Given a finite symmetric group S_n and specific Young tableau λ corresponding to a numbered partition of n, and consider the action of ${\displaystyle S_{n}}$  given by permuting the boxes of ${\displaystyle \lambda }$ . Define two permutation subgroups ${\displaystyle P_{\lambda }}$  and ${\displaystyle Q_{\lambda }}$  of S_n as follows:^{[clarification needed]}

${\displaystyle P_{\lambda }=\{g\in S_{n}:g{\text{ preserves each row of }}\lambda \}}$ 

and

${\displaystyle Q_{\lambda }=\{g\in S_{n}:g{\text{ preserves each column of }}\lambda \}.}$ 

Corresponding to these two subgroups, define two vectors in the group algebra ${\displaystyle \mathbb {C} S_{n}}$  as

${\displaystyle a_{\lambda }=\sum _{g\in P_{\lambda }}e_{g}}$ 

and

${\displaystyle b_{\lambda }=\sum _{g\in Q_{\lambda }}\operatorname {sgn}(g)e_{g}}$ 

where ${\displaystyle e_{g}}$  is the unit vector corresponding to g, and ${\displaystyle \operatorname {sgn}(g)}$  is the sign of the permutation. The product

${\displaystyle c_{\lambda }:=a_{\lambda }b_{\lambda }=\sum _{g\in P_{\lambda },h\in Q_{\lambda }}\operatorname {sgn}(h)e_{gh}}$ 

is the Young symmetrizer corresponding to the Young tableau λ. Each Young symmetrizer corresponds to an irreducible representation of the symmetric group, and every irreducible representation can be obtained from a corresponding Young symmetrizer. (If we replace the complex numbers by more general fields the corresponding representations will not be irreducible in general.)

Let V be any vector space over the complex numbers. Consider then the tensor product vector space ${\displaystyle V^{\otimes n}=V\otimes V\otimes \cdots \otimes V}$  (n times). Let S_n act on this tensor product space by permuting the indices. One then has a natural group algebra representation ${\displaystyle \mathbb {C} S_{n}\to \operatorname {End} (V^{\otimes n})}$  on ${\displaystyle V^{\otimes n}}$  (i.e. ${\displaystyle V^{\otimes n}}$  is a right ${\displaystyle \mathbb {C} S_{n}}$  module).

Given a partition λ of n, so that ${\displaystyle n=\lambda _{1}+\lambda _{2}+\cdots +\lambda _{j}}$ , then the image of ${\displaystyle a_{\lambda }}$  is

${\displaystyle \operatorname {Im} (a_{\lambda }):=V^{\otimes n}a_{\lambda }\cong \operatorname {Sym} ^{\lambda _{1}}V\otimes \operatorname {Sym} ^{\lambda _{2}}V\otimes \cdots \otimes \operatorname {Sym} ^{\lambda _{j}}V.}$ 

For instance, if ${\displaystyle n=4}$ , and ${\displaystyle \lambda =(2,2)}$ , with the canonical Young tableau ${\displaystyle \{\{1,2\},\{3,4\}\}}$ . Then the corresponding ${\displaystyle a_{\lambda }}$  is given by

${\displaystyle a_{\lambda }=e_{\text{id}}+e_{(1,2)}+e_{(3,4)}+e_{(1,2)(3,4)}.}$ 

For any product vector ${\displaystyle v_{1,2,3,4}:=v_{1}\otimes v_{2}\otimes v_{3}\otimes v_{4}}$  of ${\displaystyle V^{\otimes 4}}$  we then have

${\displaystyle v_{1,2,3,4}a_{\lambda }=v_{1,2,3,4}+v_{2,1,3,4}+v_{1,2,4,3}+v_{2,1,4,3}=(v_{1}\otimes v_{2}+v_{2}\otimes v_{1})\otimes (v_{3}\otimes v_{4}+v_{4}\otimes v_{3}).}$ 

Thus the set of all ${\displaystyle a_{\lambda }v_{1,2,3,4}}$  clearly spans ${\displaystyle \operatorname {Sym} ^{2}V\otimes \operatorname {Sym} ^{2}V}$  and since the ${\displaystyle v_{1,2,3,4}}$  span ${\displaystyle V^{\otimes 4}}$  we obtain ${\displaystyle V^{\otimes 4}a_{\lambda }=\operatorname {Sym} ^{2}V\otimes \operatorname {Sym} ^{2}V}$ , where we wrote informally ${\displaystyle V^{\otimes 4}a_{\lambda }\equiv \operatorname {Im} (a_{\lambda })}$ .

Notice also how this construction can be reduced to the construction for ${\displaystyle n=2}$ . Let ${\displaystyle \mathbb {1} \in \operatorname {End} (V^{\otimes 2})}$  be the identity operator and ${\displaystyle S\in \operatorname {End} (V^{\otimes 2})}$  the swap operator defined by ${\displaystyle S(v\otimes w)=w\otimes v}$ , thus ${\displaystyle \mathbb {1} =e_{\text{id}}}$  and ${\displaystyle S=e_{(1,2)}}$ . We have that

${\displaystyle e_{\text{id}}+e_{(1,2)}=\mathbb {1} +S}$ 

maps into ${\displaystyle \operatorname {Sym} ^{2}V}$ , more precisely

${\displaystyle {\frac {1}{2}}(\mathbb {1} +S)}$ 

is the projector onto ${\displaystyle \operatorname {Sym} ^{2}V}$ . Then

${\displaystyle {\frac {1}{4}}a_{\lambda }={\frac {1}{4}}(e_{\text{id}}+e_{(1,2)}+e_{(3,4)}+e_{(1,2)(3,4)})={\frac {1}{4}}(\mathbb {1} \otimes \mathbb {1} +S\otimes \mathbb {1} +\mathbb {1} \otimes S+S\otimes S)={\frac {1}{2}}(\mathbb {1} +S)\otimes {\frac {1}{2}}(\mathbb {1} +S)}$ 

which is the projector onto ${\displaystyle \operatorname {Sym} ^{2}V\otimes \operatorname {Sym} ^{2}V}$ .

The image of ${\displaystyle b_{\lambda }}$  is

${\displaystyle \operatorname {Im} (b_{\lambda })\cong \bigwedge ^{\mu _{1}}V\otimes \bigwedge ^{\mu _{2}}V\otimes \cdots \otimes \bigwedge ^{\mu _{k}}V}$ 

where μ is the conjugate partition to λ. Here, ${\displaystyle \operatorname {Sym} ^{i}V}$  and ${\displaystyle \bigwedge ^{j}V}$  are the symmetric and alternating tensor product spaces.

The image ${\displaystyle \mathbb {C} S_{n}c_{\lambda }}$  of ${\displaystyle c_{\lambda }=a_{\lambda }\cdot b_{\lambda }}$  in ${\displaystyle \mathbb {C} S_{n}}$  is an irreducible representation of S_n, called a Specht module. We write

${\displaystyle \operatorname {Im} (c_{\lambda })=V_{\lambda }}$ 

for the irreducible representation.

Some scalar multiple of ${\displaystyle c_{\lambda }}$  is idempotent,^[1] that is ${\displaystyle c_{\lambda }^{2}=\alpha _{\lambda }c_{\lambda }}$  for some rational number ${\displaystyle \alpha _{\lambda }\in \mathbb {Q} .}$  Specifically, one finds ${\displaystyle \alpha _{\lambda }=n!/\dim V_{\lambda }}$ . In particular, this implies that representations of the symmetric group can be defined over the rational numbers; that is, over the rational group algebra ${\displaystyle \mathbb {Q} S_{n}}$ .

Consider, for example, S₃ and the partition (2,1). Then one has

${\displaystyle c_{(2,1)}=e_{123}+e_{213}-e_{321}-e_{312}.}$ 

If V is a complex vector space, then the images of ${\displaystyle c_{\lambda }}$  on spaces ${\displaystyle V^{\otimes d}}$  provides essentially all the finite-dimensional irreducible representations of GL(V).

• Representation theory of the symmetric group

• William Fulton. Young Tableaux, with Applications to Representation Theory and Geometry. Cambridge University Press, 1997.
• Lecture 4 of Fulton, William; Harris, Joe (1991). Representation theory. A first course. Graduate Texts in Mathematics, Readings in Mathematics. Vol. 129. New York: Springer-Verlag. doi:10.1007/978-1-4612-0979-9. ISBN 978-0-387-97495-8. MR 1153249. OCLC 246650103.
• Bruce E. Sagan. The Symmetric Group. Springer, 2001.