Lie bialgebra


In mathematics, a Lie bialgebra is the Lie-theoretic case of a bialgebra: it is 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

A vector space is a Lie bialgebra if it is a Lie algebra,
and there is the structure of Lie algebra also on the dual vector space which is compatible.
More precisely the Lie algebra structure on is given
by a Lie bracket
and the Lie algebra structure on is given by a Lie
bracket.
Then the map dual to is called the cocommutator,
and the compatibility condition is the following cocycle relation:
where is the adjoint.
Note that this definition is symmetric and is also a Lie bialgebra, the dual Lie bialgebra.

Example

Let be any semisimple Lie algebra.
To specify a Lie bialgebra structure we thus need to specify a compatible Lie algebra structure on the dual vector space.
Choose a Cartan subalgebra and a choice of positive roots.
Let be the corresponding opposite Borel subalgebras, so that and there is a natural projection.
Then define a Lie algebra
which is a subalgebra of the product , and has the same dimension as.
Now identify with dual of via the pairing
where and is the Killing form.
This defines a Lie bialgebra structure on, and is the "standard" example: it underlies the Drinfeld-Jimbo quantum group.
Note that is solvable, whereas is semisimple.

Relation to Poisson-Lie groups

The Lie algebra of a Poisson-Lie group G has a natural structure of Lie bialgebra.
In brief the Lie group structure gives the Lie bracket on as usual, and the linearisation of the Poisson structure on G
gives the Lie bracket on
.
In more detail, let G be a Poisson-Lie group, with being two smooth functions on the group manifold. Let be the differential at the identity element. Clearly,. The Poisson structure on the group then induces a bracket on, as
where is the Poisson bracket. Given be the Poisson bivector on the manifold, define to be the right-translate of the bivector to the identity element in G. Then one has that
The cocommutator is then the tangent map:
so that
is the dual of the cocommutator.