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 $\Phi$ which controls the non-coassociativity. One of their key properties is that the corresponding category of modules forms a tensor category.

Definition[edit]

A quasi-bialgebra ${\mathcal {B_{A}}}=({\mathcal {A}},\Delta ,\varepsilon ,\Phi ,l,r)$ is an algebra ${\mathcal {A}}$ over a field $\mathbb {F}$ equipped with morphisms of algebras

\Delta :{\mathcal {A}}\rightarrow {\mathcal {A\otimes A}}

\varepsilon :{\mathcal {A}}\rightarrow \mathbb {F}

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

(id\otimes \Delta )\circ \Delta (a)=\Phi \lbrack (\Delta \otimes id)\circ \Delta (a)\rbrack \Phi ^{-1},\quad \forall a\in {\mathcal {A}}

\lbrack (id\otimes id\otimes \Delta )(\Phi )\rbrack \ \lbrack (\Delta \otimes id\otimes id)(\Phi )\rbrack =(1\otimes \Phi )\ \lbrack (id\otimes \Delta \otimes id)(\Phi )\rbrack \ (\Phi \otimes 1)

(\varepsilon \otimes id)(\Delta a)=l^{-1}al,\qquad (id\otimes \varepsilon )\circ \Delta =r^{-1}ar,\quad \forall a\in {\mathcal {A}}

(id\otimes \varepsilon \otimes id)(\Phi )=r\otimes l^{-1}.

Where $\Delta$ and $\epsilon$ are called the comultiplication and counit, $r$ and $l$ are called the right and left unit constraints (resp.), and $\Phi$ is sometimes called the Drinfeld associator.^[1]^{: 369–376} This definition is constructed so that the category ${\mathcal {A}}-Mod$ 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. $l=r=1$ 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: $l=r=1$ and $\Phi =1\otimes 1\otimes 1$ .

Braided quasi-bialgebras[edit]

A braided quasi-bialgebra (also called a quasi-triangular quasi-bialgebra) is a quasi-bialgebra whose corresponding tensor category ${\mathcal {A}}-Mod$ 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 $({\mathcal {A}},\Delta ,\epsilon ,\Phi ,l,r)$ is braided if it has a universal R-matrix, ie an invertible element $R\in {\mathcal {A\otimes A}}$ such that the following 3 identities hold:

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

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

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

Where, for every $a_{1}\otimes ...\otimes a_{k}\in {\mathcal {A}}^{\otimes k}$ , $a_{i_{1}i_{2}...i_{n}}$ is the monomial with $a_{j}$ in the $i_{j}$ th spot, where any omitted numbers correspond to the identity in that spot. Finally we extend this by linearity to all of ${\mathcal {A}}^{\otimes k}$ .^[1]^: 371

Again, similar to the braided bialgebra case, this universal R-matrix satisfies (a non-associative version of) the Yang–Baxter equation:

R_{12}\Phi _{321}R_{13}(\Phi _{132})^{-1}R_{23}\Phi _{123}=\Phi _{321}R_{23}(\Phi _{231})^{-1}R_{13}\Phi _{213}R_{12}

^[1]^: 372

Twisting[edit]

Given a quasi-bialgebra, further quasi-bialgebras can be generated by twisting (from now on we will assume $r=l=1$ ) .

If ${\mathcal {B_{A}}}$ is a quasi-bialgebra and $F\in {\mathcal {A\otimes A}}$ is an invertible element such that $(\varepsilon \otimes id)F=(id\otimes \varepsilon )F=1$ , set

\Delta '(a)=F\Delta (a)F^{-1},\quad \forall a\in {\mathcal {A}}

\Phi '=(1\otimes F)\ ((id\otimes \Delta )F)\ \Phi \ ((\Delta \otimes id)F^{-1})\ (F^{-1}\otimes 1).

Then, the set $({\mathcal {A}},\Delta ',\varepsilon ,\Phi ')$ is also a quasi-bialgebra obtained by twisting ${\mathcal {B_{A}}}$ by F, which is called a twist or gauge transformation.^[1]^: 373 If $({\mathcal {A}},\Delta ,\varepsilon ,\Phi )$ was a braided quasi-bialgebra with universal R-matrix $R$ , then so is $({\mathcal {A}},\Delta ',\varepsilon ,\Phi ')$ with universal R-matrix $F_{21}RF^{-1}$ (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 $F_{1}$ and then $F_{2}$ is equivalent to twisting by $F_{2}F_{1}$ , and twisting by $F$ then $F^{-1}$ recovers the original quasi-bialgebra.

Twistings have the important property that they induce categorical equivalences on the tensor category of modules:

Theorem: Let ${\mathcal {B_{A}}}$ , ${\mathcal {B_{A'}}}$ be quasi-bialgebras, let ${\mathcal {B'_{A'}}}$ be the twisting of ${\mathcal {B_{A'}}}$ by $F$ , and let there exist an isomorphism: $\alpha :{\mathcal {B_{A}}}\to {\mathcal {B'_{A'}}}$ . Then the induced tensor functor $(\alpha ^{*},id,\phi _{2}^{F})$ is a tensor category equivalence between ${\mathcal {A'}}-mod$ and ${\mathcal {A}}-mod$ . Where $\phi _{2}^{F}(v\otimes w)=F^{-1}(v\otimes w)$ . Moreover, if $\alpha$ is an isomorphism of braided quasi-bialgebras, then the above induced functor is a braided tensor category equivalence.^[1]^{: 375–376}

Usage[edit]

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.

References[edit]

^ ^a ^b ^c ^d ^e ^f ^g ^h C. Kassel. "Quantum Groups". Graduate Texts in Mathematics Springer-Verlag. ISBN 0387943706