Quasi-bialgebra

In mathematics, quasi-bialgebras are a generalization of bialgebras: they were first defined by the Ukrainian mathematician Vladimir Drinfeld in 1990. A quasi-bialgebra differs from a bialgebra by having coassociativity replaced by an invertible element ${\displaystyle \mathrm{\Phi }}$ which controls the non-coassociativity. One of their key properties is that the corresponding category of modules forms a tensor category.

Definition

A quasi-bialgebra ${\displaystyle {{B}}_{{𝒜}}=({𝒜},\mathrm{\Delta },\epsilon ,\mathrm{\Phi },l,r)}$ is an algebra ${\displaystyle {𝒜}}$ over a field ${\displaystyle \mathbb{𝔽}}$ equipped with morphisms of algebras

${\displaystyle \mathrm{\Delta }:{𝒜}\to {𝒜}{\otimes }{𝒜}}$

${\displaystyle \epsilon :{𝒜}\to \mathbb{𝔽}}$

along with invertible elements ${\displaystyle \mathrm{\Phi }\in {𝒜}{\otimes }{𝒜}{\otimes }{𝒜}}$, and ${\displaystyle r,l\in A}$ such that the following identities hold:

${\displaystyle (id\otimes \mathrm{\Delta })\circ \mathrm{\Delta }(a)=\mathrm{\Phi }[(\mathrm{\Delta }\otimes id)\circ \mathrm{\Delta }(a)]{\mathrm{\Phi }}^{-1},\mathrm{\forall }a\in {𝒜}}$

$$\begin{gathered} {\displaystyle [(id\otimes id\otimes \mathrm{\Delta })(\mathrm{\Phi })] \\ [(\mathrm{\Delta }\otimes id\otimes id)(\mathrm{\Phi })]=(1\otimes \mathrm{\Phi }) \\ [(id\otimes \mathrm{\Delta }\otimes id)(\mathrm{\Phi })] \\ (\mathrm{\Phi }\otimes 1)} \end{gathered}$$

${\displaystyle (\epsilon \otimes id)(\mathrm{\Delta }a)=l^{-1}al,(id\otimes \epsilon )\circ \mathrm{\Delta }=r^{-1}ar,\mathrm{\forall }a\in {𝒜}}$

${\displaystyle (id\otimes \epsilon \otimes id)(\mathrm{\Phi })=r\otimes l^{-1}.}$

Where ${\displaystyle \mathrm{\Delta }}$ and ${\displaystyle ϵ}$ are called the comultiplication and counit, ${\displaystyle r}$ and ${\displaystyle l}$ are called the right and left unit constraints (resp.), and ${\displaystyle \mathrm{\Phi }}$ is sometimes called the Drinfeld associator.^{[1]: 369–376} This definition is constructed so that the category ${\displaystyle {𝒜}-Mod}$ is a tensor category under the usual vector space tensor product, and in fact this can be taken as the definition instead of the list of above identities.^[1]: 368 Since many of the quasi-bialgebras that appear "in nature" have trivial unit constraints, ie. ${\displaystyle l=r=1}$ the definition may sometimes be given with this assumed.^[1]: 370 Note that a bialgebra is just a quasi-bialgebra with trivial unit and associativity constraints: ${\displaystyle l=r=1}$ and ${\displaystyle \mathrm{\Phi }=1\otimes 1\otimes 1}$.

Braided quasi-bialgebras

A braided quasi-bialgebra (also called a quasi-triangular quasi-bialgebra) is a quasi-bialgebra whose corresponding tensor category ${\displaystyle {𝒜}-Mod}$ is braided. Equivalently, by analogy with braided bialgebras, we can construct a notion of a universal R-matrix which controls the non-cocommutativity of a quasi-bialgebra. The definition is the same as in the braided bialgebra case except for additional complications in the formulas caused by adding in the associator. Proposition: A quasi-bialgebra ${\displaystyle ({𝒜},\mathrm{\Delta },ϵ,\mathrm{\Phi },l,r)}$ is braided if it has a universal R-matrix, ie an invertible element ${\displaystyle R\in {𝒜}{\otimes }{𝒜}}$ such that the following 3 identities hold:

${\displaystyle ({\mathrm{\Delta }}^{op})(a)=R\mathrm{\Delta }(a)R^{-1}}$

${\displaystyle (id\otimes \mathrm{\Delta })(R)=({\mathrm{\Phi }}_{231}{)}^{-1}{R}_{13}{\mathrm{\Phi }}_{213}{R}_{12}({\mathrm{\Phi }}_{213}{)}^{-1}}$

${\displaystyle (\mathrm{\Delta }\otimes id)(R)=({\mathrm{\Phi }}_{321})R_{13}({\mathrm{\Phi }}_{213}{)}^{-1}{R}_{23}{\mathrm{\Phi }}_{123}}$

Where, for every ${\displaystyle a_1\otimes ...\otimes a_k\in {{𝒜}}^{\otimes k}}$, ${\displaystyle a_{i_1{i}_2...i_n}}$ is the monomial with ${\displaystyle a_j}$ in the ${\displaystyle i_j}$th spot, where any omitted numbers correspond to the identity in that spot. Finally we extend this by linearity to all of ${\displaystyle {{𝒜}}^{\otimes k}}$.^[1]: 371 Again, similar to the braided bialgebra case, this universal R-matrix satisfies (a non-associative version of) the Yang–Baxter equation:

${\displaystyle R_{12}{\mathrm{\Phi }}_{321}{R}_{13}({\mathrm{\Phi }}_{132}{)}^{-1}{R}_{23}{\mathrm{\Phi }}_{123}={\mathrm{\Phi }}_{321}{R}_{23}({\mathrm{\Phi }}_{231}{)}^{-1}{R}_{13}{\mathrm{\Phi }}_{213}{R}_{12}}$^[1]: 372

Twisting

Given a quasi-bialgebra, further quasi-bialgebras can be generated by twisting (from now on we will assume ${\displaystyle r=l=1}$) . If ${\displaystyle {{B}}_{{𝒜}}}$ is a quasi-bialgebra and ${\displaystyle F\in {𝒜}{\otimes }{𝒜}}$ is an invertible element such that ${\displaystyle (\epsilon \otimes id)F=(id\otimes \epsilon )F=1}$, set

${\displaystyle {\mathrm{\Delta }}^{\prime }(a)=F\mathrm{\Delta }(a)F^{-1},\mathrm{\forall }a\in {𝒜}}$

$$\begin{gathered} {\displaystyle {\mathrm{\Phi }}^{\prime }=(1\otimes F) \\ ((id\otimes \mathrm{\Delta })F) \\ \mathrm{\Phi } \\ ((\mathrm{\Delta }\otimes id)F^{-1}) \\ (F^{-1}\otimes 1).} \end{gathered}$$

Then, the set ${\displaystyle ({𝒜},{\mathrm{\Delta }}^{\prime },\epsilon ,{\mathrm{\Phi }}^{\prime })}$ is also a quasi-bialgebra obtained by twisting ${\displaystyle {{B}}_{{𝒜}}}$ by F, which is called a twist or gauge transformation.^[1]: 373 If ${\displaystyle ({𝒜},\mathrm{\Delta },\epsilon ,\mathrm{\Phi })}$ was a braided quasi-bialgebra with universal R-matrix ${\displaystyle R}$ , then so is ${\displaystyle ({𝒜},{\mathrm{\Delta }}^{\prime },\epsilon ,{\mathrm{\Phi }}^{\prime })}$ with universal R-matrix ${\displaystyle F_{21}R{F}^{-1}}$ (using the notation from the above section).^[1]: 376 However, the twist of a bialgebra is only in general a quasi-bialgebra. Twistings fulfill many expected properties. For example, twisting by ${\displaystyle F_1}$ and then ${\displaystyle F_2}$ is equivalent to twisting by ${\displaystyle F_2{F}_1}$, and twisting by ${\displaystyle F}$ then ${\displaystyle F^{-1}}$ recovers the original quasi-bialgebra. Twistings have the important property that they induce categorical equivalences on the tensor category of modules: Theorem: Let ${\displaystyle {{B}}_{{𝒜}}}$, ${\displaystyle {{B}}_{{{𝒜}}^{\prime }}}$ be quasi-bialgebras, let ${\displaystyle {ℬ}{{\text{'}}}_{{{𝒜}}^{\prime }}}$ be the twisting of ${\displaystyle {{B}}_{{{𝒜}}^{\prime }}}$ by ${\displaystyle F}$, and let there exist an isomorphism: ${\displaystyle \alpha :{{B}}_{{𝒜}}\to {ℬ}{{\text{'}}}_{{{𝒜}}^{\prime }}}$. Then the induced tensor functor ${\displaystyle ({\alpha }^{*},id,{\varphi }_2^F)}$ is a tensor category equivalence between ${\displaystyle {{𝒜}}^{\prime }-mod}$ and ${\displaystyle {𝒜}-mod}$. Where ${\displaystyle {\varphi }_2^F(v\otimes w)=F^{-1}(v\otimes w)}$. Moreover, if ${\displaystyle \alpha }$ is an isomorphism of braided quasi-bialgebras, then the above induced functor is a braided tensor category equivalence.^{[1]: 375–376}

Usage

Quasi-bialgebras form the basis of the study of quasi-Hopf algebras and further to the study of Drinfeld twists and the representations in terms of F-matrices associated with finite-dimensional irreducible representations of quantum affine algebra. F-matrices can be used to factorize the corresponding R-matrix. This leads to applications in statistical mechanics, as quantum affine algebras, and their representations give rise to solutions of the Yang–Baxter equation, a solvability condition for various statistical models, allowing characteristics of the model to be deduced from its corresponding quantum affine algebra. The study of F-matrices has been applied to models such as the XXZ in the framework of the Algebraic Bethe ansatz.

See also

• Bialgebra
• Hopf algebra
• Quasi-Hopf algebra

References

Further reading

• Vladimir Drinfeld, Quasi-Hopf algebras, Leningrad Math J. 1 (1989), 1419-1457
• J.M. Maillet and J. Sanchez de Santos, Drinfeld Twists and Algebraic Bethe Ansatz, Amer. Math. Soc. Transl. (2) Vol. 201, 2000