Representations of semisimple Lie algebras

Abstract

In this chapter, we study representations of complex semisimple Lie algebras. Recall that by results of Section 6.3, every finite-dimensional representation is completely reducible and thus can be written in the form V = ⊕ n i V i , where V i are irreducible representations and n i ∈ ℤ + are the multiplicities. Thus, the study of representations reduces to classification of irreducible representations and finding a way to determine, for a given representation V , the multiplicities n i . Both of these questions have a complete answer, which will be given below. Throughout this chapter, g is a complex finite-dimensional semisimple Lie algebra. We fix a choice of a Cartan subalgebra and thus the root decomposition g = h ⊕⊕ R g α (see Section 6.6). We will freely use notation from Chapter 7; in particular, we denote by α i , i = 1 … r , simple roots, and by s i ∈ W corresponding simple reflections. We will also choose a non-degenerate invariant symmetric bilinear form (,) on g . All representations considered in this chapter are complex and unless specified otherwise, finite-dimensional. Weight decomposition and characters As in the study of representations of sl(2, ℂ) (see Section 4.8), the key to the study of representations of g is decomposing the representation into the eigenspaces for the Cartan subalgebra. Definition 8.1. Let V be a representation of g . A vector u ∈ V is called a vector of weight λ ∈ h * if, for any h ∈ h, one has hu = 〈λ, h 〉 u .