In mathematics, especially in the field of representation theory, Schur functors (named after Issai Schur) are certain functors from the category of modules over a fixed commutative ring to itself. They generalize the constructions of exterior powers and symmetric powers of a vector space. Schur functors are indexed by Young diagrams in such a way that the horizontal diagram with n cells corresponds to the nth symmetric power functor, and the vertical diagram with n cells corresponds to the nth exterior power functor. If a vector space V is a representation of a group G, then
SλV
Sλ(-)
Schur functors are indexed by partitions and are described as follows. Let R be a commutative ring, E an R-moduleand λ a partition of a positive integer n. Let T be a Young tableau of shape λ, thus indexing the factors of the n-fold direct product,, with the boxes of T. Consider those maps of R-modules
\varphi:E x n\toM
\varphi
\varphi
\varphi
I\subset\{1,2,...,n\}
\varphi(x)=\sumx'\varphi(x')
|I|
i-1
The universal R-module
SλE
\varphi
\tilde{\varphi}:SλE\toM
For an example of the condition (3) placed on
\varphi
(2,2,1)
I=\{4,5\}
\varphi(x1,x2,x3,x4,x5)= \varphi(x4,x5,x3,x1,x2)+ \varphi(x4,x2,x5,x1,x3)+ \varphi(x1,x4,x5,x2,x3),
I=\{5\}
\varphi(x1,x2,x3,x4,x5)= \varphi(x5,x2,x3,x4,x1)+ \varphi(x1,x5,x3,x4,x2)+ \varphi(x1,x2,x5,x4,x3).
Fix a vector space V over a field of characteristic zero. We identify partitions and the corresponding Young diagrams. The following descriptions hold:[1]
Λn+1(V) ⊗ Symm-1(V)~\xrightarrow{\Delta ⊗ id
Let V be a complex vector space of dimension k. It's a tautological representation of its automorphism group GL(V). If λ is a diagram where each row has no more than k cells, then Sλ(V) is an irreducible GL(V)-representation of highest weight λ. In fact, any rational representation of GL(V) is isomorphic to a direct sum of representations of the form Sλ(V) ⊗ det(V)⊗m, where λ is a Young diagram with each row strictly shorter than k, and m is any (possibly negative) integer.
In this context Schur-Weyl duality states that as a GL(V)-module
V ⊗ =oplusλ(Sλ
| ⊕ fλ | |
| V) |
fλ
GL(V) x ak{S}n
V ⊗ =oplusλ(SλV) ⊗ \operatorname{Specht}(λ)
\operatorname{Specht}(λ)
See main article: Plethysm. For two Young diagrams λ and μ consider the composition of the corresponding Schur functors Sλ(Sμ(−)). This composition is called a plethysm of λ and μ. From the general theory it is known[1] that, at least for vector spaces over a characteristic zero field, the plethysm is isomorphic to a direct sum of Schur functors. The problem of determining which Young diagrams occur in that description and how to calculate their multiplicities is open, aside from some special cases like Symm(Sym2(V)).