In mathematics, the Cartan decomposition is a decomposition of a semisimple Lie group or Lie algebra, which plays an important role in their structure theory and representation theory.
Its history can be traced to the 1880s work of Élie Cartan and Wilhelm Killing.
be a real semisimple Lie algebra and let
whose square is equal to the identity.
is a positive definite bilinear form.
are considered equivalent if they differ only by an inner automorphism.
Any real semisimple Lie algebra has a Cartan involution, and any two Cartan involutions are equivalent.
be an involution on a Lie algebra
denote the eigenspaces corresponding to +1 and -1, respectively, then
is a Lie algebra automorphism, the Lie bracket of two of its eigenspaces is contained in the eigenspace corresponding to the product of their eigenvalues.
with these extra properties determines an involution
is also called a Cartan pair of
is called a symmetric pair.
This notion of a Cartan pair here is not to be confused with the distinct notion involving the relative Lie algebra cohomology
The special feature of a Cartan decomposition is that the Killing form is negative definite on
are orthogonal complements of each other with respect to the Killing form on
be a non-compact semisimple Lie group and
be the resulting Cartan pair.
is also called the global Cartan involution, and the diffeomorphism
is called the global Cartan decomposition.
For the general linear group,
[clarification needed] A refinement of the Cartan decomposition for symmetric spaces of compact or noncompact type states that the maximal Abelian subalgebras
In the compact and noncompact case the global Cartan decomposition thus implies Geometrically the image of the subgroup
is a totally geodesic submanifold.
is the real Lie algebra of skew-symmetric matrices, so that
is the subspace of symmetric matrices.
Thus the exponential map is a diffeomorphism from
onto the space of positive definite matrices.
Up to this exponential map, the global Cartan decomposition is the polar decomposition of a matrix.
The polar decomposition of an invertible matrix is unique.