Representation on coordinate rings

In mathematics, a representation on coordinate rings is a representation of a group on coordinate rings of affine varieties.

Let X be an affine algebraic variety over an algebraically closed field k of characteristic zero with the action of a reductive algebraic group G.^[1] G then acts on the coordinate ring $k[X]$ of X as a left regular representation: $(g\cdot f)(x)=f(g^{-1}x)$ . This is a representation of G on the coordinate ring of X.

The most basic case is when X is an affine space (that is, X is a finite-dimensional representation of G) and the coordinate ring is a polynomial ring. The most important case is when X is a symmetric variety; i.e., the quotient of G by a fixed-point subgroup of an involution.

Isotypic decomposition[edit]

Let $k[X]_{(\lambda )}$ be the sum of all G-submodules of $k[X]$ that are isomorphic to the simple module $V^{\lambda }$ ; it is called the $\lambda$ -isotypic component of $k[X]$ . Then there is a direct sum decomposition:

k[X]=\bigoplus _{\lambda }k[X]_{(\lambda )}

where the sum runs over all simple G-modules $V^{\lambda }$ . The existence of the decomposition follows, for example, from the fact that the group algebra of G is semisimple since G is reductive.

X is called multiplicity-free (or spherical variety^[2]) if every irreducible representation of G appears at most one time in the coordinate ring; i.e., $\operatorname {dim} k[X]_{(\lambda )}\leq \operatorname {dim} V^{\lambda }$ . For example, $G$ is multiplicity-free as $G\times G$ -module. More precisely, given a closed subgroup H of G, define

\phi _{\lambda }:V^{{\lambda }*}\otimes (V^{\lambda })^{H}\to k[G/H]_{(\lambda )}

by setting $\phi _{\lambda }(\alpha \otimes v)(gH)=\langle \alpha ,g\cdot v\rangle$ and then extending $\phi _{\lambda }$ by linearity. The functions in the image of $\phi _{\lambda }$ are usually called matrix coefficients. Then there is a direct sum decomposition of $G\times N$ -modules (N the normalizer of H)

k[G/H]=\bigoplus _{\lambda }\phi _{\lambda }(V^{{\lambda }*}\otimes (V^{\lambda })^{H})

,

which is an algebraic version of the Peter–Weyl theorem (and in fact the analytic version is an immediate consequence.) Proof: let W be a simple $G\times N$ -submodules of $k[G/H]_{(\lambda )}$ . We can assume $V^{\lambda }=W$ . Let $\delta _{1}$ be the linear functional of W such that $\delta _{1}(w)=w(1)$ . Then $w(gH)=\phi _{\lambda }(\delta _{1}\otimes w)(gH)$ . That is, the image of $\phi _{\lambda }$ contains $k[G/H]_{(\lambda )}$ and the opposite inclusion holds since $\phi _{\lambda }$ is equivariant.

Examples[edit]

Let $v_{\lambda }\in V^{\lambda }$ be a B-eigenvector and X the closure of the orbit $G\cdot v_{\lambda }$ . It is an affine variety called the highest weight vector variety by Vinberg–Popov. It is multiplicity-free.

The Kostant–Rallis situation[edit]

Notes[edit]

^ G is not assumed to be connected so that the results apply to finite groups.
^ Goodman & Wallach 2009, Remark 12.2.2.

References[edit]

Goodman, Roe; Wallach, Nolan R. (2009). Symmetry, Representations, and Invariants (in German). doi:10.1007/978-0-387-79852-3. ISBN 978-0-387-79852-3. OCLC 699068818.

[1] G is not assumed to be connected so that the results apply to finite groups.

[2] Goodman & Wallach 2009, Remark 12.2.2.

[1]

[2]

Isotypic decomposition[edit]

Examples[edit]

The Kostant–Rallis situation[edit]

See also[edit]

Notes[edit]

References[edit]