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Élie Cartan

Élie Cartan
Professor Élie Joseph Cartan
Born (1869-04-09)9 April 1869
Dolomieu, Isère, France
Died 6 May 1951(1951-05-06) (aged 82)
Paris, France
Nationality France
Fields Mathematics and physics
Institutions University of Paris
(École Normale Supérieure)
Alma mater University of Paris
Doctoral advisor Gaston Darboux
Sophus Lie
Doctoral students Charles Ehresmann
Mohsen Hashtroodi
Radu Rosca
Kentaro Yano
Known for Lie groups
Differential geometry
Special and general relativity
Quantum mechanics : spinor, rotating vectors
Notable awards Leconte Prize (1930)
Lobachevsky Prize (1937)
Fellow of the Royal Society[1]

Élie Joseph Cartan (French: ; 9 April 1869 – 6 May 1951) was an influential French mathematician who did fundamental work in the theory of Lie groups and their geometric applications. He also made significant contributions to mathematical physics, differential geometry, and group theory.[2][3] He was the father of another influential mathematician, Henri Cartan, and the composer Jean Cartan.

Contents

  • Life 1
  • Work 2
  • See also 3
  • Publications 4
  • References 5
  • External links 6

Life

Élie Cartan was born in the village of

  • "On certain differential expressions and the Pfaff problem"
  • "On the integration of systems of total differential equations"
  • Lessons on integral invariants.
  • "The structure of infinite groups"
  • "Spaces with conformal connections"
  • "On manifolds with projective connections"
  • "The unitary theory of Einstein-Mayer"
  • "E. Cartan, Exterior Differential Systems and its Applications, (Translated in to English by M. Nadjafikhah)"

English translations of some of his books and articles:

External links

  1. ^  
  2. ^  .
  3. ^ Élie Cartan at the Mathematics Genealogy Project
  4. ^ Neurath, Otto (1938). "Unified Science as Encyclopedic Integration".  
  5. ^ "Élie J. Cartan (1869 - 1951)". Royal Netherlands Academy of Arts and Sciences. Retrieved 19 July 2015. 
  6. ^ Levy, Harry (1935). ""Review: La Méthode de Repère Mobile, La Théorie des Groupes Continus, et Les Espaces Généralisés. Bull. Amer. Math. Soc. 41 (11): 774.  
  7. ^ Vanderslice, J. L. (1938). "Leçons sur la théorie des espaces à connexion projective"Review: . Bull. Amer. Math. Soc. 44 (1, Part 1): 11–13.  
  8. ^  
  9. ^  
  10. ^ Ruse, Harold Stanley (July 1939). by E. Cartan"Leçons sur le theórie des spineurs"Review: . The Mathematical Gazette 23 (255): 320–323.  
  11. ^ Thomas, J. M. (1947). "Les systèmes différentiels extérieurs et leurs applications géométriques"Review: . Bull. Amer. Math. Soc. 53 (3): 261–266.  

References

  • Cartan, Élie (1894), Sur la structure des groupes de transformations finis et continus, Thesis, Nony 
  • Leçons sur les invariants intégraux, Hermann, Paris, 1922
  • La Géométrie des espaces de Riemann, 1925
  • Leçons sur la géométrie des espaces de Riemann, Gauthiers-Villars, 1928
  • La théorie des groups finis et continus et l'analysis situs, Gauthiers-Villars, 1930
  • Leçons sur la géométrie projective complexe, Gauthiers-Villars, 1931
  • La parallelisme absolu et la théorie unitaire du champ, Hermann, 1932
  • La méthode de repère mobile, la théorie des groupes continus, et les espaces généralisés, 1935[6]
  • Leçons sur la théorie des espaces à connexion projective, Gauthiers-Villars, 1937[7]
  • La théorie des groupes finis et continus et la géométrie différentielle traitées par la méthode du repère mobile, Gauthiers-Villars, 1937[8]
  • Cartan, Élie (1981) [1938], The theory of spinors, New York: [10][9] 
  • Les systèmes différentiels extérieurs et leurs applications géométriques, Hermann, 1945[11]
  • Oeuvres complètes, 3 parts in 6 vols., Paris 1952 to 1955, reprinted by CNRS 1984:
    • Part 1: Groupes de Lie (in 2 vols.), 1952
    • Part 2, Vol. 1: Algèbre, formes différentielles, systèmes différentiels, 1953
    • Part 2, Vol. 2: Groupes finis, Systèmes différentiels, théories d'équivalence, 1953
    • Part 3, Vol. 1: Divers, géométrie différentielle, 1955
    • Part 3, Vol. 2: Géométrie différentielle, 1955

Publications

See also

  1. Lie theory
  2. Representations of Lie groups
  3. Hypercomplex numbers, division algebras
  4. Systems of PDEs, Cartan–Kähler theorem
  5. Theory of equivalence
  6. Integrable systems, theory of prolongation and systems in involution
  7. Infinite-dimensional groups and pseudogroups
  8. Differential geometry and moving frames
  9. Generalised spaces with structure groups and connections, Cartan connection, holonomy, Weyl tensor
  10. Geometry and topology of Lie groups
  11. Riemannian geometry
  12. Symmetric spaces
  13. Topology of compact groups and their homogeneous spaces
  14. Integral invariants and classical mechanics
  15. Relativity, spinors

In the Travaux, he breaks down his work into 15 areas. Using modern terminology, they are these:

With these basics — Lie groups and differential forms — he went on to produce a very large body of work, and also some general techniques such as moving frames, that were gradually incorporated into the mathematical mainstream.

He defined the general notion of anti-symmetric differential form, in the style now used; his approach to Lie groups through the Maurer–Cartan equations required 2-forms for their statement. At that time what were called Pfaffian systems (i.e. first-order differential equations given as 1-forms) were in general use; by the introduction of fresh variables for derivatives, and extra forms, they allowed for the formulation of quite general PDE systems. Cartan added the exterior derivative, as an entirely geometric and coordinate-independent operation. It naturally leads to the need to discuss p-forms, of general degree p. Cartan writes of the influence on him of Charles Riquier’s general PDE theory.

By his own account, in his Notice sur les travaux scientifiques, the main theme of his works (numbering 186 and published throughout the period 1893–1947) was the theory of Lie groups. He began by working over the foundational material on the complex simple Lie algebras, tidying up the previous work by Friedrich Engel and Wilhelm Killing. This proved definitive, as far as the classification went, with the identification of the four main families and the five exceptional cases. He also introduced the algebraic group concept, which was not to be developed seriously before 1950.

Work

In 1937 he became foreign member of the Royal Netherlands Academy of Arts and Sciences.[5]

He died in Paris after a long illness. [4]

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