Weyl Group Symmetric Functions and the Representation Theory of Lie Algebras

Arun Ram
Department of Mathematics and Statistics
University of Melbourne
Parkville, VIC 3010 Australia
aram@unimelb.edu.au

Last update: 11 September 2013

Centralizer algebras

Let $M$ be a finite dimensional module for a semisimple Lie algebra or its enveloping algebra $𝔘 .$ By Weyl's complete reduciblity theorem we know that $M$ decomposes as a direct sum of irreducible $𝔘$ modules $V^{λ},$ with certain multiplicities $c_{λ},$ $M ≅ ⨁_{λ \in \hat{M}} c_{λ} V^{λ} .$ $M$ denotes the set of $λ \in P^{+}$ such that $V^{λ}$ appears in the decomposition of $M .$ Let $C$ be the centralizer of the action of $𝔘$ on $M,$ i.e. $C = {End}_{𝔘} (M) .$ The following theorem is the basic result of the double centralizer theory.

$M$ is a bimodule for $C \times 𝔘$ and $M ≅ ⨁_{λ \in \hat{M}} C_{λ} \otimes V^{λ},$ where $C_{λ}$ is an irreducible module for $C .$

This decomposition induces a pairing between the irreducible modules $C_{λ}$ of $C$ and irreducible $𝔘$ modules $V^{λ},$ $λ \in \hat{M} .$ It is true that the set of $C_{λ},$ $λ \in \hat{M},$ is a complete set of irreducible modules of $C .$ The pairing between irreducible $C$ modules and the irreducible $𝔘$ modules appearing as factors in $M$ can be given in terms of characters. By definition, a character of $C$ is a linear functional $ξ : C \to ℂ$ such that $ξ (c_{1} c_{2}) = ξ (c_{2} c_{1}),$ for all $c_{1}, c_{2} \in ℂ .$ Let $\hat{C}$ be the vector space of characters of $C .$ Given a $C -module$ $M$ the character $ξ$ of $C$ corresponding to $M$ is given by defining $ξ (c),$ $c \in C,$ to be the trace of the action of $c$ on $M .$ Let $ξ_{λ}$ denote the irreducible character of $C$ corresponding to the irreducible $C -module$ $C_{λ} .$ For each $λ \in P^{+}$ let $χ^{λ}$ denote the corresponding Weyl character for $𝔘 .$ Let $Λ_{\hat{M}}$ be the vector space which is the span of the $χ^{λ},$ $λ \in \hat{M} .$ Define the characteristic map $ch$ to be the map given by $\begin{matrix} ch : & \hat{C} & ⟶ & Λ_{\hat{M}} \\ ξ_{λ} & ⟼ & χ^{λ} \end{matrix}$

For each $μ = \sum_{i} μ_{i} ω_{i} \in P$ define the $μ -weight$ space of $M$ to be the vector space $M_{μ} = {m \in M | for each 1 \leq i \leq n, h_{i} m = μ_{i} m} .$ Let $𝔘 (𝔥)$ be the subalgebra of $𝔘$ generated by the $h_{i} .$ $M$ decomposes as a direct sum of weight spaces under the action of $𝔘 (𝔥),$ $\begin{matrix} M ≅ ⨁_{μ \in P} M_{μ} . & (4.2) \end{matrix}$ Since $𝔘 (𝔥)$ is a subalgebra of $𝔘$ each $M_{μ}$ is a $C$ module. The bicharacter of $M$ is defined to be $\begin{matrix} bichar M = \sum_{μ \in P} η_{μ} e^{μ}, & (4.3) \end{matrix}$ where $η_{μ}$ denotes the character of $M_{μ}$ as a $C -module.$ In view of the decomposition in (4.1) we also have $\begin{matrix} bichar M = \sum_{λ \in \hat{M}} ξ_{λ} χ^{λ} . & (4.4) \end{matrix}$

Construction of irreducible modules for centralizer algebras

Consider the action of the generators $x_{i} \in 𝔘$ on the weight spaces $M_{μ}$ of $M .$ For each $μ \in P$ $x_{i} : M_{μ} ⟶ M_{μ + α_{i}} .$ Let ${ker}_{μ} (x_{i})$ denote the kernel of the map $x_{i}$ acting on $M_{μ} .$ Let ${\overline{C}}_{μ} = ⋂_{i} {ker}_{μ} (x_{i}) .$

1)	$\overline{C} μ$ is either $0$ or an irreducible $C$ module. Furthermore all irreducible $C$ modules can be obtained in this fashion.
2)	${\overline{C}}_{μ} \neq 0 ⟺ μ \in \hat{M} .$

Proof.

Using (4.1) we have that $M_{μ} = \oplus_{λ \in \hat{M}} C_{λ} \otimes {(V^{λ})}_{μ} .$ But the only weight in $V^{λ}$ killed by all $x_{i}$ is $λ .$ So there are no elements of ${(V^{λ})}_{μ}$ in the $\cap_{i} {ker}_{μ} (x_{i})$ unless $λ = μ .$ When $λ = μ .$ we have ${(V^{μ})}_{μ} \subseteq {ker}_{μ} (x_{i}) .$ Thus $\begin{matrix} {\overline{C}}_{μ} & = & ⋂_{i} {ker}_{μ} (x_{i}) \\ ≅ & ⨁_{λ \in \hat{M}} C_{λ} \otimes {(V^{λ})}_{μ} δ_{λ μ} \\ ≅ & C_{μ}, \end{matrix}$ as $C -modules.$

$□$

A character formula for $C_{λ}$

The character of the irreducible $C -module$ $C_{λ}$ can be given by $ξ_{λ} = \sum_{w \in W} ε (w) η_{λ + ρ - w ρ},$ where $η_{μ}$ is the character of $M_{μ}$ as a $C -module.$

Proof.

Equating the expressions (4.3) and (4.4) and rewriting $χ^{λ}$ by using (2.8) we have $\sum_{λ} ξ_{λ} \sum_{w \in W} ε (w) e^{w (λ + ρ) - ρ} = \sum_{μ \in P} \sum_{w \in W} η_{μ} ε (w) e^{μ + w ρ - ρ} .$ Substitute $γ = μ + w ρ - ρ$ to get $\sum_{λ} ξ_{λ} \sum_{w \in W} ε (w) e^{w (λ + ρ) - ρ} = \sum_{μ \in P} (\sum_{w \in W} ε (w) η_{γ + ρ - w ρ}) e^{γ} .$ Compare coefficients of $e^{γ}$ for $γ \in P^{+}$ on each side of this equation. Since $λ \in P^{+}$ we know by (2.3) that $w (λ + ρ) - ρ$ is not an element of $P^{+}$ for any $w \in W$ except the identity. Thus $ξ_{λ} = \sum_{w \in W} ε (w) η_{λ + ρ - w ρ} .$

$□$

The dimension $c_{λ}$ of the irreducible $C -module$ $C_{λ}$ is given by $c_{λ} = \sum_{w \in W} ε (w) d_{λ + ρ - w ρ},$ where $d_{μ}$ is the dimension of the weight space $M_{μ} .$

Proof.

Evaluate the identity in Theorem (4.6) at the identity of $C .$

$□$

Notes and references

This is an excerpt of a paper entitled Weyl Group Symmetric Functions and the Representation Theory of Lie Algebras, written by Arun Ram.

page history