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
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.
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.
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.
C. WHITING, BEAUFORT HOUSE, STRAND.
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No. X.—PINDAR (translated by the Rev. C. A. Wheelwright, Prebendary of Lincoln); and ANACREON, by Mr. Thomas Bourne.
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.
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.
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.
6 Shaw’s Translation of Boerhaave’s Chemistry, i. 20.
7 Genesis iv. 22.
8 De Iside and Osiride, c. 5.
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.
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.”
11 Preface to Mangetus’s Bibliotheca Chemica Curiosa.
12 Ibid.
13 Bergmann, Opusc. iv. 121.
14 I allude to his Manuale sive de Lapide Philosophico Medicinali. Opera Paracelsi, ii. 133. Folio edition. Geneva, 1658.
15 Wilson’s Chemistry, p. 375.
16 Ibid., p. 379.
17 Probably corrosive sublimate.
18 Probably calomel.
19 Mangeti Bibliothecæ Chemicæ Præfatio.
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.
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.
22 Mem. Paris, 1722, p. 61.
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.
24 Sprengel’s History of Medicine, iv. 368.
25 It is curious that Olaus Borrichius omits Albertus Magnus in the list of alchymistical writers that he has given.
26 This tract and the next, which is of considerable length, will be found in Mangetus’s Bibliotheca Chemica Curiosa, i. 613.
27 Gmelin’s Geschitte der Chemie, i. 74.
28 Exodus xi. 2—xxv. 11, 12, 13, 17, 18, 24, 25, 26—xxviii. 8—xxxii. 2, &c.
29 Genesis xlvii. 14.
30 For example, Exodus xi. 2—xxvi. 19, 21—xxvii. 10, 11, 17, &c.
31 Genesis iv. 22.
32 For example, Exodus xxvii. 2, 3, 4, 6, 10, 11, 17, 18, 19—xxx. 18, &c. Numbers xxi. 9.
33 Deut. viii. 9.
34 Beitrage, vi. 81.
35 Plinii Hist. Nat. xxxiv. 1.
36 Plinii Hist. Nat. xxxiv. 2.
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.
38 Beitrage, vi. 89.
39 Beitrage, vi. 118. The statue in question was known by the name of “The Statue of Püstrichs,” at Sondershausen.
40 Ibid., p. 127.
41 Ibid., p. 132.
42 Ibid., p. 134.
43 Plinii Hist. Nat. xxxiv. 11.
44 Lib. v. c. 117.
45 See Plinii Hist. Nat. xxxiv. 13.
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.
54 Xenophon’s Anabasis, v. 5.
55 Plinii Hist. Nat. xxxiv. 14.
56 Numbers xxxi. 22.
57 Iliad xi. 25.
58 Lib. xxxiv. c. 17.
59 Numbers xxxi. 22.
60 Dioscorides, lib. v. c. 110.
61 Lib. v. c. 110.
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.
63 Lib. v. c. 99.
64 Lib. xxxiii. c. 6.
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.
69 Περι των λιθων, c. 71.
70 Bucol. iv. 1. 45.
71 Plinii Hist. Nat. xxxv. 6.
72 Phil. Trans. 1814, p. 97.
73 Job xxviii. 17.
74 Plinii Hist. Nat. xxxvi. 26.
75 Beitrage, vi. 140.
76 Ibid., p. 142.
77 Beitrage, p. 144.
78 Phil. Trans. 1815, p. 108.
79 Plinii Hist. Nat. xxxvii. 2.
80 Plinii Hist. Nat. xxxvii. 2.
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.
82 Plinii Hist. Nat. ix. 38.
83 Ibid., ix. 36.
84 Plinii Hist. Nat. ix. c. 38.
85 Exodus xxv. 4.
86 See Bancroft on Permanent Colours, i. 79.
87 Plinii Hist. Nat. xxxv. 11.
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.”
89 Hist. of Inventions, iii. 239.
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.”
93 Plinii Hist. Nat. xxxv. 12.
94 The word topazo is said by Pliny to signify, in the language of the Troglodytes, to seek.
95 Plinii Hist. Nat. ii. 63.
96 Beitrage, iii. 104.
97 “Quoniam inficiendis claro colore lanis candidum liquidumque utilissimum est, contraque fuscis et obscuris nigrum.”—Plinii, xxxv. 15.
98 See Dioscorides, lib. v. c. 123. Plinii Hist. Nat. xxxv. 18.
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.”
100 Proverbs xxv. 20.
101 “Cujus asperitas visque in tabem margeritas resolvit.”
102 Plinii Hist. Nat. ix. 35.
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.
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.
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.
107 Sum of Perfection, book ii. part i. chap. 5.
108 Ibid.
109 Ibid., chap. 6.
110 Sum of Perfection, book ii. part i. chap. 7.
111 Ibid.
112 Ibid., chap. 8.
113 Ibid.
114 Ibid., chap. 9.
115 Sum of Perfection, book ii. part i. chap. 9.
116 Ibid.
117 Ibid., chap. 10.
118 Investigation and Search of Perfection, chap. 3.
119 Invention of Verity, chap. 4.
120 Search of Perfection, chap. 3.
121 De Investigatione Perfect. chap. 4.
122 Invention of Verity, chap. 23.
123 Ibid., chap. 21.
124 Ibid., chap. 23.
125 Invention of Verity, chap. 8.
126 Sum of Perfection, book i. part iii. chap. 4.
127 Ibid., chap. 6.
128 Ibid.
129 Sum of Perfection, book i. part iv. chap. 16.
130 Invention of Verity, chap. 10.
131 Sum of Perfection, book i. part iii. chap. 4.
132 Ibid.
133 Invention of Verity, chap. 6.
134 Invention of Verity, chap. 7.
135 Sum of Perfection, book ii. part. ii. chap. 11.
136 Invention of Verity, chap. 14.
137 Ibid., chap. 4 and 12.
138 Sum of Perfection, book ii. part iii. chap. 10.
139 Invention of Verity, chap. 4.
140 Sum of Perfection, book i. part iii. chap. 8.
141 Ibid., book i. part iii. chap. 8.
142 Investigation of Perfections, chap. 11.
143 See Testamentum Paracelsi, passim.
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.
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.
146 Opera Paracelsi, i. 485.
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.
148 Opera Paracelsi, iii, 101.
149 Opera Paracelsi, i. 243.
150 Ibid., ii. 84.
151 Opera Paracelsi, i. 328.
152 “Qui elegantiorem optat, ille eum condat.”—Ibid.
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.
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.
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.
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.”
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.”
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.
164 De Flatibus, sect. 49. Opera Van Helmont, p. 405.
165 Ibid., p. 408.
166 Ibid., p. 409.
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.
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.
169 Shaw’s Boyle, iii, 424.
170 De Ortu et Progressu Chemiæ. Hafniæ, 1674.
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.
172 Mem. Paris, 1734, p. 539.
173 Phil. Trans. 1733. No. 430, p. 145.
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.
175 Born’s New Process of Amalgamation, translated by Raspe, p. 11.
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.
177 For 1711, p. 238.
178 Mem. Paris, 1718, p. 202; and 1720, p. 20.
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.”
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.”
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.
182 1763, p. 235.
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.
184 Hist. de l’Acad. R. des Sciences, 1784, p. 24.
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.
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.
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.