Marcel Riesz

Quick Info

16 November 1886
Györ, Hungary
4 September 1969
Lund, Sweden

Marcel Riesz was a Hungarian-born mathematician who worked on summation methods, potential theory and other parts of analysis, as well as number theory and partial differential equations.


Marcel Riesz's father, Ignácz Riesz, was a medical man. Marcel was the younger brother of Frigyes Riesz. He was brought up in the problem solving environment of Hungarian mathematics teaching which proved so successful in creating a whole generation of world-class mathematicians. He excelled in this environment and won the Loránd Eötvös competition in 1904. He studied at Budapest University and, influenced by Féjér, undertook research on problems from the theory of series. Riesz wrote his doctoral thesis Summierbare trigonometrische Reihen und Potenzreihen in 1907 and presented it to the University of Budapest; it was published in the following year. In it he gave the correct generalisation of Cantor's uniqueness theorem for convergent trigonometric series to trigonometric series summable by the Cesàro method. His doctoral thesis was written in Hungarian, but he extended the results further before publishing the main ones in a paper Über summierbare trigonometrische Reihen written in German in 1911. Perhaps we should add at this point that after writing a few early papers in Hungarian, and one later paper in Swedish, all his papers are written in French or German until the latter part of his career when he wrote in English.

Invited by Mittag-Leffler to Sweden in 1908, he spent the whole of his life there up to his retirement. Appointed to Stockholm in 1911 he had a number of outstanding doctoral students including Olof Thorin, Harald Cramér, Franz Berwald, and Einar Hille. In 1923 he applied for a chair at Lund but was unsuccessful as Carleman was appointed to fill the chair. Von Koch, who was the professor at Stockholm, died in March 1924 and several mathematicians, including Ivar Bendixson and Ivar Fredholm, supported Riesz to fill the vacancy. However, again he lost out to Carleman but in 1926 Riesz was appointed to a chair at Lund [6]:-
Lund did not have much of a mathematical tradition but Riesz's arrival meant a change of atmosphere. He was now an international star, active with his own research and he also had the time and incentive to broaden his interests.
Among his doctoral students at Lund, we mention Otto Frostman and Lars Hörmander.

Marcel Riesz's interests ranged from functional analysis to partial differential equations, mathematical physics, number theory and algebra. Later in his career he also worked on Clifford algebras and spinors. The first period of his work, from the beginning of his doctoral research up to around the beginning of World War I, concentrated on the theory of series, in particular the summability theory of power series, trigonometric series and Dirichlet series. In 1914 he gave an interpolation formula for trigonometric polynomials. This was an important discovery and the formula now appears in most texts on interpolation. It leads to quick proofs of Bernstein's inequality and Markov's inequality. Another highlight from this period is his beautiful proof of Fatou's theorem which give conditions under which the power series of an analytic function converges to a point on its circle of convergence.

In a joint work with Hardy The general theory of Dirichlet's series, published by Cambridge University Press in 1915, he introduced Riesz means. He has only one joint paper with his brother, but it is an important contribution written during World War I and published in 1920, on the boundary behaviour of an analytic function. W H J Fuchs, reviewing [2], writes about how Riesz's interests developed through the 1920s:-
To the consummate skill in handling formulas which is typical of the classical Hungarian school he now added a more abstract, functional analytic view, long before functional analysis had become a commonplace tool.
Riesz broadened his range of interests during the 1930 when he became interested in potential theory and in partial differential equations. He was motivated by wave propagation and in particular Dirac's relativistic equation for the electron. In 1949, Riesz published a 223 page paper L'intégrale de Riemann-Liouville et le problème de Cauchy in which he introduced a multiple integral of Riemann-Liouville type and showed how important this idea is in the theory of the wave equation. Feller writes that the paper:-
... contains an account of all results previously published without detailed proofs. Formally, therefore, we have a research paper. However, the paper is written in the style of a book. All details are given and, where desirable, passages of previously published papers are reproduced. The author takes care to compare his method with others and to point out the details which make the mechanism work. The paper is self-contained and should be accessible also to non-experts.
In Problems related to characteristic surfaces Riesz extended these ideas to obtain the solution of the wave equation for a very general class of characteristic boundaries.

We noted above that Riesz was interested in number theory but as yet have given no examples of his work in this area. Let us fill this gap by mentioning Sur le lemme de Zolotareff et sur la loi de réciprocité des restes quadratiques (1953) which bring a comment from Derrick Lehmer:-
The whole presentation is very elegant.
W H J Fuchs, reviewing [2], writes:-
M Riesz was a perfectionist and a gentleman. He spent endless trouble on giving his presentation a high polish and he worked as hard on improving the proofs of known theorems as on the finding of new ones. The final publication of his results often took place many years after their first announcements. His masterful exposition makes his papers a joy to read. His work covered a wide area of analysis and just an enumeration would be too long for a review.
Garding, in [6], writes from personal experience of Riesz from his time as a student in Lund:-
He then had a small circle of graduate students. Each one got personal attention. Riesz loved to talk about mathematics and he appreciated having listeners. He could go on for hours and when he was in good form, his grip on the listener never slackened. Riesz lived alone and these personal lectures took place sometimes in his home, sometimes in his favourite café and sometimes over the telephone. ... He worked constantly, often at late hours and periodically with great intensity. These habits did not change much with advancing age ...
Riesz retired in 1952 and went to the United States. He spent ten years in several different universities such as Maryland and Chicago. He gave an important series of lectures Clifford numbers and spinors at the University of Maryland between October 1957 and January 1958. The first four of six intended chapters was published in 1958 but, despite the title, these published notes do not reach spinors. In 1993 a facsimile reproduction of Riesz's notes from these lectures was published. D Lambert writes:-
The seminal material which contributed greatly to the start of modern research on Clifford algebras is supplemented by notes which Riesz dictated to Folke Bolinder in the following year and which were intended to be a fifth chapter of the Riesz lecture notes.
After spending ten years in the United States during which time he continued to work for many hours a day, Riesz suffered a breakdown in 1962 and returned to Lund. He continued to work after this but at nothing like the intensity that had typified his whole life up to that point. During the final seven years of his life his health deteriorated steadily and he [6]:-
... bore the burden of his last illness with great courage.
Among the many honours Riesz received, let us mention his election to the Swedish Academy of Sciences, the Physiographical Society in Lund, and the Videnska Selskab in Copenhagen. He was awarded honorary degrees from the universities of Copenhagen and Lund and an honorary membership of the Swedish Mathematical Society.

References (show)

  1. Biography in Dictionary of Scientific Biography (New York 1970-1990). See THIS LINK.
  2. E F Bolinder and P Lounesto, Marcel Riesz: Clifford Numbers and Spinors , (Kluwer, 1993).
  3. L Garding and L Hörmander (eds.), Marcel Riesz : Collected papers (Springer-Verlag, Berlin, 1988).
  4. M L Cartwright, Manuscripts of Hardy, Littlewood, Marcel Riesz and Titchmarsh, Bull. London Math. Soc. 14 (6) (1982), 472-532.
  5. J J Duistermaat, M Riesz's families of operators, Nieuw Arch. Wisk. (4) 9 (1) (1991), 93-101.
  6. L Garding, Marcel Riesz in Memoriam, Acta Mathematica 124 (1970), x-xi.
  7. J Horváth, The mathematical work of Marcel Riesz I (Hungarian), Mat. Lapok 26 (1-2) (1975), 11-37.
  8. J Horváth, The mathematical work of Marcel Riesz II (Hungarian), Mat. Lapok 28 (1-3) (1980), 65-100.
  9. J Horváth, L'oeuvre mathématique de Marcel Riesz I, Proceedings of the Seminar on the History of Mathematics 3 (Paris, 1982), 83-121.
  10. J Horváth, L'oeuvre mathématique de Marcel Riesz II, Proceedings of the Seminar on the History of Mathematics 4 (Paris, 1983), 1-59.
  11. J Peetre, Marcel Riesz in Lund, Function spaces and applications, Lecture Notes in Math. 1302 (Berlin-New York, 1988), 1-10.
  12. J D Stegeman, Marcel Riesz: collected papers, Nieuw Arch. Wisk. (4) 9 (1) (1991), 87-91.

Additional Resources (show)

Cross-references (show)

Written by J J O'Connor and E F Robertson
Last Update November 2006