Schur functor: Difference between revisions

Revision as of 04:34, 17 June 2012

Definition as a functor from vector spaces to vector spaces

Schur functor associated with a representation of the symmetric group

Suppose $ρ : S_{n} \to G L (W)$ is a linear representation of the symmetric group $S_{n}$ over a field $K$ . The Schur functor associated with $ρ$ , denoted $S_{ρ}$ , is a functor from the category of $K$ -vector spaces to the category of $K$ -vector spaces defined as follows. First, using the equivalence of definitions of linear representation, consider $W$ as a module over the group ring $K S_{n}$ . Now, the functor is defined as follows:

On objects: It sends a vector space $V$ to the tensor product of modules $V^{\otimes n} \otimes_{K S_{n}} W$ . Here is what this means. $V^{\otimes n}$ is the $n$ -fold tensor product of $V$ as a $K$ -vector space. This naturally acquires the structure of a $K S_{n}$ -module where $S_{n}$ acts by permuting the tensor product factors. We now take its tensor product as a $K S_{n}$ -module with $W$ . This is not the same as taking the tensor product of vector spaces. Note that since $K S_{n}$ is not commutative, we have to treat $W$ as a left $K S_{n}$ -module and $V^{\otimes n}$ as a right $K S_{n}$ -module. Also note that once we have taken the tensor product, we no longer have a $K S_{n}$ -module structure, just a $K$ -vector space.
On morphisms: Given a linear map $μ : V_{1} \to V_{2}$ , it induces a map $μ^{\otimes n} : V_{1}^{\otimes n} \to V_{2}^{\otimes n}$ which in turn induces a map of the tensor products with $W$ . Functoriality must be checked, but is true.

Schur functor associated with a partition

Assume that $K$ has characteristic zero. Suppose $λ$ is a unordered integer partition of a positive integer $n$ . The Schur functor associated with $λ$ , denoted $S_{λ}$ , is defined as the Schur functor associated with the irreducible linear representation of $S_{n}$ corresponding to $λ$ (see linear representation theory of symmetric groups).

In this case, the module for the irreducible representation can be thought of explicitly as a left ideal inside $K S_{n}$ and the tensor product operation can be thought of as multiplication on the right by this ideal. Note that multiplication by the two-sided ideal corresponding to the representation would give a sum of the Schur functor with itslf degree of the representation many times.

The result also holds if the characteristic of $K$ is greater than $n$ . If $K$ has characteristic a prime less than or equal to $n$ , there is some ambiguity about how to define the Schur functor.

Definition as a functor from representations to representations

This definition can be obtained using abstract nonsense from the definition for vector spaces. For a representation $α : G \to G L (V)$ and a linear representation $ρ$ of a symmetric group $S_{n}$ , we define $S_{ρ} (α)$ as a representation of $G$ on the vector space $S_{ρ} (V)$ , with the map:

$G \to S_{ρ} (V)$

given by:

$g \mapsto S_{ρ} (α (g))$

where the latter $S_{ρ}$ denotes the effect of the functor on morphisms.

Facts

Formula for calculating effect of Schur functor on character
We have the following:

$V^{\otimes n} = ⨁_{λ} d_{λ} S_{λ}$

where $d_{λ}$ denotes the degree of the irreducible representation of $S_{n}$ corresponding to $λ$ .

@@ Line 31: / Line 31: @@
 * [[Formula for calculating effect of Schur functor on character]]
+* We have the following:
+<math>V^{\otimes n} = \bigoplus_\lambda d_\lambda \mathbb{S}_\lambda</math>
+where <math>d_\lambda</math> denotes the degree of the irreducible representation of <math>S_n</math> corresponding to <math>\lambda</math>.