Heinrich Martin Georg Friedrich Weber

Quick Info

5 March 1842
Heidelberg, Germany
17 May 1913
Strasbourg, Germany (now France)

Heinrich Weber was a German mathematician whose main work was in algebra, number theory, analysis and applications of analysis to mathematical physics.


Heinrich Weber was born in Heidelberg, the son of Georg Weber (1808-1888) who was an historian, author of History of the World, and principal of a high school. Georg Weber had been born in the Rhine Palatinate town of Bergzabern, which was at this time under French rule, and studied at Speyer and the University of Erlangen before being awarded a doctorate from the University of Heidelberg in 1832 for his dissertation De Gytheo et rebus navalibus Lacedaemoniorum . He married Ida Helene Marie Wilhelmine Becher (died 1887) in 1839 and Heinrich was their eldest son. Heinrich's love of mathematics began while he was at the Lyceum in Heidelberg. There he was taught by Arthur Arneth (1802-1858) who was professor of mathematics and physics at the Lyceum and also a privatdozent at the University of Heidelberg. Arneth wrote the important book History of Pure Mathematics in its Relation to the History of the Development of the Human Mind (1852). The Weber family were very involved in education and they strongly encouraged Heinrich to think in terms of an academic career from a young age. The influence of Weber's family was particularly strong since he lived at home throughout his school and university studies in Heidelberg.

After graduating from the Lyceum, Weber entered the University of Heidelberg in 1860 to study mathematics and physics. At this time Heidelberg had some outstanding physicists and mathematicians on the staff who gave courses that Weber attended. These included Gustav Kirchhoff (appointed to Heidelberg in 1854), Robert Bunsen (appointed to Heidelberg in 1852), Hermann von Helmholtz (appointed to Heidelberg in 1858), Otto Hesse (appointed to Heidelberg in 1856), and Moritz Cantor (appointed to Heidelberg in 1853). As was the common practice of German students at this time, Weber spent part of his time studying at a different university. He chose the University of Leipzig in the middle of his studies, spending a semester there in 1862 before returning to Heidelberg to complete his education. He was awarded a doctorate from the University of Heidelberg on 19 February 1863 having been advised by Otto Hesse. He was not required to write a thesis.

In order to become a university teacher, Weber needed to write a further thesis, his habilitation thesis. He went to Königsberg where he studied under Franz Neumann and Friedrich Julius Richelot, who had been a student of Jacobi. Although Jacobi had died over ten years before Weber began his studies at Königsberg, his influence was still strongly felt and it would not be unreasonable to say that Weber, through his teachers at Königsberg, was strongly influenced by Jacobi's style of mathematics. In [15] Peter Roquette examines why Weber went to Königsberg for his postgraduate study and notes that three of his teachers at Heidelberg, Hesse, Kirchhoff and Helmholtz, came from Königsberg:-
... academic life in Heidelberg around 1863, as far as mathematics and the neighbouring sciences were concerned, was flourishing, and that it was largely dominated by people who came from Königsberg. They knew the stimulating and challenging atmosphere which Königsberg offered to young mathematicians at that time. So it seems natural that young Weber, when he asked his academic teachers where he should go for his postdoctoral studies, was advised to move to Königsberg.
There were other students at Königsberg at this time who would become important in the development of mathematics, in particular Albert Wangerin, who studied for his doctorate around the same time as Weber worked for his habilitation, and former students such as Albert Clebsch whose influence was still being felt. In fact Weber mentions the names of nine of his fellow students at Königsberg who went on to high profile careers as scientists.

On 11 August 1866 Weber's habilitation thesis Singuläre Auflösungen partieller Differentialgleichungen erster Ordnung was accepted and he became a privatdozent at Heidelberg in that year. His habilitation thesis was published in Volume 66 of Crelle's journal. Three years later, on 20 July 1869, he was appointed as extraordinary professor at Heidelberg but later in the same year he accepted an appointment as a full professor at the Eidgenössische Technische Hochschule in Zürich. He married Emilie Dittenberger in 1870 in Zürich. Emilie was the daughter of a chaplain to the Weimar court. Heinrich and Emilie Weber had seven children, three of whom died young. A daughter, Emilie Weber, gained fame as the translator from French into German of Henri Poincaré's philosophical writings. Her translations were published in 1906 and she died in 1911. A son, Rudolph Heinrich Georg Weber, born 16 August 1874 in Zürich, went on to study mathematics and physics. Rudolph was appointed to the University of Heidelberg in 1902 but spent most of his career as professor of mathematical physics at the University of Rostock. Rudolph sometimes collaborated with his father and we mention in particular a joint publication on Gauss's work on fluids. Over the next twenty-five years, Heinrich Weber taught at a surprising number of different institutions. As well as teaching in Zürich at the Eidgenössische Polytechnikum, he also taught at the University of Königsberg from 1875 to 1883 having been appointed as Richelot's successor - Richelot, born in 1808, died in 1875.

Together with Richard Dedekind, Weber had been editing Riemann's Collected works and this important book was published in 1876. However, one of the most significant things to happen during his time teaching at Königsberg was in 1880 when two young students, David Hilbert and Hermann Minkowski, enrolled there. At this time Weber was lecturing on number theory, also gave a course on elliptic functions, and ran a seminar on the theory of invariants. All of these courses were attended by the young Hilbert (and probably also by Minkowski). The lecture notes from one of these courses has been preserved, the course on number theory, and Roquette gives an indication of the contents in [15]:-
Weber's course started from the very beginning of number theory, working through congruence calculus, continued fractions, towards quadratic reciprocity. After that, binary quadratic forms are discussed, their classes, their composition, and the analytic class number formulas. Also, the existence of primes in arithmetic progressions, using L-series, is included. In this last part the reader gets the impression that things went quite fast but the proofs are recorded in detail. We conclude that much of the concept of the lecture was based on Gauss's 'Disquisitiones' and Dirichlet's papers. In addition Weber was quite explicit in making use of modern notions, for instance the abstract notion of a group is to be found, as well as what we now call the "main theorem on finite abelian groups", i.e., decomposition of finite abelian groups into cyclic factors (in the context of description of characters).
After leaving Königsberg in 1883, Weber was appointed to the Technische Hochschule in Charlottenburg where he spent only one year before he moved again to the Philipps University of Marburg where he was rector of the university during session 1890-91. His next move, in 1892, was to the Georg-August University of Göttingen where he spent three years. His successor at Göttingen was Hilbert. While at Göttingen he published Die allgemeinen Grundlagen der Galois'schen Gleichungstheorie which is the first paper to contain a discussion of an abstract group, either finite or infinite. Weber's final post was to Strasbourg where he was appointed in 1895. It is reasonable to consider why Weber left Göttingen, perhaps the leading mathematical centre in the world at this time, to move to Strasbourg.

Germany had captured Strasbourg after a 50-day siege during the Franco-Prussian war of 1870-71 and annexed the city. After taking control of Alsace-Lorraine, the Germans had reorganised the University of Strasbourg and reopened it as the German Kaiser-Wilhelm University of Strasbourg in 1872. Two mathematics chairs were founded at this time, the first in Mathematics which was filled by Elwin Christoffel and the second in Geometry and Mechanics which was filled by Theodor Reye. Both Christoffel and Reye considered it their patriotic duty to assist in making the University of Strasbourg a German university. Christoffel had been forced to stop teaching in 1892 due to health problems and in 1894 retired leaving the chair vacant. However, Weber did not move to Strasbourg for mathematical reasons, but rather for personal ones. Strasbourg was quite close to Weber's native city of Heidelberg, and one of Weber's daughters, Lina Weber-Holtzmann, had married Heinrich Holtzmann, the professor of theology at Strasbourg, and was living there. Another reason was that his salary was higher in Strasbourg than Göttingen, at least in part because taxes in Alsace were significantly less than those in Prussia. Once he had arrived in Strasbourg he had as colleagues Theodor Reye and the extraordinary professor Adolph Krazer (1858-1926), a student of Friedrich Emil Prym (1841-1919).

Again Weber served as rector of the university in which he was working, taking on this role at Strasbourg during session 1900-01. Note that Weber served as rector three times during his career at three different universities. Weber remained in Strasbourg for the rest of his life and during this time it remained a German city; only at the end of the World War I in 1918 did the city revert to France. Of course, the reader of this biography will have noted the large number of different universities at which Weber worked. In fact he holds the record for the largest number of different university posts by any 19th century German mathematician.

Weber's main work was in algebra, number theory, analysis and applications of analysis to mathematical physics. This seems a contradiction in terms, for we have now almost said that Weber's main work spans the whole spectrum of mathematics. In fact this is not far from the truth for Weber's work was characterised by its breadth across a wide range of topics. To a certain extent this breadth can be attributed to the various influences on Weber from colleagues around him. The applications to mathematical physics certainly grew from working with Franz Neumann in Königsberg. But in Königsberg there was also the Jacobi influence, particularly coming through one of his other teachers Friedrich Richelot, which saw Weber doing important work on algebraic functions.

Perhaps Weber is today remembered for his outstanding text Lehrbuch der Algebra published in 1895 and it is for his work in algebra and number theory that he is best known. If he was influenced by his colleagues to work in different areas of mathematics then it is a very fair question to ask where the influence came from which prompted Weber to work on algebra and number theory. The answer must be Dedekind. He wrote an important paper with Dedekind, Theorie der algebraischen Funktionen einer Veränderlichen , published in 1882 in Crelle's journal, in which they examined algebraic functions from an algebraic rather than analytic point of view. In this paper [16]:-
... the notion of point on an abstract algebraic curve is defined for the first time in history, thus taking a decisive step towards the creation of modern algebraic geometry.
The third volume of Lehrbuch der Algebra , published in 1903, was dedicated by Weber to Dedekind, Hilbert and Minkowski:-
... the three men to whom I feel closest in scientific respect.
Weber's Lehrbuch der Algebra is an outstanding work but, although he tried hard to connect the various algebraic theories, even fundamental concepts such as a field and a group are only seen as tools and not properly developed as theories in their own right. It was, however, a remarkable book which was effective over many years as a teaching tool. James Pierpont writes in a review [13]:-
A classic from the day of its publication, it is destined to a long and useful career, a monument of honour to its genial author.
G A Miller wrote in 1913 [11]:-
Among the advanced text-books on algebra there is probably none which is more favourably known than Weber's "Lehrbuch der Algebra" in three large volumes.
For longer extracts from these reviews THIS LINK.

Norbert Schappacher writes 100 years after the book was published:-
[T]his work marks the transition from the late 19th century treatment of algebra to the "modern algebra" whose first full-fledged textbook treatment was going to be van der Waerden's well-known treatise of 1930-31. The third volume would not be called algebra today. It ... contains a classical treatment of elliptic functions, especially their arithmetic theory, along with parts of algebraic number theory and class field theory, as well as a small chapter on differentials of curves in the higher rank case including Riemann-Roch.
This third volume of Lehrbuch der Algebra was built on three papers he had written on class field theory entitled Über Zahlengruppen in algebraischen Zahlkörpern (1897-98). In these [16]:-
... he emphasized the decomposition behaviour, as opposed to Hilbert's chief interest in the unramifiedness of the (Hilbert) class field.
Among other books by Weber we mention Die Partiellen Differentialgleichungen der Mathematischen Physik and (with Josef Wellstein) Encyklopädie der Elementar-Mathematik .

Again extracts from reviews of these books are given at THIS LINK

Bruno Schoeneberg, in [1], comments on Weber as a teacher:-
Weber was an enthusiastic and inspiring teacher who took great interest in educational questions.
Voss writes of Weber's character in [21]:-
On closer contact he opened up without reservation to his friends whom he found through scientific cooperation and common interests.
Towards the end of Weber's life a number of tragedies affected him deeply. His wife Emilie died in 1901 and one of his daughters then looked after the household. However, this daughter died in 1909.

Weber received many honours including the publication of a Festschrift compiled by his friends and colleagues to celebrate his 70th birthday on 5 March 1912. He received an honorary doctorate from the University of Kristiana in 1902 at the time of Abel's centenary celebrations. He received an honorary doctorate from the University of Heidelberg in 1912. He was elected to the Göttingen Academy of Sciences (1875), the Berlin Academy of Science (1896), the Munich Academy of Sciences (1903), the Royal Swedish Academy of Sciences, the Uppsala Academy of Sciences, and the Accademia dei Lincei. He was elected president of the German Mathematical Society twice, in 1895 and again in 1904. He was also President of the International Congress of Mathematicians held in Heidelberg in 1904. From 1893 he served as an editor of the Mathematische Annalen.

References (show)

  1. B Schoeneberg, Biography in Dictionary of Scientific Biography (New York 1970-1990). See THIS LINK.
  2. Festschrift Heinrich Weber zu seinem siebzigsten Geburtstag am 5. März 1912 (New York, 1971).
  3. J S Ames, Review: Die Partiellen Differentialgleichungen der Mathematischen Physik (4th edition), by H Weber, Bull. Amer. Math. Soc. 8 (2) (1901), 81-85.
  4. R C Archibald, Review: Festschrift Heinrich Weber zu seinem siebzigsten Geburtstag am 5 März 1912, Bull. Amer. Math. Soc. 20 (3) (1913), 152-155.
  5. T A A B, Review: Encyklopädie der Elementar-Mathematik. Vol 1. Arithmetik, Algebra und Analysis (5th edition), by Heinrich Weber, Josef Wellstein and Paul Epstein, The Mathematical Gazette 19 (233) (1935), 159-160.
  6. Editors, Review: Encyklopädie der Elementar-Mathematik, Angewandte Elementar-Mathematik Vol 3, by Heinrich Weber and Josef Wellstein, The Mathematical Gazette 4 (67) (1907), 163.
  7. G Frei, Heinrich Weber and the emergence of class field theory, in Rowe and McCleary, The history of modern mathematics I (Academic Press, Boston, MA, 1989), 425-450.
  8. Heinrich Weber (1842-1913), in Dietrich Rauschning and Donata v Nerée, Die Albertus-Universität zu Königsberg und ihre Professoren, aus Anlass der Gründung der Albertus-Universität vor 450 Jahren (Duncker & Humblot, Berlin), 509-520.
  9. O D Kellog, Review: Die Partiellen Differentialgleichungen der Mathematischen Physik (5th edition), by H Weber, Bull. Amer. Math. Soc. 18 (2) (1911), 87-89.
  10. G B Mathews, Review: Die Partiellen Differentialgleichungen der Mathematischen Physik (4th edition), Vol 1, by Heinrich Weber, The Mathematical Gazette 2 (27) (1901), 51-52.
  11. G A Miller, Review: Lehrbuch der Algebra. Kleine Ausgabe in einem Bande, by Heinrich Weber, Science, New Series 38 (981) (1913), 550-551.
  12. F W Owens, Review: Encyklopädie der Elementar-Mathematik, by H Weber and J Wellstein, Bull. Amer. Math. Soc. 17 (10) (1911), 546.
  13. J Pierpont, Review: Lehrbuch der Algebra, by H Weber, Bull. Amer. Math. Soc. 4 (5) (1898), 200-234.
  14. J Pierpont, Review: Lehrbuch der Algebra (2nd edition), by H Weber, Bull. Amer. Math. Soc. 5 (10) (1899), 480-482.
  15. P Roquette, Heinrich Weber, David Hilbert and Königsberg, Hilbert Seminar, State University of Kaliningrad, Svedlogorsk (1 June 1992).
  16. N Schappacher, On the History of Hilbert's Twelfth Problem: A Comedy of Errors, Matériaux pour l'histoire des mathématiques au XXe siècle, Nice, 1996, Sémin. Congr. 3 (Société Mathématique de France, Paris, 1998), 243-273.
  17. N Schappacher and K Volkert, Heinrich Weber: un mathématicien à Strasbourg, 1895-1913, in Sciences et cultures - Les trois universités de Strasbourg 1872-1945 (1998).
  18. J B Shaw, Review: Encyklopädie der Elementar-Mathematik. Angewandte Elementar-Mathematik. (1st part, Vol 3) (2nd edition), by Heinrich Weber and Josef Wellstein, Bull. Amer. Math. Soc. 19 (2) (1912), 87-88.
  19. J B Shaw, Review: Encyklopädie der Elementar-Mathematik. Angewandte Elementar-Mathematik. (2nd part, Vol 3) (2nd edition), by Heinrich Weber and Josef Wellstein, Bull. Amer. Math. Soc. 19 (8) (1913), 422-423.
  20. D E Smith, Review: Encyklopädie der Elementar-Mathematik Vol 1, by H Weber and J Wellstein, Bull. Amer. Math. Soc. 10 (4) (1904), 200-204.
  21. A Voss, Heinrich Weber, Jahresberichte der Deutschen Mathematiker-Vereinigung 23 (1914), 431-444.
  22. H S White, Review: Encyklopädie der Elementar-Mathematik Vol 2 and Vol3, by H Weber and J Wellstein, Bull. Amer. Math. Soc. 14 (10) (1908), 499-501.
  23. J W Young, Review: Encyklopädie der Elementar-Mathematik. Vol 1. Arithmetik, Algebra und Analysis (4th edition), by Heinrich Weber, Josef Wellstein and Paul Epstein, Bull. Amer. Math. Soc. 29 (10) (1923), 480.

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Written by J J O'Connor and E F Robertson
Last Update July 2014