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In ] he became a lecturer at ''Stockholms Högskola'' (now ]), being promoted to professor of physics (with much opposition) in ], and ] in ]. | In ] he became a lecturer at ''Stockholms Högskola'' (now ]), being promoted to professor of physics (with much opposition) in ], and ] in ]. | ||
He developed a theory to explain the ]s, and first formulated the idea that changes in the levels of carbon dioxide in the atmosphere could substantially alter the surface temperature through the ] ("On the Influence of Carbonic Acid in the Air Upon the Temperature of the Ground", Philosophical Magazine 1896(41): 237-76). He was influenced by the work of others, including ]'s argument that the earth's atmosphere acted like the glass of a hot-house. Arrhenius wrote more about this in 1903, in a technical book titled ''Lehrbuch der kosmischen Physik'', but the theory received little comment from scientists. He later wrote ''Worlds in the Making'' directed at a general audience and from that, the hot-house theory gained more attention. Nevertheless, until about 1960, most scientists dismissed the hot-house / greenhouse effect as implausible. We now know that Arrhenius actually the degree to which humans could affect global temperatures, nevertheless carbon dioxide levels have risen at a rate much faster than Arrhenius first predicted -about 25 percent. | He developed a theory to explain the ]s, and first formulated the idea that changes in the levels of carbon dioxide in the atmosphere could substantially alter the surface temperature through the ] ("On the Influence of Carbonic Acid in the Air Upon the Temperature of the Ground", Philosophical Magazine 1896(41): 237-76). He was influenced by the work of others, including ]'s argument that the earth's atmosphere acted like the glass of a hot-house. Arrhenius wrote more about this in 1903, in a technical book titled ''Lehrbuch der kosmischen Physik'', but the theory received little comment from scientists. He later wrote ''Worlds in the Making'' directed at a general audience and from that, the hot-house theory gained more attention. Nevertheless, until about 1960, most scientists dismissed the hot-house / greenhouse effect as implausible. We now know that Arrhenius actually the degree to which humans could affect global temperatures, nevertheless carbon dioxide levels have risen at a rate much faster than Arrhenius first predicted -about 25 percent. | ||
He was married twice, to Sofia Rudbeck, (who bore him one son) from ] to ], and to Maria Johansson (who bore him two daughters and a son), from ] onward. | He was married twice, to Sofia Rudbeck, (who bore him one son) from ] to ], and to Maria Johansson (who bore him two daughters and a son), from ] onward. |
Revision as of 15:14, 12 October 2005
Svante August Arrhenius (February 19, 1859 – October 2, 1927) was a Swedish chemist and one of the founders of the science of physical chemistry.
Arrhenius was born at Vik (also spelled Wik or Wijk), near Uppsala, Sweden, the son of Svante Gustav and Carolina Thunberg Arrhenius. His father had been a land surveyor for Uppsala University, moving up to a supervisory position. At the age of three, Arrhenius taught himself to read, despite his parents' wishes, and by watching his father's addition of numbers in his account books, became an arithmetical prodigy.
In later life, Arrhenius enjoyed using masses of data to discover mathematical relationships and laws. At age 8, he entered the local cathedral school, starting in the fifth grade, distinguishing himself in physics and mathematics, and graduating as the youngest and ablest student in 1876.
At the University of Uppsala, he was unsatisfied with the chief instructor of physics and the only faculty member who could have supervised him in chemistry, so he left to study at the Physical Institute of the Swedish Academy of Sciences in Stockholm under the physicist Erik Edlund in 1881. His work specialized on the conductivities of electrolytes. In 1884, based on this work, he submitted a 150-page dissertation on electrolytic conductivity to Uppsala for the doctorate. It did not impress the professors, and he received the lowest possible passing grade. Later this very work would earn him the Nobel Prize in Chemistry.
There were 56 theses put forth in the 1884 dissertation, and most would still be accepted today unchanged or with minor modifications. The most important idea in the dissertation was his explanation of the fact that neither pure salts nor pure water is a conductor, but solutions of salts in water are.
Arrhenius' explanation was that in forming a solution, the salt dissociates into charged particles (which Michael Faraday had given the name ions many years earlier). Faraday's belief had been that ions were produced in the process of electrolysis; Arrhenius proposed that, even in the absence of an electric current, solutions of salts contained ions. He thus proposed that chemical reactions in solution were reactions between ions. For weak electrolytes this is still believed the case, but modifications (by Peter J. W. Debye and Erich Hückel) were found necessary to account for the behavior of strong electrolytes.
The dissertation was not very impressive to the professors at Uppsala, but Arrhenius sent it to a number of scientists in Europe who were developing the new science of physical chemistry, such as Rudolf Clausius, Wilhelm Ostwald, and J. H. van 't Hoff. They were far more impressed, and Ostwald even came to Uppsala to persuade Arrhenius to join his research team. Arrhenius declined, however, as he preferred to stay in Sweden for a while (his father was very ill and would die in 1885) and had gotten an appointment at Uppsala.
Arrhenius next received a travel grant from the Swedish Academy of Sciences, which enabled him to study with Ostwald in Riga (now in Latvia), with Friedrich Kohlrausch in Würzburg, Germany, with Ludwig Boltzmann in Graz, Austria, and with van 't Hoff in Amsterdam.
In 1889 Arrhenius explained the fact that most reactions require added heat energy to proceed by formulating the concept of activation energy, an energy barrier that must be overcome before two molecules will react. The Arrhenius equation gives the quantitative basis of the relationship between the activation energy and the rate at which a reaction proceeds.
In 1891 he became a lecturer at Stockholms Högskola (now Stockholm University), being promoted to professor of physics (with much opposition) in 1895, and rector in 1896.
He developed a theory to explain the ice ages, and first formulated the idea that changes in the levels of carbon dioxide in the atmosphere could substantially alter the surface temperature through the greenhouse effect ("On the Influence of Carbonic Acid in the Air Upon the Temperature of the Ground", Philosophical Magazine 1896(41): 237-76). He was influenced by the work of others, including Joseph Fourier's argument that the earth's atmosphere acted like the glass of a hot-house. Arrhenius wrote more about this in 1903, in a technical book titled Lehrbuch der kosmischen Physik, but the theory received little comment from scientists. He later wrote Worlds in the Making directed at a general audience and from that, the hot-house theory gained more attention. Nevertheless, until about 1960, most scientists dismissed the hot-house / greenhouse effect as implausible. We now know that Arrhenius actually underestimated the degree to which humans could affect global temperatures, nevertheless carbon dioxide levels have risen at a rate much faster than Arrhenius first predicted -about 25 percent.
He was married twice, to Sofia Rudbeck, (who bore him one son) from 1894 to 1896, and to Maria Johansson (who bore him two daughters and a son), from 1905 onward.
In 1901 Arrhenius was elected to the Swedish Academy of Sciences, against strong opposition. In 1903 he became the first Swede to be awarded the Nobel Prize in chemistry. In 1905, upon the founding of the Nobel Institute for Physical Research at Stockholm, he was appointed rector of the institute, the position where he remained until retirement in 1927.
Eventually, Arrhenius' theories became generally accepted and he turned to other scientific topics. In 1902 he began to investigate physiological problems in terms of chemical theory. He determined that reactions in living organisms and in the test tube followed the same laws. He also turned his attention to astronomy, cosmology, and astrophysics, accounting for the birth of the solar system by interstellar collision. He considered radiation pressure as accounting for comets, the solar corona, the aurora borealis, and zodiacal light.
He thought life might have been carried from planet to planet by the transport of spores, the theory now known as panspermia. He thought of the idea of a universal language, proposing a modification of the English language.
In his last years he wrote both textbooks and popular books, trying to emphasize the need for further work on the topics he discussed.
In September, 1927, he came down with an attack of acute intestinal catarrh, died on October 2, and was buried in Uppsala.
References
Svante Arrhenius, 1896a, Ueber den Einfluss des Atmosphärischen Kohlensäurengehalts auf die Temperatur der Erdoberfläche, Bihang till Kongliga Svenska Vetenskaps-Akademiens Handlingar, Stockholm 1896, Band 22 Afd I N:o 1, p1-101.
Svante Arrhenius, 1896b, On the Influence of Carbonic Acid in the Air upon the Temperature of the Ground, The London, Edinburgh, and Dublin Philosophical Magazine and Journal of Science April 1896. vol 41, p237-275
Svante Arrhenius, 1901a, Ueber die Wärmeabsorption durch Kohlensäure, Annalen der Physik Bd 4. 1901, p690-705.
Svante Arrhenius 1901b Über Die Wärmeabsorption Durch Kohlensäure Und Ihren Einfluss Auf Die Temperatur Der Erdoberfläche. Öfversigt af Kongliga Vetenskaps-Akademiens Förhandlingar 58: 25-58.
Svante Arrhenius, 1903, Lehrbuch der Kosmischen Physik Vol I and II, Verlag S. Hirschel Leipzig, 1026 pp
Svante Arrhenius, 1908 (3. bis 8. tausend), Das Werden der Welten, Akademische Verlagsgesellschaft, Leipzig, 208 pp
External links
- The Nobel Prize in Chemistry 1903
- "On the Influence of Carbonic Acid in the Air Upon the Temperature of the Ground":
Obituaries
- Obs 50 (1927) 363 (one paragraph)
- PASP 39 (1927) 385 (one paragraph)