Affine Lie algebra

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In mathematics, an affine Lie algebra is an infinite-dimensional Lie algebra that is constructed in a canonical fashion out of a finite-dimensional simple Lie algebra. It is a Kac–Moody algebra for which the generalized Cartan matrix is positive semi-definite and has corank 1. From purely mathematical point of view, affine Lie algebras are interesting because their representation theory, like representation theory of finite dimensional, semisimple Lie algebras is much better understood than that of general Kac–Moody algebras. As observed by Victor Kac, the character formula for representations of affine Lie algebras implies certain combinatorial identities, the Macdonald identities.

Affine Lie algebras play an important role in string theory and conformal field theory due to the way they are constructed: starting from a simple Lie algebra \mathfrak{g}, one considers the loop algebra, L\mathfrak{g}, formed by the \mathfrak{g}-valued functions on a circle (interpreted as the closed string) with pointwise commutator. The affine Lie algebra \hat{\mathfrak{g}} is obtained by adding one extra dimension to the loop algebra and modifying a commutator in a non-trivial way, which physicists call a quantum anomaly (in this case, the anomaly of the WZW model) and mathematicians a central extension. More generally, if σ is an automorphism of the simple Lie algebra \mathfrak{g} associated to an automorphism of its Dynkin diagram, the twisted loop algebra L_\sigma\mathfrak{g} consists of \mathfrak{g}-valued functions f on the real line which satisfy the twisted periodicity condition f(x+2π) = σ f(x). Their central extensions are precisely the twisted affine Lie algebras. The point of view of string theory helps to understand many deep properties of affine Lie algebras, such as the fact that the characters of their representations transform amongst themselves under the modular group.

Affine Lie algebras from simple Lie algebras

Definition

If \mathfrak{g} is a finite dimensional simple Lie algebra, the corresponding affine Lie algebra \hat{\mathfrak{g}} is constructed as a central extension of the infinite-dimensional Lie algebra \mathfrak{g}\otimes\mathbb{C}[t,t^{-1}], with one-dimensional center \mathbb{C}c. As a vector space,

\widehat{\mathfrak{g}}=\mathfrak{g}\otimes\mathbb{C}[t,t^{-1}]\oplus\mathbb{C}c,

where \mathbb{C}[t,t^{-1}] is the complex vector space of Laurent polynomials in the indeterminate t. The Lie bracket is defined by the formula

[a\otimes t^n+\alpha c, b\otimes t^m+\beta c]=[a,b]\otimes t^{n+m}+\langle a|b\rangle n\delta_{m+n,0}c

for all a,b\in\mathfrak{g}, \alpha,\beta\in\mathbb{C} and n,m\in\mathbb{Z}, where [a,b] is the Lie bracket in the Lie algebra \mathfrak{g} and \langle\cdot |\cdot\rangle is the Cartan-Killing form on \mathfrak{g}.

The affine Lie algebra corresponding to a finite-dimensional semisimple Lie algebra is the direct sum of the affine Lie algebras corresponding to its simple summands. There is a distinguished derivation of the affine Lie algebra defined by

 \delta (a\otimes t^m+\alpha c) = t{d\over dt} (a\otimes t^m).

The corresponding affine Kac-Moody algebra is defined by adding an extra generator d satisfying [d,A] = δ(A) (a semidirect product).

Constructing the Dynkin diagrams

The Dynkin diagram of each affine Lie algebra consists of that of the corresponding simple Lie algebra plus an additional node, which corresponds to the addition of an imaginary root. Of course, such a node cannot be attached to the Dynkin diagram in just any location, but for each simple Lie algebra there exists a number of possible attachments equal to the cardinality of the group of outer automorphisms of the Lie algebra. In particular, this group always contains the identity element, and the corresponding affine Lie algebra is called an untwisted affine Lie algebra. When the simple algebra admits automorphisms that are not inner automorphisms, one may obtain other Dynkin diagrams and these correspond to twisted affine Lie algebras.

Dynkin diagrams for affine Lie algebras
Affine Dynkin diagrams.png
The set of extended (untwisted) affine Dynkin diagrams, with added nodes in green
Twisted affine Dynkin diagrams.png
"Twisted" affine forms are named with (2) or (3) superscripts.
(k is the number of nodes in the graph)

Classifying the central extensions

The attachment of an extra node to the Dynkin diagram of the corresponding simple Lie algebra corresponds to the following construction. An affine Lie algebra can always be constructed as a central extension of the loop algebra of the corresponding simple Lie algebra. If one wishes to begin instead with a semisimple Lie algebra, then one needs to centrally extend by a number of elements equal to the number of simple components of the semisimple algebra. In physics, one often considers instead the direct sum of a semisimple algebra and an abelian algebra \mathbb{C}^n. In this case one also needs to add n further central elements for the n abelian generators.

The second integral cohomology of the loop group of the corresponding simple compact Lie group is isomorphic to the integers. Central extensions of the affine Lie group by a single generator are topologically circle bundles over this free loop group, which are classified by a two-class known as the first Chern class of the fibration. Therefore, the central extensions of an affine Lie group are classified by a single parameter k which is called the level in the physics literature, where it first appeared. Unitary highest weight representations of the affine compact groups only exist when k is a natural number. More generally, if one considers a semi-simple algebra, there is a central charge for each simple component.

Representation theory

The representation theory for affine Lie algebras is usually developed using Verma modules. Just as in the case of semi-simple Lie algebras, these can be gotten as the highest weight modules. There are no finite-dimensional representations; this follows from the fact that the null vectors of a finite-dimensional Verma module are necessarily zero; whereas those for the affine Lie algebras are not. Roughly speaking, this follows because the Killing form is Lorentzian in the c,\delta directions, thus (z, \bar{z}) are sometimes called "lightcone coordinates" on the string. The "radially ordered" current operator products are can be understood to be time-like normal ordered by taking z=\exp(\tau + i\sigma) with \tau the time-like direction along the string world sheet and \sigma the spatial direction.

Weyl group and characters

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The Weyl group of an affine Lie algebra can be written as a semi-direct product of the Weyl group of the zero-mode algebra (the Lie algebra used to define the loop algebra) and the coroot lattice.

The Weyl character formula of the algebraic characters of the affine Lie algebras generalizes to the Weyl-Kac character formula. A number of interesting constructions follow from these. One may construct generalizations of the Jacobi theta function. These theta functions transform under the modular group. The usual denominator identities of semi-simple Lie algebras generalize as well; because the characters can be written as "deformations" or q-analogs of the highest weights, this led to many new combinatoric identities, include many previously unknown identities for the Dedekind eta function. These generalizations can be viewed as a practical example of the Langlands program.

Applications

They appear naturally in theoretical physics (for example, in conformal field theories such as the WZW model and coset models and even on the worldsheet of the heterotic string), geometry, and elsewhere in mathematics.

References

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