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Franz S. Exner

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Franz S. Exner
Exner in 1915
Born(1849-03-24)24 March 1849
Died15 October 1926(1926-10-15) (aged 77)
Alma materUniversity of Vienna
Known forPioneering physics in Austria
Spouse(s)1. Auguste Bach
2. Friederike Schuh
Parents
Scientific career
FieldsPhysicist
InstitutionsUniversity of Vienna
Doctoral advisorViktor von Lang
Other academic advisors
Doctoral students

Franz Serafin Exner (24 March 1849 – 15 October 1926) was an Austrian physicist and professor at the University of Vienna. He is known for pioneering physical chemistry education in Austria.[1][2][3] The early introduction to university curricula of subjects such as radioactivity, spectroscopy, electrochemistry electricity in the atmosphere, and color theory in Austria are often credited to him.[4][5]

He advised many notable students including Stefan Meyer, Erwin Schrödinger, and Marian Smoluchowski.

Life

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Early life and family

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Franz Serafin Exner came from an important university family in the Austro-Hungarian Empire. His family included Adolf Exner [de], Karl Exner [de], Sigmund Exner, and Marie von Frisch [de]. Exner was youngest of the five children who survived to adulthood of parents Franz Serafin Exner [de] (1802-1853) and Charlotte Dusensy (1816–1859). His father Franz Serafin was, from 1831 to 1848, a professor of philosophy in Prague and from 1848 onwards a member of the Board of Education in Vienna, becoming an influential reformer of Austrian university education.

Academic studies

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Franz Exner began his university physics studies at Vienna in 1867. He received a doctorate from the University of Vienna in 1871, after an academic year at Zürich under August Kundt, also working alongside Wilhelm Conrad Röntgen, Kundt's student and, especially through the 1879s, regular research assistant/partner.[6][7]

The greatest influence on Exner's student career was probably the theoretical physicist Viktor von Lang, who had taken the University Chair in Physics at a still relatively young age in 1866, and who played a key role in encouraging and backing his gifted student. Exner received his habilitation in 1874 with a work entitled "On the Diffusion through Liquid Lamellas" (German: Über die Diffusion durch Flüssigkeitslamellen).[8][4] He continued to work for von Lang as the latter's research assistant till 1879.[8] Between 1874 and 1879 he also held a lectureship at the University of Natural Resources and Life Sciences, Vienna "k.k. Hochschule für Bodencultur" (Imperial College for Earth Sciences) which provided both a welcome supplementary income and the chance to share his ideas and insights with the large audiences attracted by his lectures.[6]

Professorship

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In 1879, still only 30, Franz Exner accepted an Extraordinary Professorship at the University of Vienna.[5] In 1885 he was elected to corresponding membership of the Austrian Academy of Sciences and Humanities. Full membership would follow in 1896.[2][8] Promotion came in 1891 when he was offered and accepted an "ordinary" (full) professorship at the university chemical physics Institute in the Türkenstraße. He arrived in the post with a clear agenda for change, which he now implemented. He created a new "school for experimental physics" to which, through a rare combination of sound judgment and good fortune, he was able to entice a stellar generation of younger researchers. New laboratory courses were inaugurated for advanced student, notably in respect of physics and medicine.[6]

Exner's appointment to the professorship followed the retirement of Josef Loschmidt. Loschmidt had been a junior colleague and good friend to Exner's father. Himself a brilliant scientist-mathematician he had looked after the interests of the younger Franz Exner and his four elder siblings following the early deaths of their father and mother in 1853 and 1859, becoming something of a mentor to the younger Franz.[9]

The university chemical physics Institute in the Türkenstraße remained the focus of Exner's professional career through most of the most productive years of his career. The premises were nevertheless something of an embarrassment, being desperately cramped and short on equipment. The situation improved a little in 1905 when the department was renamed as the "Zweites Physikalisches Instutut" ("Second [University] Physics Institute"), correctly implying a complementary status to "Erstes Physikalisches Institut" ("First [University] Physics Institute") which, under the directorship of Ludwig Boltzmann, sustained its own reputation for brilliance in other branches of the rapidly expanding subjects-palette of interest to physicists.

Exner also took his turn in university administration. He served as philosophy dean of faculty during 1903-1904, and served as a member of the university senate during 1907-1908.[8] By the time he served, during 1908-1909, as rector of the University of Vienna, he was at the pinnacle of his scientific achievements.[1][2][8]

World War I

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In 1913 additional space was made available within new institute buildings. However, since the outbreak in 1914 of World War I was accompanied by funding cuts, while the young men were sent away to participate on the Italian front. By the time war ended, in 1918, Austro-Hungarian Empire was destroyed, and intensifying austerity had left university funding a long way down the list of public priorities. Some of Exner's most brilliant former students found their way to the United States.[6] He himself was already over 70 in 1918.

Retirement and death

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Franz Exner retired from his university responsibilities in 1920 and died at Vienna in 1926.[10] His body was buried at the large Sieveringer Friedhof [de] cemetery on the western (then) outskirts of Vienna. Slightly more than ten years later, in 1937, a bronze tablet to his memory was produced by Michael Powolny and, with due ceremony, placed in the university's Arkadenhof in 1937.[8]

Endorsing Röntgen

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Franz Exner was a gregarious man, regularly holding informal dinners for university colleagues at his home. At the start of 1896, at one of these gatherings, he showed some them a copy of "Ueber eine neue Art von Strahlen" ("On a new kind of [radioactive] ray") a brief learned article which he had received form the author, his friend since their time together in Zürich, Wilhelm Röntgen. Röntgen, unlike his friend, was an exceptionally shy and self-contained scholar, but on New Year's Day 1896 he had, uncharacteristically, made a trip to the post office at Würzburg (the city where he lived and worked) with no fewer than 90 envelopes. Each was addressed to a different European physicist. In twelve of the envelopes - including the one addressed to Exner - there were some X-ray copies. Exner's copy arrived on 6 January 1896: it was one of those accompanied by several copies of the first X-rays. One of the colleagues to whom Exner showed his fiend's work was Ernst Lecher, established already as a talented experimental physicist, and a scholar-scientist for whose future career Röntgen's discoveries would prove pivotal. Lecher was also a son to Zacharias Konrad Lecher (1829–1905), the publisher and at this time editor in chief of the Neue Freie Presse, one of Vienna's a leading mass-circulation newspapers. After the little meeting, Exner left the book and the X-ray copies with Lechner, and news of Röntgen's invention very quickly found its way into the public consciousness across and beyond Europe through the Vienna press.[1][2][11]

Research

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The extent of his contribution as an organiser and mentor, helping to ensure that physics research was based on a sound footing from which the discoveries of the 20th century might flow, has frequently led Exner's own research work to be downplayed or overlooked by commentators.[citation needed]

His earliest published work concerned determination of the temperature at which water will reach its maximum density. His focus between 1877 and 1894 was on the rapidly evolving field of electrochemistry and the chemical implications of galvanic processes in different materials. Subsequently he broadened his research interests to incorporate aspects of meteorology, spectroscopy and radioactivity, with a particular interest in measurement techniques involving atmospheric electricity. Inspired by the prospect of being able to determine more precisely the chemical compositions of some of the very many of meteorites that had accumulated in the university collection, during the later 1890s he turned to work on spectral analytic investigation, working with his student Eduard Haschek to develop a method for rapid measurement of wavelengths by using enlarged photo-plates and spectral projections onto a white screen. During his final decades his personal research work was primarily concerned with the implications of the Young–Helmholtz theory, attempting to ground the theory more firmly in experimental evidence, and defending it against detractors.[6][12]

Notable students

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Exner was viewed by admirers, including his students, as a versatile and exceptionally broadly educated physicist with a strong vision, cultivating versatile and highly educated pupils. He was a pioneer in numerous areas of modern physics, greatly broadening the accepted scope of the subject through his endeavours. His most famous pupils included Marian Smoluchowski, a Viennese physicist of Polish descent, who discovered a theory of for Brownian motion, independently of Albert Einstein and Friedrich Hasenöhrl.[13]

Erwin Schrödinger, who later also won the 1933 Nobel Prize in Physics, also began his career as Exner's pupil, later becoming his research assistant in 1911. In 1914, Schrödinger received his Habilitation (higher postgraduate degree) with his "Studies on the kinetics of dielectrics, melting point, pyro- and piezoelectricity". Exner supervised the habilitation.[14][15][a]

Another of Exner's doctoral students was Stefan Meyer, who became the first director of the Institute for Radium Research ("Institut für Radiumforschung"), itself the first university institute in the world dedicated to researching radioactivity, and opened in 1910 in Vienna by Exner himself.[17][18]

Lise Meitner, credited with several important discoveries including, in 1917, that of the radioactive isotope protactinium-231, was another of Exner's doctoral students.[19][20][21]

During the 1920s and 1930s a remarkable preponderence of university chairs in Physics in the German speaking world were occupied by Exner's former students:[5]

Selected publications

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  • Franz Exner und Sigmund Exner: Die physikalischen Grundlagen der Blütenfärbungen, 1910
  • W C Röntgen und F Exner: Über die Anwendung des Eiskalorimeters zur Bestimmung der Intensität der Sonnenstrahlen. Wien Ber 69: 228 (1874)
  • Franz Exner: Vom Chaos zur Gegenwart, 1926 (unpublished)

Notes

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  1. ^ "Studien über Kinetik der Dielektrika, den Schmelzpunkt, Pyro- und Piezoelektrizität"[16]

References

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  • Berta Karlik, Erich Schmid: Franz Serafin Exner und sein Kreis. Ein Beitrag zur Geschichte der Physik in Osterreich, Wien: Verlag der Österreichischen Akademie der Wissenschaften 1982
  • Hans Benndorf: Zur Erinnerung an Franz Exner, 1927
  1. ^ a b c "Exner, Franz, Physiker" (PDF). Österreichisches Biographisches Lexikon. Österreichische Akademie der Wissenschaften, Wien. p. 275. Retrieved 31 December 2021.
  2. ^ a b c d Max Toperczer (1959). "Exner, Franz Serafin: Physiker, * 24.3.1849 Wien, † 15.11.1926 Wien". Neue Deutsche Biographie. Historische Kommission bei der Bayerischen Akademie der Wissenschaften (HiKo), München. p. 699. Retrieved 31 December 2021.
  3. ^ Bob (Dr. Robert O.) Doyle, Ph.D (compiler) (1922). "Franz Serafin Exner (the father, 1802-1853) (the son, 1853-1925)". Lectures on the Physical Principles of Natural Science. The Information Philosopher. p. 677. Retrieved 31 December 2021.
  4. ^ a b Georg Federmann. "Franz Serafin Exner: Einige Lebensdaten". Viktor Hess und die Entdeckung der Kosmischen Strahlung. Universität Innsbruck. Retrieved 31 December 2021.
  5. ^ a b c Wolfgang L. Reiter (August 2017). Mäzenatentum, Wissenschaft und Politik in Österreich um 1900 .... Exner und seine Schüler. Lit Verlag. pp. 91–93. ISBN 9 78-3643508256. Retrieved 31 December 2021. {{cite book}}: |work= ignored (help)
  6. ^ a b c d e Jagdish Mehra; Helmut Rechenberg (2000). Franz Exner and his school. Springer Verlag. pp. 74–77. ISBN 9780387951751. Retrieved 1 January 2021. {{cite book}}: |work= ignored (help)
  7. ^ August Kundt; Wilhelm Conrad Röntgen (3 May 1879). "Über die elektromagnetische Drehung der Polarisationsebene des Lichtes in den Gasen". In: Annalen der Physik und Chemie. 3. Folge. Bibliothèque nationale de France (site Gallica), Paris. pp. 278–298. Retrieved 1 January 2022.
  8. ^ a b c d e f Katharina Kniefacz (20 January 2017). "Franz Serafin Exner jun., o. Univ.-Prof. Dr. phil.: 24.3.1849 – 15.11.1926 ... geb. in Wien, Österreich gest. in Wien, Österreich". 650 plus – Geschichte der Universität Wien. Retrieved 31 December 2021.
  9. ^ Alfred Bader; Leonard Parker. "Biography of Josef Loschmidt". Loschmidt Laboratories, Brno. Retrieved 1 January 2022.
  10. ^ "Gedenktafelenthüllung für Professor Dr. Franz Exner". newspaper report of the inauguration of a memorial tablet at the University of Vienna to celebrate the life of Prof. Exner. (see the right hand column on page 6, approximately halfway down). Neue Freie Presse. 24 January 1937. p. 6. Retrieved 31 December 2021.
  11. ^ Joachim Pietzsch. "Perspectives: A helping hand from the media". The Nobel Prize in Physics 1901 .... The world first discovered the sensational news that Wilhelm Röntgen’s mysterious X-rays could penetrate clothing and human skin, not through scientists but through the press. Nobel Prize Outreach AB, Stockholm. Retrieved 2 January 2022.
  12. ^ Marco Fontani; Mariagrazia Costa; Mary Virginia Orna (2015). From Monium to Victorium and in pursuit of Ionium and Incognitum .... The element E or X2. Oxford University Press. pp. 207–208, 202–208. ISBN 9780199383344. Retrieved 2 January 2021. {{cite book}}: |work= ignored (help)
  13. ^ Jacek Rodzeń (2017). "Światy indeterministyczne Franza-Serafina Exnera i Mariana Smoluchowskiego (Indeterministic worlds of Franz-Serafin Exner and Marian Smoluchowski)". Philosophical Problems in Science (Zagadnienia Filozoficzne W Nauce) (62). Uniwersytet Jana Kochanowskiego w Kielcach, Instytut Dziennikarstwa i Informacji & Zagadnienia Filozoficzne w Nauce: 73–98. Retrieved 1 January 2022.
  14. ^ Karl von Meÿenn (2007). "Schrödinger, Erwin Rudolf Josef Alexander". Neue Deutsche Biographie. Historische Kommission bei der Bayerischen Akademie der Wissenschaften (HiKo), München. pp. 578–580. Retrieved 1 January 2022.
  15. ^ Christian Joas; Shaul Katzir (14 July 2010). "Analogy, extension, and novelty: Young Schrödinger on electric phenomena in solids" (PDF). Studies in History and Philosophy of Modern Physics. Fritz-Haber-Institut der MPG, Berlin & Elsevier Ltd. Retrieved 1 January 2022.
  16. ^ Erwin Schrödinger. "Studien über Kinetik der Dielektrika, den Schmelzpunkt, Pyro- und Piezoelektrizität" (PDF). Aus den Sitzungsberichten der kaiserl. Akademie der Wissenschaften in Wien. IEEE, New York. Retrieved 1 January 2021.
  17. ^ "Eröffnung des Instituts für Radiumforschung". Neue Freie Presse, Wien. 28 October 1910. pp. 3–4. Retrieved 1 January 2022.
  18. ^ Helmut Rechenberg (1994). "Meyer, Stefan: Physiker, * 27.4.1872 Wien, † 29.12.1949 Bad Ischl. (evangelisch)". Neue Deutsche Biographie. Historische Kommission bei der Bayerischen Akademie der Wissenschaften (HiKo), München. p. 321-322. Retrieved 1 January 2022.
  19. ^ Herbert Posch (12 February 2015). "Lise Meitner, Dr. 7.11.1878 – 27.10.1968 geb. in Wien, Österreich gest. in Cambridge, Vereinigtes Königreich". 650 plus – Geschichte der Universität Wien. Retrieved 1 January 2022.
  20. ^ Ruth Lewin Sime, Lise Meitner, University of California Press 1997, p. 17f
  21. ^ Maria Osiezki (1990). "Meitner, Lise: Kernphysikerin, * 7.11.1878 Wien, † 27.10.1968 Cambridge (England). (evangelisch)". Neue Deutsche Biographie. Historische Kommission bei der Bayerischen Akademie der Wissenschaften (HiKo), München. p. 731-734. Retrieved 1 January 2022.
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