Partition algebra

Template:Short description The partition algebra is an associative algebra with a basis of set-partition diagrams and multiplication given by diagram concatenation.^[1] Its subalgebras include diagram algebras such as the Brauer algebra, the Temperley–Lieb algebra, or the group algebra of the symmetric group. Representations of the partition algebra are built from sets of diagrams and from representations of the symmetric group.

A partition of ${\displaystyle 2k}$ elements labelled ${\displaystyle 1,\overline{1},2,\overline{2},\dots ,k,\overline{k}}$ is represented as a diagram, with lines connecting elements in the same subset. In the following example, the subset ${\displaystyle \{\overline{1},\overline{4},\overline{5},6\}}$ gives rise to the lines ${\displaystyle \overline{1}-\overline{4},\overline{4}-\overline{5},\overline{5}-6}$, and could equivalently be represented by the lines ${\displaystyle \overline{1}-6,\overline{4}-6,\overline{5}-6,\overline{1}-\overline{5}}$ (for instance).

Diagram representation of a partition of 14 elements

For ${\displaystyle n\in ℂ}$ and ${\displaystyle k\in {\mathbb{N}}^{*}}$, the partition algebra ${\displaystyle P_k(n)}$ is defined by a ${\displaystyle ℂ}$-basis made of partitions, and a multiplication given by diagram concatenation. The concatenated diagram comes with a factor ${\displaystyle n^D}$, where ${\displaystyle D}$ is the number of connected components that are disconnected from the top and bottom elements.

The partition algebra ${\displaystyle P_k(n)}$ is generated by ${\displaystyle 3k-2}$ elements of the type

These generators obey relations that include^[2]

${\displaystyle s_i^2=1,s_i{s}_{i+1}{s}_i=s_{i+1}{s}_i{s}_{i+1},p_i^2=n{p}_i,b_i^2=b_i,p_i{b}_i{p}_i=p_i}$

Other elements that are useful for generating subalgebras include

Elements of the partition algebra that are useful for generating subalgebras

In terms of the original generators, these elements are

${\displaystyle e_i=b_i{p}_i{p}_{i+1}{b}_i,l_i=s_i{p}_i,r_i=p_i{s}_i}$

The partition algebra ${\displaystyle P_k(n)}$ is an associative algebra. It has a multiplicative identity

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The partition algebra ${\displaystyle P_k(n)}$ is semisimple for ${\displaystyle n\in ℂ-\{0,1,\dots ,2k-2\}}$. For any two ${\displaystyle n,n^{\prime }}$ in this set, the algebras ${\displaystyle P_k(n)}$ and ${\displaystyle P_k(n^{\prime })}$ are isomorphic.^[1]

The partition algebra is finite-dimensional, with ${\displaystyle \dim P_k(n)=B_{2k}}$ (a Bell number).

Subalgebras of the partition algebra can be defined by the following properties:^[3]

• Whether they are planar i.e. whether lines may cross in diagrams.
• Whether subsets are allowed to have any size ${\displaystyle 1,2,\dots ,2k}$, or size ${\displaystyle 1,2}$, or only size ${\displaystyle 2}$.
• Whether we allow top-top and bottom-bottom lines, or only top-bottom lines. In the latter case, the parameter ${\displaystyle n}$ is absent, or can be eliminated by ${\displaystyle p_i\to \frac{1}{n}{p}_i}$.

Combining these properties gives rise to 8 nontrivial subalgebras, in addition to the partition algebra itself:^[1][3]

Notation	Name	Generators	Dimension	Example
${\displaystyle P_k(n)}$	Partition	${\displaystyle s_i,p_i,b_i}$	${\displaystyle B_{2k}}$	A partition
${\displaystyle P{P}_k(n)}$	Planar partition	${\displaystyle p_i,b_i}$	${\displaystyle \frac{1}{2k+1}{\displaystyle (\genfrac{}{}{0ex}{}{4k}{2k})}}$	A planar partition
${\displaystyle R{B}_k(n)}$	Rook Brauer	${\displaystyle s_i,e_i,p_i}$	${\displaystyle {\displaystyle \sum _{\ell =0}^k}{\displaystyle (\genfrac{}{}{0ex}{}{2k}{2\ell })}(2\ell -1)!!}$	A rook Brauer partition
${\displaystyle M_k(n)}$	Motzkin	${\displaystyle e_i,l_i,r_i}$	${\displaystyle {\displaystyle \sum _{\ell =0}^k}\frac{1}{\ell +1}{\displaystyle (\genfrac{}{}{0ex}{}{2\ell }{\ell })}{\displaystyle (\genfrac{}{}{0ex}{}{2k}{2\ell })}}$	A Motkzin partition
${\displaystyle B_k(n)}$	Brauer	${\displaystyle s_i,e_i}$	${\displaystyle (2k-1)!!}$	A Brauer partition
${\displaystyle T{L}_k(n)}$	Temperley–Lieb	${\displaystyle e_i}$	${\displaystyle \frac{1}{k+1}{\displaystyle (\genfrac{}{}{0ex}{}{2k}{k})}}$	A Temperley-Lieb partition
${\displaystyle R_k}$	Rook	${\displaystyle s_i,p_i}$	${\displaystyle {\displaystyle \sum _{\ell =0}^k}{{\displaystyle (\genfrac{}{}{0ex}{}{k}{\ell })}}^2\ell !}$	A rook monoid partition
${\displaystyle P{R}_k}$	Planar rook	${\displaystyle l_i,r_i}$	${\displaystyle {\displaystyle (\genfrac{}{}{0ex}{}{2k}{k})}}$	A planar rook monoid partition
${\displaystyle ℂS_k}$	Symmetric group	${\displaystyle s_i}$	${\displaystyle k!}$	A permutation partition

The symmetric group algebra ${\displaystyle ℂS_k}$ is the group ring of the symmetric group ${\displaystyle S_k}$ over ${\displaystyle ℂ}$. The Motzkin algebra is sometimes called the dilute Temperley–Lieb algebra in the physics literature.^[4]

The listed subalgebras are semisimple for ${\displaystyle n\in ℂ-\{0,1,\dots ,2k-2\}}$.

Inclusions of planar into non-planar algebras:

${\displaystyle P{P}_k(n)\subset P_k(n),M_k(n)\subset R{B}_k(n),T{L}_k(n)\subset B_k(n),P{R}_k\subset R_k}$

Inclusions from constraints on subset size:

${\displaystyle B_k(n)\subset R{B}_k(n)\subset P_k(n),T{L}_k(n)\subset M_k(n)\subset P{P}_k(n),ℂS_k\subset R_k}$

Inclusions from allowing top-top and bottom-bottom lines:

${\displaystyle R_k\subset R{B}_k(n),P{R}_k\subset M_k(n),ℂS_k\subset B_k(n)}$

We have the isomorphism:

${\displaystyle P{P}_k(n^2)\cong T{L}_{2k}(n),\{\begin{array}{c}{p}_i\mapsto n{e}_{2i-1}\\ b_i\mapsto \frac{1}{n}{e}_{2i}\end{array}}$

In addition to the eight subalgebras described above, other subalgebras have been defined:

• The totally propagating partition subalgebra ${\displaystyle \text{prop}{P}_k}$ is generated by diagrams whose blocks all propagate, i.e. partitions whose subsets all contain top and bottom elements.^[5] These diagrams from the dual symmetric inverse monoid, which is generated by ${\displaystyle s_i,b_i{p}_{i+1}{b}_{i+1}}$.^[6]
• The quasi-partition algebra ${\displaystyle Q{P}_k(n)}$ is generated by subsets of size at least two. Its generators are ${\displaystyle s_i,b_i,e_i}$ and its dimension is ${\displaystyle 1+{\displaystyle \sum _{j=1}^{2k}}(-1{)}^{j-1}{B}_{2k-j}}$.^[7]
• The uniform block permutation algebra ${\displaystyle U_k}$ is generated by subsets with as many top elements as bottom elements. It is generated by ${\displaystyle s_i,b_i}$.^[8]

An algebra with a half-integer index ${\displaystyle k+\frac{1}{2}}$ is defined from partitions of ${\displaystyle 2k+2}$ elements by requiring that ${\displaystyle k+1}$ and ${\displaystyle \overline{k+1}}$ are in the same subset. For example, ${\displaystyle P_{k+\frac{1}{2}}}$ is generated by ${\displaystyle s_{i\le k-1},b_{i\le k},p_{i\le k}}$ so that ${\displaystyle P_k\subset P_{k+\frac{1}{2}}\subset P_{k+1}}$, and ${\displaystyle \dim P_{k+\frac{1}{2}}=B_{2k+1}}$.^[2]

Periodic subalgebras are generated by diagrams that can be drawn on an annulus without line crossings. Such subalgebras include a translation element ${\displaystyle u=}$ such that ${\displaystyle u^k=1}$. The translation element and its powers are the only combinations of ${\displaystyle s_i}$ that belong to periodic subalgebras.

For an integer ${\displaystyle 0\le \ell \le k}$, let ${\displaystyle D_{\ell }}$ be the set of partitions of ${\displaystyle k+\ell }$ elements ${\displaystyle 1,2,\dots ,k}$ (bottom) and ${\displaystyle \overline{1},\overline{2},\dots ,\overline{\ell }}$ (top), such that no two top elements are in the same subset, and no top element is alone. Such partitions are represented by diagrams with no top-top lines, with at least one line for each top element. For example, in the case ${\displaystyle k=12,\ell =5}$:

Partition diagrams act on ${\displaystyle D_{\ell }}$ from the bottom, while the symmetric group ${\displaystyle S_{\ell }}$ acts from the top. For any Specht module ${\displaystyle V_{\lambda }}$ of ${\displaystyle S_{\ell }}$ (with therefore ${\displaystyle |\lambda |=\ell }$), we define the representation of ${\displaystyle P_k(n)}$

${\displaystyle {𝒫}_{\lambda }=ℂD_{|\lambda |}{\otimes }_{ℂS_{|\lambda |}}{V}_{\lambda }.}$

The dimension of this representation is^[1]

${\displaystyle \dim {𝒫}_{\lambda }=f_{\lambda }{\displaystyle \sum _{\ell =|\lambda |}^k}\left\{\genfrac{}{}{0ex}{}{k}{\ell }\right\}{\displaystyle (\genfrac{}{}{0ex}{}{\ell }{|\lambda |})},}$

where ${\displaystyle \left\{\genfrac{}{}{0ex}{}{k}{\ell }\right\}}$ is a Stirling number of the second kind, ${\displaystyle {\displaystyle (\genfrac{}{}{0ex}{}{\ell }{|\lambda |})}}$ is a binomial coefficient, and ${\displaystyle f_{\lambda }=\dim V_{\lambda }}$ is given by the hook length formula.

A basis of ${\displaystyle {𝒫}_{\lambda }}$ can be described combinatorially in terms of set-partition tableaux: Young tableaux whose boxes are filled with the blocks of a set partition.^[1]

Assuming that ${\displaystyle P_k(n)}$ is semisimple, the representation ${\displaystyle {𝒫}_{\lambda }}$ is irreducible, and the set of irreducible finite-dimensional representations of the partition algebra is

${\displaystyle \text{Irrep}(P_k(n))={\left\{{𝒫}_{\lambda }\right\}}_{0\le |\lambda |\le k}.}$

Representations of non-planar subalgebras have similar structures as representations of the partition algebra. For example, the Brauer-Specht modules of the Brauer algebra are built from Specht modules, and certain sets of partitions.

In the case of the planar subalgebras, planarity prevents nontrivial permutations, and Specht modules do not appear. For example, a standard module of the Temperley–Lieb algebra is parametrized by an integer ${\displaystyle 0\le \ell \le k}$ with ${\displaystyle \ell \equiv kmod2}$, and a basis is simply given by a set of partitions.

The following table lists the irreducible representations of the partition algebra and eight subalgebras.^[3]

Algebra	Parameter	Conditions	Dimension
${\displaystyle P_k(n)}$	${\displaystyle \lambda }$	${\displaystyle 0\le |\lambda |\le k}$	${\displaystyle f_{\lambda }{\displaystyle \sum _{\ell =|\lambda |}^k}\left\{\genfrac{}{}{0ex}{}{k}{\ell }\right\}{\displaystyle (\genfrac{}{}{0ex}{}{\ell }{|\lambda |})}}$
${\displaystyle P{P}_k(n)}$	${\displaystyle \ell }$	${\displaystyle 0\le \ell \le k}$	${\displaystyle {\displaystyle (\genfrac{}{}{0ex}{}{2k}{k+\ell })}-{\displaystyle (\genfrac{}{}{0ex}{}{2k}{k+\ell +1})}}$
${\displaystyle R{B}_k(n)}$	${\displaystyle \lambda }$	${\displaystyle 0\le |\lambda |\le k}$	${\displaystyle f_{\lambda }{\displaystyle (\genfrac{}{}{0ex}{}{k}{|\lambda |})}{\displaystyle \sum _{m=0}^{\lfloor \frac{k-|\lambda |}{2}\rfloor }}{\displaystyle (\genfrac{}{}{0ex}{}{k-|\lambda |}{2m})}(2m-1)!!}$
${\displaystyle M_k(n)}$	${\displaystyle \ell }$	${\displaystyle 0\le \ell \le k}$	${\displaystyle {\displaystyle \sum _{m=0}^{\lfloor \frac{k-\ell }{2}\rfloor }}{\displaystyle (\genfrac{}{}{0ex}{}{k}{\ell +2m})}\{{\displaystyle (\genfrac{}{}{0ex}{}{\ell +2m}{m})}-{\displaystyle (\genfrac{}{}{0ex}{}{\ell +2m}{m-1})}\}}$
${\displaystyle B_k(n)}$	${\displaystyle \lambda }$	${\displaystyle \begin{array}{c}0\le |\lambda |\le k\\ |\lambda |\equiv kmod2\end{array}}$	${\displaystyle f_{\lambda }{\displaystyle (\genfrac{}{}{0ex}{}{k}{|\lambda |})}(k-|\lambda |-1)!!}$
${\displaystyle T{L}_k(n)}$	${\displaystyle \ell }$	${\displaystyle \begin{array}{c}0\le \ell \le k\\ \ell \equiv kmod2\end{array}}$	${\displaystyle {\displaystyle (\genfrac{}{}{0ex}{}{k}{\frac{k+\ell }{2}})}-{\displaystyle (\genfrac{}{}{0ex}{}{k}{\frac{k+\ell +2}{2}})}}$
${\displaystyle R_k}$	${\displaystyle \lambda }$	${\displaystyle 0\le |\lambda |\le k}$	${\displaystyle f_{\lambda }{\displaystyle (\genfrac{}{}{0ex}{}{k}{|\lambda |})}}$
${\displaystyle P{R}_k}$	${\displaystyle \ell }$	${\displaystyle 0\le \ell \le k}$	${\displaystyle {\displaystyle (\genfrac{}{}{0ex}{}{k}{\ell })}}$
${\displaystyle ℂS_k}$	${\displaystyle \lambda }$	${\displaystyle |\lambda |=k}$	${\displaystyle f_{\lambda }}$

The irreducible representations of ${\displaystyle \text{prop}{P}_k}$ are indexed by partitions such that ${\displaystyle 0<|\lambda |\le k}$ and their dimensions are ${\displaystyle f_{\lambda }\left\{\genfrac{}{}{0ex}{}{k}{|\lambda |}\right\}}$.^[5] The irreducible representations of ${\displaystyle Q{P}_k}$ are indexed by partitions such that ${\displaystyle 0\le |\lambda |\le k}$.^[7] The irreducible representations of ${\displaystyle U_k}$ are indexed by sequences of partitions.^[8]

Assume ${\displaystyle n\in {\mathbb{N}}^{*}}$. For ${\displaystyle V}$ a ${\displaystyle n}$-dimensional vector space with basis ${\displaystyle v_1,\dots ,v_n}$, there is a natural action of the partition algebra ${\displaystyle P_k(n)}$ on the vector space ${\displaystyle V^{\otimes k}}$. This action is defined by the matrix elements of a partition ${\displaystyle \{1,\overline{1},2,\overline{2},\dots ,k,\overline{k}\}={\bigsqcup }_h{E}_h}$ in the basis ${\displaystyle (v_{j_1}\otimes \cdots \otimes v_{j_k})}$:^[2]

${\displaystyle {\left({\bigsqcup }_h{E}_h\right)}_{j_1,j_2,\dots ,j_k}^{j_{\overline{1}},j_{\overline{2}},\dots ,j_{\overline{k}}}={\mathrm{𝟏}}_{r,s\in E_h⟹j_r=j_s}.}$

This matrix element is one if all indices corresponding to any given partition subset coincide, and zero otherwise. For example, the action of a Temperley–Lieb generator is

${\displaystyle e_i(v_{j_1}\otimes \cdots \otimes v_{j_i}\otimes v_{j_{i+1}}\otimes \cdots \otimes v_{j_k})={\delta }_{j_i,j_{i+1}}{\displaystyle \sum _{j=1}^n}{v}_{j_1}\otimes \cdots \otimes v_j\otimes v_j\otimes \cdots \otimes v_{j_k}.}$

Let ${\displaystyle n\ge 2k}$ be integer. Let us take ${\displaystyle V}$ to be the natural permutation representation of the symmetric group ${\displaystyle S_n}$. This ${\displaystyle n}$-dimensional representation is a sum of two irreducible representations: the standard and trivial representations, ${\displaystyle V=[n-1,1]\oplus [n]}$.

Then the partition algebra ${\displaystyle P_k(n)}$ is the centralizer of the action of ${\displaystyle S_n}$ on the tensor product space ${\displaystyle V^{\otimes k}}$,

${\displaystyle P_k(n)\cong {\text{End}}_{S_n}\left(V^{\otimes k}\right).}$

Moreover, as a bimodule over ${\displaystyle P_k(n)\times S_n}$, the tensor product space decomposes into irreducible representations as^[1]

${\displaystyle V^{\otimes k}=\underset{0\le |\lambda |\le k}{⨁}{𝒫}_{\lambda }\otimes V_{[n-|\lambda |,\lambda ]},}$

where ${\displaystyle [n-|\lambda |,\lambda ]}$ is a Young diagram of size ${\displaystyle n}$ built by adding a first row to ${\displaystyle \lambda }$, and ${\displaystyle V_{[n-|\lambda |,\lambda ]}}$ is the corresponding Specht module of ${\displaystyle S_n}$.

The duality between the symmetric group and the partition algebra generalizes the original Schur-Weyl duality between the general linear group and the symmetric group. There are other generalizations. In the relevant tensor product spaces, we write ${\displaystyle V_n}$ for an irreducible ${\displaystyle n}$-dimensional representation of the first group or algebra:

Tensor product space	Group or algebra	Dual algebra or group	Comments
${\displaystyle {(V_{n-1}\oplus V_1)}^{\otimes k}}$	${\displaystyle S_n}$	${\displaystyle P_k(n)}$	The duality for the full partition algebra
${\displaystyle {(V_{n-2}\oplus V_1\oplus V_1)}^{\otimes k}}$	${\displaystyle S_{n-1}}$	${\displaystyle P_{k+\frac{1}{2}}(n)}$	Case of a partition algebra with a half-integer index[2]
${\displaystyle V_n^{\otimes k}}$	${\displaystyle G{L}_n(ℂ)}$	${\displaystyle S_k}$	The original Schur-Weyl duality
${\displaystyle V_n^{\otimes k}}$	${\displaystyle O(n)}$	${\displaystyle B_k(n)}$	Duality between the orthogonal group and the Brauer algebra
${\displaystyle {(V_n\oplus V_1)}^{\otimes k}}$	${\displaystyle O(n)}$	${\displaystyle R{B}_k(n+1)}$	Duality between the orthogonal group and the rook Brauer algebra[9]
${\displaystyle V_n^{\otimes k}}$	${\displaystyle R_n}$	${\displaystyle \text{prop}{P}_k}$	Duality between the rook algebra and the totally propagating partition algebra[10][5]
${\displaystyle V_2^{\otimes k}}$	${\displaystyle gl(1|1)}$	${\displaystyle P{R}_{k-1}}$	Duality between a Lie superalgebra and the planar rook algebra[11]
${\displaystyle V_{n-1}^{\otimes k}}$	${\displaystyle S_n}$	${\displaystyle Q{P}_k(n)}$	Duality between the symmetric group and the quasi-partition algebra[7]
${\displaystyle V_n^{\otimes r}\otimes {\left(V_n^{*}\right)}^{\otimes s}}$	${\displaystyle G{L}_n(ℂ)}$	${\displaystyle B_{r,s}(n)}$	Duality involving the walled Brauer algebra.[12]

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