Algebraic expression: Difference between revisions

In mathematics, a Lie bialgebra is the Lie-theoretic case of a bialgebra: it's a set with a Lie algebra and a Lie coalgebra structure which are compatible.

It is a bialgebra where the comultiplication is skew-symmetric and satisfies a dual Jacobi identity, so that the dual vector space is a Lie algebra, whereas the comultiplication is a 1-cocycle, so that the multiplication and comultiplication are compatible. The cocycle condition implies that, in practice, one studies only classes of bialgebras that are cohomologous to a Lie bialgebra on a coboundary.

They are also called Poisson-Hopf algebras, and are the Lie algebra of a Poisson-Lie group.

Lie bialgebras occur naturally in the study of the Yang-Baxter equations.

Definition

More precisely, comultiplication on the algebra, ${\displaystyle \delta :\mathfrak{g}\to \mathfrak{g}\otimes \mathfrak{g}}$, is called the cocommutator, and must satisfy two properties. The dual

${\displaystyle {\delta }^{*}:{\mathfrak{g}}^{*}\otimes {\mathfrak{g}}^{*}\to {\mathfrak{g}}^{*}}$

must be a Lie bracket on ${\displaystyle {\mathfrak{g}}^{*}}$, and it must be a cocycle:

${\displaystyle \delta ([X,Y])=({\mathrm{ad}}_X\otimes 1+1\otimes {\mathrm{ad}}_X)\delta (Y)-({\mathrm{ad}}_Y\otimes 1+1\otimes {\mathrm{ad}}_Y)\delta (X)}$

where ${\displaystyle {\mathrm{ad}}_{X}Y=[X,Y]}$ is the adjoint.

Relation to Poisson-Lie groups

Let G be a Poisson-Lie group, with ${\displaystyle f_1,f_2\in C^{\mathrm{\infty }}(G)}$ being two smooth functions on the group manifold. Let ${\displaystyle \xi =(df{)}_e}$ be the differential at the identity element. Clearly, ${\displaystyle \xi \in {\mathfrak{g}}^{*}}$. The Poisson structure on the group then induces a bracket on ${\displaystyle {\mathfrak{g}}^{*}}$, as

${\displaystyle [{\xi }_1,{\xi }_2]=(d\{f_1,f_2\}{)}_e}$

where ${\displaystyle \{,\}}$ is the Poisson bracket. Given ${\displaystyle \eta }$ be the Poisson bivector on the manifold, define ${\displaystyle {\eta }^R}$ to be the right-translate of the bivector to the identity element in G. Then one has that

${\displaystyle {\eta }^R:G\to \mathfrak{g}\otimes \mathfrak{g}}$

The cocommutator is then the tangent map:

${\displaystyle \delta =T_e{\eta }^R}$

so that

${\displaystyle [{\xi }_1,{\xi }_2]={\delta }^{*}({\xi }_1\otimes {\xi }_2)}$

is the dual of the cocommutator.

See also

• Lie coalgebra
• Manin triple

References

• H.-D. Doebner, J.-D. Hennig, eds, Quantum groups, Proceedings of the 8th International Workshop on Mathematical Physics, Arnold Sommerfeld Institute, Claausthal, FRG, 1989, Springer-Verlag Berlin, ISBN 3-540-53503-9.
• Vyjayanthi Chari and Andrew Pressley, A Guide to Quantum Groups, (1994), Cambridge University Press, Cambridge ISBN 0-521-55884-0.