Davy, Sir Humphry

Davy, Sir Humphry

SUBJECT AREA: Chemical technology, Mining and extraction technology

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b. 17 December 1778 Penzance, Cornwall, England

d. 29 May 1829 Geneva, Switzerland

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English chemist, discoverer of the alkali and alkaline earth metals and the halogens, inventor of the miner's safety lamp.

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Educated at the Latin School at Penzance and from 1792 at Truro Grammar School, Davy was apprenticed to a surgeon in Penzance. In 1797 he began to teach himself chemistry by reading, among other works, Lavoisier's elementary treatise on chemistry. In 1798 Dr Thomas Beddoes of Bristol engaged him as assistant in setting up his Pneumatic Institution to pioneer the medical application of the newly discovered gases, especially oxygen.

In 1799 he discovered the anaesthetic properties of nitrous oxide, discovered not long before by the chemist Joseph Priestley. He also noted its intoxicating qualities, on account of which it was dubbed "laughing-gas". Two years later Count Rumford, founder of the Royal Institution in 1800, appointed Davy Assistant Lecturer, and the following year Professor. His lecturing ability soon began to attract large audiences, making science both popular and fashionable.

Davy was stimulated by Volta's invention of the voltaic pile, or electric battery, to construct one for himself in 1800. That enabled him to embark on the researches into electrochemistry by which is chiefly known. In 1807 he tried decomposing caustic soda and caustic potash, hitherto regarded as elements, by electrolysis and obtained the metals sodium and potassium. He went on to discover the metals barium, strontium, calcium and magnesium by the same means. Next, he turned his attention to chlorine, which was then regarded as an oxide in accordance with Lavoisier's theory that oxygen was the essential component of acids; Davy failed to decompose it, however, even with the aid of electricity and concluded that it was an element, thus disproving Lavoisier's view of the nature of acids. In 1812 Davy published his Elements of Chemical Philosophy, in which he presented his chemical ideas without, however, committing himself to the atomic theory, recently advanced by John Dalton.

In 1813 Davy engaged Faraday as Assistant, perhaps his greatest service to science. In April 1815 Davy was asked to assist in the development of a miner's lamp which could be safely used in a firedamp (methane) laden atmosphere. The "Davy lamp", which emerged in January 1816, had its flame completely surrounded by a fine wire mesh; George Stephenson's lamp, based on a similar principle, had been introduced into the Northumberland pits several months earlier, and a bitter controversy as to priority of invention ensued, but it was Davy who was awarded the prize for inventing a successful safety lamp.

In 1824 Davy was the first to suggest the possibility of conferring cathodic protection to the copper bottoms of naval vessels by the use of sacrificial electrodes. Zinc and iron were found to be equally effective in inhibiting corrosion, although the scheme was later abandoned when it was found that ships protected in this way were rapidly fouled by weeds and barnacles.

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Principal Honours and Distinctions

Knighted 1812. FRS 1803; President, Royal Society 1820. Royal Society Copley Medal 1805.

Bibliography

1812, Elements of Chemical Philosophy.

1839–40, The Collected Works of Sir Humphry Davy, 9 vols, ed. John Davy, London.

Further Reading

J.Davy, 1836, Memoirs of the Life of Sir Humphry Davy, London (a classic biography). J.A.Paris, 1831, The Life of Sir Humphry Davy, London (a classic biography). H.Hartley, 1967, Humphry Davy, London (a more recent biography).

J.Z.Fullmer, 1969, Cambridge, Mass, (a bibliography of Davy's works).

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Davy

n. mannelijke voornaam; familienaam; Davy, Sir Humphry (1778-1829), Engelse chemicus

Davy

→ Davylamp Davylamp/

Chemical technology

See also: INDEX BY SUBJECT AREA

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Abel, Sir Frederick August

Argand, François-Pierre Amis

Baekeland, Leo Hendrik

Bell, Sir Isaac Lowthian

Bergius, Friedrich Carl Rudolf

Bissell, George Henry

Bosch, Carl

Bowser, Sylvanus F.

Bunsen, Robert Wilhelm

Caro, Heinrich

Carothers, Wallace Hume

Castner, Hamilton Young

Chevreul, Michel Eugène

Coffey, Aeneas

Crawford, John William Croom

Cross, Charles Frederick

Davy, Sir Humphry

Deacon, Henry

Dickson, J.T.

Drummond, Thomas

Gesner, Abraham

Gibson, R.O.

Goodyear, Charles

Gossage, William

Haber, Fritz

Hancock, Thomas

Hofmann, August Wilhelm von

Hyatt, John Wesley

Lavoisier, Antoine Laurent

Leblanc, Nicolas

Liebig, Justus von

Linde, Carl von

Lundstrom, Johan E.

MacArthur, John Stewart

Macintosh, Charles

Mansfield, Charles Blachford

Maxwell, James Clerk

Messel, Rudolf

Moissan, Ferdinand-Frédéric-Henri

Mond, Ludwig

Monro, Philip Peter

Muspratt, James

Neri, Antonio Ludovico

Nobel, Alfred Bernhard

Nobel, Immanuel

Parkes, Alexander

Pasteur, Louis

Perkin, Sir William Henry

Pilkington, Sir Lionel Alexander Bethune

Ravenscroft, George

Roebuck, John

Schrötter, Anton von

Sobrero, Ascanio

Solvay, Ernest

Spence, Peter

Staudinger, Hermann

Tennant, Charles

Walton, Frederick

Ward, Joshua

Weldon, Walter

Welsbach, Baron Carl Auer von

Whinfield, John Rex

Young, James

Zeng Gonglian

Mining and extraction technology

See also: INDEX BY SUBJECT AREA

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Albert, Wilhelm August Julius

Beaumont, Huntingdon

Bergius, Friedrich Carl Rudolf

Bickford, William

Biringuccio, Vanoccio Vincenzio Agustino Luca

Bissell, George Henry

Blackett, William Cuthbert

Blenkinsop, John

Born, Ignaz Edler von

Brandt, Alfred

Brunel, Sir Marc Isambard

Buddle, John

Chaudron, Joseph

Coster, John

Crælius, Per Anton

Curr, John

Davy, Sir Humphry

Dörell, Georg Ludwig Wilhelm

Drake, Edwin Laurentine

Ercker, Lazarus

Fauvelle, Pierre-Pascal

Garforth, William Edward

Gilbert, John

Gilbert, Thomas

Glenck, Karl Christian Friedrich

Greathead, James Henry

Gurney, Sir Goldsworthy

Hair, Thomas H.

Hedley, William

Ingersoll, Simon

Jobard, Jean-Baptiste-Ambroise Marcelin

Kegel, Karl

Kind, Karl Gotthelf

Koepe, Friedrich

Leschot, Georges Auguste

Leupold, Jacob

Lucas, Anthony Francis

Menzies, Michael

Merivale, John Herman

Nobel, Immanuel

Oeynhausen, Karl von

Polhem, Christopher

Pötsch, Friedrich Hermann

Raky, Anton

Rammler, Erich

Rateau, Auguste Camille-Edmond

Rittinger, Peter von

Rowland, Thomas Fitch

Sommeiller, Germain

Stanley, Robert Crooks

Thompson, Benjamin

Treadgold, Arthur Newton Christian

Williams, Thomas

Wolf, Carl

Faraday, Michael

SUBJECT AREA: Electricity

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b. 22 September 1791 Newington, Surrey, England

d. 25 August 1867 London, England

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English physicist, discoverer of the principles of the electric motor and dynamo.

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Faraday's father was a blacksmith recently moved south from Westmorland. The young Faraday's formal education was limited to attendance at "a Common Day School", and then he worked as an errand boy for George Riebau, a bookseller and bookbinder in London's West End. Riebau subsequently took him as an apprentice bookbinder, and Faraday seized every opportunity to read the books that came his way, especially scientific works.

A customer in the shop gave Faraday tickets to hear Sir Humphry Davy lecturing at the Royal Institution. He made notes of the lectures, bound them and sent them to Davy, asking for scientific employment. When a vacancy arose for a laboratory assistant at the Royal Institution, Davy remembered Faraday, who he took as his assistant on an 18- month tour of France, Italy and Switzerland (despite the fact that Britain and France were at war!). The tour, and especially Davy's constant company and readiness to explain matters, was a scientific education for Faraday, who returned to the Royal Institution as a competent chemist in his own right. Faraday was interested in electricity, which was then viewed as a branch of chemistry. After Oersted's announcement in 1820 that an electric current could affect a magnet, Faraday devised an arrangement in 1821 for producing continuous motion from an electric current and a magnet. This was the basis of the electric motor. Ten years later, after much thought and experiment, he achieved the converse of Oersted's effect, the production of an electric current from a magnet. This was magneto-electric induction, the basis of the electric generator.

Electrical engineers usually regard Faraday as the "father" of their profession, but Faraday himself was not primarily interested in the practical applications of his discoveries. His driving motivation was to understand the forces of nature, such as electricity and magnetism, and the relationship between them. Faraday delighted in telling others about science, and studied what made a good scientific lecturer. At the Royal Institution he introduced the Friday Evening Discourses and also the Christmas Lectures for Young People, now televised in the UK every Christmas.

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Bibliography

1991, Curiosity Perfectly Satisfyed. Faraday's Travels in Europe 1813–1815, ed. B.Bowers and L.Symons, Peter Peregrinus (Faraday's diary of his travels with Humphry Davy).

Further Reading

L.Pearce Williams, 1965, Michael Faraday. A Biography, London: Chapman \& Hall; 1987, New York: Da Capo Press (the most comprehensive of the many biographies of Faraday and accounts of his work).

For recent short accounts of his life see: B.Bowers, 1991, Michael Faraday and the Modern World, EPA Press. G.Cantor, D.Gooding and F.James, 1991, Faraday, Macmillan.

J.Meurig Thomas, 1991, Michael Faraday and the Royal Institution, Adam Hilger.

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Babbage, Charles

SUBJECT AREA: Electronics and information technology

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b. 26 December 1791 Walworth, Surrey, England

d. 18 October 1871 London, England

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English mathematician who invented the forerunner of the modern computer.

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Charles Babbage was the son of a banker, Benjamin Babbage, and was a sickly child who had a rather haphazard education at private schools near Exeter and later at Enfield. Even as a child, he was inordinately fond of algebra, which he taught himself. He was conversant with several advanced mathematical texts, so by the time he entered Trinity College, Cambridge, in 1811, he was ahead of his tutors. In his third year he moved to Peterhouse, whence he graduated in 1814, taking his MA in 1817. He first contributed to the Philosophical Transactions of the Royal Society in 1815, and was elected a fellow of that body in 1816. He was one of the founders of the Astronomical Society in 1820 and served in high office in it.

While he was still at Cambridge, in 1812, he had the first idea of calculating numerical tables by machinery. This was his first difference engine, which worked on the principle of repeatedly adding a common difference. He built a small model of an engine working on this principle between 1820 and 1822, and in July of the latter year he read an enthusiastically received note about it to the Astronomical Society. The following year he was awarded the Society's first gold medal. He submitted details of his invention to Sir Humphry Davy, President of the Royal Society; the Society reported favourably and the Government became interested, and following a meeting with the Chancellor of the Exchequer Babbage was awarded a grant of £1,500. Work proceeded and was carried on for four years under the direction of Joseph Clement.

In 1827 Babbage went abroad for a year on medical advice. There he studied foreign workshops and factories, and in 1832 he published his observations in On the Economy of Machinery and Manufactures. While abroad, he received the news that he had been appointed Lucasian Professor of Mathematics at Cambridge University. He held the Chair until 1839, although he neither resided in College nor gave any lectures. For this he was paid between £80 and £90 a year! Differences arose between Babbage and Clement. Manufacture was moved from Clement's works in Lambeth, London, to new, fireproof buildings specially erected by the Government near Babbage's house in Dorset Square, London. Clement made a large claim for compensation and, when it was refused, withdrew his workers as well as all the special tools he had made up for the job. No work was possible for the next fifteen months, during which Babbage conceived the idea of his "analytical engine". He approached the Government with this, but it was not until eight years later, in 1842, that he received the reply that the expense was considered too great for further backing and that the Government was abandoning the project. This was in spite of the demonstration and perfectly satisfactory operation of a small section of the analytical engine at the International Exhibition of 1862. It is said that the demands made on manufacture in the production of his engines had an appreciable influence in improving the standard of machine tools, whilst similar benefits accrued from his development of a system of notation for the movements of machine elements. His opposition to street organ-grinders was a notable eccentricity; he estimated that a quarter of his mental effort was wasted by the effect of noise on his concentration.

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Principal Honours and Distinctions

FRS 1816. Astronomical Society Gold Medal 1823.

Bibliography

Babbage wrote eighty works, including: 1864, Passages from the Life of a Philosopher.

1832, On the Economy of Manufacture and Machinery.

July 1822, Letter to Sir Humphry Davy, PRS, on the Application of Machinery to the purpose of calculating and printing Mathematical Tables.

Further Reading

1961, Charles Babbage and His Calculating Engines: Selected Writings by Charles Babbage and Others, eds Philip and Emily Morrison, New York: Dover Publications.

IMcN

Stephenson, George

SUBJECT AREA: Land transport, Railways and locomotives

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b. 9 June 1781 Wylam, Northumberland, England

d. 12 August 1848 Tapton House, Chesterfield, England

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English engineer, "the father of railways".

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George Stephenson was the son of the fireman of the pumping engine at Wylam colliery, and horses drew wagons of coal along the wooden rails of the Wylam wagonway past the house in which he was born and spent his earliest childhood. While still a child he worked as a cowherd, but soon moved to working at coal pits. At 17 years of age he showed sufficient mechanical talent to be placed in charge of a new pumping engine, and had already achieved a job more responsible than that of his father. Despite his position he was still illiterate, although he subsequently learned to read and write. He was largely self-educated.

In 1801 he was appointed Brakesman of the winding engine at Black Callerton pit, with responsibility for lowering the miners safely to their work. Then, about two years later, he became Brakesman of a new winding engine erected by Robert Hawthorn at Willington Quay on the Tyne. Returning collier brigs discharged ballast into wagons and the engine drew the wagons up an inclined plane to the top of "Ballast Hill" for their contents to be tipped; this was one of the earliest applications of steam power to transport, other than experimentally.

In 1804 Stephenson moved to West Moor pit, Killingworth, again as Brakesman. In 1811 he demonstrated his mechanical skill by successfully modifying a new and unsatisfactory atmospheric engine, a task that had defeated the efforts of others, to enable it to pump a drowned pit clear of water. The following year he was appointed Enginewright at Killingworth, in charge of the machinery in all the collieries of the "Grand Allies", the prominent coal-owning families of Wortley, Liddell and Bowes, with authorization also to work for others. He built many stationary engines and he closely examined locomotives of John Blenkinsop's type on the Kenton \& Coxlodge wagonway, as well as those of William Hedley at Wylam.

It was in 1813 that Sir Thomas Liddell requested George Stephenson to build a steam locomotive for the Killingworth wagonway: Blucher made its first trial run on 25 July 1814 and was based on Blenkinsop's locomotives, although it lacked their rack-and-pinion drive. George Stephenson is credited with building the first locomotive both to run on edge rails and be driven by adhesion, an arrangement that has been the conventional one ever since. Yet Blucher was far from perfect and over the next few years, while other engineers ignored the steam locomotive, Stephenson built a succession of them, each an improvement on the last.

During this period many lives were lost in coalmines from explosions of gas ignited by miners' lamps. By observation and experiment (sometimes at great personal risk) Stephenson invented a satisfactory safety lamp, working independently of the noted scientist Sir Humphry Davy who also invented such a lamp around the same time.

In 1817 George Stephenson designed his first locomotive for an outside customer, the Kilmarnock \& Troon Railway, and in 1819 he laid out the Hetton Colliery Railway in County Durham, for which his brother Robert was Resident Engineer. This was the first railway to be worked entirely without animal traction: it used inclined planes with stationary engines, self-acting inclined planes powered by gravity, and locomotives.

On 19 April 1821 Stephenson was introduced to Edward Pease, one of the main promoters of the Stockton \& Darlington Railway (S \& DR), which by coincidence received its Act of Parliament the same day. George Stephenson carried out a further survey, to improve the proposed line, and in this he was assisted by his 18-year-old son, Robert Stephenson, whom he had ensured received the theoretical education which he himself lacked. It is doubtful whether either could have succeeded without the other; together they were to make the steam railway practicable.

At George Stephenson's instance, much of the S \& DR was laid with wrought-iron rails recently developed by John Birkinshaw at Bedlington Ironworks, Morpeth. These were longer than cast-iron rails and were not brittle: they made a track well suited for locomotives. In June 1823 George and Robert Stephenson, with other partners, founded a firm in Newcastle upon Tyne to build locomotives and rolling stock and to do general engineering work: after its Managing Partner, the firm was called Robert Stephenson \& Co.

In 1824 the promoters of the Liverpool \& Manchester Railway (L \& MR) invited George Stephenson to resurvey their proposed line in order to reduce opposition to it. William James, a wealthy land agent who had become a visionary protagonist of a national railway network and had seen Stephenson's locomotives at Killingworth, had promoted the L \& MR with some merchants of Liverpool and had carried out the first survey; however, he overreached himself in business and, shortly after the invitation to Stephenson, became bankrupt. In his own survey, however, George Stephenson lacked the assistance of his son Robert, who had left for South America, and he delegated much of the detailed work to incompetent assistants. During a devastating Parliamentary examination in the spring of 1825, much of his survey was shown to be seriously inaccurate and the L \& MR's application for an Act of Parliament was refused. The railway's promoters discharged Stephenson and had their line surveyed yet again, by C.B. Vignoles.

The Stockton \& Darlington Railway was, however, triumphantly opened in the presence of vast crowds in September 1825, with Stephenson himself driving the locomotive Locomotion, which had been built at Robert Stephenson \& Co.'s Newcastle works. Once the railway was at work, horse-drawn and gravity-powered traffic shared the line with locomotives: in 1828 Stephenson invented the horse dandy, a wagon at the back of a train in which a horse could travel over the gravity-operated stretches, instead of trotting behind.

Meanwhile, in May 1826, the Liverpool \& Manchester Railway had successfully obtained its Act of Parliament. Stephenson was appointed Engineer in June, and since he and Vignoles proved incompatible the latter left early in 1827. The railway was built by Stephenson and his staff, using direct labour. A considerable controversy arose c. 1828 over the motive power to be used: the traffic anticipated was too great for horses, but the performance of the reciprocal system of cable haulage developed by Benjamin Thompson appeared in many respects superior to that of contemporary locomotives. The company instituted a prize competition for a better locomotive and the Rainhill Trials were held in October 1829.

Robert Stephenson had been working on improved locomotive designs since his return from America in 1827, but it was the L \& MR's Treasurer, Henry Booth, who suggested the multi-tubular boiler to George Stephenson. This was incorporated into a locomotive built by Robert Stephenson for the trials: Rocket was entered by the three men in partnership. The other principal entrants were Novelty, entered by John Braithwaite and John Ericsson, and Sans Pareil, entered by Timothy Hackworth, but only Rocket, driven by George Stephenson, met all the organizers' demands; indeed, it far surpassed them and demonstrated the practicability of the long-distance steam railway. With the opening of the Liverpool \& Manchester Railway in 1830, the age of railways began.

Stephenson was active in many aspects. He advised on the construction of the Belgian State Railway, of which the Brussels-Malines section, opened in 1835, was the first all-steam railway on the European continent. In England, proposals to link the L \& MR with the Midlands had culminated in an Act of Parliament for the Grand Junction Railway in 1833: this was to run from Warrington, which was already linked to the L \& MR, to Birmingham. George Stephenson had been in charge of the surveys, and for the railway's construction he and J.U. Rastrick were initially Principal Engineers, with Stephenson's former pupil Joseph Locke under them; by 1835 both Stephenson and Rastrick had withdrawn and Locke was Engineer-in-Chief. Stephenson remained much in demand elsewhere: he was particularly associated with the construction of the North Midland Railway (Derby to Leeds) and related lines. He was active in many other places and carried out, for instance, preliminary surveys for the Chester \& Holyhead and Newcastle \& Berwick Railways, which were important links in the lines of communication between London and, respectively, Dublin and Edinburgh.

He eventually retired to Tapton House, Chesterfield, overlooking the North Midland. A man who was self-made (with great success) against colossal odds, he was ever reluctant, regrettably, to give others their due credit, although in retirement, immensely wealthy and full of honour, he was still able to mingle with people of all ranks.

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Principal Honours and Distinctions

President, Institution of Mechanical Engineers, on its formation in 1847. Order of Leopold (Belgium) 1835. Stephenson refused both a knighthood and Fellowship of the Royal Society.

Bibliography

1815, jointly with Ralph Dodd, British patent no. 3,887 (locomotive drive by connecting rods directly to the wheels).

1817, jointly with William Losh, British patent no. 4,067 (steam springs for locomotives, and improvements to track).

Further Reading

L.T.C.Rolt, 1960, George and Robert Stephenson, Longman (the best modern biography; includes a bibliography).

S.Smiles, 1874, The Lives of George and Robert Stephenson, rev. edn, London (although sycophantic, this is probably the best nineteenthcentury biography).

PJGR

Wollaston, William Hyde

SUBJECT AREA: Metallurgy

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b. 6 August 1766 East Dereham, Norfolk, England

d. 22 December 1828 London, England

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English chemist and metallurgist who discovered palladium and rhodium, pioneer in the fabrication of platinum.

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Wollaston qualified in medicine at Cambridge University but gave up his practice in 1800 to devote himself to chemistry and metallurgy, funded from the profits from making malleable platinum. In partnership with Smithson Tennant, a friend from his Cambridge days, he worked on the extraction of platinum by dissolving it in aqua regia. In 1802 he found that in addition to platinum the solution contained a new metal, which he named palladium. Two years later he identified another new metal, rhodium.

Wollaston developed a method of forming platinum by means of powder metallurgy and was the first to produce malleable and ductile platinum on a commercial scale. He produced platinum vessels for sulphuric acid manufacture and scientific apparatus such as crucibles. He devised an elegant method for forming fine platinum wire. He also applied his inventive talents to improving scientific apparatus, including the sextant and microscope and a reflecting goniometer for measuring crystal angles. In 1807 he was appointed Joint Secretary of the Royal Society with Sir Humphry Davy, which entailed a heavy workload and required them to referee all the papers submitted to the Society for publication.

Wollaston's output of platinum began to decline after 1822. Due to ill health he ceased business operations in 1828 and at last made public the details of his secret platinum fabrication process. It was fully described in the Bakerian Lecture he delivered to the Royal Society on 28 November 1828, shortly before his death.

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Principal Honours and Distinctions

FRS 1793.

Bibliography

His scientific papers were published in various journals, nearly all listed in the Royal Society Catalogue of Scientific Papers.

Further Reading

There is no good general biography, the best general account being the entry in

Dictionary of Scientific Biography.

D.McDonald, 1960, A History of Platinum from the Earliest Times to the Eighteen- Eighties, London (provides a good discussion of his work on platinum).

M.E.Weeks, 1939, "The discovery of the elements", Journal of Chemical Education: 184–5.

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