Symmetric groups edit

The lowest-dimensional representations of the symmetric groups can be described explicitly,^[4][5] and over arbitrary fields.^{[6][page needed]} 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 n ≥ 2, 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.

For all n, there is an n-dimensional representation of the symmetric group of order n!, called the natural permutation representation, which consists of permuting n coordinates. This has the trivial subrepresentation consisting of vectors whose coordinates are all equal. The orthogonal complement consists of those vectors whose coordinates sum to zero, and when n ≥ 2, the representation on this subspace is an (n − 1)-dimensional irreducible representation, called the standard representation. Another (n − 1)-dimensional irreducible representation is found by tensoring with the sign representation. An exterior power ${\displaystyle \Lambda ^{k}V}$  of the standard representation ${\displaystyle V}$  is irreducible provided ${\displaystyle 0\leq k\leq n-1}$  (Fulton & Harris 2004).

For n ≥ 7, these are the lowest-dimensional irreducible representations of S_n – all other irreducible representations have dimension at least n. However for n = 4, the surjection from S₄ to S₃ allows S₄ to inherit a two-dimensional irreducible representation. For n = 6, the exceptional transitive embedding of S₅ into S₆ produces another pair of five-dimensional irreducible representations.

Alternating groups edit

The representation theory of the alternating groups is similar, though the sign representation disappears. For n ≥ 7, the lowest-dimensional irreducible representations are the trivial representation in dimension one, and the (n − 1)-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 n ≥ 5 have only one one-dimensional irreducible representation, the trivial representation. For n = 3, 4 there are two additional one-dimensional irreducible representations, corresponding to maps to the cyclic group of order 3: A₃ ≅ C₃ and A₄ → A₄/V ≅ C₃.

• For n ≥ 7, there is just one irreducible representation of degree n − 1, and this is the smallest degree of a non-trivial irreducible representation.
• For n = 3 the obvious analogue of the (n − 1)-dimensional representation is reducible – the permutation representation coincides with the regular representation, and thus breaks up into the three one-dimensional representations, as A₃ ≅ C₃ is abelian; see the discrete Fourier transform for representation theory of cyclic groups.
• For n = 4, there is just one n − 1 irreducible representation, but there are the exceptional irreducible representations of dimension 1.
• For n = 5, there are two dual irreducible representations of dimension 3, corresponding to its action as icosahedral symmetry.
• For n = 6, there is an extra irreducible representation of dimension 5 corresponding to the exceptional transitive embedding of A₅ in A₆.

Kronecker coefficients edit

The tensor product of two representations of ${\displaystyle S_{n}}$  corresponding to the Young diagrams ${\displaystyle \lambda ,\mu }$  is a combination of irreducible representations of ${\displaystyle S_{n}}$ ,

${\displaystyle V_{\lambda }\otimes V_{\mu }\cong \sum _{\nu }C_{\lambda ,\mu ,\nu }V_{\nu }}$ 

The coefficients ${\displaystyle C_{\lambda \mu \nu }\in \mathbb {N} }$  are called the Kronecker coefficients of the symmetric group. They can be computed from the characters of the representations (Fulton & Harris 2004):

${\displaystyle C_{\lambda ,\mu ,\nu }=\sum _{\rho }{\frac {1}{z_{\rho }}}\chi _{\lambda }(C_{\rho })\chi _{\mu }(C_{\rho })\chi _{\nu }(C_{\rho })}$ 

The sum is over partitions ${\displaystyle \rho }$  of ${\displaystyle n}$ , with ${\displaystyle C_{\rho }}$  the corresponding conjugacy classes. The values of the characters ${\displaystyle \chi _{\lambda }(C_{\rho })}$  can be computed using the Frobenius formula. The coefficients ${\displaystyle z_{\rho }}$  are

${\displaystyle z_{\rho }=\prod _{j=0}^{n}j^{i_{j}}i_{j}!={\frac {n!}{|C_{\rho }|}}}$ 

where ${\displaystyle i_{j}}$  is the number of times ${\displaystyle j}$  appears in ${\displaystyle \rho }$ , so that ${\displaystyle \sum i_{j}j=n}$ .

A few examples, written in terms of Young diagrams (Hamermesh 1989):

${\displaystyle (n-1,1)\otimes (n-1,1)\cong (n)+(n-1,1)+(n-2,2)+(n-2,1,1)}$ 

${\displaystyle (n-1,1)\otimes (n-2,2){\underset {n>4}{\cong }}(n-1,1)+(n-2,2)+(n-2,1,1)+(n-3,3)+(n-3,2,1)}$ 

${\displaystyle (n-1,1)\otimes (n-2,1,1)\cong (n-1,1)+(n-2,2)+(n-2,1,1)+(n-3,2,1)+(n-3,1,1,1)}$ 

${\displaystyle {\begin{aligned}(n-2,2)\otimes (n-2,2)\cong &(n)+(n-1,1)+2(n-2,2)+(n-2,1,1)+(n-3,3)\\&+2(n-3,2,1)+(n-3,1,1,1)+(n-4,4)+(n-4,3,1)+(n-4,2,2)\end{aligned}}}$ 

There is a simple rule for computing ${\displaystyle (n-1,1)\otimes \lambda }$  for any Young diagram ${\displaystyle \lambda }$  (Hamermesh 1989): the result is the sum of all Young diagrams that are obtained from ${\displaystyle \lambda }$  by removing one box and then adding one box, where the coefficients are one except for ${\displaystyle \lambda }$  itself, whose coefficient is ${\displaystyle \#\{\lambda _{i}\}-1}$ , i.e., the number of different row lengths minus one.

A constraint on the irreducible constituents of ${\displaystyle V_{\lambda }\otimes V_{\mu }}$  is (James & Kerber 1981)

${\displaystyle C_{\lambda ,\mu ,\nu }>0\implies |d_{\lambda }-d_{\mu }|\leq d_{\nu }\leq d_{\lambda }+d_{\mu }}$ 

where the depth ${\displaystyle d_{\lambda }=n-\lambda _{1}}$  of a Young diagram is the number of boxes that do not belong to the first row.

Reduced Kronecker coefficients edit

For ${\displaystyle \lambda }$  a Young diagram and ${\displaystyle n\geq \lambda _{1}}$ , ${\displaystyle \lambda [n]=(n-|\lambda |,\lambda )}$  is a Young diagram of size ${\displaystyle n}$ . Then ${\displaystyle C_{\lambda [n],\mu [n],\nu [n]}}$  is a bounded, non-decreasing function of ${\displaystyle n}$ , and

${\displaystyle {\bar {C}}_{\lambda ,\mu ,\nu }=\lim _{n\to \infty }C_{\lambda [n],\mu [n],\nu [n]}}$ 

is called a reduced Kronecker coefficient^[7] or stable Kronecker coefficient.^[8] There are known bounds on the value of ${\displaystyle n}$  where ${\displaystyle C_{\lambda [n],\mu [n],\nu [n]}}$  reaches its limit.^[7] The reduced Kronecker coefficients are structure constants of Deligne categories of representations of ${\displaystyle S_{n}}$  with ${\displaystyle n\in \mathbb {C} -\mathbb {N} }$ .^[9]

In contrast to Kronecker coefficients, reduced Kronecker coefficients are defined for any triple of Young diagrams, not necessarily of the same size. If ${\displaystyle |\nu |=|\lambda |+|\mu |}$ , then ${\displaystyle {\bar {C}}_{\lambda ,\mu ,\nu }}$  coincides with the Littlewood-Richardson coefficient ${\displaystyle c_{\lambda ,\mu }^{\nu }}$ .^[10] Reduced Kronecker coefficients can be written as linear combinations of Littlewood-Richardson coefficients via a change of bases in the space of symmetric functions, giving rise to expressions that are manifestly integral although not manifestly positive.^[8] Reduced Kronecker coefficients can also be written in terms of Kronecker and Littlewood-Richardson coefficients ${\displaystyle c_{\alpha \beta \gamma }^{\lambda }}$  via Littlewood's formula^[11][12]

${\displaystyle {\bar {C}}_{\lambda ,\mu ,\nu }=\sum _{\lambda ',\mu ',\nu ',\alpha ,\beta ,\gamma }C_{\lambda ',\mu ',\nu '}c_{\lambda '\beta \gamma }^{\lambda }c_{\mu '\alpha \gamma }^{\mu }c_{\nu '\alpha \beta }^{\nu }}$ 

Conversely, it is possible to recover the Kronecker coefficients as linear combinations of reduced Kronecker coefficients.^[7]

Reduced Kronecker coefficients are implemented in the computer algebra system SageMath.^[13][14]

Given an element ${\displaystyle w\in S_{n}}$  of cycle-type ${\displaystyle \mu =(\mu _{1},\mu _{2},\dots ,\mu _{k})}$  and order ${\displaystyle m={\text{lcm}}(\mu _{i})}$ , the eigenvalues of ${\displaystyle w}$  in a complex representation of ${\displaystyle S_{n}}$  are of the type ${\displaystyle \omega ^{e_{j}}}$  with ${\displaystyle \omega =e^{\frac {2\pi i}{m}}}$ , where the integers ${\displaystyle e_{j}\in {\frac {\mathbb {Z} }{m\mathbb {Z} }}}$  are called the cyclic exponents of ${\displaystyle w}$  with respect to the representation.^[15]

There is a combinatorial description of the cyclic exponents of the symmetric group (and wreath products thereof). Defining ${\displaystyle \left(b_{\mu }(1),\dots ,b_{\mu }(n)\right)=\left({\frac {m}{\mu _{1}}},2{\frac {m}{\mu _{1}}},\dots ,m,{\frac {m}{\mu _{2}}},2{\frac {m}{\mu _{2}}},\dots ,m,\dots \right)}$ , let the ${\displaystyle \mu }$ -index of a standard Young tableau be the sum of the values of ${\displaystyle b_{\mu }}$  over the tableau's descents, ${\displaystyle {\text{ind}}_{\mu }(T)=\sum _{k\in \{{\text{descents}}(T)\}}b_{\mu }(k){\bmod {m}}}$ . Then the cyclic exponents of the representation of ${\displaystyle S_{n}}$  described by the Young diagram ${\displaystyle \lambda }$  are the ${\displaystyle \mu }$ -indices of the corresponding Young tableaux.^[15]

In particular, if ${\displaystyle w}$  is of order ${\displaystyle n}$ , then ${\displaystyle b_{\mu }(k)=k}$ , and ${\displaystyle {\text{ind}}_{\mu }(T)}$  coincides with the major index of ${\displaystyle T}$  (the sum of the descents). The cyclic exponents of an irreducible representation of ${\displaystyle S_{n}}$  then describe how it decomposes into representations of the cyclic group ${\displaystyle {\frac {\mathbb {Z} }{n\mathbb {Z} }}}$ , with ${\displaystyle \omega ^{e_{j}}}$  being interpreted as the image of ${\displaystyle w}$  in the (one-dimensional) representation characterized by ${\displaystyle e_{j}}$ .

• Alternating polynomials
• Symmetric polynomials
• Schur functor
• Robinson–Schensted correspondence
• Schur–Weyl duality
• Jucys–Murphy element
• Garnir relations

• Fulton, William; Harris, Joe (2004). "Representation Theory". Graduate Texts in Mathematics. New York, NY: Springer New York. doi:10.1007/978-1-4612-0979-9. ISBN 978-3-540-00539-1. ISSN 0072-5285.
• Hamermesh, M (1989). Group theory and its application to physical problems. New York: Dover Publications. ISBN 0-486-66181-4. OCLC 20218471.
• James, Gordon; Kerber, Adalbert (1981), The representation theory of the symmetric group, Encyclopedia of Mathematics and its Applications, vol. 16, Addison-Wesley Publishing Co., Reading, Mass., ISBN 978-0-201-13515-2, MR 0644144
• James, G. D. (1983), "On the minimal dimensions of irreducible representations of symmetric groups", Mathematical Proceedings of the Cambridge Philosophical Society, 94 (3): 417–424, Bibcode:1983MPCPS..94..417J, doi:10.1017/S0305004100000803, ISSN 0305-0041, MR 0720791, S2CID 123113210