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Carl Ludwig Siegel

Carl Ludwig Siegel (31 December 1896 – 4 April 1981) was a German mathematician specialising in analytic number theory. He is known for, amongst other things, his contributions to the Thue–Siegel–Roth theorem in Diophantine approximation, Siegel's method,[1] Siegel's lemma and the Siegel mass formula for quadratic forms. He has been named one of the most important mathematicians of the 20th century.[2][3]

For the German architecture professor, see Carl August Benjamin Siegel.

André Weil, without hesitation, named[4] Siegel as the greatest mathematician of the first half of the 20th century. Atle Selberg said of Siegel and his work:

Biography[edit]

Siegel was born in Berlin, where he enrolled at the Humboldt University in Berlin in 1915 as a student in mathematics, astronomy, and physics. Amongst his teachers were Max Planck and Ferdinand Georg Frobenius, whose influence made the young Siegel abandon astronomy and turn towards number theory instead. His best-known student was Jürgen Moser, one of the founders of KAM theory (KolmogorovArnold–Moser), which lies at the foundations of chaos theory. Another notable student was Kurt Mahler, the number theorist.


Siegel was an antimilitarist, and in 1917, during World War I he was committed to a psychiatric institute as a conscientious objector. According to his own words, he withstood the experience only because of his support from Edmund Landau, whose father had a clinic in the neighborhood. After the end of World War I, he enrolled at the University of Göttingen, studying under Landau, who was his doctoral thesis supervisor (PhD in 1920). He stayed in Göttingen as a teaching and research assistant; many of his groundbreaking results were published during this period. In 1922, he was appointed professor at the Goethe University Frankfurt as the successor of Arthur Moritz Schönflies. Siegel, who was deeply opposed to Nazism, was a close friend of the docents Ernst Hellinger and Max Dehn and used his influence to help them. This attitude prevented Siegel's appointment as a successor to the chair of Constantin Carathéodory in Munich.[5] In Frankfurt he took part with Dehn, Hellinger, Paul Epstein, and others in a seminar on the history of mathematics, which was conducted at the highest level. In the seminar they read only original sources. Siegel's reminiscences about the time before World War II are in an essay in his collected works.


In 1936 he was a Plenary Speaker at the ICM in Oslo. In 1938, he returned to Göttingen before emigrating in 1940 via Norway to the United States, where he joined the Institute for Advanced Study in Princeton, where he had already spent a sabbatical in 1935. He returned to Göttingen after World War II, when he accepted a post as professor in 1951, which he kept until his retirement in 1959. In 1968 he was elected a foreign associate of the U.S. National Academy of Sciences.[6]

Career[edit]

Siegel's work on number theory, diophantine equations, and celestial mechanics in particular won him numerous honours. In 1978, he was awarded the first Wolf Prize in Mathematics, one of the most prestigious in the field. When the prize committee decided to select the greatest living mathematician, the discussion centered around Siegel and Israel Gelfand as the leading candidates. The prize was ultimately split between them.[7]


Siegel's work spans analytic number theory; and his theorem on the finiteness of the integer points of curves, for genus > 1, is historically important as a major general result on diophantine equations, when the field was essentially undeveloped. He worked on L-functions, discovering the (presumed illusory) Siegel zero phenomenon. His work, derived from the Hardy–Littlewood circle method on quadratic forms, appeared in the later, adele group theories encompassing the use of theta-functions. The Siegel modular varieties, which describe Siegel modular forms, are recognised as part of the moduli theory of abelian varieties. In all this work the structural implications of analytic methods show through.


In the early 1970s Weil gave a series of seminars on the history of number theory prior to the 20th century and he remarked that Siegel once told him that when the first person discovered the simplest case of Faulhaber's formula then, in Siegel's words, "Es gefiel dem lieben Gott." (It pleased the dear Lord.) Siegel was a profound student of the history of mathematics and put his studies to good use in such works as the Riemann–Siegel formula, which Siegel found[8] while reading through Riemann's unpublished papers.

Transcendental numbers, 1949

[9]

Analytic functions of several complex variables, Stevens 1949; 2008 pbk edition

[10]

Gesammelte Werke (Collected Works), 3 Bände, Springer 1966

with Lectures on Celestial mechanics 1971, based upon the older work Vorlesungen über Himmelsmechanik, Springer 1956[11]

Jürgen Moser

On the history of the Frankfurt Mathematics Seminar, Mathematical Intelligencer Vol.1, 1978/9, No. 4

Über einige Anwendungen diophantischer Approximationen, Sitzungsberichte der Preussischen Akademie der Wissenschaften 1929 (sein Satz über Endlichkeit Lösungen ganzzahliger Gleichungen)

Transzendente Zahlen, BI Hochschultaschenbuch 1967

Vorlesungen über Funktionentheorie, 3 Bde. (auch in Bd.3 zu seinen Modulfunktionen, English translation "Topics in Complex Function Theory", 3 Vols., Wiley)

[12]

Symplectic geometry, Academic Press, September 2014

Advanced analytic number theory, Tata Institute of Fundamental Research 1980

Lectures on the Geometry of Numbers. Berlin Heidelberg: Springer-Verlag. 16 November 1989.  978-3-540-50629-4.

ISBN

to Louis J. Mordell, March 3, 1964.

Letter

by Siegel:


about Siegel:

Bourget's hypothesis

Siegel's conjecture

Siegel's number

Siegel disk

Siegel's lemma

Siegel upper half-space

Siegel–Weil formula

Siegel parabolic subgroup

Smith–Minkowski–Siegel mass formula

Riemann–Siegel formula

Riemann–Siegel theta function

Siegel–Shidlovsky theorem

Siegel–Walfisz theorem

(Minkowski–Hlawka theorem)

Siegel's theorem

at the Mathematics Genealogy Project

Carl Ludwig Siegel

Freddy Litten Die Carathéodory-Nachfolge in München 1938–1944

(PDF; 6,77 MB)

85. Vol. Heft 4 der DMV (with 3 articles about Siegel's life and works)

Siegel, Carl (1921). "Approximation algebraischer Zahlen". Mathematische Zeitschrift (Dissertation) (in German). 10 (3–4): 173–213. :10.1007/BF01211608. ISSN 0025-5874.

doi

Siegel, Carl (1921). . Jahresbericht der Deutschen Mathematiker-Vereinigung. 31: 22–26.

"Additive Zahlentheorie in Zahlkörpern"