Brauer algebra

In mathematics, a Brauer algebra is an associative algebra introduced by Richard Brauer^[1] in the context of the representation theory of the orthogonal group. It plays the same role that the symmetric group does for the representation theory of the general linear group in Schur–Weyl duality.

The Brauer algebra ${\displaystyle {\mathfrak{𝔅}}_n(\delta )}$ is a ${\displaystyle \mathbb{\mathbb{Z}}[\delta ]}$-algebra depending on the choice of a positive integer ${\displaystyle n}$. Here ${\displaystyle \delta }$ is an indeterminate, but in practice ${\displaystyle \delta }$ is often specialised to the dimension of the fundamental representation of an orthogonal group ${\displaystyle O(\delta )}$. The Brauer algebra has the dimension

${\displaystyle \dim {\mathfrak{𝔅}}_n(\delta )=\frac{(2n)!}{2^{n}n!}=(2n-1)!!=(2n-1)(2n-3)\cdots 5\cdot 3\cdot 1}$

A basis of ${\displaystyle {\mathfrak{𝔅}}_n(\delta )}$ consists of all pairings on a set of ${\displaystyle 2n}$ elements ${\displaystyle X_1,...,X_n,Y_1,...,Y_n}$ (that is, all perfect matchings of a complete graph ${\displaystyle K_n}$: any two of the ${\displaystyle 2n}$ elements may be matched to each other, regardless of their symbols). The elements ${\displaystyle X_i}$ are usually written in a row, with the elements ${\displaystyle Y_i}$ beneath them.

The product of two basis elements ${\displaystyle A}$ and ${\displaystyle B}$ is obtained by concatenation: first identifying the endpoints in the bottom row of ${\displaystyle A}$ and the top row of ${\displaystyle B}$ (Figure AB in the diagram), then deleting the endpoints in the middle row and joining endpoints in the remaining two rows if they are joined, directly or by a path, in AB (Figure AB=nn in the diagram). Thereby all closed loops in the middle of AB are removed. The product ${\displaystyle A\cdot B}$ of the basis elements is then defined to be the basis element corresponding to the new pairing multiplied by ${\displaystyle {\delta }^r}$ where ${\displaystyle r}$ is the number of deleted loops. In the example ${\displaystyle A\cdot B={\delta }^{2}AB}$.

${\displaystyle {\mathfrak{𝔅}}_n(\delta )}$ can also be defined as the ${\displaystyle \mathbb{\mathbb{Z}}[\delta ]}$-algebra with generators ${\displaystyle s_1,\dots ,s_{n-1},e_1,\dots ,e_{n-1}}$ satisfying the following relations:

• Relations of the symmetric group:

${\displaystyle s_i^2=1}$

${\displaystyle s_i{s}_j=s_j{s}_i}$ whenever ${\displaystyle |i-j|>1}$

${\displaystyle s_i{s}_{i+1}{s}_i=s_{i+1}{s}_i{s}_{i+1}}$

• Almost-idempotent relation:

${\displaystyle e_i^2=\delta e_i}$

• Commutation:

${\displaystyle e_i{e}_j=e_j{e}_i}$

${\displaystyle s_i{e}_j=e_j{s}_i}$

whenever${\displaystyle |i-j|>1}$

• Tangle relations

${\displaystyle e_i{e}_{i\pm 1}{e}_i=e_i}$

${\displaystyle s_i{s}_{i\pm 1}{e}_i=e_{i\pm 1}{e}_i}$

${\displaystyle e_i{s}_{i\pm 1}{s}_i=e_i{e}_{i\pm 1}}$

• Untwisting:

${\displaystyle s_i{e}_i=e_i{s}_i=e_i}$:

${\displaystyle e_i{s}_{i\pm 1}{e}_i=e_i}$

In this presentation ${\displaystyle s_i}$ represents the diagram in which ${\displaystyle X_k}$ is always connected to ${\displaystyle Y_k}$ directly beneath it except for ${\displaystyle X_i}$ and ${\displaystyle X_{i+1}}$ which are connected to ${\displaystyle Y_{i+1}}$ and ${\displaystyle Y_i}$ respectively. Similarly ${\displaystyle e_i}$ represents the diagram in which ${\displaystyle X_k}$ is always connected to ${\displaystyle Y_k}$ directly beneath it except for ${\displaystyle X_i}$ being connected to ${\displaystyle X_{i+1}}$ and ${\displaystyle Y_i}$ to ${\displaystyle Y_{i+1}}$.

The Brauer algebra is a subalgebra of the partition algebra.

The Brauer algebra ${\displaystyle {\mathfrak{𝔅}}_n(\delta )}$ is semisimple if ${\displaystyle \delta \in \mathbb{ℂ}-\{0,\pm 1,\pm 2,\dots ,\pm n\}}$.^[2][3]

The subalgebra of ${\displaystyle {\mathfrak{𝔅}}_n(\delta )}$ generated by the generators ${\displaystyle s_i}$ is the group algebra of the symmetric group ${\displaystyle S_n}$.

The subalgebra of ${\displaystyle {\mathfrak{𝔅}}_n(\delta )}$ generated by the generators ${\displaystyle e_i}$ is the Temperley-Lieb algebra ${\displaystyle T{L}_n(\delta )}$.^[4]

The Brauer algebra is a cellular algebra.

For a pairing ${\displaystyle A}$ let ${\displaystyle n(A)}$ be the number of closed loops formed by identifying ${\displaystyle X_i}$ with ${\displaystyle Y_i}$ for any ${\displaystyle i=1,2,\dots ,n}$: then the Jones trace ${\displaystyle \text{Tr}(A)={\delta }^{n(A)}}$ obeys ${\displaystyle \text{Tr}(AB)=\text{Tr}(BA)}$ i.e. it is indeed a trace.

Brauer-Specht modules are finite-dimensional modules of the Brauer algebra. If ${\displaystyle \delta }$ is such that ${\displaystyle {\mathfrak{𝔅}}_n(\delta )}$ is semisimple, they form a complete set of simple modules of ${\displaystyle {\mathfrak{𝔅}}_n(\delta )}$.^[4] These modules are parametrized by partitions, because they are built from the Specht modules of the symmetric group, which are themselves parametrized by partitions.

For ${\displaystyle 0\le \ell \le n}$ with ${\displaystyle \ell \equiv nmod2}$, let ${\displaystyle B_{n,\ell }}$ be the set of perfect matchings of ${\displaystyle n+\ell }$ elements ${\displaystyle X_1,\dots ,X_n,Y_1,\dots ,Y_{\ell }}$, such that ${\displaystyle Y_j}$ is matched with one of the ${\displaystyle n}$ elements ${\displaystyle X_1,\dots ,X_n}$. For any ring ${\displaystyle k}$, the space ${\displaystyle k{B}_{n,\ell }}$ is a left ${\displaystyle {\mathfrak{𝔅}}_n(\delta )}$-module, where basis elements of ${\displaystyle {\mathfrak{𝔅}}_n(\delta )}$ act by graph concatenation. (This action can produce matchings that violate the restriction that ${\displaystyle Y_1,\dots ,Y_{\ell }}$ cannot match with one another: such graphs must be modded out.) Moreover, the space ${\displaystyle k{B}_{n,\ell }}$ is a right ${\displaystyle S_{\ell }}$-module.^[5]

Given a Specht module ${\displaystyle V_{\lambda }}$ of ${\displaystyle k{S}_{\ell }}$, where ${\displaystyle \lambda }$ is a partition of ${\displaystyle \ell }$ (i.e. ${\displaystyle |\lambda |=\ell }$), the corresponding Brauer-Specht module of ${\displaystyle {\mathfrak{𝔅}}_n(\delta )}$ is

${\displaystyle W_{\lambda }=k{B}_{n,|\lambda |}{\otimes }_{k{S}_{|\lambda |}}{V}_{\lambda }(|\lambda |\le n,|\lambda |\equiv nmod2)}$

A basis of this module is the set of elements ${\displaystyle b\otimes v}$, where ${\displaystyle b\in B_{n,|\lambda |}}$ is such that the ${\displaystyle |\lambda |}$ lines that end on elements ${\displaystyle Y_j}$ do not cross, and ${\displaystyle v}$ belongs to a basis of ${\displaystyle V_{\lambda }}$.^[5] The dimension is

${\displaystyle \dim (W_{\lambda })={\displaystyle (\genfrac{}{}{0ex}{}{n}{|\lambda |})}(n-|\lambda |-1)!!\dim (V_{\lambda })}$

i.e. the product of a binomial coefficient, a double factorial, and the dimension of the corresponding Specht module, which is given by the hook length formula.

Let ${\displaystyle V={\mathbb{ℝ}}^d}$ be a euclidean vector space of dimension ${\displaystyle d}$, and ${\displaystyle O(V)=O(d,\mathbb{ℝ})}$ the corresponding orthogonal group. Then write ${\displaystyle B_n(d)}$ for the specialisation ${\displaystyle \mathbb{ℝ}{\otimes }_{\mathbb{\mathbb{Z}}[\delta ]}{\mathfrak{𝔅}}_n(\delta )}$ where ${\displaystyle \delta }$ acts on ${\displaystyle \mathbb{ℝ}}$ by multiplication with ${\displaystyle d}$. The tensor power ${\displaystyle V^{\otimes n}:=\underset{n\text{ times}}{\underbrace{V\otimes \cdots \otimes V}}}$ is naturally a ${\displaystyle B_n(d)}$-module: ${\displaystyle s_i}$ acts by switching the ${\displaystyle i}$th and ${\displaystyle (i+1)}$th tensor factor and ${\displaystyle e_i}$ acts by contraction followed by expansion in the ${\displaystyle i}$th and ${\displaystyle (i+1)}$th tensor factor, i.e. ${\displaystyle e_i}$ acts as

${\displaystyle v_1\otimes \cdots \otimes v_{i-1}\otimes (v_i\otimes v_{i+1})\otimes \cdots \otimes v_n\mapsto v_1\otimes \cdots \otimes v_{i-1}\otimes (⟨v_i,v_{i+1}⟩{\displaystyle \sum _{k=1}^d}(w_k\otimes w_k))\otimes \cdots \otimes v_n}$

where ${\displaystyle w_1,\dots ,w_d}$ is any orthonormal basis of ${\displaystyle V}$. (The sum is in fact independent of the choice of this basis.)

This action is useful in a generalisation of the Schur-Weyl duality: if ${\displaystyle d\ge n}$, the image of ${\displaystyle B_n(d)}$ inside ${\displaystyle \mathrm{End}(V^{\otimes n})}$ is the centraliser of ${\displaystyle O(V)}$ inside ${\displaystyle \mathrm{End}(V^{\otimes n})}$, and conversely the image of ${\displaystyle O(V)}$ is the centraliser of ${\displaystyle B_n(d)}$.^[2] The tensor power ${\displaystyle V^{\otimes n}}$ is therefore both an ${\displaystyle O(V)}$- and a ${\displaystyle B_n(d)}$-module and satisfies

${\displaystyle V^{\otimes n}=\underset{\lambda }{⨁}{U}_{\lambda }⊠W_{\lambda }}$

where ${\displaystyle \lambda }$ runs over a subset of the partitions such that ${\displaystyle |\lambda |\le n}$ and ${\displaystyle |\lambda |\equiv nmod2}$, ${\displaystyle U_{\lambda }}$ is an irreducible ${\displaystyle O(V)}$-module, and ${\displaystyle W_{\lambda }}$ is a Brauer-Specht module of ${\displaystyle B_n(d)}$.

It follows that the Brauer algebra has a natural action on the space of polynomials on ${\displaystyle V^n}$, which commutes with the action of the orthogonal group.

If ${\displaystyle \delta }$ is a negative even integer, the Brauer algebra is related by Schur-Weyl duality to the symplectic group ${\displaystyle {\text{Sp}}_{-\delta }(\mathbb{ℂ})}$, rather than the orthogonal group.

The walled Brauer algebra ${\displaystyle {\mathfrak{𝔅}}_{r,s}(\delta )}$ is a subalgebra of ${\displaystyle {\mathfrak{𝔅}}_{r+s}(\delta )}$. Diagrammatically, it consists of diagrams where the only allowed pairings are of the types ${\displaystyle X_{i\le r}-X_{j>r}}$, ${\displaystyle Y_{i\le r}-Y_{j>r}}$, ${\displaystyle X_{i\le r}-Y_{j\le r}}$, ${\displaystyle X_{i>r}-Y_{j>r}}$. This amounts to having a wall that separates ${\displaystyle X_{i\le r},Y_{i\le r}}$ from ${\displaystyle X_{i>r},Y_{i>r}}$, and requiring that ${\displaystyle X-Y}$ pairings cross the wall while ${\displaystyle X-X,Y-Y}$ pairings don't.^[6]

The walled Brauer algebra is generated by ${\displaystyle \{s_i{\}}_{1\le i\le r+s-1,i\ne r}\cup \{e_r\}}$. These generators obey the basic relations of ${\displaystyle {\mathfrak{𝔅}}_{r+s}(\delta )}$ that involve them, plus the two relations^[7]

${\displaystyle e_r{s}_{r+1}{s}_{r-1}{e}_r{s}_{r-1}=e_r{s}_{r+1}{s}_{r-1}{e}_r{s}_{r+1},s_{r-1}{e}_r{s}_{r+1}{s}_{r-1}{e}_r=s_{r+1}{e}_r{s}_{r+1}{s}_{r-1}{e}_r}$

(In ${\displaystyle {\mathfrak{𝔅}}_{r+s}(\delta )}$, these two relations follow from the basic relations.)

For ${\displaystyle \delta }$ a natural integer, let ${\displaystyle V}$ be the natural representation of the general linear group ${\displaystyle G{L}_{\delta }(\mathbb{ℂ})}$. The walled Brauer algebra ${\displaystyle {\mathfrak{𝔅}}_{r,s}(\delta )}$ has a natural action on ${\displaystyle V^{\otimes r}\otimes (V^{*}{)}^{\otimes s}}$, which is related by Schur-Weyl duality to the action of ${\displaystyle G{L}_{\delta }(\mathbb{ℂ})}$.^[6]

• Birman–Wenzl algebra, a deformation of the Brauer algebra.

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