'Élie Joseph Cartan' (
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.
He was the father of another influential mathematician,
Henri Cartan.
Life
Élie Cartan was born in the village of
Dolomieu in
Savoie, the son of a blacksmith. He became a student at the
École Normale Superieure in Paris in 1888 and obtained his doctorate in 1894. He subsequently held lecturing positions in
Montpellier and
Lyon, becoming a professor in
Nancy in 1903. He took a lecturing position at the
Sorbonne in Paris in 1909, becoming professor there in 1912 until his retirement in 1940. He died in Paris after a long illness. He was the father of the mathematician
Henri Cartan.
Work
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.
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.
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.
In the ''Travaux'', he breaks down his work into 15 areas. Using modern terminology, they are these:
# Lie groups
#
Representations of Lie groups
#
Hypercomplex numbers,
division algebras
# Systems of PDEs,
Cartan–Kähler theorem
#
Theory of equivalence
#
Integrable systems, theory of prolongation and systems in involution
# Infinite-dimensional groups and
pseudogroups
#
Differential geometry and
moving frames
# Generalised spaces with structure groups and
connections,
Cartan connection,
holonomy,
Weyl tensor
# Geometry and topology of Lie groups
#
Riemannian geometry
#
Symmetric spaces
# Topology of
compact groups and their
homogeneous spaces
# Integral invariants and
classical mechanics
#
Relativity,
spinors
Influence and legacy
Most of these topics have been worked over thoroughly by later mathematicians. That cannot be said of all of them: while Cartan's own methods were remarkably unified, in the majority of cases the subsequent work can be said to have removed his characteristic touch. That is, it became more algebraic.
To look at some of those less mainstream areas:
★ the PDE theory has to take into account singular solutions (i.e.
envelopes), such as are seen in
Clairaut's equation;
★ the prolongation method is supposed to terminate in a system ''in involution'' (this is an analytic theory, rather than smooth, and leads to the theory of formal integrability and
Spencer cohomology);
★ the
equivalence problem, as he put it, is to construct differential isomorphisms of structures (and discover thereby the invariants) by forcing their graphs to be integral manifolds of a differential system;
★ the moving frames method, as well as being connected to
principal bundles and their connections, should also use frames adapted to geometry;
★ these days, the
jet bundle method of
Ehresmann is applied to use
contact as a systematic equivalence relation.
There is a sense, therefore, in which the distinctive side of Cartan's work is still being digested by
mathematicians. This is constantly seen in areas such as
calculus of variations,
Bäcklund transformations and the general theory of differential systems; roughly speaking those parts of differential algebra which feel that the existing,
Galois theory-led model of symmetry is too narrow and requires something more analogous to a category of relations.
See also
★
Cartan connection,
Cartan connection applications
★
Cartan matrix
★
Cartan's theorem
★
Cartan subalgebra
★
Cartan's equivalence method
★
Einstein–Cartan theory
★
Integrability conditions for differential systems
★
CAT(''k'') space
References
External links
★ Shiing-Shen Chern and Claude Chevalley,
''Élie Cartan and his mathematical work'', Bull. Amer. Math. Soc. '58' (1952), 217-250.
★ J. H. C. Whitehead, ''Elie Joseph Cartan 1869-1851,'' Obituary Notices of Fellows of the Royal Society, Vol. 8, No. 21 (Nov., 1952), pp. 71-95.
★
★
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