present state of each. The first volume treats entirely
-of docimasy, or the art of assaying the different
-metallic ores. Though this art has been much improved
-since Hellot’s time, yet the processes given in
-this volume are not without their value. The second
-volume treats of the various metallurgic processes followed
-in order to extract metals from their ores. This
-volume is furnished with no fewer than fifty-five plates,
-in which all the various furnaces, &amp;c. used in these
-processes are exhibited to the eye.</p>
-
-<p>While occupied in preparing this work for the press
-he was chosen to endeavour to bring the porcelain manufactory
-at Sevre to a greater state of perfection than
-it had yet reached. In this he was successful. He
-even discovered various new colours proper for painting
-upon porcelain; which contributed to give to this
-manufactory the celebrity which it acquired.</p>
-
-<p>In the year 1763 a phenomenon at that time quite
-new to France took place in the coal-mine of Brian&ccedil;on.
-A quantity of carburetted hydrogen gas had collected
-<span class="pagenum" id="Page_288">288</span>
-in the bottom of the mine, and being kindled by the
-lights employed by the miners, it exploded with great
-violence, and killed or wounded every person in the
-mine. This destructive gas, distinguished in this
-country by the name of <i>fire-damp</i>, had been long known
-in Great Britain and in the Low Countries, though
-it had not before been known in France. The Duke
-de Choiseul, informed of this event, had recourse to
-the academy for assistance, who appointed Messrs. de
-Montigny, Duhamel, and Hellot, a committee to
-endeavour to discover the remedies proper to prevent
-any such accident from happening for the future. The
-report of these gentlemen was published in the Memoirs
-of the Academy;<a id="FNanchor_182" href="#Footnote_182" class="fnanchor">182</a> they give an account both of
-the fire-damp, and <i>choke-damp</i>, or <i>carbonic acid gas</i>,
-which sometimes also makes its appearance in coal-mines.
-They very justly observe that the proper way
-to obviate the inconveniency of these gases is to ventilate
-the mine properly; and they give various methods
-by which this ventilation may be promoted by means
-of fires lighted at the bottom of the shaft, &amp;c.</p>
-
-<p>In 1763 M. Hellot was appointed, conjointly with
-M. Tillet, to examine the process followed for assaying
-gold and silver. They showed that the cupels always
-retained a small portion of the silver assayed, and
-that this loss, ascribed to the presence of a foreign
-metal, made the purity of the silver be always reckoned
-under the truth, which occasioned a loss to the proprietor.</p>
-
-<p>His health continued tolerably good till he reached
-his eightieth year: he was then struck with palsy, but
-partially recovered from the first attack; but a second
-attack, on the 13th of February, 1765, refused to
-yield to every medical treatment, and he died on
-the 15th of that month, at an age a little beyond
-eighty.
-<span class="pagenum" id="Page_289">289</span></p>
-
-<p>Henry Louis Duhamel du Monceau was born at
-Paris in the year 1700. He was descended from
-Loth Duhamel, a Dutch gentleman, who came to
-France in the suite of the infamous Duke of Burgundy,
-about the year 1400. Young Duhamel was
-educated in the College of Harcourt; but the course
-of study did not suit his taste. He left it with only
-one fact engraven on his memory&mdash;that men, by observing
-nature, had created a science called <i>physics</i>;
-and he resolved to profit by his freedom from restraint
-and turn the whole of his attention to that subject.
-He lodged near the Jardin du Roi, where alone, at
-that time, physics were attended to in Paris. Dufoy,
-Geoffroy, Lemery, Jussieu, and Vaillant, were the
-friends with whom he associated on coming to Paris.
-His industry was stimulated solely by a love of study,
-and by the pleasure which he derived from the increase
-of knowledge; love of fame does not appear to have
-entered into his account.</p>
-
-<p>In the year 1718 saffron, which is much cultivated
-in that part of France formerly distinguished by the
-name of G&acirc;tinois, where Duhamel’s property lay, was
-attacked by a malady which appeared contagious.
-Healthy bulbs, when placed in the neighbourhood of
-those that were diseased, soon became affected with
-the same malady. Government consulted the academy
-on the subject; and this learned body thought
-they could not do better than request M. Duhamel to
-investigate the cause of the disease; though he was
-only eighteen years of age, and not even a member
-of the academy. He ascertained that the malady
-was owing to a parasitical plant, which attached itself
-to the bulb of the saffron, and drew nourishment from
-it. This plant extended under the earth, from one
-bulb to another, and thus infected the whole saffron
-plantations.</p>
-
-<p>M. Duhamel formed the resolution at the commencement
-of his scientific career to devote himself
-<span class="pagenum" id="Page_290">290</span>
-to public utility, and to prosecute those subjects which
-were likely to contribute most effectually to the comfort
-of the lower ranks of men. Much of his time
-was spent in endeavouring to promote the culture of
-vegetables, and in rendering that culture more useful
-to society. This naturally led to a careful study of
-the physiology of trees. The fruit of this study he
-gave to the world in the year 1758, when his Physique
-des Arbres was published. This constitutes one of
-the most important works on the subject which has
-ever appeared. It contains a great number of new
-and original facts; and contributed very much indeed
-to advance this difficult, but most important branch
-of science: nor is it less remarkable for modesty than
-for value. The facts gathered from other sources,
-even those which make against his own opinions, are
-most carefully and accurately stated: the experiments
-that preceded his are repeated and verified with much
-care; and the reader is left to discover the new facts
-and new views of the author, without any attempt
-on his part to claim them as his own.</p>
-
-<p>M. Duhamel had been attached to the department
-of the marine by M. de Maurepas, who had given him
-the title of <i>inspector-general</i>. This led him to turn
-his attention to naval science in general. The construction
-of vessels, the weaving of sailcloths, the
-construction of ropes and cables, the method of preserving
-the wood, occupied his attention successively,
-and gave birth to several treatises, which, like all his
-works, contain immense collections of facts and experiments.
-He endeavours always to discover which is
-the best practice, to reduce it to fixed rules, and to
-support it by philosophical principles; but abstains
-from all theory when it can be supported only by
-hypothesis.</p>
-
-<p>From the year 1740, when he became an academician,
-till his death in 1781, he made a regular set of
-meteorological observations at Pithiviers, with details
-<span class="pagenum" id="Page_291">291</span>
-relative to the direction of the needle, to agriculture,
-to the medical constitution of the year, and to the time
-of nest-building, and of the passage of birds.</p>
-
-<p>Above sixty memoirs of his were published in the
-Transactions of the French Academy of Sciences.
-They are so multifarious in their nature, and embrace
-such a variety of subjects, that I shall not attempt
-even to give their titles, but satisfy myself with stating
-such only as bear more immediately upon the science
-of chemistry.</p>
-
-<p>It will be proper in conducting this review to notice
-the result of his labours connected with the ossification
-of bones; because, though not strictly chemical, they
-throw light upon some branches of the animal economy,
-more closely connected with chemistry than with any
-other of the sciences. He examined, in the first place,
-whether the ossification of bones, and their formation
-and reparation, did not follow the same law that he
-had assigned to the increments of trees, and he established,
-by a set of experiments, that bones increase
-by the ossification of layers of the periosteum, as trees
-do by the hardening of their cortical layers. Bones in
-a soft state increase in every direction, like the young
-branches of plants; but after their induration they increase
-only like trees, by successive additions of successive
-layers. This organization was incompatible
-with the opinion of those who thought that bones increased
-by the addition of an earthy matter deposited
-in the meshes of the organized network which forms
-the texture of bones. M. Duhamel combated this
-opinion by an ingenious experiment. He had been
-informed by Sir Hans Sloane that the bones of young
-animals fed upon madder were tinged red. He conceived
-the plan of feeding them alternately with food
-mingled with madder, and with ordinary food. The
-bones of animals thus treated were found to present
-alternate concentric layers of red and white, corresponding
-to the different periods in which the animal
-<span class="pagenum" id="Page_292">292</span>
-had been fed with food containing or not containing
-madder. When these bones are sawn longitudinally we
-see the thickness of the coloured layers, greater or less,
-according to the number of plates of the periosteum
-that have ossified. As for the portions still soft, or
-susceptible of extending themselves in every direction,
-such as the plates in the neighbourhood of the marrow,
-the reservoir of which increases during a part of
-the time that the animal continues to grow, the red
-colour marks equally the progress of their ossification
-by coloured points more or less extended.</p>
-
-<p>This opinion was attacked by Haller, and defended
-by M. Fougeroux, nephew of M. Duhamel; but it is
-not our business here to inquire how far correct.</p>
-
-<p>One of the most important of M. Duhamel’s papers,
-which will secure his name a proud station in the
-annals of chemistry, is that which was inserted in
-the Memoirs of the Academy for 1737, in which he
-shows that the base of common salt is a true fixed
-alkali, different in some respects from the alkali extracted
-from land plants, and known by the name of
-<i>potash</i>, but similar to that obtained by the incineration
-of marine plants. We are surprised that a fact
-so simple and elementary was disputed by the French
-chemists, and rather indicated than proved by Stahl
-and his followers. The conclusions of Duhamel were
-disputed by Pott; but finally confirmed by Margraaf.
-M. Duhamel carried his researches further, he wished to
-know if the difference between potash and soda depends
-on the plants that produce them, or on the nature of
-the soil in which they grow. He sowed kali at Denainvilliers,
-and continued his experiments during a great
-number of years. M. Cadet, at his request, examined
-the salts contained in the ashes of the kali of Denainvilliers.
-He found that during the first year soda predominated
-in these ashes. During the successive
-years the potash increased rapidly, and at last the
-soda almost entirely disappeared. It was obvious from
-<span class="pagenum" id="Page_293">293</span>
-this, that the alkalies in plants are drawn at least
-chiefly from the soil in which they vegetate.</p>
-
-<p>The memoirs of M. Duhamel on ether, at that time
-almost unknown, on soluble tartars, and on lime, contain
-many facts both curious and accurately stated;
-though our present knowledge of these bodies is so
-much greater than his&mdash;the new facts ascertained respecting
-them are so numerous and important, that the
-contributions of this early experimenter, which probably
-had a considerable share in the success of subsequent
-investigations, are now almost forgotten. Nor
-would many readers bear patiently with an attempt
-to enumerate them.</p>
-
-<p>There is a curious paper of his in the Memoirs of
-the Academy for 1757. In this he gives the details
-of a spontaneous combustion of large pieces of
-cloth soaked in oil and strongly pressed. Cloth thus
-prepared had often produced similar accidents. Those
-who were fortunate enough to prevent them, took care
-to conceal the facts, partly from ignorance of the real
-cause of the combustion, and partly from a fear that if
-they were to state what they saw, their testimony would
-not gain credit. If the combustion had not been prevented,
-then the public voice would have charged those
-who had the care of the cloths with culpable negligence,
-or even with criminal conduct. The observation of
-M. Duhamel, therefore, was useful, in order to prevent
-such unjust suspicions from hindering those concerned
-from taking the requisite precautions. Yet, twenty
-years after the publication of his paper, two accidental
-spontaneous combustions, in Russia, were ascribed to
-treason. The empress Catharine II. alone suspected
-that the combustion was spontaneous, and experiments
-made by her orders fully confirmed the evidence
-previously advanced by the French philosopher.</p>
-
-<p>One man alone would have been insufficient for all
-the labours undertaken by M. Duhamel; but he had
-a brother who lived upon his estate at Denainvilliers
-<span class="pagenum" id="Page_294">294</span>
-(the name of which he bore), and divided his time between
-the performance of benevolent actions and
-studying the operations of nature. M. Denainvilliers
-prosecuted in his retreat the observations and experiments
-intrusted by his brother to his charge. Thus
-in fact the memoirs of Duhamel exhibit the assiduous
-labours of two individuals, one of whom contentedly
-remained unknown to the world, satisfied
-with the good which he did, and the favours which he
-conferred upon his country and the human race.</p>
-
-<p>The works of M. Duhamel are very voluminous,
-and are all written with the utmost plainness. Every
-thing is elementary, no previous knowledge is taken
-for granted. His writings are not addressed to philosophers,
-but to all those who are in quest of practical
-knowledge. He has been accused of diffuseness of
-style, and of want of correctness; but his style is
-simple and clear; and as his object was to inform, not
-philosophers, but the common people, greater conciseness
-would have been highly injudicious.</p>
-
-<p>Neither he nor his brother ever married, but thought
-it better to devote their undivided attention to study.
-Both were assiduous in no ordinary degree, but the
-ardour of Duhamel himself continued nearly undiminished
-till within a year of his death; when, though
-he still attended the meetings of the academy, he no
-longer took the same interest in its proceedings. On
-the 22d of July, 1781, just after leaving the academy,
-he was struck with apoplexy, and died after lingering
-twenty-two days in a state of coma.</p>
-
-<p>He was without doubt one of the most eminent men
-of the age in which he lived; but his merits as a chemist
-will chiefly be remembered in consequence of his
-being the first person who demonstrated by satisfactory
-evidence the peculiar nature of soda, which had
-been previously confounded with potash. His merits
-as a vegetable physiologist and agriculturist were of a
-very high order.
-<span class="pagenum" id="Page_295">295</span></p>
-
-<p>Peter Joseph Macquer was born at Paris, in 1718.
-His father, Joseph Macquer, was descended from a
-noble Scottish family, which had sacrificed its property
-and its country, out of attachment to the family of
-the Stuarts.<a id="FNanchor_183" href="#Footnote_183" class="fnanchor">183</a> Young Macquer made choice of medicine
-as a profession, and devoted himself chiefly to
-chemistry, for which he showed early a decided taste.
-He was admitted a member of the Academy of
-Sciences in the year 1745, when he was twenty-seven
-years of age. Original researches in chemistry, the
-composition of chemical elementary works, and the
-study of the arts connected with chemistry, occupied
-the whole remainder of his life.</p>
-
-<p>His first paper treated of the effect produced by
-heating a mixture of saltpetre and white arsenic. It was
-previously known, that when such a mixture is distilled
-nitric acid comes over tinged with a blue colour; but
-nobody had thought of examining the residue of this
-distillation. Macquer found it soluble in water and
-capable of crystallizing into a neutral salt composed
-of potash (the base of saltpetre), and an acid into
-which the arsenic was changed by the nitric acid communicating
-oxygen to it.</p>
-
-<p>Macquer found that a similar salt might be obtained
-with soda or ammonia for its base. Thus he was the
-first person who pointed out the existence of arsenic
-acid, and ascertained the properties of some of the
-salts which it forms. But he made no attempt to obtain
-arsenic acid in a separate state, or to determine its
-properties. That very important step was reserved
-for Scheele, for Macquer seems to have had no suspicion
-of the true nature of the salt which he had
-formed.
-<span class="pagenum" id="Page_296">296</span></p>
-
-<p>His next set of experiments was on Prussian blue.
-He made the first step towards the discovery of the nature
-of the principle to which that pigment owes its
-colour. Prussian blue had been accidentally discovered
-by Diesbach, an operative chemist of Berlin,
-in 1710, but the mode of producing it was kept secret
-till it was published in 1724, by Dr. Woodward in the
-Philosophical Transactions. It consisted in mixing
-potash and blood together, and heating the mixture in
-a covered crucible, having a small hole in the lid, till
-it ceased to give out smoke. The solution of this mixture
-in water, when mixed with a solution of sulphate
-of iron, threw down a green powder, which became
-blue when treated with muriatic acid: this blue matter
-was <i>Prussian blue</i>. Macquer ascertained that
-when Prussian blue is exposed to a red heat its blue
-colour disappears, and it is converted into common
-peroxide of iron. Hence he concluded that Prussian
-blue is a compound of oxide of iron, and of something
-which is destroyed or driven off by a red heat.
-He showed that this something possessed the characters
-of an acid; for when Prussian blue is boiled with
-caustic potash it loses its blue colour, and if the potash
-be boiled with successive portions of Prussian blue,
-as long as it is capable of discolouring them, it loses
-the characters of an acid and assumes those of a neutral
-salt, and at the same time acquires the property
-of precipitating iron from the solutions of the sulphate
-at once of a blue colour. Macquer ascribed
-the green colour thrown down, by mixing the blood-lie
-and sulphate of iron to the potash in the blood-lie,
-not being saturated with the colouring matter of Prussian
-blue. Hence a portion of the iron is thrown
-down in the state of Prussian blue, and another portion
-in that of yellow oxide of iron: these two being
-mixed form a green. The muriatic acid dissolves the
-yellow oxide and leaves the Prussian blue untouched.
-Macquer, however, did not succeed in determining the
-<span class="pagenum" id="Page_297">297</span>
-nature of the colouring matter; a task reserved for
-Scheele, whose lot it was to take up the half-finished
-investigations of Macquer, and throw upon them a
-new and brilliant light. Macquer thought that this
-colouring matter was <i>phlogiston</i>. On that account the
-potash saturated with it, which was employed by chemists
-to detect the presence of iron by forming with
-it Prussian blue, was called <i>phlogisticated alkali</i>.</p>
-
-<p>Macquer, conjointly with Baum&eacute;, subjected the
-grains of crude platinum, to which the attention of
-chemists had been newly drawn, to experiment. Their
-principle object was to examine its fusibility and ductility.
-They succeeded in fusing it imperfectly, by
-means of a burning mirror, and found that the grains
-thus treated were not destitute of ductility. But upon
-the whole the experiments of these chemists threw
-but little light upon the subject. Many years elapsed
-before chemists were able to work this refractory metal,
-and to make it into vessels fitted for the uses of the
-laboratory. For this important improvement, which
-constitutes an era in chemistry, the chemical world
-was chiefly indebted to Dr. Wollaston.</p>
-
-<p>In the year 1750 M. Macquer was charged with a
-commission by the court. There existed at that time
-in Brittany a man, the Count de la Garaie, who,
-yielding to a passion for benevolence, had for forty
-years devoted himself to the service of suffering humanity.
-He had built an hospital by the side of a
-chemical laboratory: he took care of the patients in
-the hospital himself; and treated them with medicines
-prepared in his laboratory. Some of these were new,
-and, in his opinion, excellent medicines; and he
-offered to sell them to government for the service of
-his hospital. Macquer was charged by government
-with the examination of these medicines. The project
-of the Count de la Garaie was to extract the salutary
-parts of minerals, by a long maceration with neutral
-<span class="pagenum" id="Page_298">298</span>
-salts. Among other things he had prepared a mercurial
-tincture, by a process which lasted several
-months: but this tincture was merely a solution of
-corrosive sublimate in spirit of wine. Such is the
-history of most of those boasted secrets; sometimes
-they are chimerical, and sometimes known to all the
-world, except to those who purchase them.</p>
-
-<p>M. Macquer had the fortune to live at a time when
-chemistry began to be freed from the reveries of alchymists;
-but methodical arrangement was a merit
-still unknown to the elementary chemical books, especially
-in France, where a residue of Cartesianism
-added to the natural obscurity of the science, by surcharging
-it with pretended mechanical explanations.
-Macquer was the first French chemist who gave to an
-elementary treatise the same clearness, simplicity, and
-method, which is to be found in the other branches of
-science. This was no small merit, and undoubtedly
-contributed considerably to the rapid improvement of
-the science which so speedily followed. His elements
-of chemistry were translated into different languages,
-especially into English; and long constituted the textbook
-employed in the different European universities.
-Dr. Black recommended it for many years in the University
-of Edinburgh. Indeed, it was only superseded
-in consequence of the new views introduced into chemistry
-by Lavoisier, which, requiring a new language
-to render them intelligible, naturally superseded all
-the elementary chemical books which had preceded
-the introduction of that language.</p>
-
-<p>Macquer, during a number of years, delivered regular
-courses of chemical lectures, conjointly with
-Baum&eacute;. In these courses he preferred that arrangement
-which appeared to him to require the least preliminary
-knowledge of chemistry. He described the
-experiments, stated the facts with clearness and precision,
-and explained them in the way which appeared
-<span class="pagenum" id="Page_299">299</span>
-to him most plausible, according to the opinions generally
-received; but without placing much confidence
-in the accuracy of these explanations. He thought it
-necessary to theorize a little, to enable his pupils the
-better to connect the facts and to remember them;
-and to put an end to that painful state of uncertainty
-which always results from a collection of facts without
-any theoretical links to bind them together. When
-the discoveries of Lavoisier began to shake the foundation
-of the Stahlian theory, Macquer was old; and
-it appears from a letter of his, published by Delametherie
-in the Journal de Physique, that he was
-alarmed at the prophetic announcements of Lavoisier
-in the academy that the reign of Phlogiston was
-drawing towards an end. M. Condorcet assures us
-that his attachment to theory, by which he means
-phlogiston, was by no means strong;<a id="FNanchor_184" href="#Footnote_184" class="fnanchor">184</a> but his own
-letter to Delametherie rather shows that this statement
-was not quite correct. How, indeed, could he
-fail to experience an attachment to opinions which it
-had been the business of his whole life to inculcate?</p>
-
-<p>Macquer also published a dictionary of chemistry,
-which was very successful, and which was translated
-into most of the European languages. This mode of
-treating chemistry was well suited to a science still in
-its infancy, and which did not yet constitute a complete
-whole. It enabled him to discuss the different
-topics in succession, and independent of each other:
-and thus to introduce much important matter which
-could not easily have been introduced into a systematic
-work on chemistry. The second edition of this dictionary
-was published just at the time when the gases
-began to attract the attention of scientific men; when
-facts began to multiply with prodigious rapidity, and to
-shake the confidence of chemists in all received theories.
-He acquitted himself of the difficult task of
-<span class="pagenum" id="Page_300">300</span>
-collecting and stating these new facts with considerable
-success; and doubtless communicated much new
-information to his countrymen: for the discoveries
-connected with the gases originated, and were chiefly
-made, in England, from which, on account of the revolutionary
-American war, there was some difficulty
-of obtaining early information.</p>
-
-<p>M. Hellot, who was commissioner of the counsel
-for dyeing, and chemist to the porcelain manufacture,
-requested to have M. Macquer for an associate. This
-request did much honour to Hellot, as he was conscious
-that the reputation of Macquer as a chemist was superior
-to his own. Macquer endeavoured, in the first
-place, to lay down the true principles of the art of
-dyeing, as the best method of dissipating the obscurity
-which still hung over it. A great part of his treatise
-on the art of dyeing silk, published in the collection
-of the Academy of Sciences, has these principles for
-its object. He gave processes also for dyeing silk
-with Prussian blue, and for giving to silk, by means
-of cochineal, as brilliant a scarlet colour as can be
-given to woollen cloth by the same dye-stuff. He
-published nothing on the porcelain manufacture,
-though he attended particularly to the processes, and
-introduced several ameliorations. The beautiful porcelain
-earth at present used at Sevre, was discovered in
-consequence of a premium which he offered to any
-person who could point out a clay in every respect
-proper for making porcelain.</p>
-
-<p>Macquer passed a great part of his life with a brother,
-whom he affectionately loved: after his death
-he devoted himself entirely to his wife and two children,
-whose education he superintended. He was
-rather averse to society, but conducted himself while
-in it with much sweetness and affability. He was
-fond of tranquillity and independence. Though his
-health had been injured a good many years before his
-death, the calmness and serenity of his temper prevented
-<span class="pagenum" id="Page_301">301</span>
-strangers from being aware that he was afflicted
-with any malady. He himself was sensible that his
-strength was gradually sinking; he predicted his approaching
-end to his wife, whom he thanked for the
-happiness which she had spread over his life. He left
-orders that his body should be opened after his decease,
-that the cause of his death might be discovered.
-He died on the 15th of February, 1784. An ossification
-of the aorta, and several calculous concretions
-found in the cavities of the heart, had been the cause
-of the disease under which he had suffered for several
-years before his death.</p>
-
-<p>These four chemists, of whose lives a sketch has
-just been given, were the most eminent that France
-ever produced belonging to the Stahlian school of chemistry.
-Baron, Malouin, Rouelle senior, Tillet,
-Cadet, Baum&eacute;, Sage, and several others whose names
-I purposely omit, likewise cultivated chemistry, during
-that period, with assiduity and success; and were each
-of them the authors of papers which deserve attention,
-but which it would be impossible to particularize
-without swelling this work into a size greatly beyond
-its proper limits.</p>
-
-<p>Hilaire-Marin Rouelle, who was born at Caen in
-1718, was, however, too eminent a chemist to be
-passed over in silence. His elder brother, William
-Francis, was a member of the Academy of Sciences,
-and demonstrator to Macquer, who gave lectures in the
-Jardin du Roi. At the death of Macquer, in 1770,
-Hilaire-Marin Rouelle succeeded him. He devoted the
-whole of his time and money to this situation, and quite
-altered the nature of the experimental course of chemistry
-given in the Jardin du Roi. He was in some
-measure the author of the chemistry of animal bodies,
-at least in France. When he published his experiments
-on the salts of urine, and of blood, he had
-scarcely any model; and though he committed some
-considerable mistakes, he ascertained several essential
-<span class="pagenum" id="Page_302">302</span>
-and important facts, which have been since fully confirmed
-by more modern experimenters. He died on the
-7th of April, 1779, aged sixty-one years. His temper
-was peculiar, and he was too honest and too open for
-the situation in which he was placed, and for a state
-of society in which every thing was carried by intrigue
-and finesse. This is the reason why, in France, his
-reputation was lower than it ought to have been. It
-accounts, too, for his never becoming a member of the
-Academy of Sciences, nor of any of the other numerous
-academies which at that time swarmed in France.
-Nothing is more common than to find these unjust
-decisions raise or depress men of science far above
-or far below their true standard. Rom&eacute; de Lisle, the
-first person who commenced the study of crystals, and
-placed that study in a proper point of view, was a man
-of the same stamp with the younger Rouelle, and
-never on that account, became a member of any academy,
-or acquired that reputation during his lifetime,
-to which his laborious career justly entitled him. It
-would be an easy, though an invidious task, to point
-out various individuals, especially in France, whose
-reputation, in consequence of accidental and adventitious
-circumstances, rose just as much above their
-deserts, as those of Rouelle, and Rom&eacute; de Lisle were
-sunk below.
-<span class="pagenum" id="Page_303">303</span></p>
-
-<hr class="chap" />
-<h2 id="CHAPTER_IX">CHAPTER IX.<br />
-
-<span class="large">OF THE FOUNDATION AND PROGRESS OF SCIENTIFIC
-CHEMISTRY IN GREAT BRITAIN.</span></h2>
-
-<p>The spirit which Newton had infused for the mathematical
-science was so great, that during many years
-they drew within their vortex almost all the scientific
-men in Great Britain. Dr. Stephen Hales is almost the
-only remarkable exception, during the early part of the
-eighteenth century. His vegetable statics constituted
-a most ingenious and valuable contribution to vegetable
-physiology. His h&aelig;mastatics was a no less valuable
-contribution to iatro-mathematics, at that time
-the fashionable medical theory in Great Britain. While
-his <i>analysis of air</i>, and experiments on the animal
-calculus constituted, in all probability, the foundation-stone
-of the whole discoveries respecting the gases to
-which the great subsequent progress of chemistry is
-chiefly owing.</p>
-
-<p>Dr. William Cullen, to whom medicine lies under
-deep obligations, and who afterwards raised the
-medical celebrity of the College of Edinburgh to so
-high a pitch, had the merit of first perceiving the
-importance of scientific chemistry, and the reputation
-which that man was likely to earn, who should
-devote himself to the cultivation of it. Hitherto chemistry
-in Great Britain, and on the continent also,
-was considered as a mere appendage to medicine, and
-useful only so far as it contributed to the formation of
-<span class="pagenum" id="Page_304">304</span>
-new and useful remedies. This was the reason why it
-came to constitute an essential part of the education
-of every medical man, and why a physician was considered
-as unfit for practice unless he was also a
-chemist. But Dr. Cullen viewed the science as far
-more important; as capable of throwing light on the
-constitution of bodies, and of improving and amending
-of those arts and manufactures that are most useful
-to man. He resolved to devote himself to its cultivation
-and improvement; and he would undoubtedly
-have derived celebrity from this science, had not his
-fate led rather to the cultivation of medicine. But
-Dr. Cullen, as the true commencer of the study of
-scientific chemistry in Great Britain, claims a conspicuous
-place in this historical sketch.</p>
-
-<p>William Cullen was born in Lanarkshire, in Scotland,
-in the year 1712, on the 11th of December. His
-father, though chief magistrate of Hamilton, was not
-in circumstances to lay out much money on his son.
-William, therefore, after serving an apprenticeship to
-a surgeon in Glasgow, went several voyages to the
-West Indies, as surgeon, in a trading-vessel from
-London; but tiring of this, he settled, when very
-young, in the parish of Shotts; and after residing
-for a short time among the farmers and country people,
-he went to Hamilton, with a view of practising as a
-physician.</p>
-
-<p>While he resided near Shotts, it happened that
-Archibald, Duke of Argyle, who at that time bore the
-chief political sway in Scotland, paid a visit to a
-gentleman of rank in that neighbourhood. The duke
-was fond of science, and was at that time engaged in
-some chemical researches which required to be elucidated
-by experiment. Eager in these pursuits, while
-on his visit he found himself at a loss for some piece
-of chemical apparatus which his landlord could not
-furnish; but he mentioned young Cullen to the duke
-as a person fond of chemistry, and likely therefore to
-<span class="pagenum" id="Page_305">305</span>
-possess the required apparatus. He was accordingly
-invited to dine, and introduced to his Grace. The
-duke was so pleased with his knowledge, politeness,
-and address, that an acquaintance commenced, which
-laid the foundation of all Cullen’s future advancement.</p>
-
-<p>His residence in Hamilton naturally made his name
-known to the Duke of Hamilton, whose palace is
-situated in the immediate vicinity of that town. His
-Grace being taken with a sudden illness, sent for
-Cullen, and was highly delighted with the sprightly
-character, and ingenious conversation of the young
-physician. He found no difficulty, especially as young
-Cullen was already known to the Duke of Argyle, in
-getting him appointed to a place in the University of
-Glasgow, where his singular talents as a teacher soon
-became very conspicuous.</p>
-
-<p>It was while Dr. Cullen was a practitioner in Shotts
-that he formed a connexion with William, afterwards
-Doctor Hunter, the famous lecturer on anatomy in
-London, who was a native of the same part of the
-country as Cullen. These two young men, stimulated
-by genius, though thwarted by the narrowness of their
-circumstances, entered into a copartnery business, as
-surgeons and apothecaries, in the country. The chief
-object of their contract was to furnish the parties with
-the means of carrying on their medical studies, which
-they were not able to do separately. It was stipulated
-that one of them, alternately, should be allowed to study
-in whatever college he preferred, during the winter,
-while the other carried on the common business in his
-absence. In consequence of this agreement, Cullen
-was first allowed to study in the University of Edinburgh,
-for a winter. When it came to Hunter’s turn
-next winter, he rather chose to go to London. There
-his singular neatness in dissecting, and uncommon
-dexterity in making anatomical preparations, his assiduity
-in study, his mild manners, and easy temper,
-drew upon him the attention of Dr. Douglas, who at
-<span class="pagenum" id="Page_306">306</span>
-that time read lectures on anatomy and midwifery in
-the capital. He engaged him as his assistant, and
-he afterwards succeeded him in the same department
-with much honour to himself, and advantage to the
-public. Thus was dissolved a copartnership of perhaps
-as singular a kind as any that occurs in the
-annals of science. Cullen was not disposed to let any
-engagement with him prove a bar to his partner’s
-advancement in the world. The articles were abandoned,
-and Cullen and Hunter kept up ever after a
-friendly correspondence; though there is reason to
-believe that they never afterwards met.</p>
-
-<p>It was while a country practitioner that young Cullen
-married a Miss Johnston, daughter of a neighbouring
-clergyman. The connexion was fortunate and lasting.
-She brought her husband a numerous family, and
-continued his faithful companion through all the alterations
-of his fortune. She died in the summer of 1786.</p>
-
-<p>In the year 1746 Cullen, who had now taken the degree
-of doctor of medicine, was appointed lecturer on
-chemistry in the University of Glasgow; and in the
-month of October began a course on that science.
-His singular talent for arrangement, his distinctness
-of enunciation, his vivacity of manner, and his knowledge
-of the science which he taught, rendered his
-lectures interesting to a degree which had been till
-then unknown in that university: he was adored
-by the students. The former professors were eclipsed
-by the brilliancy of his reputation, and he had to
-encounter all those little rubs and insults that disappointed
-envy naturally threw in his way. But he
-proceeded in his career regardless of these petty mortifications;
-and supported by the public, he was more
-than consoled for the contumely heaped upon him by
-the ill nature and pitiful malignity of his colleagues.
-His practice as a physician increased every day, and a
-vacancy occurring in the chair in 1751, he was appointed
-by the crown professor of medicine, which put
-<span class="pagenum" id="Page_307">307</span>
-him on a footing of equality with his colleagues in the
-university. This new appointment called forth powers
-which he was not before known to possess, and thus
-served still further to increase his reputation.</p>
-
-<p>At that time the patrons of the University of Edinburgh
-were eagerly bent on raising the reputation of
-their medical school, and were in consequence on the
-look out for men of abilities and reputation to fill their
-respective chairs. Their attention was soon drawn
-towards Cullen, and on the death of Dr. Plummer, in
-1756, he was unanimously invited to fill the vacant
-<i>chemical chair</i>. He accepted the invitation, and began
-his academical career in the College of Edinburgh
-in October of that year, and here he continued during
-the remainder of his life.</p>
-
-<p>The appearance of Dr. Cullen in the College of
-Edinburgh constitutes a memorable era in the progress
-of that celebrated school. Hitherto chemistry being
-reckoned of little importance, had been attended by
-very few students; when Cullen began to lecture it
-became a favourite study, almost all the students
-flocking to hear him, and the chemical class becoming
-immediately more numerous than any other in the
-college, anatomy alone excepted. The students in
-general spoke of the new professor with that rapturous
-ardour so natural to young men when highly pleased.
-These eulogiums were doubtless extravagant, and
-proved disgusting to his colleagues. A party was
-formed to oppose this new favourite of the public.
-His opinions were misrepresented, it was affirmed
-that he taught doctrines which excited the alarm
-of some of the most moderate and conscientious
-of his colleagues. Thus a violent ferment was excited,
-and some time elapsed before the malignant
-arts by which this flame had been blown up were discovered.</p>
-
-<p>During this time of public ferment Cullen went
-steadily forward; he never gave an ear to the gossip
-<span class="pagenum" id="Page_308">308</span>
-brought him respecting the conduct of his colleagues,
-nor did he take any notice of the doctrines which they
-taught. Some of their unguarded strictures on himself
-might occasionally have come to his ears; but if
-it was so, he took no notice of them whatever; they
-seemed to have made no impression on him.</p>
-
-<p>This futile attempt to lower his character being thus
-baffled, his fame as a professor, and his reputation as
-a physician, increased daily: nor could it be otherwise;
-his professional knowledge was always great,
-and his manner of lecturing singularly clear and intelligible,
-lively, and entertaining. To his patients his
-conduct was so pleasing, his address so affable and
-engaging, and his manner so open, so kind, and so
-little regulated by pecuniary considerations, that those
-who once applied to him for medical assistance could
-never afterwards dispense with it: he became the friend
-and companion of every family he visited, and his future
-acquaintance could not be dispensed with.</p>
-
-<p>His private conduct to his students was admirable,
-and deservedly endeared him to every one of them.
-He was so uniformly attentive to them, and took so
-much interest in the concerns of those who applied
-to him for advice; was so cordial and so warm,
-that it was impossible for any one, who had a heart
-susceptible of generous emotions, not to be delighted
-with a conduct so uncommon and so kind. It was
-this which served more than any thing else to extend
-his reputation over every civilized quarter of the globe.
-Among ingenuous youth gratitude easily degenerates
-into rapture; hence the popularity which he enjoyed,
-and which to those who do not well weigh the causes
-which operated on the students must appear excessive.</p>
-
-<p>The general conduct of Cullen to his students was
-this: with all such as he observed to be attentive
-and diligent he formed an early acquaintance, by inviting
-them by twos, by threes, and by fours at a time
-to sup with him; conversing with them at such times
-<span class="pagenum" id="Page_309">309</span>
-with the most engaging ease, entering freely with them
-into the subject of their studies, their amusements,
-their difficulties, their hopes and future prospects. In
-this way he usually invited the whole of his numerous
-class till he made himself acquainted with their private
-character, their abilities, and their objects of pursuit.
-Those of whom he formed the highest opinion
-were of course invited most frequently, till an intimacy
-was gradually formed which proved highly beneficial
-to them. To their doubts and difficulties he listened
-with the most obliging condescension, and he solved
-them to the utmost of his power. His library was at
-all times open for their accommodation: in short, he
-treated them as if they had been all his relatives and
-friends. Few men of distinction left the University of
-Edinburgh, in his time, with whom he did not keep up
-a correspondence till they were fairly established in
-business. This enabled him gradually to form an accurate
-knowledge of the state of medicine in every
-country, and the knowledge thus acquired put it in
-his power to direct students in the choice of places
-where they might have an opportunity of engaging in
-business with a reasonable prospect of success.</p>
-
-<p>Nor was it in this way alone that he befriended the
-students in the University of Edinburgh. Remembering
-the difficulties with which he had himself to struggle
-in his younger days, he was at all times singularly
-attentive to the pecuniary wants of the students. From
-the general intimacy which he contracted with them he
-found no difficulty in discovering those whose circumstances
-were contracted, or who laboured under any
-pecuniary embarrassment, without being under the
-necessity of hurting their feelings by a direct inquiry.
-To such persons, when their habits of study admitted
-it, he was peculiarly attentive: they were more frequently
-invited to his house than others, they were
-treated with unusual kindness and familiarity, they
-were conducted to his library and encouraged by the
-<span class="pagenum" id="Page_310">310</span>
-most delicate address to borrow from it freely whatever
-books he thought they had occasion for; and as persons
-under such circumstances are often extremely shy,
-books were sometimes pressed upon them as a sort
-of task, the doctor insisting upon knowing their opinion
-of such and such passages which they had not read,
-and desiring them to carry the book home for that purpose:
-in short, he behaved to them as if he had courted
-their company. He thus raised them in the opinion
-of their acquaintances, which, to persons in their circumstances,
-was of no little consequence. They were
-inspired at the same time with a secret sense of dignity,
-which elevated their minds, and excited an uncommon
-ardour, instead of that desponding inactivity so natural
-to depressed circumstances. Nor was he less delicate
-in the manner of supplying their wants: he often
-found out some polite excuse for refusing to take
-money for a first course, and never was at a loss for
-one to an after course. Sometimes (as his lectures
-were never written) he would request the favour of a
-sight of their notes, if he knew that they were taken
-with care, in order to refresh his memory. Sometimes
-he would express a wish to have their opinion of a particular
-part of his course, and presented them with a ticket
-for the purpose. By such delicate pieces of address,
-in which he greatly excelled, he took care to anticipate
-their wants. Thus he not only gave them the benefit
-of his own lectures, but by refusing to take money
-enabled them to attend such others as were necessary
-for completing their course of medical study.</p>
-
-<p>He introduced another general rule into the university
-dictated by the same spirit of disinterested benevolence.
-Before he came to Edinburgh, it was the
-custom of the medical professors to accept of fees for
-their medical attendance when wanted, even from
-medical students themselves, though they were perhaps
-attending the professor’s lectures at the time.
-But Dr. Cullen never would take a fee from any student
-<span class="pagenum" id="Page_311">311</span>
-of the university, though he attended them, when
-called on as a physician, with the same assiduity and
-care as if they had been persons of the first rank who
-paid him most liberally. This gradually led others to
-follow his example; and it has now become a general
-rule for medical professors to decline taking any fees
-when their assistance is necessary to a student. For
-this useful reform, as well as for many others, the students
-in the University of Edinburgh are entirely indebted
-to Dr. Cullen.</p>
-
-<p>The first lectures which Dr. Cullen delivered in
-Edinburgh were on chemistry; and for many years he
-also gave lectures on the cases that occurred in the
-infirmary. In the month of February, 1763, Dr. Alston
-died, after having begun his usual course of lectures
-on the materia medica. The magistrates of Edinburgh,
-who are the patrons of the university, appointed
-Dr. Cullen to that chair, requesting that he would
-finish the course of lectures that had been begun by
-his predecessor. This he agreed to do, and, though he
-had only a few days to prepare himself, he never once
-thought of reading the lectures of his predecessor, but
-resolved to deliver a new course, which should be entirely
-his own. Some idea may be formed of the popularity
-of Cullen, by the increase of students to a class
-nearly half finished: Dr. Alston had been lecturing
-to ten; as soon as Dr. Cullen began, a hundred new
-students enrolled themselves.</p>
-
-<p>Some years after, on the death of Dr. Whytt, professor
-of the theory of medicine, Dr. Cullen was appointed
-to give lectures in his stead. It was then that
-he thought it requisite to resign the chemical chair in
-favour of Dr. Black, his former pupil, whose talents
-in that department of science were well known. Soon
-after, on the death of Dr. Rutherford, professor of the
-practice of medicine, Dr. John Gregory having become
-a candidate for this place, along with Dr. Cullen,
-a sort of compromise took place between them, by
-<span class="pagenum" id="Page_312">312</span>
-which they agreed to give lectures alternately, on the
-theory and practice of medicine, during their joint
-lives, the longest survivor being allowed to hold either
-of the classes he should incline. Unluckily this arrangement
-was soon destroyed, by the sudden and
-unexpected death of Dr. Gregory, in the flower of his
-age. Dr. Cullen thenceforth continued to give lectures
-on the practice of medicine till within a few
-months of his death, which happened on the 5th of
-February, 1790, when he was in the seventy-seventh
-year of his age.</p>
-
-<p>It is not our business to follow Dr. Cullen’s medical
-career, nor to point out the great benefits which he
-conferred on nosology and the practice of medicine.
-He taught four different classes in the University of
-Edinburgh, which we are not aware to have happened
-to any other individual, except to professor Dugald
-Stewart.</p>
-
-<p>Notwithstanding the important impulse which he
-gave to chemistry, he published nothing upon that
-science, except a short paper on the cold produced by
-the evaporation of ether, which made its appearance
-in one of the volumes of the Edinburgh Physical and
-Literary Essays. Dr. Cullen employed Dr. Dobson
-of Liverpool, at that time his pupil, to make experiments
-on the heat and cold produced by mixing
-liquids and solids with each other. Dr. Dobson, in
-making these experiments, observed that the thermometer,
-when lifted out of many of the liquids, and
-suspended a short time in the air beside them, fell to a
-lower degree than indicated by another thermometer
-which had undergone no such process. After varying
-his observations on this phenomenon, he found
-reason to conclude that it was occasioned by the evaporation
-of the last drop of liquid which adhered to the
-bulb of the thermometer; the sinking of the thermometer
-being always greatest when this instrument was
-taken out of the most volatile liquids. Dr. Cullen had
-<span class="pagenum" id="Page_313">313</span>
-the curiosity to try whether the same phenomenon
-would appear on repeating these experiments under
-the exhausted receiver of an air-pump. To satisfy
-himself, he put on the plate of the air-pump a glass
-goblet containing water; and in the goblet he placed a
-wide-mouthed phial containing sulphuric ether. The
-whole was covered with an air-pump receiver, having
-at the upper end a collar of leathers in a brass socket,
-through which a thick smooth wire could be moved;
-and from the lower end of this wire, projecting into
-the receiver, was suspended a thermometer. By
-pushing down the wire, the thermometer could be dipped
-into the ether; by drawing it up it could be taken
-out, and suspended over the phial.</p>
-
-<p>The apparatus being thus adjusted, the air-pump
-was worked to extract the air. An unexpected phenomenon
-immediately appeared, which prevented the
-experiment from being made in the way intended.
-The ether was thrown into a violent agitation, which
-Dr. Cullen ascribed to the extrication of a great
-quantity of air: in reality, however, it was boiling
-violently. What was still more remarkable, the ether,
-by this boiling or rapid evaporation, became all of a
-sudden so cold, as to freeze the water in the goblet
-around it; though the temperature of the air and of all
-the materials were at the fifty-fourth degree of Fahrenheit
-at the beginning of the experiment.</p>
-
-<p>I have been particular in giving an account of this
-curious phenomenon, as it was the only direct contribution
-to the science of chemistry which Dr. Cullen
-communicated to the public. The nature of the phenomenon
-was afterwards explained by Dr. Black; in
-addition to Dr. Cullen, a philosopher, whom the grand
-stimulus which his lectures gave to the cultivation of
-scientific chemistry in this country, had the important
-merit of bringing forward.</p>
-
-<p>Joseph Black was born in France, on the banks of
-the Garonne, in the year 1728: his father, Mr. John
-<span class="pagenum" id="Page_314">314</span>
-Black, was a native of Belfast, but of a Scottish family
-which had been for some time settled there. Mr. Black
-resided for the most part at Bordeaux, where he was
-engaged in the wine trade. He married a daughter of
-Mr. Robert Gordon, of the family of Hillhead, in Aberdeenshire,
-who was also engaged in the same trade at
-Bordeaux. Mr. Black was a gentleman of most
-amiable manners, candid and liberal in his sentiments,
-and of no common information. These qualities, together
-with the warmth of his heart, appear very conspicuous
-in a series of letters to his son, which that
-son preserved with the nicest care. His good qualities
-did not escape the discerning eye of the great Montesquieu,
-one of the presidents of the court of justice in
-that province. This illustrious and excellent man
-honoured Mr. Black with a friendship and intimacy
-altogether rare; of which his descendants were justly
-proud.</p>
-
-<p>Long before Mr. Black retired from business, his
-son Joseph was sent home to Belfast, that he might
-have the education of a British subject. This was in
-the year 1740, when he was twelve years of age. After
-the ordinary instruction at the grammar-school, he was
-sent, in 1746, to continue his education in the University
-of Glasgow. Here he studied with much assiduity
-and success: physical science, however, chiefly
-engrossed his attention. He was a favourite pupil of
-Dr. Robert Dick, professor of natural philosophy, and
-the intimate companion of his son and successor. This
-young professor was of a character peculiarly suited to
-Dr. Black’s taste, having the clearest conception, and
-soundest judgment, accompanied by a modesty that
-was very uncommon. When he succeeded his father, in
-1751, he became the delight of the students. He was
-carried off by a fever in 1757.</p>
-
-<p>Young Black being required by his father to make
-choice of a profession, he preferred that of medicine
-as the most suitable to the general habits of his studies.
-<span class="pagenum" id="Page_315">315</span>
-Fortunately Dr. Cullen had just begun his great
-career in the College of Glasgow, and having made
-choice of the field of philosophical chemistry which
-lay as yet unoccupied before him. Hitherto chemistry
-had been treated as a curious and useful art; but Cullen
-saw in it a vast department of the science of nature,
-depending on principles as immutable as the laws of
-mechanism, and capable of being formed into a system
-as comprehensive and as complete as astronomy itself.
-He conceived the resolution of attempting himself to
-explore this magnificent field, and expected much reputation
-from accomplishing his object. Nor was he
-altogether disappointed. He quickly took the science
-out of the hands of artists, and exhibited it as a study
-fit for a gentleman. Dr. Black attended his chemical
-lectures, and, from the character which has already
-been given of him, it is needless to say that he soon
-discovered the uncommon value of his pupil, and attached
-him to himself, rather as a co-operator and a
-friend, than a pupil. He was considered as his assistant
-in all his operations, and his experiments were frequently
-adduced in the lecture as good authority.</p>
-
-<p>Young Black laid down a very comprehensive and
-serious plan of study. This appears from a number
-of note-books found among his papers. There are
-some in which he seems to have inserted every thing
-as it took his fancy, in medicine, chemistry, jurisprudence,
-or matters of taste. Into others, the same
-things are transferred, but distributed according to
-their scientific connexions. In short, he kept a
-journal and ledger of his studies, and has posted his
-books like a merchant. What particularly strikes one
-in looking over these books, is the steadiness with
-which he advanced in any path of knowledge. Things
-are inserted for the first time from some present impression
-of their singularity or importance, but without
-any allusion to their connexions. When a thing
-of the same kind is mentioned again, there is generally
-<span class="pagenum" id="Page_316">316</span>
-a reference back to its fellow; and thus the most
-isolated facts often acquired a connexion which gave
-them importance.</p>
-
-<p>He went to Edinburgh to finish his medical studies
-in 1750 or 1751, where he lived with his cousin german,
-Mr. James Russel, professor of natural philosophy in
-that university.</p>
-
-<p>It was the good fortune of chemical science, that
-at this very time the opinions of professors were divided
-concerning the manner in which certain lithontriptic
-medicines, particularly lime-water, acted in
-alleviating the excruciating pains of the stone and
-gravel. The students usually partake of such differences
-of opinion: they are thereby animated to more
-serious study, and science gains by their emulation.
-This was a subject quite to the taste of young Mr.
-Black, one of Dr. Cullen’s most zealous and intelligent
-chemical pupils. It was, indeed, a most interesting
-subject, both to the chemist and the physician.</p>
-
-<p>All the medicines which were then in vogue as solvents
-of urinary calculi had a greater or less resemblance
-to caustic potash or soda; substances so acrid,
-when in a concentrated state, that in a short time they
-reduce the fleshy parts of the animal body to a mere
-pulp. Thus, though they might possess lithontriptic
-properties, their exhibition was dangerous, if in unskilful
-hands. They all seemed to derive their efficacy
-from quicklime, which again derives its power
-from the fire. It was therefore very natural for them
-to ascribe its power to igneous matter imbibed from
-the fire, retained by the lime, and communicated by
-it to alkalies, which it renders powerfully acrid. Hence,
-undoubtedly, the term <i>caustic</i> applied to the alkalies
-in that state, and hence also the <i>acidum pingue</i> of
-Mayer, which was a peculiar state of fire. It appears
-from Dr. Black’s note-books, that he originally entertained
-the opinion, that caustic alkalies acquired
-igneous matter from quicklime. In one of them he
-<span class="pagenum" id="Page_317">317</span>
-hints at some way of catching this matter as it escapes
-from lime, while it becomes mild by exposure to the
-air; but on the opposite blank page is written, “Nothing
-escapes&mdash;the cup rises considerably by absorbing
-air.” A few pages further on, he compares the
-loss of weight sustained by an ounce of chalk when
-calcined, with its loss while dissolved in muriatic acid.
-Immediately after this, a medical case is mentioned,
-which occurred in November, 1752. Hence it would
-appear, that he had before that time suspected the real
-cause of the difference between limestone and burnt
-lime. He had prosecuted his inquiry with vigour; for the
-experiments with magnesia are soon after mentioned.</p>
-
-<p>These experiments laid open the whole mystery, as
-appears by another memorandum. “When I precipitate
-lime by a common alkali there is no effervescence:
-the air quits the alkali for the lime; but it is
-lime no longer, but C. C. C.: it now effervesces, which
-good lime will not.” What a multitude of important
-consequences naturally flowed from this discovery! He
-now knew to what the causticity of alkalies is owing,
-and how to induce it or remove it at pleasure. The
-common notion was entirely reversed. Lime imparts
-nothing to the alkalies; it only removes from them
-a peculiar kind of air (<i>carbonic acid gas</i>) with which
-they were combined, and which prevented their natural
-caustic properties from being developed. All the
-former mysteries disappear, and the greatest simplicity
-appears in those operations of nature which before
-appeared so intricate and obscure.</p>
-
-<p>Dr. Black had fixed upon this subject for his inaugural
-dissertation, and was induced, in consequence,
-to defer applying for his degree till he had succeeded
-in establishing his doctrine beyond the possibility of
-contradiction. The inaugural essay was delivered at
-a moment peculiarly favourable to the advancement
-of science. Dr. Cullen had been just removed to
-Edinburgh, and there was a vacancy in the chemical
-<span class="pagenum" id="Page_318">318</span>
-chair in Glasgow: it could not be bestowed better
-than on such an <i>alumnus</i> of the university&mdash;on one
-who had distinguished himself both as a chemist and
-an excellent reasoner; for few finer models of inductive
-investigation exist than are displayed in Black’s
-essay on quicklime and magnesia. He was appointed
-professor of anatomy and lecturer on chemistry in the
-University of Glasgow in 1756. It was a fortunate
-circumstance both for himself and for the public, that
-a situation thus presented itself, just at the time when
-he was under the necessity of settling in the world&mdash;a
-situation which allowed him to dedicate his talents
-chiefly to the cultivation of chemistry, his favourite
-science.</p>
-
-<p>When Dr. Black took his degree in medicine, he
-sent some copies of his essay to his father at Bordeaux.
-A copy was given by the old gentleman to
-his friend, the President Montesquieu, who, after a
-few days called on Mr. Black, and said to him,
-“Mr. Black, my very good friend, I rejoice with
-you; your son will be the honour of your name and
-family.” This anecdote was told Professor John Robison
-by the brother of Dr. Black.</p>
-
-<p>Thus Dr. Black, while in Glasgow, taught at one
-and the same time two different classes. He did not
-consider himself very well qualified to teach anatomy,
-but determined to do his utmost; but he soon afterwards
-made arrangements with the professor of medicine,
-who, with the concurrence of the university,
-exchanged his own chair for that of Dr. Black.</p>
-
-<p>Black’s medical lectures constituted his chief task
-while in Glasgow. They gave the greatest satisfaction
-by their perspicuity and simplicity, and by
-the cautious moderation of all his general doctrines:
-and, indeed, all his perspicuity, and all his neatness
-of manner in exhibiting simple truths, were necessary
-to create a relish for moderation and caution, after the
-brilliant prospects of systematic knowledge to which
-<span class="pagenum" id="Page_319">319</span>
-the students had been accustomed by Dr. Cullen, his
-celebrated predecessor. But Dr. Black had no wish
-to form a medical school, distinguished by some all-comprehending
-doctrine: he satisfied himself with a
-clear account of as much of physiology as he thought
-founded on good principles, and a short sketch of such
-general doctrines as were maintained by the most eminent
-authors, though perhaps on a less firm foundation.
-He then endeavoured to deduce a few canons
-of medical practice, and concluded with certain rules
-founded on successful practice only, but not deducible
-from the principles of physiology previously laid
-down. With his medical lectures he does not appear
-to have been himself entirely satisfied: he did not
-encourage conversation on the different topics, and
-no remains of these lectures were to be found among
-his papers. The preceding account of them was given
-to Professor Robison by a surgeon in Glasgow, who
-attended the two last medical courses which Dr. Black
-ever delivered.</p>
-
-<p>Dr. Black’s reception at Glasgow by the university
-was in the highest degree encouraging. His former
-conduct as a student had not only done him credit in
-his classes, but had conciliated the affection of the
-professors to a very high degree. He became immediately
-connected in the strictest friendship with the
-celebrated Dr. Adam Smith&mdash;a friendship which continued
-intimate and confidential through the whole of
-their lives. Both were remarkable for a certain simplicity
-of character and the most incorruptible integrity.
-Dr. Smith used to say, that no one had less
-nonsense in his head than Dr. Black; and he often
-acknowledged himself obliged to him for setting him
-right in his judgment of character, confessing that he
-himself was too apt to form his opinion from a single
-feature.</p>
-
-<p>It was during his residence in Glasgow, between
-the years 1759 and 1763, that he brought to maturity
-<span class="pagenum" id="Page_320">320</span>
-those speculations concerning the combination of <i>heat</i>
-with <i>matter</i>, which had frequently occupied a portion
-of his thoughts. It had long been known that ice
-has the property of continuing always at the temperature
-of 32&deg; till it be melted. This happens equally though
-it be placed in contact with the warm hand or surrounded
-with bodies many degrees hotter than itself.
-The hotter the bodies are that surround it, the sooner
-is it melted; but its temperature during the whole
-process of melting, continues uniformly the same. Yet,
-during the whole process of melting, it is constantly
-robbing the surrounding bodies of heat; for it makes
-them colder, without acquiring itself any sensible heat.</p>
-
-<p>Dr. Black had some vague notion that the heat so
-received by the ice, during its conversion into water,
-was not lost, but was contained in the water. This
-opinion was founded chiefly on a curious observation
-of Fahrenheit, recorded by Boerhaave; namely, that
-water might in some cases be made considerably colder
-than melting snow, without freezing. In such cases,
-when disturbed it would freeze in a moment, and in
-the act of freezing always gave out a quantity of heat.
-This opinion was confirmed by observing the slowness
-with which water is converted into ice, and ice into
-water. A fine winter-day of sunshine is never sufficient
-to clear the hills of snow; nor is one frosty
-night capable of covering the ponds with a thick coating
-of ice. The phenomena satisfied him that much
-heat was absorbed and fixed in the water which trickles
-from wreaths of snow, and that much heat emerged
-from it while water was slowly converted into ice;
-for during a thaw the melting snow is always colder
-than the air, and must, therefore, be always receiving
-heat from it; while, during a frost, the air is always
-colder than the freezing water, and must therefore be
-always receiving heat from it. These observations,
-and many others which it is needless to state, satisfied
-Dr. Black that when ice is converted into water it
-<span class="pagenum" id="Page_321">321</span>
-unites with a quantity of heat, without increasing in
-temperature; and that when water is frozen into ice
-it gives out a quantity of heat without diminishing in
-temperature. The heat thus combined is the cause
-of the fluidity of the water. As it is not sensible to
-the thermometer, Dr. Black called it <i>latent heat</i>. He
-made an experiment to determine the quantity of heat
-necessary to convert ice into water. This he estimated
-by the length of time necessary to melt a given weight
-of ice, measuring how much heat entered into the
-same weight of water, reduced as nearly to the temperature
-of ice as possible during the first half-hour
-that the experiment lasted. As the ice continued
-during the whole of its melting at the same temperature
-as at first, he concluded that it would absorb,
-every half-hour that the process lasted, as much heat
-as the water did during the first half hour. The result
-of this experiment was, that the latent heat of
-water amounts to 140&deg;; or, in other words, that this
-heat, if thrown into a quantity of water, equal in
-weight to that of the ice melted, would raise its temperature
-140&deg;.</p>
-
-<p>Dr. Black, having established this discovery in
-the most incontrovertible manner by simple and
-decisive experiments, drew up an account of the
-whole investigation, and the doctrine which he founded
-upon it, and read it to a literary society which met
-every Friday in the faculty-room of the college, consisting
-of the members of the university and several
-gentlemen of the city, who had a relish for science
-and literature. This paper was read on the 23d of
-April, as appears by the registers of the society.</p>
-
-<p>Dr. Black quickly perceived the vast importance of
-this discovery, and took a pleasure in laying before
-his students a view of the beneficial effects of this habitude
-of heat in the economy of nature. During the
-summer season a vast magazine of heat was accumulated
-in the water, which, by gradually emerging
-<span class="pagenum" id="Page_322">322</span>
-during congelation, serves to temper the cold of winter.
-Were it not for this accumulation of heat in water and
-other bodies, the sun would no sooner go a few degrees
-to the south of the equator, than we should feel all
-the horrors of winter. He did not confine his views
-to the congelation of water alone, but extended them
-to every case of congelation and liquefaction which
-he has ascribed equally to the evolution or fixation
-of latent heat. Even those bodies which change from
-solid to fluid, not all at once, but by slow degrees, as
-butter, tallow, resins, owe, he found, their gradual
-softening to the same absorption of heat, and the same
-combination of it with the substance undergoing liquefaction.</p>
-
-<p>Another subject that engaged his attention at this
-time, was an examination of the scale of the thermometer,
-to learn whether equal differences of expansion
-corresponded to equal additions or abstractions of
-heat. His mode was to mix together equal weights of
-water of different temperatures, and to measure the
-temperature of the mixture by a thermometer. It is
-obvious that the temperature must be the exact mean
-of that of the two portions of water; and that if the
-expansion or contraction of the mercury in the thermometer
-be an exact measure of the difference of
-temperature, a thermometer, so placed, will indicate
-the exact mean. Suppose one pound of water at 100&deg;
-to be mixed with one pound of water at 200&deg;, and the
-whole heat still to remain in the mixture, it is obvious
-that it would divide itself equally between the two
-portions of water. The water of 100&deg; would become
-hotter, and the water of 200&deg; would become colder:
-and the increase of temperature in the colder portion
-would be just as much as the diminution of temperature
-in the hotter portion. The colder portion would become
-hotter by 50&deg;, while the hotter portion would
-become colder by 50&deg;. Hence the real temperature,
-after mixture, would be 150&deg;; and a thermometer
-<span class="pagenum" id="Page_323">323</span>
-plunged into such a mixture, if a true measurer of
-heat, would indicate 150&deg;. The result of his experiments
-was, that as high up as he could try by mixing
-water of different temperatures, the mercurial thermometer
-is an accurate measurer of the alterations of
-temperature.</p>
-
-<p>An account of his experiments on this subject was
-drawn up by him, and read to the literary society of
-the College of Glasgow, on the 28th of March, 1760.
-Dr. Black, at the time he made these experiments, did
-not know that he had been already anticipated in
-them by Dr. Brooke Taylor, the celebrated mathematician,
-who had obtained similar results, and had consigned
-his experiments to the Royal Society, in whose
-Transactions for 1723 they were published. It has
-been since found by Coulomb and Petit, that at higher
-temperatures than 212&deg; the rate of the expansion of
-mercury begins to increase. Hence it happens that
-at high temperatures the expansion of mercury is no
-longer an accurate measurer of temperature. Fortunately,
-the expansion of glass very nearly equals the
-increment of that of mercury. The consequence is,
-that in a common glass-thermometer mercury measures
-the true increments of temperature very nearly
-up to its boiling point; for the boiling point of mercury
-measured by an air-thermometer is 662&deg;: and if
-a glass mercurial thermometer be plunged into boiling
-mercury, it will indicate 660&deg;, a difference of only 2&deg;
-from the true point.</p>
-
-<p>There is such an analogy between the cessation of
-thermometric expansion during the liquefaction of ice,
-and during the conversion of water into steam, that
-there could be no hesitation about explaining both in
-the same way. Dr. Black immediately concluded
-that as water is ice united to a certain quantity of <i>latent
-heat</i>, so steam is water united to a still greater quantity.
-The slow conversion of water into steam, notwithstanding
-the great quantity of heat constantly
-<span class="pagenum" id="Page_324">324</span>
-flowing into it from the fire, left no reasonable doubt
-about the accuracy of this conclusion. In short, all
-the phenomena are precisely similar to those of the
-conversion of ice into water; and so, of course, must
-the explanation be. So much was he convinced of
-this, that he taught the doctrine in his lectures in
-1761, before he had made a single experiment on the
-subject; and he explained, with great felicity of argument,
-many phenomena of nature, which result
-from this vaporific combination of heat. From notes
-taken in his class during this session, it appears that
-nothing more was wanting to complete his views on
-this subject, than a set of experiments to determine the
-exact quantity of heat which was combined in steam
-in a state not indicated by the thermometer, and therefore
-<i>latent</i>, in the same sense that the heat of liquefaction
-in water is <i>latent</i>.</p>
-
-<p>The requisite experiments were first attempted by
-Dr. Black, in 1764. They consisted merely in measuring
-the time requisite to convert a certain weight
-of water of a given temperature into steam. The
-water was put into a tin-plate wide-mouthed vessel,
-and laid upon a red-hot plate of iron, the initial temperature
-of the water was marked, and the time necessary
-to heat it from that point to the boiling point
-noted, and then the time requisite to boil the whole to
-dryness. It was taken for granted that as much heat
-would enter into the water during every minute that
-the experiment lasted, as did during the first minute.
-From this it was concluded that the latent heat of
-steam is not less than 810 degrees.</p>
-
-<p>Mr. James Watt afterwards repeated these experiments
-with a better apparatus and very great care,
-and calculated from his results that the latent heat of
-steam is not under 950 degrees. Lavoisier and Laplace
-afterwards made experiments in a different way, and
-deduced 1000&deg; as the result of their experiments.
-The subsequent experiments of Count Rumford, made
-<span class="pagenum" id="Page_325">325</span>
-in a very ingenious manner, so as to obviate most of
-the sources of error, to which such researches are
-liable, come very nearly to those of Lavoisier. 1000&deg;
-therefore, is usually now-a-days adopted as the number
-which denotes the true latent heat of steam.</p>
-
-<p>Dr. Black continued in the University of Glasgow
-from 1756 to 1766, much esteemed as an eminent
-professor, much employed as an able and attentive
-physician, and much beloved as an amiable and accomplished
-man, happy in the enjoyment of a small
-but select society of friends. Meanwhile his reputation
-as a chemical philosopher was every day increasing,
-and pupils from foreign countries carried home with
-them the peculiar doctrines of his courses&mdash;so that
-<i>fixed air</i> and <i>latent heat</i> began to be spoken of
-among the naturalists of the continent. In 1766 Dr.
-Cullen, at that time professor of chemistry in Edinburgh,
-was appointed professor of medicine, and thus
-a vacancy was made in the chemical chair of that
-university. There was but one wish with regard to a
-successor. Indeed, when the vacancy happened in
-1756, on the death of Dr. Plummer, the reputation of
-Dr. Black, who had just taken his degree, was so high,
-both as a chemist and an accurate thinker and reasoner,
-that, had the choice depended on the university,
-he would have been the new professor of chemistry.
-He had now, in 1766, greatly added to his claim of
-merit by his important discovery of latent heat; and
-he had acquired the esteem of all by the singular moderation
-and scrupulous caution which marked all his
-researches.</p>
-
-<p>Dr. Black was appointed to the chemical chair in
-Edinburgh in 1766, to the general satisfaction of
-the public, but the University of Glasgow suffered an
-irreparable loss. In this new situation his talents were
-more conspicuous and more extensively useful. He
-saw that the case was so, and while he could not but
-be gratified by the number of students whom the high
-<span class="pagenum" id="Page_326">326</span>
-reputation of Edinburgh, as a medical school, brought
-together, his mind was forcibly struck by the importance
-of his duties as a teacher. This led him to form
-the resolution of devoting the whole of his study to the
-improvement of his pupils in the elementary knowledge
-of chemistry. Many of them came to his class with
-a very scanty stock of previous knowledge. Many
-from the workshop of the manufacturer had little or none.
-He was conscious that the number of this kind of pupils
-must increase with the increasing activity and prosperity
-of the country; and they appeared to him by no
-means the least important part of his auditory. To engage
-the attention of such pupils, and to be perfectly
-understood by the most illiterate of his audience, Dr.
-Black considered as a sacred duty: he resolved,
-therefore, that plain doctrines taught in the plainest
-manner, should henceforth employ his chief study. To
-render his lectures perfectly intelligible they were illustrated
-by suitable experiments, by the exhibition of
-specimens, and by the repetition of chemical processes.</p>
-
-<p>To this method of lecturing Dr. Black rigidly adhered,
-endeavouring every year to make his courses more plain
-and familiar, and illustrating them by a greater variety
-of examples in the way of experiment. No man could
-perform these more neatly or successfully; they were
-always ingeniously and judiciously contrived, clearly
-establishing the point in view, and were never more
-complicated than was sufficient for the purpose. Nothing
-that had the least appearance of quackery; nothing
-calculated to surprise and astonish his audience;
-nothing savouring of a showman or sleight-of-hand
-man was ever permitted in his lecture-room. Every
-thing was simple, neat, and elegant, calculated equally
-to please and to inform: indeed simplicity and neatness
-stamped his character. It was this that constituted
-the charm of his lectures, and rendered them so delightful
-to his pupils. I can speak of them from experience,
-for I was fortunate enough to hear the last
-<span class="pagenum" id="Page_327">327</span>
-course of lectures which he ever delivered. I can
-say with perfect truth that I never listened to any
-lectures with so much pleasure as to his: and it was
-the elegant simplicity of his manner, the perfect clearness
-of his statements, and the vast quantity of information
-which he contrived in this way to communicate,
-that delighted me. I was all at once transported into
-a new world&mdash;my views were suddenly enlarged, and
-I looked down from a height which I had never before
-reached; and all this knowledge was communicated
-without any apparent effort either on the part of the
-professor or his pupils. His illustrations were just sufficient
-to answer completely the object in view, and
-nothing more. No quackery, no trickery, no love of
-mere dazzle and glitter, ever had the least influence
-upon his conduct. He constituted the most complete
-model of a perfect chemical lecturer that I have ever
-had an opportunity of witnessing.</p>
-
-<p>The discovery which Dr. Black had made that
-marble is a combination of lime and a peculiar substance,
-to which he gave the name of <i>fixed air</i>, began
-gradually to attract the attention of chemists in
-other parts of the world. It was natural in the first
-place to examine the nature and properties of this
-fixed air, and the circumstances under which it is generated.
-It may seem strange and unaccountable that
-Dr. Black did not enter with ardour into this new
-career which he had himself opened, and that he
-allowed others to reap the corn after having himself
-sown the grain. Yet he did take some steps towards
-ascertaining the properties of <i>fixed air</i>; though I
-am not certain what progress he made. He knew that
-a candle would not burn in it, and that it is destructive
-to life, when any living animal attempts to breathe
-it. He knew that it was formed in the lungs during
-the breathing of animals, and that it is generated
-during the fermentation of wine and beer. Whether
-he was aware that it possesses the properties of an
-<span class="pagenum" id="Page_328">328</span>
-acid I do not know; though with the knowledge which
-he possessed that it combines with alkalies and alkaline
-earths, and neutralizes them, or at least blunts and diminishes
-their alkaline properties, the conclusion that
-it partook of alkaline properties was scarcely avoidable.
-All these, and probably some other properties of <i>fixed
-air</i> he was in the constant habit of stating in his lectures
-from the very commencement of his academical career;
-though, as he never published anything on the subject
-himself, it is not possible to know exactly how far his
-knowledge of the properties of <i>fixed air</i> extended. The
-oldest manuscript copy of his lectures that I have seen
-was taken down in writing in the year 1773; and
-before that time Mr. Cavendish had published his
-paper on <i>fixed air</i> and <i>hydrogen gas</i>, and had detailed
-the properties of each. It was impossible from the
-manuscript of Dr. Black’s lectures to know which of the
-properties of <i>fixed air</i> stated by him were discovered
-by himself, and which were taken from Mr. Cavendish.</p>
-
-<p>This languor and listlessness, on the part of Dr.
-Black, is chiefly to be ascribed to the delicate state of
-his health, which precluded much exertion, and was
-particularly inconsistent with any attempt at putting
-his thoughts down upon paper. Hence, probably, that
-carelessness about posthumous fame, and that regardlessness
-of reputation, which, however it may be accounted
-for from bodily ailment, must still be considered
-as a blemish. How differently did Paschal act in
-a similar state of health! With what energy did he
-exert himself in spite of bodily ailment! But the tone
-of his mind was quite different from that of Dr. Black.
-Gentleness, diffidence, and perhaps even slowness
-of apprehension, were the characteristic features by
-which the latter was distinguished.</p>
-
-<p>There is an anecdote of Black which I was told by
-the late Mr. Benjamin Bell, of Edinburgh, author of
-a well-known system of surgery, and he assured me
-that he had it from the late Sir George Clarke, of
-<span class="pagenum" id="Page_329">329</span>
-Pennicuik, who was a witness of the circumstance
-related. Soon after the appearance of Mr. Cavendish’s
-paper on hydrogen gas, in which he made an
-approximation to the specific gravity of that body,
-showing that it was at least ten times lighter than
-common air, Dr. Black invited a party of his friends
-to supper, informing them that he had a curiosity to
-show them. Dr. Hutton, Mr. Clarke of Elden, and Sir
-George Clarke of Pennicuik, were of the number.
-When the company invited had assembled, he took
-them into a room. He had the allentois of a calf
-filled with hydrogen gas, and upon setting it at liberty,
-it immediately ascended, and adhered to the ceiling.
-The phenomenon was easily accounted for: it was
-taken for granted that a small black thread had been
-attached to the allentois, that this thread passed through
-the ceiling, and that some one in the apartment above,
-by pulling the thread, elevated it to the ceiling, and
-kept it in this position. This explanation was so probable,
-that it was acceded to by the whole company;
-though, like many other plausible theories, it turned
-out wholly unfounded; for when the allentois was
-brought down no thread whatever was found attached
-to it. Dr. Black explained the cause of the ascent to
-his admiring friends; but such was his carelessness of
-his own reputation, and of the information of the public,
-that he never gave the least account of this curious
-experiment even to his class; and more than twelve
-years elapsed before this obvious property of hydrogen
-gas was applied to the elevation of air-balloons, by
-M. Charles, in Paris.</p>
-
-<p>The constitution of Dr. Black had always been exceedingly
-delicate. The slightest cold, the most
-trifling approach to repletion, immediately affected
-his chest, occasioned feverishness, and if the disorder
-continued for two or three days, brought on a spitting
-of blood. In this situation, nothing restored him
-to ease, but relaxation of thought, and gentle exercise.
-<span class="pagenum" id="Page_330">330</span>
-The sedentary life to which study confined him, was
-manifestly hurtful; and he never allowed himself to
-indulge in any investigation that required intense
-thought, without finding these complaints increased.</p>
-
-<p>Thus situated, Dr. Black was obliged to be a contented
-spectator of the rapid progress which chemistry
-was making, without venturing himself to engage in
-any of the numerous investigations which presented
-themselves on every side. Such indeed was the eagerness
-with which chemistry was at that time prosecuted,
-and such the passion for discovery, that there was
-some risk that his undoubted claim to originality
-and priority in his own great discoveries, might be
-called in question, and even rendered doubtful. His
-friends at least were afraid of this, and often urged
-him to do justice to himself, by publishing an account
-of his own discoveries. He more than once began
-the task; but was so nice in his notions of the manner
-in which it should be executed, that the pains he took
-in forming a plan of the work never failed to affect
-his health, and oblige him to desist. It is known that
-he felt hurt at the publication of several of Lavoisier’s
-papers, in the M&eacute;moires de l’Acad&eacute;mie, without any
-allusion whatever to what he himself had previously
-done on the same subject. How far Lavoisier was
-really culpable, and whether he did not intend to do
-full justice to all the claims of his predecessors, cannot
-now be known; as he was cut off in the midst of his
-career, while so many of his scientific projects remained
-unexecuted. From the posthumous works of
-Lavoisier, there is some reason for believing that if
-he had lived, he would have done justice to all parties;
-but there is no doubt that Dr. Black, in the mean
-time, thought himself aggrieved, and that he formed
-the intention of doing himself justice, by publishing
-an account of his own discoveries; however this intention
-was thwarted and prevented by bad health.</p>
-
-<p>No one contributed more largely to establish, to support,
-<span class="pagenum" id="Page_331">331</span>
-and to increase, the high character of the medical
-school in the University of Edinburgh than Dr. Black.
-His talent for communicating knowledge was not less
-eminent than his faculty of observation. He soon became
-one of the principal ornaments of the university;
-and his lectures were attended by an audience which
-continued increasing from year to year for more than
-thirty years. His personal appearance and manners
-were those of a gentleman, and peculiarly pleasing:
-his voice, in lecturing, was low, but fine; and his articulation
-so distinct, that he was perfectly well heard
-by an audience consisting of several hundreds. While
-in Glasgow, he had practised extensively as a physician;
-but in Edinburgh he declined general practice,
-and confined his attendance to a few families of intimate
-and respected friends. He was, however, a physician
-of good repute in a place where the character of
-a physician implied no common degree of liberality,
-propriety, and dignity of manners, as well as of learning
-and skill.</p>
-
-<p>Such was Dr. Black as a public man. While young,
-his countenance was comely and interesting; and as he
-advanced in years, it continued to preserve that pleasing
-expression of inward satisfaction which, by giving
-ease to the beholder, never fails to please. His manners
-were simple, unaffected, and graceful; he was of
-the most easy approach, affable, and readily entered
-into conversation, whether serious or trivial: for he
-was not merely a man of science, but was well acquainted
-with the elegant accomplishments. He had
-an accurate musical ear, and a voice which would obey
-it in the most perfect manner; he sang and performed
-on the flute with great taste and feeling; and
-could sing a plain air at sight, which many instrumental
-performers cannot do. Music was his amusement
-in Glasgow; after his removal to Edinburgh he
-gave it up entirely. Without having studied drawing
-he had acquired a considerable power of expression
-<span class="pagenum" id="Page_332">332</span>
-with his pencil, both in figures and in landscape. He
-was peculiarly happy in expressing the passions, and
-seemed in this respect to have the talents of a historical
-painter. Figure indeed, of every kind, attracted his
-attention; in architecture, furniture, ornament of every
-sort, it was never a matter of indifference to him. Even
-a retort, or a crucible, was to his eye an example of
-beauty, or deformity. These are not indifferent things;
-they are features of an elegant mind, and they account
-for some part of that satisfaction and pleasure which
-persons of different habits and pursuits felt in Dr.
-Black’s company and conversation.</p>
-
-<p>Those circumstances of form, and in which Dr.
-Black perceived or sought for beauty, were suitableness
-or propriety: something that rendered them well
-adapted for the purposes for which they were intended.
-This love of propriety constituted the leading feature
-in Dr. Black’s mind; it was the standard to which he
-constantly appealed, and which he endeavoured to
-make the directing principle of his conduct.</p>
-
-<p>Dr. Black was fond of society, and felt himself
-beloved in it. His chief companions, in the earlier
-part of his residence in Edinburgh, were Dr. Adam
-Smith, Mr. David Hume, Dr. Adam Ferguson, Mr.
-John Home, Dr. Alexander Carlisle, and a few others.
-Mr. Clarke of Elden, and his brother Sir George, Dr.
-Roebuck, and Dr. James Hutton, particularly the latter,
-were affectionately attached to him, and in their
-society he could indulge in his professional studies.
-Dr. Hutton was the only person near him to whom
-Dr. Black imparted every speculation in chemical
-science, and who knew all his literary labours: seldom
-were the two friends asunder for two days together.</p>
-
-<p>Towards the close of the eighteenth century, the infirmities
-of advanced life began to bear more heavily on his
-feeble constitution. Those hours of walking and gentle
-exercise, which had hitherto been necessary for his
-ease, were gradually curtailed. Company and conversation
-<span class="pagenum" id="Page_333">333</span>
-began to fatigue: he went less abroad, and
-was visited only by his intimate friends. His duty at
-college became too heavy for him, and he got an
-assistant, who took a share of the lectures, and relieved
-him from the fatigue of the experiments. The
-last course of lectures which he delivered was in the
-winter of 1796-7. After this, even lecturing was too
-much for his diminished strength, and he was obliged
-to absent himself from the class altogether; but he
-still retained his usual affability of temper, and his
-habitual cheerfulness, and even to the very last was
-accustomed to walk out and take occasional exercise.
-As his strength declined, his constitution became more
-and more delicate. Every cold he caught occasioned
-some degree of spitting of blood; yet he seemed to
-have this unfortunate disposition of body almost under
-command, so that he never allowed it to proceed far,
-or to occasion any distressing illness. He spun his
-thread of life to the very last fibre. He guarded
-against illness by restricting himself to an abstemious
-diet; and he met his increasing infirmities with a
-proportional increase of attention and care, regulating
-his food and exercise by the measure of his strength.
-Thus he made the most of a feeble constitution, by
-preventing the access of disease from abroad. And
-enjoyed a state of health which was feeble, indeed, but
-scarcely interrupted; as well as a mind undisturbed in
-the calm and cheerful use of its faculties. His only
-apprehension was that of a long-continued sick-bed&mdash;from
-the humane consideration of the trouble and
-distress that he might thus occasion to attending
-friends; and never was such generous wish more completely
-gratified than in his case.</p>
-
-<p>On the 10th of November, 1799, in the seventy-first
-year of his age, he expired without any convulsion,
-shock, or stupor, to announce or retard the approach
-of death. Being at table with his usual fare, some
-bread, a few prunes, and a measured quantity of milk,
-<span class="pagenum" id="Page_334">334</span>
-diluted with water, and having the cup in his hand
-when the last stroke of his pulse was to be given, he
-set it down on his knees, which were joined together,
-and kept it steady with his hand in the manner of a
-person perfectly at ease; and in this attitude expired
-without spilling a drop, and without a writhe in his
-countenance; as if an experiment had been required
-to show to his friends the facility with which
-he departed. His servant opened the door to tell him
-that some one had left his name; but getting no answer,
-stepped about halfway to him; and seeing him
-sitting in that easy posture, supporting his basin of
-milk with one hand, he thought that he had dropped
-asleep, which was sometimes wont to happen after
-meals. He went back and shut the door; but before
-he got down stairs some anxiety, which he could not
-account for, made him return and look again at his
-master. Even then he was satisfied, after coming
-pretty near him, and turned to go away; but he again
-returned, and coming close up to him, he found him
-without life. His very near neighbour, Mr. Benjamin
-Bell, the surgeon, was immediately sent for; but nothing
-whatever could be done.<a id="FNanchor_185" href="#Footnote_185" class="fnanchor">185</a></p>
-
-<p>Dr. Black’s writings are exceedingly few, consisting
-altogether of no more than three papers. The first,
-entitled “Experiments upon Magnesia alba, Quicklime,
-and other Alkaline Substances,” constituted the
-subject of his inaugural dissertation. It afterwards
-appeared in an English dress in one of the volumes of
-The Edinburgh Physical and Literary Essays, in the
-year 1755. Mr. Creech, the bookseller, published it
-in a separate pamphlet, together with Dr. Cullen’s
-little essay on the “cold produced by evaporating
-<span class="pagenum" id="Page_335">335</span>
-fluids,” in the year 1796. This essay exhibits one of the
-very finest examples of inductive reasoning to be found
-in the English language. The author shows that magnesia
-is a peculiar earthy body, possessed of properties
-very different from lime. He gives the properties of
-lime in a pure state, and proves that it differs from limestone
-merely by the absence of the carbonic acid, which
-is a constituent of limestone. Limestone is a <i>carbonate
-of lime</i>; quicklime is the pure uncombined earth. He
-shows that magnesia has also the property of combining
-with carbonic acid; that caustic potash, or soda, is
-merely these bodies in a pure or isolated state; while
-the mild alkalies are combinations of these bodies with
-carbonic acid. The reason why quicklime converts
-mild into caustic alkali is, that the lime has a stronger
-affinity for the carbonic acid than the alkali; hence
-the lime is converted into carbonate of lime, and the
-alkali, deprived of its carbonic acid, becomes caustic.
-Mild potash is a carbonate of potash; caustic potash,
-is potash freed from carbonic acid.&mdash;The publication
-of this essay occasioned a controversy in Germany,
-which was finally settled by Jacquin and Lavoisier,
-who repeated Dr. Black’s experiments and showed
-them to be correct.</p>
-
-<p>Dr. Black’s second paper was published in the
-Philosophical Transactions for 1775. It is entitled
-“The supposed Effect of boiling on Water, in disposing
-it to freeze more readily, ascertained by Experiments.”
-He shows, that when water that has been recently boiled
-is exposed to cold air, it begins to freeze as soon as
-it reaches the freezing point; while water that has not
-been boiled may be cooled some degrees below the
-freezing point before it begins to congeal. But if the
-unboiled water be constantly stirred during the whole
-time of its exposure, it begins to freeze when cooled
-down to the freezing point as well as the other. He
-shows that the difference between the two waters consists
-<span class="pagenum" id="Page_336">336</span>
-in this, that the boiled water is constantly absorbing
-air, which disturbs it, whereas the other water remains
-in a state of rest.</p>
-
-<p>His last paper was “An Analysis of the Water of
-some boiling Springs in Iceland,” published in the
-Transactions of the Royal Society of Edinburgh. This
-was the water of the Geyser spring, brought from Iceland
-by Sir J. Stanley. Dr. Black found it to contain
-a great deal of silica, held in solution in the water
-by caustic soda.</p>
-
-<p>The tempting career which Dr. Black opened, and
-which he was unable to prosecute for want of health,
-soon attracted the attention of one of the ablest men
-that Great Britain has produced&mdash;I mean Mr. Cavendish.</p>
-
-<p>The Honourable Henry Cavendish was born in London
-on the 10th of October, 1731: his father was
-Lord Charles Cavendish, a cadet of the house of
-Devonshire, one of the oldest families in England.
-During his father’s lifetime he was kept in rather narrow
-circumstances, being allowed an annuity of &pound;500
-only; while his apartments were a set of stables,
-fitted up for his accommodation. It was during this
-period that he acquired those habits of economy,
-and those singular oddities of character, which he exhibited
-ever after in so striking a manner. At his father’s
-death he was left a very considerable fortune;
-and an aunt who died at a later period bequeathed
-him a very handsome addition to it; but, in consequence
-of the habits of economy which he had acquired, it was
-not in his power to spend the greater part of his annual
-income. This occasioned a yearly increase to his
-capital, till at last it accumulated so much, without any
-care on his part, that at the period of his death he left
-behind him nearly &pound;1,300,000; and he was at that
-time the greatest proprietor of stock in the Bank of
-England.</p>
-
-<p>On one occasion, the money in the hands of his bankers
-<span class="pagenum" id="Page_337">337</span>
-had accumulated to the amount of &pound;70,000. These
-gentlemen thinking it improper to keep so large a sum
-in their hands, sent one of the partners to wait upon
-him, in order to learn how he desired it disposed of.
-This gentleman was admitted; and, after employing
-the necessary precautions to a man of Mr. Cavendish’s
-peculiar disposition, stated the circumstance, and begged
-to know whether it would not be proper to lay out
-the money at interest. Mr. Cavendish dryly answered,
-“You may lay it out if you please,” and left the room.</p>
-
-<p>He hardly ever went into any other society than that
-of his scientific friends: he never was absent from the
-weekly dinner of the Royal Society club at the Crown
-and Anchor Tavern in the Strand. At these dinners,
-when he happened to be seated near those that he
-liked, he often conversed a great deal; though at other
-times he was very silent. He was likewise a constant
-attendant at Sir Joseph Banks’s Sunday evening meetings.
-He had a house in London, which he only
-visited once or twice a-week at stated times, and without
-ever speaking to the servants: it contained an
-excellent library, to which he gave all literary men the
-freest and most unrestrained access. But he lived in
-a house on Clapham Common, where he scarcely ever
-received any visitors. His relation, Lord George Cavendish,
-to whom he left by will the greatest part of his
-fortune, visited him only once a-year, and the visit
-hardly ever exceeded ten or twelve minutes.</p>
-
-<p>He was shy and bashful to a degree bordering on
-disease; he could not bear to have any person introduced
-to him, or to be pointed out in any way as a
-remarkable man. One Sunday evening he was
-standing at Sir Joseph Banks’s in a crowded room,
-conversing with Mr. Hatchett, when Dr. Ingenhousz,
-who had a good deal of pomposity of manner, came
-up with an Austrian gentleman in his hand, and introduced
-him formally to Mr. Cavendish. He mentioned
-the titles and qualifications of his friend at great
-<span class="pagenum" id="Page_338">338</span>
-length, and said that he had been peculiarly anxious
-to be introduced to a philosopher so profound and so
-universally known and celebrated as Mr. Cavendish.
-As soon as Dr. Ingenhousz had finished, the Austrian
-gentleman began, and assured Mr. Cavendish that his
-principal reason for coming to London was to see and
-converse with one of the greatest ornaments of the
-age, and one of the most illustrious philosophers that
-ever existed. To all these high-flown speeches Mr.
-Cavendish answered not a word, but stood with his
-eyes cast down quite abashed and confounded. At
-last, spying an opening in the crowd, he darted through
-it with all the speed of which he was master; nor did
-he stop till he reached his carriage, which drove him
-directly home.</p>
-
-<p>Of a man, whose habits were so retired, and whose
-intercourse with society was so small, there is nothing
-else to relate except his scientific labours: the current
-of his life passed on with the utmost regularity;
-the description of a single day would convey a correct
-idea of his whole existence. At one time he was in
-the habit of keeping an individual to assist him in his
-experiments. This place was for some time filled by
-Sir Charles Blagden; but they did not agree well together,
-and after some time Sir Charles left him.
-Mr. Cavendish died on the 4th of February, 1810,
-aged seventy-eight years, four months, and six days.
-When he found himself dying, he gave directions to
-his servant to leave him alone, and not to return till a
-certain time which he specified, and by which period
-he expected to be no longer alive. The servant, however,
-who was aware of the state of his master, and was
-anxious about him, opened the door of the room before
-the time specified, and approached the bed to take a
-look at the dying man. Mr. Cavendish, who was still
-sensible, was offended at the intrusion, and ordered
-him out of the room with a voice of displeasure, commanding
-him not by any means to return till the time
-<span class="pagenum" id="Page_339">339</span>
-specified. When he did come back at that time, he
-found his master dead. What a contrast between the
-characters of Mr. Cavendish and Dr. Black!</p>
-
-<p>The appearance of Mr. Cavendish did not much
-prepossess strangers in his favour; he was somewhat
-above the middle size, his body rather thick, and his
-neck rather short. He stuttered a little in his speech,
-which gave him an air of awkwardness: his countenance
-was not strongly marked, so as to indicate the
-profound abilities which he possessed. This was probably
-owing to the total absence of all the violent passions.
-His education seems to have been very complete;
-he was an excellent mathematician, a profound
-electrician, and a most acute and ingenious chemist.
-He never ventured to give an opinion on any subject,
-unless he had studied it to the bottom. He appeared
-before the world first as a chemist, and afterwards as
-an electrician. The whole of his literary labours consist
-of eighteen papers, published in the Philosophical
-Transactions, which, though they occupy only a few
-pages, are full of the most important discoveries and the
-most profound investigations. Of these papers, there are
-ten which treat of chemical subjects, two treat of electricity,
-two of meteorology, three are connected with
-astronomy, and there is one, the last which he wrote,
-which gives his method of dividing astronomical instruments.
-Of the papers in question, those alone
-which treat of Chemistry can be analyzed in a work
-like this.</p>
-
-<p>1. His first paper, entitled, “Experiments on fictitious
-Air,” was published in the year 1766, when Mr. Cavendish
-was thirty-five years of age. Dr. Hales had demonstrated
-(as had previously been done by Van Helmont
-and Glauber) that <i>air</i> is given out by a vast
-number of bodies in peculiar circumstances. But he
-never suspected that any of the <i>airs</i> which he obtained
-differed from common air. Indeed common air had
-always been considered as an elementary substance to
-<span class="pagenum" id="Page_340">340</span>
-which every elastic fluid was referred. Dr. Black had
-shown that the mild alkalies and limestone, and carbonate
-of magnesia, were combinations of these bodies
-with a gaseous substance, to which he had given the
-name of <i>fixed air</i>; and he had pointed out various
-methods of collecting this fixed air; though he himself
-had not made much progress in investigating its
-properties. This paper of Mr. Cavendish may be considered
-as a continuation of the investigations begun
-by Dr. Black. He shows that there exist two species of
-air quite different in their properties from common air:
-and he calls them <i>inflammable air</i> and <i>fixed air</i>.</p>
-
-<p>Inflammable air (hydrogen gas) is evolved when
-iron, zinc, or tin, are dissolved in dilute sulphuric or
-muriatic acid. Iron yielded about 1-22d part of its
-weight, of inflammable air, zinc about 1-23d or
-1-24th of its weight, and tin about 1-44th of its
-weight. The properties of the inflammable air were
-the same, whichever of the three metals was used
-to procure it, and whether they were dissolved in sulphuric
-or muriatic acids. When the sulphuric acid was
-concentrated, iron and zinc dissolved in it with difficulty
-and only by the assistance of heat. The air given
-out was not inflammable, but consisted of sulphurous
-acid. These facts induced Mr. Cavendish to conclude
-that the inflammable air evolved in the first case was
-the unaltered <i>phlogiston</i> of the metals, while the sulphurous
-acid evolved in the second case, was a compound
-of the same phlogiston and a portion of the
-acid, which deprived it of its inflammability. This
-opinion was very different from that of Stahl, who considered
-combustible bodies as compounds of phlogiston
-with acids or calces.</p>
-
-<p>Cavendish found the specific gravity of his inflammable
-air about eleven times less than that of common air.
-This determination is under the truth; but the error is, at
-least in part, owing to the quantity of water held in
-solution by the air, and which, as Mr. Cavendish showed,
-<span class="pagenum" id="Page_341">341</span>
-amounted to about 1-9th of the weight of the air.
-He tried the combustibility of the inflammable air,
-when mixed with various proportions of common air,
-and found that it exploded with the greatest violence when
-mixed with rather more than its bulk of common air.</p>
-
-<p>Copper he found, when dissolved in muriatic acid by
-the assistance of heat, yielded no inflammable air, but
-an air which lost its elasticity when it came in contact
-with water. This <i>air</i>, the nature of which Mr. Cavendish
-did not examine, was <i>muriatic acid gas</i>, the properties
-of which were afterwards investigated by Dr.
-Priestley.</p>
-
-<p>The <i>fixed air</i> (<i>carbonic acid gas</i>) on which Mr. Cavendish
-made his experiments was obtained by dissolving
-marble in muriatic acid. He found that it
-might be kept over mercury for any length of time
-without undergoing any alteration; that it was gradually
-absorbed by cold water; and that 100 measures
-of water of the temperature 55&deg; absorbed 103&middot;8 measures
-of fixed air. The whole of the air thus absorbed
-was separated again by exposing the water to a
-boiling heat, or by leaving it for sometime in an open
-vessel. Alcohol (the specific gravity not mentioned)
-absorbed 2&frac14; times its bulk of this air, and olive-oil
-about 1-3d of its bulk.</p>
-
-<p>The specific gravity of fixed air he found 1&middot;57, that
-of common air being 1.<a id="FNanchor_186" href="#Footnote_186" class="fnanchor">186</a> Fixed air is incapable of
-supporting combustion, and common air, when mixed
-with it, supports combustion a much shorter time than
-when pure. A small wax taper burnt eighty seconds in a
-receiver which held 180 ounce measures, when filled
-with common air only. The same taper burnt fifty-one
-seconds in the same receiver when filled with a
-mixture of one volume fixed air, and nineteen volumes
-of common air. When the fixed air was 3-40ths of
-<span class="pagenum" id="Page_342">342</span>
-the whole volume the taper burnt twenty-three seconds.
-When the fixed air was 1-10th, the taper burnt
-eleven seconds. When it was 6-55ths or 1-9&middot;16 of
-the whole mixture, the taper would not burn at all.</p>
-
-<p>Mr. Cavendish was of opinion that more than one
-kind of fixed air was given out by marble; in other words,
-that the elastic fluid emitted, consisted of two different
-airs, one more absorbable by water than the other.
-He drew his conclusion from the circumstance that
-after a solution of potash had been exposed to a
-quantity of fixed air for some time, it ceased to absorb
-any more; yet, if the residual portion of air were thrown
-away and new fixed air substituted in its place, it began
-to absorb again; but Mr. Dalton has since given
-a satisfactory explanation of this seeming anomaly by
-showing that the absorbability of fixed air in water is
-proportional to its purity, and that when mixed with a
-great quantity of common air or any other gas not
-soluble in water, it ceases to be sensibly absorbed.</p>
-
-<p>Mr. Cavendish ascertained the quantity of fixed
-air contained in marble, carbonate of ammonia, common
-pearlashes, and carbonate of potash: but notwithstanding
-the care with which these experiments
-were made they are of little value; because the proper
-precautions could not be taken, in that infant state of
-chemical science, to have these salts in a state of
-purity. The following were the results obtained by
-Mr. Cavendish:
-
-<span class="table">
-  <span class="trow">
-    <span class="tcell">1000</span>
-    <span class="tcell">grains</span>
-    <span class="tcell">of marble contained</span>
-    <span class="tcell">408</span>
-    <span class="tcell">grs. fixed air.</span>
-  </span>
-  <span class="trow">
-    <span class="tcell">1000</span>
-    <span class="tcell tdc">&mdash;</span>
-    <span class="tcell">carb. of ammonia</span>
-    <span class="tcell">533</span>
-    <span class="tcell tdc">&mdash;</span>
-  </span>
-  <span class="trow">
-    <span class="tcell">1000</span>
-    <span class="tcell tdc">&mdash;</span>
-    <span class="tcell">pearlashes</span>
-    <span class="tcell">284</span>
-    <span class="tcell tdc">&mdash;</span>
-  </span>
-  <span class="trow">
-    <span class="tcell">1000</span>
-    <span class="tcell tdc">&mdash;</span>
-    <span class="tcell">carb. of potash</span>
-    <span class="tcell">423</span>
-    <span class="tcell tdc">&mdash;</span>
-  </span>
-</span></p>
-
-<p>Supposing the marble, carbonate of ammonia, and
-carbonate of potash, to have been pure anhydrous
-simple salts, their composition would be
-
-<span class="table">
-  <span class="trow">
-    <span class="tcell">1000</span>
-    <span class="tcell">grains</span>
-    <span class="tcell">of marble contain</span>
-    <span class="tcell">440</span>
-    <span class="tcell">grs. fixed air.</span>
-  </span>
-  <span class="trow">
-    <span class="tcell">1000</span>
-    <span class="tcell tdc">&mdash;</span>
-    <span class="tcell">carb. of ammonia</span>
-    <span class="tcell">709&middot;6</span>
-    <span class="tcell tdc">&mdash;</span>
-  </span>
-  <span class="trow">
-    <span class="tcell">1000</span>
-    <span class="tcell tdc">&mdash;</span>
-    <span class="tcell">carb. of potash</span>
-    <span class="tcell">314&middot;2</span>
-    <span class="tcell tdc">&mdash;</span>
-  </span>
-</span>
-<span class="pagenum" id="Page_343">343</span></p>
-
-<p>Bicarbonate of potash was first obtained by Dr.
-Black. Mr. Cavendish formed the salt by dissolving
-pearlashes in water, and passing a current of carbonic
-acid gas through the solution till it deposited crystals.
-These crystals were not altered by exposure to the air,
-did not deliquesce, and were soluble in about four
-times their weight of cold water.</p>
-
-<p>Dr. M’Bride had already ascertained that vegetable
-and animal substances yield fixed air by putrefaction
-and fermentation. Mr. Cavendish found by experiment
-that sugar when dissolved in water and fermented,
-gives out 57-100ths of its weight of fixed air, possessing
-exactly the properties of fixed air from marble.
-During the fermentation no air was absorbed, nor was
-any change induced on the common air, at the surface
-of the fermenting liquor. Apple-juice fermented much
-faster than sugar; but the phenomena were the same,
-and the fixed air emitted amounted to 381/1000 of the
-weight of the solid extract of apples. Gravy and
-raw meat yielded inflammable air during their putrefaction,
-the former in much greater quantity than the
-latter. This air, as far as Mr. Cavendish’s experiments
-went, he found the same as the inflammable air
-from zinc by dilute sulphuric acid; but its specific
-gravity was a little higher.</p>
-
-<p>This paper of Mr. Cavendish was the first attempt
-by chemists to collect the different kinds of air, and
-endeavour to ascertain their nature. Hence all his
-processes were in some measure new: they served as a
-model to future experimenters, and were gradually
-brought to their present state of simplicity and perfection.
-He was the first person who attempted to determine
-the specific gravity of airs, by comparing their
-weight with that of the same bulk of common air;
-and though his apparatus was defective, yet the principle
-was good, and is the very same which is still employed
-to accomplish the same object. Mr. Cavendish
-then first began the true investigation of gases,
-<span class="pagenum" id="Page_344">344</span>
-and in his first paper he determined the peculiar nature
-of two very remarkable gases, <i>carbonic</i> and <i>hydrogen</i>.</p>
-
-<p>2. Mineral waters have at all times attracted the
-attention of the faculty in consequence of their
-peculiar properties and medical virtues. Some faint
-steps towards their investigation were taken by Boyle.
-Du Clos attempted a chemical analysis of the mineral
-waters in France; and Hierne made a similar investigation
-of the mineral waters of Sweden. Though these
-experiments were rude and inaccurate, they led to the
-knowledge of several facts respecting mineral waters
-which chemists were unable to explain. One of these
-was the existence of a considerable quantity of <i>calcareous
-earth</i> in some mineral waters, which was precipitated
-by boiling. Nobody could conceive in what way
-this insoluble substance (<i>carbonate of lime</i>) was held
-in solution, nor why it was thrown down when the water
-was raised to a boiling heat. It was to determine
-this point that Mr. Cavendish made his experiments on
-Rathbone-place water, which were published in the
-year 1767, and which may be considered as the first
-analysis of a mineral water that possessed tolerable
-accuracy. Rathbone-place water was raised by a
-pump, and supplied the portion of London in its immediate
-neighbourhood. Mr. Cavendish found that when
-boiled, it deposited a quantity of earthy matter, consisting
-chiefly of lime, but containing also a little
-magnesia. This he showed was held in solution by
-fixed air; and he proved experimentally, that when an
-excess of this gas is present, it has the property of
-holding lime and magnesia in solution.<a id="FNanchor_187" href="#Footnote_187" class="fnanchor">187</a> Besides these
-earthy carbonates, the water was found to contain a
-little ammonia, some sulphate of lime, and some common
-salt. Mr. Cavendish examined, likewise, some
-<span class="pagenum" id="Page_345">345</span>
-other pump-water in London, and showed that it contained
-lime, held in solution by carbonic acid.</p>
-
-<p>3. Dr. Priestley, at a pretty early period of his
-chemical career, had discovered that when nitrous gas
-is mixed with common air over water, a diminution of
-bulk takes place; that there is a still greater diminution
-of bulk when oxygen gas is employed instead of
-common air; and that the diminution is always proportional
-to the quantity of oxygen gas present in the
-gas mixed with the nitrous gas. This discovery induced
-him to employ nitrous gas as a test of the
-quantity of oxygen present in common air; and various
-instruments were contrived to facilitate the mixture of
-the gases, and the measurement of the diminution of
-volume which took place. As the goodness of air, or
-its fitness to support combustion, and maintain animal
-life, was conceived to depend upon the proportion of
-oxygen gas which it contained, these instruments were
-distinguished by the name of <i>eudiometers</i>; the simplest
-of them was contrived by Fontana, and is usually
-distinguished by the name of the <i>eudiometer of Fontana</i>.
-Philosophers, in examining air by means of
-this instrument, at various seasons, and in various
-places, had found considerable differences in the diminution
-of bulk: hence they inferred that the proportion
-of oxygen varies in different places; and to this
-variation they ascribed the healthiness or noxiousness
-of particular situations. For example, Dr. Ingenhousz
-had found a greater proportion of oxygen in the air
-above the sea, and on the sea-coast; and to this he
-ascribed the healthiness of maritime situations. Mr.
-Cavendish examined this important point with his
-usual patient industry and acute discernment, and
-published the result in the Philosophical Transactions
-for 1783. He ascertained that the apparent variations
-were owing to inaccuracies in making the experiment;
-and that when the requisite precautions are taken, the
-proportion of oxygen in air is found constant in all
-<span class="pagenum" id="Page_346">346</span>
-places, and at all seasons. This conclusion has since
-been confirmed by numerous observations in every
-part of the globe. Mr. Cavendish also analyzed
-common air, and found it to consist of
-
-<span class="table">
-  <span class="trow">
-    <span class="tcell tdr">79&middot;16</span>
-    <span class="tcell">volumes azotic gas,</span>
-  </span>
-  <span class="trow">
-    <span class="tcell tdr">20&middot;84</span>
-    <span class="tcell">volumes oxygen gas.</span>
-  </span>
-  <span class="trow">
-    <span class="tcell tdr bt">100&middot;00</span>
-    <span class="tcell">&nbsp;</span>
-  </span>
-</span></p>
-
-<p>4. For many years it was the opinion of chemists
-that mercury is essentially liquid, and that no degree
-of cold is capable of congealing it. Professor Braun’s
-accidental discovery that it may be frozen by cold,
-like other liquids, was at first doubted; and when it
-was finally established by the most conclusive experiments,
-it was inferred from the observations of Braun
-that the freezing point of mercury is several hundred
-degrees below zero on Fahrenheit’s scale. It became
-an object of great importance to determine the exact
-point of the congelation of this metal by accurate experiments.
-This was done at Hudson’s Bay, by Mr.
-Hutchins, who followed a set of directions given him
-by Mr. Cavendish, and from his experiments Mr. Cavendish,
-in a paper inserted in the Philosophical
-Transactions for 1783, deduced that the freezing point
-of mercury is 38&middot;66 degrees below the zero of Fahrenheit’s
-thermometer.</p>
-
-<p>5. These experiments naturally drew the attention
-of Mr. Cavendish to the phenomena of freezing, to
-the action of freezing mixtures, and the congelation of
-acids. He employed Mr. M’Nab, who was settled in
-the neighbourhood of Hudson’s Bay, to make the requisite
-experiments; and he published two very curious
-and important papers on these subjects in the Philosophical
-Transactions for 1786 and 1788. He explained
-the phenomena of congelation exactly according
-to the theory of Dr. Black, but rejecting the
-hypothesis that heat is a <i>substance</i> sui generis, and
-<span class="pagenum" id="Page_347">347</span>
-thinking it more probable, with Sir Isaac Newton, that
-it is owing to the rapid internal motion of the particles
-of the hot body. The latent heat of water, he found
-to be 150&deg;. The observations on the congelation of
-nitric and sulphuric acids are highly interesting: he
-showed that their freezing points vary considerably,
-according to the strength of each; and drew up tables
-indicating the freezing points of acids, of various degrees
-of strength.</p>
-
-<p>6. But the most splendid and valuable of Mr. Cavendish’s
-chemical experiments were published in two
-papers, entitled, “Experiments on Air,” in the Transactions
-of the Royal Society for 1784 and 1785. The
-object of these experiments was to determine what
-happened during the <i>phlogistication of air</i>, as it was
-at that time termed; that is, the change which air
-underwent when metals were calcined in contact with
-it, when sulphur or phosphorus was burnt in it, and
-in several similar processes. He showed, in the first
-place, that there was no reason for supposing that
-carbonic acid was formed, except when some animal
-or vegetable substance was present; that when <i>hydrogen
-gas</i> was burnt in contact with air or oxygen gas,
-it <i>combined</i> with that gas, and formed <i>water</i>; that
-<i>nitrous gas</i>, by combining with the oxygen of the atmosphere,
-formed <i>nitrous acid</i>; and that when <i>oxygen</i>
-and <i>azotic</i> gas are mixed in the requisite proportions,
-and electric sparks passed through the mixture, they
-<i>combine</i>, and form <i>nitric</i> acid.</p>
-
-<p>The first of these opinions occasioned a controversy
-between Mr. Cavendish, and Mr. Kirwan, who maintained
-that carbonic acid is always produced when air
-is phlogisticated. Two papers on this subject by
-Kirwan, and one by Cavendish, are inserted in the
-Philosophical Transactions for 1784, each remarkable
-examples of the peculiar manner of the respective
-writers. All the arguments of Kirwan are founded
-on the experiments of others. He displays great reading,
-<span class="pagenum" id="Page_348">348</span>
-and a strong memory; but does not discriminate
-between the merits of the chemists on whose authority
-he founds his opinions. Mr. Cavendish, on the other
-hand, never advances a single opinion, which he has
-not put to the test of experiment; and never suffers
-himself to go any further than his experiment will
-warrant. Whatever is not accurately determined by
-unexceptionable trials, is merely stated as a conjecture
-on which little stress is laid.</p>
-
-<p>In the first of these celebrated papers, Mr. Cavendish
-has drawn a comparison between the phlogistic
-and antiphlogistic theories of chemistry; he has shown
-that each of them is capable of explaining the phenomena
-in a satisfactory manner; though it is impossible
-to demonstrate the truth of either; and he has given
-the reasons which induced him to prefer the phlogistic
-theory&mdash;reasons which the French chemists were unable
-to refute, and which they were wise enough not to
-notice. There cannot be a more striking proof of the
-influence of fashion, even in science, and of the unwarrantable
-precipitation with which opinions are
-rejected or embraced by philosophers, than the total
-inattention paid by the chemical world to this admirable
-dissertation. Had Mr. Kirwan adopted the opinions
-of Mr. Cavendish, when he undertook the defence
-of phlogiston, instead of trusting to the vague experiments
-of inaccurate chemists, he would not have
-been obliged to yield to his French antagonists, and
-the antiphlogistic theory would not so speedily have
-gained ground.</p>
-
-<p>Such is an epitome of the chemical papers of Mr.
-Cavendish. They contain five notable discoveries;
-namely, 1. The nature and properties of hydrogen gas.
-2. The solubility of bicarbonates of lime and magnesia
-in water. 3. The exact proportion of the constituents
-of common air. 4. The composition of water. 5. The
-composition of nitric acid. It is to him also that we
-are indebted for our knowledge of the freezing point
-<span class="pagenum" id="Page_349">349</span>
-of mercury; and he was likewise the first person who
-showed that potash has a stronger affinity for acids
-than soda has. His experiments on the subject are to
-be found in a paper on Mineral Waters, published
-in the Philosophical Transactions, by Dr. Donald
-Monro.</p>
-
-<h3>END OF VOL. I.</h3>
-
-<p class="caption">C. WHITING, BEAUFORT HOUSE, STRAND.</p>
-
-<p><span class="pagenum" id="Page_xii">xii</span></p>
-
-<p><span class="pagenum" id="Page_xiii">xiii</span></p>
-
-<hr class="chap" />
-<h2 id="ANCIENT_HISTORIANS_POETS_c">ANCIENT HISTORIANS, POETS, &amp;c.</h2>
-
-<p class="hang"><i>Now in course of Publication, in Monthly volumes (containing
-on the average 350 pages of letter-press), price
-only 4s. 6d. each, neatly bound, and embellished with
-Engravings on steel by the first Artists</i>,</p>
-
-<p><span class="large">THE FAMILY CLASSICAL LIBRARY;</span><br />
-or, <span class="smcap">English Translations</span> of the most valuable <span class="smcap">Greek
-and Latin Historians, Poets and Orators</span>. With
-<span class="smcap">Biographical Sketches</span> of <span class="smcap">each Author</span>, and <span class="smcap">copious
-illustrative Notes</span>. Edited by A. J. VALPY,
-M. A.</p>
-
-<p><span class="smcap">Cicero</span> remarks, that not to know what has been transacted
-in former times, is to continue always a child. If no
-use be made of the labours of past ages, the world must
-remain always in the infancy of knowledge: and the
-learned Dr. Parr says, “If you desire your son, though no
-great scholar, to read and reflect, it is your duty <i>to place</i>
-in his hands the best <i>Translations</i> of the best <i>Classical</i>
-Authors.”</p>
-
-<p>To those, therefore, who are desirous of obtaining a
-knowledge of the most esteemed authors of Greece and
-Rome, but possess not the means or leisure for pursuing a
-regular course of study, the present undertaking must
-prove a valuable acquisition. The following are the contents
-of the volumes already published.</p>
-
-<p>No. I.&mdash;DEMOSTHENES (translated by Dr. Leland),
-comprising a sketch of the Life of Demosthenes: his Orations
-against Philip, King of Macedon; and those pronounced
-on occasions of public deliberation.</p>
-
-<p>No. II.&mdash;DEMOSTHENES, concluded, and SALLUST
-complete: (the latter translated by William Rose, M. A.)
-comprising the Orations of Dinarchus against Demosthenes,
-and Account of the Exile and Death of Demosthenes,
-and the Orations of &AElig;schines and Demosthenes
-on the Crown: a Biographical Sketch of <span class="smcap">Sallust</span>: his
-History of Catiline’s conspiracy; and History of the
-Roman War against Jugurtha, King of Numidia.</p>
-
-<p>No. III.&mdash;XENOPHON, Vol. I. (translated by E. Spelman,
-Esq.), comprising a Biographical Sketch of the Historian;
-and his Anabasis, or Expedition of Cyrus into
-Persia, and retreat of the 10,000 Greeks.
-<span class="pagenum" id="Page_xiv">xiv</span></p>
-
-<p>No. IV.&mdash;XENOPHON, vol. II. (translated by the Hon.
-Maurice Ashley Cooper), comprising the Cyrop&aelig;dia, or
-the Education, Life and Manners, Government, Wars, and
-Achievements of Cyrus, King of Persia.</p>
-
-<p>No. V.&mdash;HERODOTUS, vol. I. (translated by the Rev.
-W. Beloe), comprising a Biographical Sketch of the Historian;
-and the first two Books of his History, containing
-a Narrative of the Acquisition of the Kingdom of Lydia
-by Crœsus, and the subsequent overthrow of the Lydian
-Empire by Cyrus; the early History of the Republics of
-Athens and Laced&aelig;mon; with an account of Egypt, its
-Customs, Manners, and Governments.</p>
-
-<p>No. VI.&mdash;HERODOTUS, vol II., comprising, in the
-3d, 4th, and 5th Books, the Exploits of Cambyses, with
-the subjugation of the whole of Egypt; the elevation of
-Darius Hystaspes to the Persian throne; the disastrous
-Expeditions of the Persians against the Scythians during
-his reign; the progress of the Republics of Athens, Laced&aelig;mon
-and Corinth, and their state during the time of
-the Persian Emperor Darius.</p>
-
-<p>No. VII.&mdash;HERODOTUS, vol. III., comprising, in the
-6th to the 9th Book, the Origin of the Laced&aelig;monian
-Kings; the first Invasion of Greece by the Persians; the
-Battle of Marathon; the memorable Expedition of Xerxes
-into Greece; the Battle of Thermopyl&aelig;; the Capture and
-Burning of Athens by the Persians; the Sea-fight of Salamis;
-the Battles of Plat&aelig;a and of the Promontory of Mycale;
-and the overthrow of the Persian power in Greece.</p>
-
-<p>No. VIII.&mdash;VIRGIL, vol. I., comprising a Biographical
-Sketch of the Poet; his <i>Eclogues</i>, or Pastoral Poems,
-translated by Archdeacon Wrangham; the <i>Georgics</i>, or
-Poems on Husbandry, translated by William Sotheby,
-Esq.; and the first two Books of the <i>&AElig;neid</i>, translated by
-Dryden, and prefaced with his celebrated Dedication.</p>
-
-<p>No. IX.&mdash;VIRGIL, vol. II., comprising the remainder of
-Dryden’s translation of the <i>&AElig;neid</i>, namely, from the
-third to the twelfth Book.</p>
-
-<p>No. X.&mdash;PINDAR (translated by the Rev. C. A. Wheelwright,
-Prebendary of Lincoln); and ANACREON, by
-Mr. Thomas Bourne.</p>
-
-<h3>
-LONDON:<br />
-<br />
-PRINTED FOR H. COLBURN AND R. BENTLEY,<br />
-<br />
-NEW BURLINGTON-STREET;<br />
-<br />
-And sold by every Bookseller throughout the Kingdom.<br />
-</h3>
-
-<hr />
-
-<div class="footnotes">
-
-<h3>FOOTNOTES:</h3>
-
-<div class="footnote">
-
-<p><a id="Footnote_1" href="#FNanchor_1" class="label">1</a>
-The word χημεια is said to occur in several Greek manuscripts
-of a much earlier date. But of this, as I have never had
-an opportunity of seeing them, I cannot pretend to judge. So
-much fiction has been introduced into the history of Alchymy,
-and so many ancient names have been treacherously dragged
-into the service, that we may be allowed to hesitate when no
-evidence is presented sufficient to satisfy a reasonable man.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_2" href="#FNanchor_2" class="label">2</a>
-Χημεια, ἡ του αργυρου και χρυσου κατασκευη· ἡς τα βιβλια
-διερευνησαμενος ὁ Διοκλητιανος εκαυσε, δια τα νεωτερισθεντα
-αιγυπτιοις Διοκλητιανω· τουτοις ανημερως και φονικως εχρησατο
-ὁτεδη και τα περι χημειας χρυσου και αργυρου τοις παλαιοις
-γεγραμμενα βιβλια διερευνησαμενος εκαυσε, προς το μηκετι πλουτον
-αιγυπτιοις εκ της τοιαυτης προσγινεσθαι τεχνης, μηδε χρηματων
-αυτοις θαρῥονιτας περιουσια του λοιπου ῥωμαιοις ανταιρειν.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_3" href="#FNanchor_3" class="label">3</a>
-Δερας, το χρυσομαλλον δερας, ὁπερ ὁ Ιασων δια της ποντικης
-θαλασσης συν τοις αργοναυταις εις την κολχιδα παραγενομενοι
-ελαβον, και την Μηδειαν την Αιητου του βασιλεως θυγατερα.
-Τουτο δε ουκ ὡς ποιητικως φερεται· αλλα βιβλιον ην εν δερμασι
-γεγραμενον περισχον ὁπως δειγινεσθαι δια χημειας χρυσον· εικοτως
-ουν ὁι τοτε χρουσουν ωνομαζον αυτο δερας δια την ενεργειαν την
-εξ αυτου.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_4" href="#FNanchor_4" class="label">4</a>
-De Ortu et Progressu Chemi&aelig;, p. 12.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_5" href="#FNanchor_5" class="label">5</a>
-Σωσιμου του παναπολιτου γνησια γραφη, περι της ἱερας, και
-θειας τεχνης του χρυσου και αργυριου ποιησιος. Παναπολις
-was a city in Egypt.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_6" href="#FNanchor_6" class="label">6</a>
-Shaw’s Translation of Boerhaave’s Chemistry, i. 20.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_7" href="#FNanchor_7" class="label">7</a>
-Genesis iv. 22.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_8" href="#FNanchor_8" class="label">8</a>
-De Iside and Osiride, c. 5.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_9" href="#FNanchor_9" class="label">9</a>
-There are two Latin translations of these tables (unless we
-are rather to consider them as originals, for no Phœnician nor
-Greek original exists). I shall insert them both here.</p>
-
-<blockquote>
-
-<h3>I.&mdash;<span class="smcap">Verba secretorum Hermetis Trismegisti.</span></h3>
-
-<p>1. Verum sine mendacio certum et verissimum.</p>
-
-<p>2. Quod est inferius, est sicut quod est superius, et quod est
-superius est sicut quod est inferius ad perpetranda miracula rei unius.</p>
-
-<p>3. Et sicut omnes res fuerant ab uno meditatione unius: sic
-omnes res nat&aelig; fuerunt ab hac una re adaptatione.</p>
-
-<p>4. Pater ejus est Sol, mater ejus Luna, portavit illud ventus
-in ventre suo, nutrix ejus terra est.</p>
-
-<p>5. Pater omnis thelesmi totius mundi est hic.</p>
-
-<p>6. Vis ejus integra est, si versa fuerit in terram.</p>
-
-<p>7. Separabis terram ab igne, subtile a spisso suaviter cum
-magno ingenio.</p>
-
-<p>8. Ascendit a terra in cœlum, iterumque descendit in terram,
-et recipit vim superiorum et inferiorum, sic habebis gloriam
-totius mundi. Ideo fugiat a te omnis obscuritas.</p>
-
-<p>9. Hic est totius fortitudinis fortitudo fortis; quia vincit
-omnem rem subtilem, omnemque solidam penetrabit.</p>
-
-<p>10. Sic mundus creatus est.</p>
-
-<p>11. Hinc adaptationes erunt mirabiles, quarum modus est
-hic.</p>
-
-<p>12. Itaque vocatus sum Hermes Trismegistus, habens tres
-partes philosophi&aelig; totius mundi.</p>
-
-<p>13. Completum est quod dixi de operatione solis.</p>
-
-<h3>II.&mdash;<span class="smcap">Descriptio Arcanorum Hermetis Trismegisti.</span></h3>
-
-<p>1. Vere non ficte, certo verissime aio.</p>
-
-<p>2. Inferiora h&aelig;c cum superioribus illis, istaque cum iis vicissim
-vires sociant, ut producant rem unam omnium mirificissimam.</p>
-
-<p>3. Ac quemadmodum cuncta educta ex uno fuere verbo Dei
-unius: sic omnes quoque res perpetuo ex hac una re generantur
-dispositione Natur&aelig;.</p>
-
-<p>4. Patrem ea habet Solem, matrem Lunam: ab a&euml;re in utero
-quasi gestatur, nutritur a terra.</p>
-
-<p>5. Causa omnis perfectionis rerum ea est per univerum hoc.</p>
-
-<p>6. Ad summam ipsa perfectionem virium pervenit si redierit
-in humum.</p>
-
-<p>7. In partes tribuite humum ignem passam, attenuans densitatem
-ejus re omnium suavissima.</p>
-
-<p>8. Summa ascende ingenii sagacitate a terra in cœlum, indeque
-rursum in terram descende, ac vires superiorum inferiorumque
-coge in unum: sic potiere gloria totius mundi atque ita abject&aelig;
-sortis homo amplius non habere.</p>
-
-<p>9. Isth&aelig;c jam res ipsa fortitudine fortior existet; corpora
-quippe tam tenuia quam solida penetrando subige.</p>
-
-<p>10. Atque sic quidem qu&aelig;cunque mundus continet creata fuere.</p>
-
-<p>11. Hinc admiranda evadunt opera, qu&aelig; ad eundum modum instituantur.</p>
-
-<p>12. Mihi vero ideo nomen Hermetis Trismegisti impositum
-fuit, quod trium mundi sapienti&aelig; partium doctor deprehensus
-sum.</p>
-
-<p>13. H&aelig;c sunt qu&aelig; de chemic&aelig; artis prestantissimo opere
-consignanda esse duxi.</p></blockquote>
-</div>
-
-<div class="footnote">
-
-<p><a id="Footnote_10" href="#FNanchor_10" class="label">10</a>
-“Accipe de humore unciam unam et mediam, et de rubore
-meridionali, id est anima solis, quartam partem, id est, unciam
-mediam, et de Seyre citrino, similiter unciam mediam,
-et de auripigmenti dimidium, qu&aelig; sunt octo, id est unci&aelig; tres.
-Scitote quod vitis sapientum in tribus extrahitur, ejusque vinum
-in fine triginta peragitur.”</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_11" href="#FNanchor_11" class="label">11</a>
-Preface to Mangetus’s Bibliotheca Chemica Curiosa.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_12" href="#FNanchor_12" class="label">12</a>
-Ibid.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_13" href="#FNanchor_13" class="label">13</a>
-Bergmann, Opusc. iv. 121.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_14" href="#FNanchor_14" class="label">14</a>
-I allude to his <i>Manuale sive de Lapide Philosophico Medicinali</i>.
-Opera Paracelsi, ii. 133. Folio edition. Geneva, 1658.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_15" href="#FNanchor_15" class="label">15</a>
-Wilson’s Chemistry, p. 375.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_16" href="#FNanchor_16" class="label">16</a>
-Ibid., p. 379.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_17" href="#FNanchor_17" class="label">17</a>
-Probably corrosive sublimate.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_18" href="#FNanchor_18" class="label">18</a>
-Probably calomel.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_19" href="#FNanchor_19" class="label">19</a>
-Mangeti Bibliothec&aelig; Chemic&aelig; Pr&aelig;fatio.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_20" href="#FNanchor_20" class="label">20</a>
-Whoever wishes to enter more particularly into the processes
-for making the philosopher’s stone contrived by the alchymists,
-will find a good deal of information on the subject in
-Stahl’s Fundamenta Chemi&aelig;, vol. i. p. 219, in his chapter <i>De
-lapide philosophorum</i>: and Junker’s Conspectus Chemi&aelig;, vol.
-i. p. 604, in his tabula 28, <i>De transmutatione metallorum universali</i>:
-and tabula 29, <i>De transmutatione metallorum particulari</i>.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_21" href="#FNanchor_21" class="label">21</a>
-Kircher, in his Mundus Subterraneus, has an article on the
-philosopher’s stone, in which he examines the processes of the
-alchymists, points out their absurdity, and proves by irrefragable
-arguments that no such substance had ever been obtained.
-Those who are curious about alchymistical processes may consult
-that work.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_22" href="#FNanchor_22" class="label">22</a>
-Mem. Paris, 1722, p. 61.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_23" href="#FNanchor_23" class="label">23</a>
-The original author, whom all who have given any account
-of the alchymists have followed, is Olaus Borrichius, in his
-Conspectus Scriptorum Chemicorum Celebriorum. He does not
-inform us from what sources his information was derived.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_24" href="#FNanchor_24" class="label">24</a>
-Sprengel’s History of Medicine, iv. 368.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_25" href="#FNanchor_25" class="label">25</a>
-It is curious that Olaus Borrichius omits Albertus Magnus
-in the list of alchymistical writers that he has given.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_26" href="#FNanchor_26" class="label">26</a>
-This tract and the next, which is of considerable length,
-will be found in Mangetus’s Bibliotheca Chemica Curiosa, i. 613.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_27" href="#FNanchor_27" class="label">27</a>
-Gmelin’s Geschitte der Chemie, i. 74.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_28" href="#FNanchor_28" class="label">28</a>
-Exodus xi. 2&mdash;xxv. 11, 12, 13, 17, 18, 24, 25, 26&mdash;xxviii.
-8&mdash;xxxii. 2, &amp;c.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_29" href="#FNanchor_29" class="label">29</a>
-Genesis xlvii. 14.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_30" href="#FNanchor_30" class="label">30</a>
-For example, Exodus xi. 2&mdash;xxvi. 19, 21&mdash;xxvii. 10, 11,
-17, &amp;c.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_31" href="#FNanchor_31" class="label">31</a>
-Genesis iv. 22.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_32" href="#FNanchor_32" class="label">32</a>
-For example, Exodus xxvii. 2, 3, 4, 6, 10, 11, 17, 18, 19&mdash;xxx.
-18, &amp;c. Numbers xxi. 9.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_33" href="#FNanchor_33" class="label">33</a>
-Deut. viii. 9.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_34" href="#FNanchor_34" class="label">34</a>
-Beitrage, vi. 81.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_35" href="#FNanchor_35" class="label">35</a>
-Plinii Hist. Nat. xxxiv. 1.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_36" href="#FNanchor_36" class="label">36</a>
-Plinii Hist. Nat. xxxiv. 2.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_37" href="#FNanchor_37" class="label">37</a>
-Pliny’s phrase is <i>plumbum argentorium</i>. But that the addition
-was tin, and consequently that plumbum argentorium
-meant tin, we have the evidence of Klaproth, who analyzed
-several of these bronze statues, and found them composed of
-copper, lead, and tin.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_38" href="#FNanchor_38" class="label">38</a>
-Beitrage, vi. 89.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_39" href="#FNanchor_39" class="label">39</a>
-Beitrage, vi. 118. The statue in question was known by the
-name of “The Statue of P&uuml;strichs,” at Sondershausen.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_40" href="#FNanchor_40" class="label">40</a>
-Ibid., p. 127.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_41" href="#FNanchor_41" class="label">41</a>
-Ibid., p. 132.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_42" href="#FNanchor_42" class="label">42</a>
-Ibid., p. 134.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_43" href="#FNanchor_43" class="label">43</a>
-Plinii Hist. Nat. xxxiv. 11.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_44" href="#FNanchor_44" class="label">44</a>
-Lib. v. c. 117.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_45" href="#FNanchor_45" class="label">45</a>
-See Plinii Hist. Nat. xxxiv. 13.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_46" href="#FNanchor_46" class="label">46</a>
-Genesis iv. 22.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_47" href="#FNanchor_47" class="label">47</a>
-Deut. iv. 20.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_48" href="#FNanchor_48" class="label">48</a>
-Deut. viii. 9.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_49" href="#FNanchor_49" class="label">49</a>
-Numbers xxxv. 16.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_50" href="#FNanchor_50" class="label">50</a>
-Levit. i. 17.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_51" href="#FNanchor_51" class="label">51</a>
-Deut. xviii. 5.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_52" href="#FNanchor_52" class="label">52</a>
-Deut. xxvii. 5.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_53" href="#FNanchor_53" class="label">53</a>
-Iliad, lib. xxiii. l. 826.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_54" href="#FNanchor_54" class="label">54</a>
-Xenophon’s Anabasis, v. 5.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_55" href="#FNanchor_55" class="label">55</a>
-Plinii Hist. Nat. xxxiv. 14.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_56" href="#FNanchor_56" class="label">56</a>
-Numbers xxxi. 22.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_57" href="#FNanchor_57" class="label">57</a>
-Iliad xi. 25.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_58" href="#FNanchor_58" class="label">58</a>
-Lib. xxxiv. c. 17.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_59" href="#FNanchor_59" class="label">59</a>
-Numbers xxxi. 22.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_60" href="#FNanchor_60" class="label">60</a>
-Dioscorides, lib. v. c. 110.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_61" href="#FNanchor_61" class="label">61</a>
-Lib. v. c. 110.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_62" href="#FNanchor_62" class="label">62</a>
-The ancients were in the habit of extracting mercury from
-cinnabar, by a kind of imperfect distillation. The native mercury
-they called <i>argentum vivum</i>, that from cinnabar <i>hydrargyrus</i>.
-See Plinii Hist. Nat. xxxiii. 8.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_63" href="#FNanchor_63" class="label">63</a>
-Lib. v. c. 99.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_64" href="#FNanchor_64" class="label">64</a>
-Lib. xxxiii. c. 6.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_65" href="#FNanchor_65" class="label">65</a>
-2 Kings ix. 30.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_66" href="#FNanchor_66" class="label">66</a>
-Chap. 23. v. 40, the Vulgate has it εστιβιζω τους οφθαλμους
-σουo.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_67" href="#FNanchor_67" class="label">67</a>
-Hartmanni Praxis Chemiatrica, p. 598.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_68" href="#FNanchor_68" class="label">68</a>
-Plinii Hist. Nat. xxxiii. 6.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_69" href="#FNanchor_69" class="label">69</a>
-Περι των λιθων, c. 71.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_70" href="#FNanchor_70" class="label">70</a>
-Bucol. iv. 1. 45.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_71" href="#FNanchor_71" class="label">71</a>
-Plinii Hist. Nat. xxxv. 6.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_72" href="#FNanchor_72" class="label">72</a>
-Phil. Trans. 1814, p. 97.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_73" href="#FNanchor_73" class="label">73</a>
-Job xxviii. 17.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_74" href="#FNanchor_74" class="label">74</a>
-Plinii Hist. Nat. xxxvi. 26.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_75" href="#FNanchor_75" class="label">75</a>
-Beitrage, vi. 140.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_76" href="#FNanchor_76" class="label">76</a>
-Ibid., p. 142.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_77" href="#FNanchor_77" class="label">77</a>
-Beitrage, p. 144.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_78" href="#FNanchor_78" class="label">78</a>
-Phil. Trans. 1815, p. 108.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_79" href="#FNanchor_79" class="label">79</a>
-Plinii Hist. Nat. xxxvii. 2.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_80" href="#FNanchor_80" class="label">80</a>
-Plinii Hist. Nat. xxxvii. 2.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_81" href="#FNanchor_81" class="label">81</a>
-This opinion was first formed by Baron Born, and stated
-in his Catalogue of Minerals in M. E. Raab’s collection, i. 356.
-But the evidences in favour of it have been brought forward
-with great clearness and force by M. Roziere. See Jour. de
-Min. xxxvi. 193.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_82" href="#FNanchor_82" class="label">82</a>
-Plinii Hist. Nat. ix. 38.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_83" href="#FNanchor_83" class="label">83</a>
-Ibid., ix. 36.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_84" href="#FNanchor_84" class="label">84</a>
-Plinii Hist. Nat. ix. c. 38.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_85" href="#FNanchor_85" class="label">85</a>
-Exodus xxv. 4.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_86" href="#FNanchor_86" class="label">86</a>
-See Bancroft on Permanent Colours, i. 79.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_87" href="#FNanchor_87" class="label">87</a>
-Plinii Hist. Nat. xxxv. 11.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_88" href="#FNanchor_88" class="label">88</a>
-Plinii Hist. Nat. xxviii. 12. The passage of Pliny is as
-follows: “Prodest et sapo; Gallorum hoc inventum rutilandis
-capillis ex sevo et cinere. Optimus fagino et caprino, duobus
-modis, spissus et liquidus: uterque apud Germanos majore in
-usu viris quam feminis.”</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_89" href="#FNanchor_89" class="label">89</a>
-Hist. of Inventions, iii. 239.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_90" href="#FNanchor_90" class="label">90</a>
-Genesis ix. 20.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_91" href="#FNanchor_91" class="label">91</a>
-“Oin&ocirc; d’ ek krithe&ocirc;n pepoi&ecirc;men&ocirc; diachreontai; ou gar sphi eisi
-en t&ecirc; ch&ocirc;r&ecirc; ampeloi.” Euterpe chap. 77.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_92" href="#FNanchor_92" class="label">92</a>
-De Moribus Germanorum, c. 23. “Potui humor ex hordeo
-aut frumento in quandam similitudinem vini corruptus.”</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_93" href="#FNanchor_93" class="label">93</a>
-Plinii Hist. Nat. xxxv. 12.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_94" href="#FNanchor_94" class="label">94</a>
-The word topazo is said by Pliny to signify, in the language
-of the Troglodytes, <i>to seek</i>.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_95" href="#FNanchor_95" class="label">95</a>
-Plinii Hist. Nat. ii. 63.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_96" href="#FNanchor_96" class="label">96</a>
-Beitrage, iii. 104.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_97" href="#FNanchor_97" class="label">97</a>
-“Quoniam inficiendis claro colore lanis candidum liquidumque
-utilissimum est, contraque fuscis et obscuris nigrum.”&mdash;<i>Plinii</i>,
-xxxv. 15.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_98" href="#FNanchor_98" class="label">98</a>
-See Dioscorides, lib. v. c. 123. Plinii Hist. Nat. xxxv. 18.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_99" href="#FNanchor_99" class="label">99</a>
-Matthew v. 13.&mdash;“Ὑμεις εστε το ἁλας της γης· εαν δε το
-ἁλας μωρανθη, εν τινι ἁλισθησεται· εις ουδεν ισχωει ετι ει μη
-βληθηναι εξω, και καταπατεισθαι ὑπο των ανθρωπων.”</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_100" href="#FNanchor_100" class="label">100</a>
-Proverbs xxv. 20.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_101" href="#FNanchor_101" class="label">101</a>
-“Cujus asperitas visque in tabem margeritas resolvit.”</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_102" href="#FNanchor_102" class="label">102</a>
-Plinii Hist. Nat. ix. 35.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_103" href="#FNanchor_103" class="label">103</a>
-For a fuller account of the progress of science among the
-Arabians than would be consistent with this work, the reader is
-referred to Mortucla’s Hist. des Math&eacute;matiques, i. 351; Sprengel’s
-Hist. de la M&eacute;decine, ii. 246.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_104" href="#FNanchor_104" class="label">104</a>
-Boerhaave’s Chemistry (Shaw’s translation), i. 26. <i>Note.</i></p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_105" href="#FNanchor_105" class="label">105</a>
-Golius was not, however, the first translator of Geber.
-A translation of the longest and most important of his tracts
-into Latin appeared in Strasburg, in 1529. There was another
-translation published in Italy, from a manuscript in the Vatican.
-There probably might be other translations. I have
-compared four different copies of Geber’s works, and found
-some differences, though not very material. I have followed
-Russel’s English translation most commonly, as upon the whole
-the most accurate that I have seen.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_106" href="#FNanchor_106" class="label">106</a>
-Of course I exclude the writings of the Greek ecclesiastics
-mentioned in a previous part of this work, which still continue
-in manuscript; because, I am ignorant of what they
-contain.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_107" href="#FNanchor_107" class="label">107</a>
-Sum of Perfection, book ii. part i. chap. 5.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_108" href="#FNanchor_108" class="label">108</a>
-Ibid.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_109" href="#FNanchor_109" class="label">109</a>
-Ibid., chap. 6.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_110" href="#FNanchor_110" class="label">110</a>
-Sum of Perfection, book ii. part i. chap. 7.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_111" href="#FNanchor_111" class="label">111</a>
-Ibid.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_112" href="#FNanchor_112" class="label">112</a>
-Ibid., chap. 8.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_113" href="#FNanchor_113" class="label">113</a>
-Ibid.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_114" href="#FNanchor_114" class="label">114</a>
-Ibid., chap. 9.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_115" href="#FNanchor_115" class="label">115</a>
-Sum of Perfection, book ii. part i. chap. 9.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_116" href="#FNanchor_116" class="label">116</a>
-Ibid.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_117" href="#FNanchor_117" class="label">117</a>
-Ibid., chap. 10.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_118" href="#FNanchor_118" class="label">118</a>
-Investigation and Search of Perfection, chap. 3.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_119" href="#FNanchor_119" class="label">119</a>
-Invention of Verity, chap. 4.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_120" href="#FNanchor_120" class="label">120</a>
-Search of Perfection, chap. 3.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_121" href="#FNanchor_121" class="label">121</a>
-De Investigatione Perfect. chap. 4.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_122" href="#FNanchor_122" class="label">122</a>
-Invention of Verity, chap. 23.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_123" href="#FNanchor_123" class="label">123</a>
-Ibid., chap. 21.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_124" href="#FNanchor_124" class="label">124</a>
-Ibid., chap. 23.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_125" href="#FNanchor_125" class="label">125</a>
-Invention of Verity, chap. 8.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_126" href="#FNanchor_126" class="label">126</a>
-Sum of Perfection, book i. part iii. chap. 4.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_127" href="#FNanchor_127" class="label">127</a>
-Ibid., chap. 6.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_128" href="#FNanchor_128" class="label">128</a>
-Ibid.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_129" href="#FNanchor_129" class="label">129</a>
-Sum of Perfection, book i. part iv. chap. 16.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_130" href="#FNanchor_130" class="label">130</a>
-Invention of Verity, chap. 10.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_131" href="#FNanchor_131" class="label">131</a>
-Sum of Perfection, book i. part iii. chap. 4.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_132" href="#FNanchor_132" class="label">132</a>
-Ibid.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_133" href="#FNanchor_133" class="label">133</a>
-Invention of Verity, chap. 6.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_134" href="#FNanchor_134" class="label">134</a>
-Invention of Verity, chap. 7.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_135" href="#FNanchor_135" class="label">135</a>
-Sum of Perfection, book ii. part. ii. chap. 11.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_136" href="#FNanchor_136" class="label">136</a>
-Invention of Verity, chap. 14.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_137" href="#FNanchor_137" class="label">137</a>
-Ibid., chap. 4 and 12.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_138" href="#FNanchor_138" class="label">138</a>
-Sum of Perfection, book ii. part iii. chap. 10.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_139" href="#FNanchor_139" class="label">139</a>
-Invention of Verity, chap. 4.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_140" href="#FNanchor_140" class="label">140</a>
-Sum of Perfection, book i. part iii. chap. 8.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_141" href="#FNanchor_141" class="label">141</a>
-Ibid., book i. part iii. chap. 8.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_142" href="#FNanchor_142" class="label">142</a>
-Investigation of Perfections, chap. 11.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_143" href="#FNanchor_143" class="label">143</a>
-See Testamentum Paracelsi, passim.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_144" href="#FNanchor_144" class="label">144</a>
-“Hispania, Portugallia, Anglia, Borussia, Lithuania, Polonia,
-Pannonia, Valachia, Transylvania, Croatia, Illyrico, immo omnibus
-totius Europ&aelig; nationibus peragratis, undeque non solum
-apud medicos, sed et chirurgos, tonsores, aniculas, magos, chymistas,
-nobiles ac ignobiles, optima, selectiora ac secretiora,
-qu&aelig; uspiam extarent remedia, inquisivi acriter.”&mdash;<i>Pr&aelig;fatio
-Chirurgi&aelig; Magn&aelig;.</i> Opera Paracelsi, tom. iii.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_145" href="#FNanchor_145" class="label">145</a>
-See the dedication to his treatise <i>De Gradibus et Compositionibus
-Receptorum et Naturalium</i>. Opera Paracelsi, vol. ii.
-p. 144. I always refer to the folio edition of Paracelsus’s works,
-in three volumes, published at Geneva in 1658, by M. de Tournes,
-which is the edition in my possession.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_146" href="#FNanchor_146" class="label">146</a>
-Opera Paracelsi, i. 485.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_147" href="#FNanchor_147" class="label">147</a>
-There were two laudanums of Paracelsus; one was <i>red
-oxide of mercury</i>, the other consisted of the following substances:
-Chloride of antimony, 1 ounce; hepatic aloes, 1 ounce;
-rose-water, &frac12; ounce; saffron, 3 ounces; ambergris, 2 drams.
-All these well mixed.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_148" href="#FNanchor_148" class="label">148</a>
-Opera Paracelsi, iii, 101.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_149" href="#FNanchor_149" class="label">149</a>
-Opera Paracelsi, i. 243.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_150" href="#FNanchor_150" class="label">150</a>
-Ibid., ii. 84.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_151" href="#FNanchor_151" class="label">151</a>
-Opera Paracelsi, i. 328.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_152" href="#FNanchor_152" class="label">152</a>
-“Qui elegantiorem optat, ille eum condat.”&mdash;<i>Ibid.</i></p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_153" href="#FNanchor_153" class="label">153</a>
-Archidoxorum, lib. i. Opera Paracelsi, ii. 4.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_154" href="#FNanchor_154" class="label">154</a>
-De longa Vita. Opera Paracelsi, ii. 46.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_155" href="#FNanchor_155" class="label">155</a>
-Archidoxorum, lib. viii. Opera Paracelsi, ii. 29. In this
-book he gives the method of preparing the elixir of life. It seems
-to have been nothing else than a solution of <i>common salt</i> in water;
-for the quintessence of gold, with which this solution was to be
-mixed, was doubtless an imaginary substance.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_156" href="#FNanchor_156" class="label">156</a>
-Modus Pharmacandi. Opera Paracelsi, i. 811.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_157" href="#FNanchor_157" class="label">157</a>
-Liber de Nymphis, Sylphis, Pygm&aelig;is, et Salamandris, et de
-ceteris Spiritibus. Opera Paracelsi, ii. 388. If the reader can
-understand this singular book, his sagacity will be greater than
-mine.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_158" href="#FNanchor_158" class="label">158</a>
-Paragrani Alterius, tract. ii. Opera Paracelsi, i. 235. The
-reader who has the curiosity to consult this tract, will find
-abundance of similar stuff, which I did not think worth translating.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_159" href="#FNanchor_159" class="label">159</a>
-Philosophi&aelig;, tract. iv. De Mineralibus. Opera Paracelsi, ii.
-282. “Quando ergo hoc modo metalla fiunt et producuntur,
-dum scilicet verus metallicus fluxus et ductilitas aufertur et
-in septem metalla distribuitur; residentia qu&aelig;dam manet in
-Ares, instar fœt&ucirc;m trium primorum. Ex hac nescitur zinetum,
-quod et metallum est et non est. Sic et bisemutum et huic
-similia alia partim fluida, partim ductilia sunt&mdash;Zinetum
-maxima ex parte spuria soboles est ex cupro et bisemutum de
-stanno. Ex hisce duobus omnium plurim&aelig; f&aelig;ces et remanenti&aelig;
-in Ares fiunt.”</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_160" href="#FNanchor_160" class="label">160</a>
-It was as follows: “Collegium medicorum in Academia Parisiensi
-legitime congregatum, audita renunciatione sensorum,
-quibus demandata erat provincia examinandi apologiam sub
-nomine Mayerni Turqueti editam, ipsam unanimi consensu
-damnat, tanquam famosum libellum, mendacibus conviciis et
-impudentibus calumniis refertum, qu&aelig; nonnisi ab homine
-imperito, impudenti, temulento et furioso profiteri potuerunt.
-Ipsum Turquetum indignum judicat, qui usquam medicinam
-faciat, propter temeritatem, impudentiam et ver&aelig; medicin&aelig;
-ignorantiam. Omnes vero medicos, qui ubique gentium et
-locorum medicinam exercent, hortatur ut ipsum Turquetum
-similiaque hominum et opinionum portenta, a se suisque finibus
-arceant et in Hippocratis ac Galeni doctrina constantes permaneant:
-et prohibuit ne quis ex hoc medicorum Parisiensium
-ordine cum Turqueto eique similibus medica consilia ineat.
-Qui secus fecerit, schol&aelig; ornamentis et academi&aelig; privilegiis
-privabitur, et de regentium numero expungetur.&mdash;Datum Luteti&aelig;
-in scholis superioribus, die 5 Decembris, anno salutis, 1603.”</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_161" href="#FNanchor_161" class="label">161</a>
-J. B. Van Helmont, Opera Omnia, p. 100. The edition which
-I quote from was printed at Frankfort, in 1682, at the expense of
-John Justus Erythropilus, in a very thick quarto volume.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_162" href="#FNanchor_162" class="label">162</a>
-Van Helmont, Opera Omnia, p. 104.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_163" href="#FNanchor_163" class="label">163</a>
-Ibid., p. 105.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_164" href="#FNanchor_164" class="label">164</a>
-De Flatibus, sect. 49. Opera Van Helmont, p. 405.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_165" href="#FNanchor_165" class="label">165</a>
-Ibid., p. 408.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_166" href="#FNanchor_166" class="label">166</a>
-Ibid., p. 409.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_167" href="#FNanchor_167" class="label">167</a>
-In his Magnum Oportet, sect. 39, p. 151, he gives an
-account of the origin of metals in the earth, and in that section
-there is a description of <i>bur</i>, which those who are anxious to
-understand the ideas of the author on this subject may consult.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_168" href="#FNanchor_168" class="label">168</a>
-As an example of the prescriptions of Sylvius, we give the
-following for malignant fever:
-
-<span class="table">
-  <span class="trow">
-    <span class="tcell"><i>R.</i></span>
-    <span class="tcell">Theriac. veter. ᴣij</span>
-  </span>
-  <span class="trow">
-    <span class="tcell">&nbsp;</span>
-    <span class="tcell">Antim. diaphor. ᴣj</span>
-  </span>
-  <span class="trow">
-    <span class="tcell">&nbsp;</span>
-    <span class="tcell">Syrup. Card. Benedic. ℥ij</span>
-  </span>
-  <span class="trow">
-    <span class="tcell">&nbsp;</span>
-    <span class="tcell">Aq. prophylact. ℥j</span>
-  </span>
-  <span class="trow">
-    <span class="tcell">&nbsp;</span>
-    <span class="tcell">&mdash; Cinnam. ℥ss</span>
-  </span>
-  <span class="trow">
-    <span class="tcell">&nbsp;</span>
-    <span class="tcell">&mdash; Scabios. ℥ij</span>
-  </span>
-  <span class="trow">
-    <span class="tcell">&nbsp;</span>
-    <span class="tcell tdr">M. D.</span>
-  </span>
-</span></p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_169" href="#FNanchor_169" class="label">169</a>
-Shaw’s Boyle, iii, 424.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_170" href="#FNanchor_170" class="label">170</a>
-De Ortu et Progressu Chemi&aelig;. <i>Hafni&aelig;</i>, 1674.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_171" href="#FNanchor_171" class="label">171</a>
-While travelling in a tract-boat, one of his fellow-travellers
-more orthodox than well informed, attacked the system of Spinoza
-with so little spirit, that Boerhaave was tempted to ask him if
-he had ever read Spinoza. The polemic was obliged to confess
-that he had not; but he was so much provoked at this public exposure
-of his ignorance, that he propagated the report of Boerhaave’s
-attachment to Spinozism, and thus blasted his intention
-of becoming a clergyman.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_172" href="#FNanchor_172" class="label">172</a>
-Mem. Paris, 1734, p. 539.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_173" href="#FNanchor_173" class="label">173</a>
-Phil. Trans. 1733. No. 430, p. 145.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_174" href="#FNanchor_174" class="label">174</a>
-It is entitled, “El Arte de los Metales, en que se ensena
-el verdadero beneficio de los de oro y plata por azoque,” &amp;c.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_175" href="#FNanchor_175" class="label">175</a>
-Born’s New Process of Amalgamation, translated by
-Raspe, p. 11.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_176" href="#FNanchor_176" class="label">176</a>
-I have never seen a copy of this last work; it must have
-been valuable, as it was the book from which Scheele derived
-the first rudiments of his knowledge.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_177" href="#FNanchor_177" class="label">177</a>
-For 1711, p. 238.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_178" href="#FNanchor_178" class="label">178</a>
-Mem. Paris, 1718, p. 202; and 1720, p. 20.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_179" href="#FNanchor_179" class="label">179</a>
-In the sixth chemical thesis, in the second supplement to
-the Physica Subterranea (page 791, Stahl’s Edition. Lipsi&aelig;,
-1703), he says, “ubi etiam, continuato igne, ipsum sal volatile
-acquires, quod eadem methodo cum vitriolo seu spiritu aut oleo
-vitrioli, et oleo tartari, vel <i>borace</i> succedit.”</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_180" href="#FNanchor_180" class="label">180</a>
-“Primus in his facem pr&aelig;tulit Beccherus; eumque magno
-cum artis progressu sequentem videmus in ostendenda corporum
-analysi et synthesi chymica versatissimum et acutissimum&mdash;<i>Stahlium</i>.”</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_181" href="#FNanchor_181" class="label">181</a>
-There is a French translation of this work, entitled “Litheognosie,
-ou Examen Chymique des Pierres et des Terres en
-g&eacute;n&eacute;ral, et du Talc de la Topaz, et de la Steatite en particulier;
-avec une Dissertation sur le Feu et sur la Lumi&egrave;re.” Paris, 1753.
-With a continuation, constituting a second volume, in which all
-the experiments in the first volume are exhibited in the form of
-tables.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_182" href="#FNanchor_182" class="label">182</a>
-1763, p. 235.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_183" href="#FNanchor_183" class="label">183</a>
-I do not know what the true name was of which Macquer
-is a corruption. Ker is a Scottish name belonging to two noble
-families, the Duke of Roxburgh and the Marquis of Lothian;
-but I am not aware of M’Ker being a Scottish name: besides,
-neither of these families was attached to the house of Stuart.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_184" href="#FNanchor_184" class="label">184</a>
-Hist. de l’Acad. R. des Sciences, 1784, p. 24.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_185" href="#FNanchor_185" class="label">185</a>
-The preceding character of Dr. Black is from Professor
-Robison, who knew him intimately; and from Dr. Adam Ferguson,
-who was his next relation. See the preface to Dr. Black’s
-lectures. The portrait of Dr. Black prefixed to these lectures
-is an excellent likeness.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_186" href="#FNanchor_186" class="label">186</a>
-This I apprehend to be a little above the truth, the true
-specific gravity of carbonic acid gas being 1&middot;5277, that of air
-being unity.</p></div>
-
-<div class="footnote">
-
-<p><a id="Footnote_187" href="#FNanchor_187" class="label">187</a>
-The salts held in solution are in the state of bicarbonates
-of lime and magnesia. Boiling drives off half the carbonic acid,
-and the simple carbonates being insoluble are precipitated.</p></div></div>
-
-<div class="transnote">
-<h3>Transcriber’s Note:</h3>
-
-<p>Inconsistent spelling and hyphenation are as in the original.</p>
-
-<p>Page 51: “zeb” changed to read “zahav”.</p>
-
-<p>Page 53: “kemep” changed to read “keseph”.</p>
-
-<p>Page 54: “necheshet” changed to read “nechooshat”.</p>
-
-<p>Page 63: “berezel” changed to read “barzel”.</p>
-
-<p>Page 63: “ber” changed to read “bar”.</p>
-
-<p>Page 63: “nezel” changed to read “nazal”.</p>
-
-<p>Page 76: “arrenichon” changed to read “arrhenichon”.</p>
-
-<p>Page 81: “chuanos” changed to read “kyanos”.</p>
-</div>
-
-
-
-
-
-
-
-
-<pre>
-
-
-
-
-
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