Wilhelm Ostwald | |
Born | September 2, 1853 Riga, Latvia |
---|---|
Died | April 4, 1932 (aged 78) Leipzig, Germany |
Residence | Germany |
Nationality | German |
Fields | Physical Chemist |
Institutions | University of Dorpat Riga Polytechnicum University of Leipzig |
Alma mater | University of Dorpat |
Doctoral advisor | Carl Schmidt |
Doctoral students | Arthur Amos Noyes Georg Bredig Paul Walden |
Known for | Ostwald process Ostwald viscometer |
Notable awards | Nobel Prize for Chemistry (1909) |
Friedrich Wilhelm Ostwald, commonly just Wilhelm Ostwald (Latvian: Vilhelms Ostvalds; September 2, 1853 – April 4, 1932) was a Latvian/German chemist. He received the Nobel Prize in Chemistry in 1909 for his work on catalysis, chemical equilibria and reaction velocities. Ostwald, Jacobus Henricus van 't Hoff, and Svante Arrhenius are usually credited with being the modern founders of the field of physical chemistry.
Biography
He was born in Riga, Livonia, as the son of master-cooper Gottfried Wilhelm Ostwald (1824 – 1903) and Elisabeth Leuckel (1824 – 1903). He had two brothers, Eugen (1851 – 1932) and Gottfried (1855 – 1918).
He was ethnically a Baltic German. He graduated from the University of Tartu, Estonia, in 1875, received his Ph.D. there in 1878 under the guidance of Carl Schmidt, and taught at Tartu from 1875 to 1881 and at Riga Polytechnicum from 1881 to 1887.
On April 24, 1880 Ostwald married Helene von Reyher (1854 – 1946), with whom he had five children:
* Grete (born 1882 in Riga; died 1960 in Großbothen)
* Wolfgang (born 1883 in Riga; died 1943 in Dresden)
* Elisabeth (born 1884 in Riga; died 1968 in Großbothen)
* Walter (born 1886 in Riga; died 1958 in Freiburg im Breisgau)
* Carl Otto (born 1890 in Leipzig; died 1958 in Leipzig)
In 1887, he moved to Leipzig where he worked for the rest of his life. Arthur Noyes was one of his students, as was Willis Rodney Whitney.
Overview
Wilhelm Ostwald is usually credited with inventing the Ostwald process (patent 1902), used in the manufacture of nitric acid, although the basic chemistry had been patented some 64 years earlier by Kuhlmann, when it was probably of only academic interest due to the lack of a significant source of ammonia. That may have still been the state of affairs in 1902, although things were due to change dramatically in the second half of the decade as a result of Haber and Bosch's work on their nitrogen fixing process (completed by 1911 or 1913). The date 1908 (six years after the patent) is often given for the invention of the Ostwald process, and it may be that these developments motivated him to do additional work to commercialize the process in that time-frame. Alternatively, six years might simply have been the bureaucratic interval between filing the patent and the time it was granted.
The combination of these two breakthroughs soon led to more economical and larger-scale production of fertilizers and explosives, of which Germany was to find itself in desperate need of during World War I. Ostwald also did significant work on dilution theory leading to his discovery of the law of dilution which is named after him. Ostwald's rule concerns the behaviour of polymorphs. The word mole, according to Gorin, was introduced into chemistry around 1900 by Ostwald. Ostwald defined one mole as the molecular weight of a substance in mass grams. The concept was linked to the ideal gas, according to Ostwald. Ironically, Ostwald's development of the mole concept was directly related to his philosophical opposition to the atomic theory, against which he (along with Ernst Mach) was one of the last holdouts. He explained in a conversation with Arnold Sommerfeld that he was converted by Einstein's explanation of Brownian Motion
Ostwald was a member of the International Committee on Atomic Weights. As a consequence of World War I this membership ended in 1917 and was not resumed after the war. The 1917 Annual report of the committee ended with the unusual note: "Because of the European war the Committee has had much difficulty in the way of correspondence. The German member, Professor Ostwald, has not been heard from in connection with this report. Possibly the censorship of letters, either in Germany or en route, has led to a miscarriage".
In addition to his work in chemistry, Wilhelm Ostwald was very productive in an extremely broad range of fields. His published work, which includes numerous philosophical writings, contains about forty thousand pages. Ostwald was also engaged in the peace movement of Berta von Suttner.
Among his other interests, Ostwald was a passionate amateur painter who made his own pigments, and who developed a strong interest in color theory in the later decades of his life. He wrote several publications in the field, such as his Malerbriefe (Letters to a Painter, 1904) and Die Farbenfibel (The Color Primer, 1916). His work in color theory was influenced by that of Albert Henry Munsell, and in turn influenced Paul Klee and members of De Stijl, including Piet Mondrian.[1] He was also interested in the international language movement, first learning Esperanto, then later becoming an Idist.[2]
He was also one of the directors of the Die Brücke institute in München.
Ostwald died in a hospital in Leipzig on April 4, 1932, and was buried at his house in Großbothen, near Leipzig.
Publications
* Couturat, L.; Jespersen O., Lorenz R., Ostwald Wilhelm, and Pfaundler L. (1910). International language and science: Considerations on the introduction of an international language into science. Constable and Company Limited.
* Ostwald, W. (1900). Grundriss der allgemeinen Chemie. Engelmann.
* Ostwald, W. (1906). Process of manufacturing nitric acid. Patent.
* Ostwald, W. (1917). Grundriss der allgemeinen Chemie, 5th edition, Steinkopff.
See also
* Ostwald's rule
Notes
1. ^ John Gage, Color and Culture: Practice and Meaning from Antiquity to Abstraction, Boston, Little, Brown and Co., 1993; pp. 247– 8, 257– 60.
2. ^ The Esperanto Movement By Peter Glover Forster
References
* Clark, F.W. (1916). "Annual report of the international committee on atomic weights". J. Am. Chem. Soc. 38 (11): 2219-2221. doi:10.1021/ja02268a001.
* Gorin, G. (1994). "Mole and chemical amount: A discussion of the fundamental measurements of chemistry". J. Chem. Education 71 (2).
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