In mathematics, the representation theory of the symmetric group is a particular case of the representation theory of finite groups, for which a concrete and detailed theory can be obtained. This has a large area of potential applications, from symmetric function theory to quantum chemistry studies of atoms, molecules and solids.[1] [2]
The symmetric group Sn has order n!. Its conjugacy classes are labeled by partitions of n. Therefore according to the representation theory of a finite group, the number of inequivalent irreducible representations, over the complex numbers, is equal to the number of partitions of n. Unlike the general situation for finite groups, there is in fact a natural way to parametrize irreducible representations by the same set that parametrizes conjugacy classes, namely by partitions of n or equivalently Young diagrams of size n.
Each such irreducible representation can in fact be realized over the integers (every permutation acting by a matrix with integer coefficients); it can be explicitly constructed by computing the Young symmetrizers acting on a space generated by the Young tableaux of shape given by the Young diagram. The dimension
dλ
λ
To each irreducible representation ρ we can associate an irreducible character, χρ.To compute χρ(π) where π is a permutation, one can use the combinatorial Murnaghan–Nakayama rule.[3] Note that χρ is constant on conjugacy classes,that is, χρ(π) = χρ(σ−1πσ) for all permutations σ.
Over other fields the situation can become much more complicated. If the field K has characteristic equal to zero or greater than n then by Maschke's theorem the group algebra KSn is semisimple. In these cases the irreducible representations defined over the integers give the complete set of irreducible representations (after reduction modulo the characteristic if necessary).
However, the irreducible representations of the symmetric group are not known in arbitrary characteristic. In this context it is more usual to use the language of modules rather than representations. The representation obtained from an irreducible representation defined over the integers by reducing modulo the characteristic will not in general be irreducible. The modules so constructed are called Specht modules, and every irreducible does arise inside some such module. There are now fewer irreducibles, and although they can be classified they are very poorly understood. For example, even their dimensions are not known in general.
The determination of the irreducible modules for the symmetric group over an arbitrary field is widely regarded as one of the most important open problems in representation theory.
The lowest-dimensional representations of the symmetric groups can be described explicitly, and over arbitrary fields. The smallest two degrees in characteristic zero are described here:
Every symmetric group has a one-dimensional representation called the trivial representation, where every element acts as the one by one identity matrix. For, there is another irreducible representation of degree 1, called the sign representation or alternating character, which takes a permutation to the one by one matrix with entry ±1 based on the sign of the permutation. These are the only one-dimensional representations of the symmetric groups, as one-dimensional representations are abelian, and the abelianization of the symmetric group is C2, the cyclic group of order 2.
ΛkV
V
0\leqk\leqn-1
For, these are the lowest-dimensional irreducible representations of Sn – all other irreducible representations have dimension at least n. However for, the surjection from S4 to S3 allows S4 to inherit a two-dimensional irreducible representation. For, the exceptional transitive embedding of S5 into S6 produces another pair of five-dimensional irreducible representations.
| Irreducible representation of Sn | Dimension | Young diagram of size n | |
|---|---|---|---|
| Trivial representation | 1 | (n) | |
| Sign representation | 1 | (1n)=(1,1,...,1) | |
| Standard representation V | n-1 | (n-1,1) | |
| Exterior power ΛkV | \binom{n-1}{k} | (n-k,1k) |
The representation theory of the alternating groups is similar, though the sign representation disappears. For, the lowest-dimensional irreducible representations are the trivial representation in dimension one, and the -dimensional representation from the other summand of the permutation representation, with all other irreducible representations having higher dimension, but there are exceptions for smaller n.
The alternating groups for have only one one-dimensional irreducible representation, the trivial representation. For there are two additional one-dimensional irreducible representations, corresponding to maps to the cyclic group of order 3: and .
The tensor product of two representations of
Sn
λ,\mu
Sn
Vλ ⊗ V\mu\cong\sum\nuCλ,\mu,\nuV\nu
Cλ\mu\nu\inN
Cλ,\mu,\nu=\sum\rho
| 1 | |
| z\rho |
\chiλ(C\rho)\chi\mu(C\rho)\chi\nu(C\rho)
\rho
n
C\rho
\chiλ(C\rho)
z\rho
z\rho=
| n | |
| \prod | |
| j=0 |
| ij | |
| j |
ij!=
| n! | |
| |C\rho| |
ij
j
\rho
\sumijj=n
A few examples, written in terms of Young diagrams :
(n-1,1) ⊗ (n-1,1)\cong(n)+(n-1,1)+(n-2,2) +(n-2,1,1)
(n-1,1) ⊗ (n-2,2)\underset{n>4}{\cong}(n-1,1)+(n-2,2) +(n-2,1,1)+(n-3,3) +(n-3,2,1)
(n-1,1) ⊗ (n-2,1,1)\cong(n-1,1)+(n-2,2)+(n-2,1,1) +(n-3,2,1)+(n-3,1,1,1)
\begin{align} (n-2,2) ⊗ (n-2,2)\cong&(n)+(n-1,1)+2(n-2,2) +(n-2,1,1)+(n-3,3) \ &+2(n-3,2,1)+(n-3,1,1,1) +(n-4,4)+(n-4,3,1) +(n-4,2,2) \end{align}
(n-1,1) ⊗ λ
λ
λ
λ
\#\{λi\}-1
A constraint on the irreducible constituents of
Vλ ⊗ V\mu
Cλ,\mu,\nu>0\implies|dλ-d\mu|\leqd\nu\leqdλ+d\mu
dλ=n-λ1
For
λ
n\geqλ1
λ[n]=(n-|λ|,λ)
n
Cλ[n],\mu[n],\nu[n]
n
\bar{C}λ,\mu,\nu=\limn\toinftyCλ[n],\mu[n],\nu[n]
n
Cλ[n],\mu[n],\nu[n]
Sn
n\inC-N
In contrast to Kronecker coefficients, reduced Kronecker coefficients are defined for any triple of Young diagrams, not necessarily of the same size. If
|\nu|=|λ|+|\mu|
\bar{C}λ,\mu,\nu
| \nu | |
| c | |
| λ,\mu |
| λ | |
| c | |
| \alpha\beta\gamma |
\bar{C}λ,\mu,\nu=\sumλ',\mu',\nu',\alpha,\beta,\gammaCλ',\mu',\nu'
| λ | |
| c | |
| λ'\beta\gamma |
| \mu | |
| c | |
| \mu'\alpha\gamma |
| \nu | |
| c | |
| \nu'\alpha\beta |
Reduced Kronecker coefficients are implemented in the computer algebra system SageMath.
Given an element
w\inSn
\mu=(\mu1,\mu2,...,\muk)
m=lcm(\mui)
w
Sn
| ej | |
| \omega |
| ||||
| \omega=e |
ej\in
| Z | |
| mZ |
w
There is a combinatorial description of the cyclic exponents of the symmetric group (and wreath products thereof). Defining
\left(b\mu(1),...,b\mu(n)\right)=\left(
| m | ,2 | |
| \mu1 |
| m | |
| \mu1 |
,...,m,
| m | ,2 | |
| \mu2 |
| m | |
| \mu2 |
,...,m,...\right)
\mu
b\mu
ind\mu(T)=\sumk\in
Sn
λ
\mu
In particular, if
w
n
b\mu(k)=k
ind\mu(T)
T
Sn
| Z | |
| nZ |
| ej | |
| \omega |
w
ej