The initial construction by Élie Cartan and Wilhelm Killing of finite dimensional simple Lie algebras from the Cartan integers was type dependent. In 1966 Jean-Pierre Serre showed that relations of Claude Chevalley and Harish-Chandra, with simplifications by Nathan Jacobson, give a defining presentation for the Lie algebra. One could thus describe a simple Lie algebra in terms of generators and relations using data from the matrix of Cartan integers, which is naturally positive definite. "Almost simultaneously in 1967, Victor Kac in the USSR and Robert Moody in Canada developed what was to become Kac–Moody algebra. Kac and Moody noticed that if Wilhelm Killing's conditions were relaxed, it was still possible to associate to the Cartan matrix a Lie algebra which, necessarily, would be infinite dimensional." – A. J. Coleman In his 1967 thesis, Robert Moody considered Lie algebras whose Cartan matrix is no longer positive definite. This still gave rise to a Lie algebra, but one which is now infinite dimensional. Simultaneously, Z-graded Lie algebras were being studied in Moscow where I. L. Kantor introduced and studied a general class of Lie algebras including what eventually became known as Kac–Moody algebras. Victor Kac was also studying simple or nearly simple Lie algebras with polynomial growth. A rich mathematical theory of infinite dimensional Lie algebras evolved. An account of the subject, which also includes works of many others is given in. See also.
Definition
A Kac–Moody algebra may be defined by first giving the following:
A set of nlinearly independent elements of and a set of n linearly independent elements of the dual space, such that. The are analogue to the simple roots of a semi-simple Lie algebra, and the to the simple coroots.
The Kac–Moody algebra is then the Lie algebra defined by generators and and the elements of and relations
A real Lie algebra is also considered a Kac–Moody algebra if its complexification is a Kac–Moody algebra.
Root-space decomposition of a Kac–Moody algebra
is the analogue of a Cartan subalgebra for the Kac–Moody algebra. If is an element of such that for some, then is called a root vector and is a root of. The set of all roots of is often denoted by and sometimes by. For a given root, one denotes by the root space of ; that is, It follows from the defining relations of that and. Also, if and, then by the Jacobi identity. A fundamental result of the theory is that any Kac–Moody algebra can be decomposed into the direct sum of and its root spaces, that is and that every root can be written as with all the being integers of the same sign.
Types of Kac–Moody algebras
Properties of a Kac–Moody algebra are controlled by the algebraic properties of its generalized Cartan matrix C. In order to classify Kac–Moody algebras, it is enough to consider the case of an indecomposable matrix C, that is, assume that there is no decomposition of the set of indices I into a disjoint union of non-empty subsets I1 and I2 such that Cij = 0 for all i in I1 and j in I2. Any decomposition of the generalized Cartan matrix leads to the direct sum decomposition of the corresponding Kac–Moody algebra: where the two Kac–Moody algebras in the right hand side are associated with the submatrices of C corresponding to the index setsI1 and I2. An important subclass of Kac–Moody algebras corresponds to symmetrizable generalized Cartan matrices C, which can be decomposed as DS, where D is a diagonal matrix with positive integer entries and S is a symmetric matrix. Under the assumptions that C is symmetrizable and indecomposable, the Kac–Moody algebras are divided into three classes:
An indefinite matrixS gives rise to a Kac–Moody algebra of indefinite type.
Since the diagonal entries of C and S are positive, S cannot be negative definite or negative semidefinite.
Symmetrizable indecomposable generalized Cartan matrices of finite and affine type have been completely classified. They correspond to Dynkin diagrams and affine Dynkin diagrams. Little is known about the Kac–Moody algebras of indefinite type, although the groups corresponding to these Kac–Moody algebras were constructed over arbitrary fields by Jacques Tits. Among the Kac–Moody algebras of indefinite type, most work has focused on those hyperbolic type, for which the matrix S is indefinite, but for each proper subset of I, the corresponding submatrix is positive definite or positive semidefinite. Hyperbolic Kac–Moody algebras have rank at most 10, and they have been completely classified. There are infinitely many of rank 2, and 238 of ranks between 3 and 10.