Carl Wilhelm Scheele

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Carl Wilhelm Scheele

Carl Scheele
Born 9 December 1742 (1742-12-09)
Stralsund, Swedish Pomerania, today Germany
Died 21 May 1786 (1786-05-22) (aged 43)
Köping, Sweden
Nationality German-Swedish
Fields Chemistry
Known for Discovered oxygen (independently), molybdenum, tungsten, chlorine, and more

Carl Wilhelm Scheele (9 December 1742 21 May 1786) was a Swedish Pomeranian pharmaceutical chemist. Isaac Asimov called him "hard-luck Scheele" because he made a number of chemical discoveries before others who are generally given the credit. For example, Scheele discovered oxygen (although Joseph Priestley published his findings first), and identified molybdenum, tungsten, barium, hydrogen, and chlorine before Humphry Davy, among others. Scheele discovered organic acids tartaric, oxalic, uric, lactic, and citric, as well as hydrofluoric, hydrocyanic, and arsenic acids.[1] He preferred speaking German his whole life, and German was commonly spoken among Swedish pharmacists.[2]

Biography

Scheele was born in Stralsund, in western Pomerania, which was at the time part of Sweden. Scheele's father Joachim (or Johann) Christian Scheele, was a grain dealer and brewer from a respected German family. His mother was Margaretha Eleanore Warnekros.

Friends of his parents taught him the art of reading prescriptions and the meaning of chemical and pharmaceutical signs.[3] Then in 1757, at age fourteen, Carl was sent to Gothenburg as an apprentice pharmacist[2] with another family friend and apothecary, Martin Andreas Bauch. He retained this position for eight years. During this time he ran experiments late into the night and read the works of Nicolas Lemery, Caspar Neumann, Johann von Löwenstern-Kunckel and Georg Ernst Stahl (the champion of the phlogiston theory). Much of his later theoretical speculations were based upon Stahl.[3]

In 1765 he worked under the progressive and well informed apothecary, C. M. Kjellström in Malmö, and became acquainted with Anders Jahan Retzius, a lecturer at the University of Lund and later a professor of chemistry at Stockholm. Scheele arrived in Stockholm some time between 1767 and 1769 and worked as a pharmacist. During this period he discovered tartaric acid, and with his friend Retzius, studied the relation of quicklime to calcium carbonate. While in the capital, he also became acquainted with many luminaries, such as Abraham Bäck, Peter Jonas Bergius, Bengt Bergius and Carl Friedreich von Schultzenheim.

In the fall of 1770 he became director of the laboratory of the great pharmacy of Locke, at Uppsala (about 40 miles north of Stockholm). The laboratory supplied chemicals to professor of chemistry Torbern Bergman, and a friendship developed after Scheele analyzed a reaction which Bergman and his assistant Johan Gottlieb Gahn could not resolve. The reaction was between melted saltpetre and acetic acid, producing a red vapor. Further study of this reaction later led to Scheele's discovery of oxygen (see "The theory of phlogiston" below). Based upon this friendship and respect, Scheele was given free use of Bergman's laboratory, both men profiting from their working relationship. In 1774 Scheele was nominated by Peter Jonas Bergius to be a member of the Royal Swedish Academy of Sciences and was elected February 4, 1775. In 1775 he also managed a pharmacy for a short time in Köping, and between the end of 1776 and the beginning of 1777, established his own business there.

On October 29, 1777 he took his seat for the first and only time at a meeting of the Academy of Sciences, and on November 11 he passed the examination as apothecary before the Royal Medical College, with highest honors. After his return to Köping he devoted himself, outside of his business, to scientific researches resulting in a long series of important papers.[3]

Existing theories before Scheele

By the time he was a teenager, Scheele had learned the dominant theory of gases in the 1770s, the phlogiston theory. Phlogiston, classified as "matter of fire", was supposed to be released from any burning material, and when it was exhausted, combustion would stop. When Scheele discovered oxygen he called it "fire air" because it supported combustion, but he explained oxygen using phlogistical terms because he did not believe that his discovery disproved the phlogiston theory.

Before Scheele made his discovery of oxygen, he studied air. Air was thought to be an element that made up the environment in which chemical reactions took place but did not interfere with the reactions. Scheele's investigation of air enabled him to conclude that air was a mixture of "fire air" and "foul air;" in other words, a mixture of two gases. He performed numerous experiments in which he burned substances such as saltpeter (potassium nitrate), manganese dioxide, heavy metal nitrates, silver carbonate and mercuric oxide. In all of these experiments, he isolated gas with the same properties: his "fire air," which he believed combined with phlogiston in materials to be released during heat-releasing reactions. However, his first publication, Chemische Abhandlung von der Luft und dem Feuer, was delivered to the printer Swederus in 1775, but not published until 1777, at which time both Joseph Priestley and Lavoisier had already published their experimental data and conclusions concerning oxygen and the phlogiston theory. The first English edition, Chemical Observation and Experiments on Air and Fire was published in 1780, with an introduction "Chemical Treatise on Air and Fire"[4]

The theory of phlogiston

d. Königl. Schwed. Acad. d. Wissenschaft Mitgliedes, Chemische Abhandlung von der Luft und dem Feuer (1777)
Chemical Observations & Experiments on Air & Fire (1780)

Historians of science no longer question the role of Carl Scheele in the overturning of the phlogiston theory, although Scheele himself never discarded the theory. It is generally accepted that he was the first to discover oxygen, among a number of prominent scientists (namely his esteemed colleagues Antoine Lavoisier, Joseph Black, and Joseph Priestley). In fact, it was determined that Scheele made the discovery three years prior to Priestley and at least several before Lavoisier. Joseph Priestley relied heavily on Scheele's work, perhaps so much so that he would not have made the discovery of oxygen on his own. Correspondence between Lavoisier and Scheele indicate that Scheele achieved interesting results without the advanced laboratory equipment that Lavoisier was accustomed to. Through the studies of Lavoisier, Joseph Priestley, Scheele, and others, chemistry was made a standardized field with consistent procedures. Although Scheele was unable to grasp the significance of his discovery of oxygen, his work was essential for the invalidation of the long-held theory of phlogiston.

Scheele's study of the gas not yet named oxygen was prompted by a complaint by Torbern Olof Bergman a professor at Upsala University who would eventually become Scheele's friend. Bergman informed Scheele that the saltpeter he had purchased from Scheele's employer, after long heating, produced red vapors (now known to be nitrogen dioxide) when it came into contact with acetic acid. Scheele's quick explanation was that the saltpeter had absorbed phlogiston with the heat (had been reduced to nitrite, in modern terms) and gave off a new phlogisticated gas as an active principle when combined with an acid (even a weak acid).

Bergman next suggested that Scheele analyze the properties of manganese dioxide. It was through his studies of manganese dioxide that Scheele developed his concept of "fire air" (his name for oxygen). He ultimately obtained oxygen by heating mercuric oxide, silver carbonate, magnesium nitrate, and other nitrate salts. Scheele wrote about his findings to Lavoisier who was able to see the significance of the results.

Although Scheele would always believe in some form of the phlogiston theory, his work reduced phlogiston to an unusually simple form, complicated only by the fact that chemists of Scheele's day still believed that light and heat were elements and were to be found in combination with them. Thus, Scheele assumed that hydrogen was composed of phlogiston (a reducing principle lost when objects were burned) plus heat. Scheele speculated that his fire air or oxygen (which he found the active part of air, estimating it to compose one quarter of air) combined with the phlogiston in objects to produce either light or heat (light an heat were presumed to be composed of differing proportions of phlogiston and oxygen).

When other chemists later showed water is produced when buring hydrogen and that rusting of metals added weight to them and that passing water over hot iron gave hydrogen, Scheele modified his theory to suggest that oxygen was the salt (or "saline principle" of water), and that when added to iron, water was reproduced, which added weight to the iron as rust.

Pyrolusite or MnO2.

New elements and compounds

In addition to his joint recognition for the discovery of oxygen, Scheele is argued to have been the first to discover other chemical elements such as barium (1774), manganese (1774), molybdenum (1778), and tungsten (1781), as well as several chemical compounds, including citric acid, lactic acid, glycerol, hydrogen cyanide (also known, in aqueous solution, as prussic acid), hydrogen fluoride, and hydrogen sulfide (1777). In addition, he discovered a process similar to pasteurization, along with a means of mass-producing phosphorus (1769), leading Sweden to become one of the world's leading producers of matches.

Chlorine gas.
Statue of Scheele in Köping.

Scheele made one other very important scientific discovery in 1774, arguably more revolutionary than his isolation of oxygen. He identified lime, silica, and iron in a specimen of pyrolusite (impure manganese dioxide) given to him by his friend, Johann Gottlieb Gahn, but could not identify an additional component (this was the manganese, which Scheele recognized was present as a new element, but could not isolate). When he treated the pyrolusite with hydrochloric acid over a warm sand bath, a yellow-green gas with a strong odor was produced. He found that the gas sank to the bottom of an open bottle and was denser than ordinary air. He also noted that the gas was not soluble in water. It turned corks a yellow color and removed all color from wet, blue litmus paper and some flowers. He called this gas with bleaching abilities, "dephlogisticated muriatic acid" (dephlogisticated hydrochloric acid, or oxidized hydrochloric acid). Eventually, Sir Humphry Davy named the gas chlorine.

Chlorine's bleaching properties were eventually turned into an industry by Berzelius, and became the foundation of a second industry of disinfection and deodorzation of putrified tissue and wounds (including wounds in living humans) in the hands of Labarraque, by 1824.

Death

In the fall of 1785, Scheele began to suffer from symptoms described as kidney disease. In early 1786, he also contracted a disease of the skin, which, combined with kidney problems, so enfeebled him that he could foresee an early death. With this in mind, he married the widow of his predecessor,[3] Pohl, two days before he died, so that he could pass undisputed title to his pharmacy and his possessions to her.

While Scheele's experiments generated substances which have long since been found to be hazardous, the compounds and elements he used to start his experiments were dangerous to begin with, especially heavy metals. Scheele had a bad habit of sniffing and tasting any new substances he discovered.[5] Cumulative exposure to arsenic, mercury, lead, their compounds, and perhaps hydrofluoric acid which he had discovered, and other substances took their toll on Scheele, who died at the early age of 43, on 21 May 1786, at his home in Köping. Doctors said that he died of mercury poisoning .

Published Papers

All of the following papers were published by Scheele within a span of fifteen years.[3]

1. (1771) Fluospar and its Acid—2.(1774) "Braunstein" or Magnesia [ Manganese ], two papers—3. (1775) Benzoin Salt [ Benzoic Acid ]—4. Arsenic and its Acid—5. Silica, Alumina, and Alum—6. Urinary Calculi—7. (1777) Chemical Treatise on Air and Fire—8. (1778) Wet Process for Preparing Mercurius dulcis [ Calomel ]—9. Simple Process for Preparing Pulvis Algarothi [ oxychloride of antimony ]—10. Molybdenum—11. Preparation of a New Green Color—12. (1779) On the Quantity of Pure Air daily present in the Atmosphere—13. Decomposition of Neutral Salts by Lime or Iron—14. Plumbago—15. Heavy spar—16. (1780) Fluospar—17. Milk and its Acid—18. Acid of Milk sugar—19. On the Relationship of Bodies—20. (1781) Tungsten—21. The Combustible Substance in Crude Lime—22. Preparation of White Lead—23. (1782) Ether—24. Preservation of Vinegar—25. Coloring Matter in Berlin Blue—26. (1783) Berlin Blue—27. Peculiar Sweet Principle from Oils and Fats [ Glycerin ]—28. (1784) Attempt to Crystallize Lemon juice—29. Constituents of Rhubarb-earth [ Calcium Oxalate ] and Preparation of Acetosella Acid [ Oxalic Acid ]—30. The Coloring "Middle-salt" of "Blood lye" [Yellow Prussiate of Potassium]—31. Air-acid [ Carbonic Acid or Carbon dioxide ]; Benzoic Acid. Lapis infernalis—32. Sweet Principle from Oils and Fats. Air-acid—33. (1785) Acid of Fruits, especially of Raspberry—34. Phosphate of Iron; and Pearl-salt—35. Occurrence of Rhubarb-earth [see 29] in various Plants—36. Preparation of Magnesia alba—37. Fulminating Gold. Corn oil [ Fusel oil ]. Calomel—38 Air-acid—39. Lead amalgam—40. Vinegar-naphtha—41. Lime. Ammonia or Volatile Alkali—42. Malic Acid and Citric Acid—43. Air, Fire, and Water—44. (1786) The Essential Salt of Galls [ Gallic Acid ]—45. Nitric Acid—46. Oxide of Lead. Fuming Sulphuric Acid—47. Pyrophorus—48. Peculiarities of Hydrofluoric Acid.

See also

Notes

  1. Richard Myers, The Basics of Chemistry (2003)
  2. 2.0 2.1 Fors, Hjalmar 2008. Stepping through Science’s Door: C. W. Scheele, from Pharmacist’s Apprentice to Man of Science. Ambix 55: 29-49
  3. 3.0 3.1 3.2 3.3 3.4 Castle, Fred'k A. American Druggist Vol.15, August, 1886 "Carl Wilhelm Scheele"
  4. p101, A Source Book in Chemistry, 1400-1900, Henry Marshall Leicester, Herbert S. Klickstein - 1969
  5. Asimov, Isaac (1966). The Noble Gases. ISBN 978-0465051298

References

  • Abbott, David. (1983). Biographical Dictionary of Scientists: Chemists. New York: Peter Bedrick Books. pp. 126–127. ISBN 0-911745-81-5. 
  • Bell, Madison S. (2005). Lavoisier in the Year One. New York: W.W. Norton & Company, Inc. ISBN 0-393-05155-2. 
  • Cardwell, D.S.L. (1971). From Watt to Clausius: The Rise of Thermodynamics in the Early Industrial Age. Heinemann: London. pp. 60–61. ISBN 0-435-54150-1. 
  • Dobbin, L. (trans.) (1931). Collected Papers of Carl Wilhelm Scheele. G. Bell & Sons, London. 
  • Farber, Eduard ed. (1961). Great Chemists. New York: Interscience Publishers. pp. 255–261. 
  • Greenberg, Arthur. (2000). A Chemical History Tour: Picturing Chemistry from Alchemy to Modern Molecular Science. Hoboken: John Wiley & Sons, Inc. pp. 135–137. ISBN 0-471-35408-2. 
  • Greenberg, Arthur. (2003). The Art of Chemistry: Myths, Medicines and Materials. Hoboken: John Wiley & Sons, Inc. pp. 161–166. ISBN 0-471-07180-3. 
  • Schofield, Robert E (2004). The Enlightened Joseph Priestley: A Study of His Life and Work from 1773-1804. Pennsylvania: The Pennsylvania State University Press. ISBN 0-271-02459-3. 
  • Shectman (2003). Groundbreaking Scientific Experiments, Inventions, and Discoveries of the 18th Century. Connecticut: Greenwood Press. ISBN 0-313-32015-2. 
  • Sootin, Harry (1960). 12 Pioneers of Science. New York: Vanguard Press. 

External links

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