Lie bialgebroid

A Lie algebroid consists of a bilinear skew-symmetric operation ${\displaystyle [\cdot ,\cdot ]}$  on the sections ${\displaystyle \Gamma (A)}$  of a vector bundle ${\displaystyle A\to M}$  over a smooth manifold ${\displaystyle M}$ , together with a vector bundle morphism ${\displaystyle \rho :A\to TM}$  subject to the Leibniz rule

${\displaystyle [\phi ,f\cdot \psi ]=\rho (\phi )[f]\cdot \psi +f\cdot [\phi ,\psi ],}$ 

and Jacobi identity

${\displaystyle [\phi ,[\psi _{1},\psi _{2}]]=[[\phi ,\psi _{1}],\psi _{2}]+[\psi _{1},[\phi ,\psi _{2}]]}$ 

where ${\displaystyle \phi ,\psi _{k}}$  are sections of ${\displaystyle A}$  and ${\displaystyle f}$  is a smooth function on ${\displaystyle M}$ .

The Lie bracket ${\displaystyle [\cdot ,\cdot ]_{A}}$  can be extended to multivector fields ${\displaystyle \Gamma (\wedge A)}$  graded symmetric via the Leibniz rule

${\displaystyle [\Phi \wedge \Psi ,\mathrm {X} ]_{A}=\Phi \wedge [\Psi ,\mathrm {X} ]_{A}+(-1)^{|\Psi |(|\mathrm {X} |-1)}[\Phi ,\mathrm {X} ]_{A}\wedge \Psi }$ 

for homogeneous multivector fields ${\displaystyle \phi ,\psi ,X}$ .

The Lie algebroid differential is an ${\displaystyle \mathbb {R} }$ -linear operator ${\displaystyle d_{A}}$  on the ${\displaystyle A}$ -forms ${\displaystyle \Omega _{A}(M)=\Gamma (\wedge A^{*})}$  of degree 1 subject to the Leibniz rule

${\displaystyle d_{A}(\alpha \wedge \beta )=(d_{A}\alpha )\wedge \beta +(-1)^{|\alpha |}\alpha \wedge d_{A}\beta }$ 

for ${\displaystyle A}$ -forms ${\displaystyle \alpha }$  and ${\displaystyle \beta }$ . It is uniquely characterized by the conditions

${\displaystyle (d_{A}f)(\phi )=\rho (\phi )[f]}$ 

and

${\displaystyle (d_{A}\alpha )[\phi ,\psi ]=\rho (\phi )[\alpha (\psi )]-\rho (\psi )[\alpha (\phi )]-\alpha [\phi ,\psi ]}$ 

for functions ${\displaystyle f}$  on ${\displaystyle M}$ , ${\displaystyle A}$ -1-forms ${\displaystyle \alpha \in \Gamma (A^{*})}$  and ${\displaystyle \phi ,\psi }$  sections of ${\displaystyle A}$ .

A Lie bialgebroid consists of two Lie algebroids ${\displaystyle (A,\rho _{A},[\cdot ,\cdot ]_{A})}$  and ${\displaystyle (A^{*},\rho _{*},[\cdot ,\cdot ]_{*})}$  on the dual vector bundles ${\displaystyle A\to M}$  and ${\displaystyle A^{*}\to M}$ , subject to the compatibility

${\displaystyle d_{*}[\phi ,\psi ]_{A}=[d_{*}\phi ,\psi ]_{A}+[\phi ,d_{*}\psi ]_{A}}$ 

for all sections ${\displaystyle \phi ,\psi }$  of ${\displaystyle A}$ . Here ${\displaystyle d_{*}}$  denotes the Lie algebroid differential of ${\displaystyle A^{*}}$  which also operates on the multivector fields ${\displaystyle \Gamma (\wedge A)}$ .

It can be shown that the definition is symmetric in ${\displaystyle A}$  and ${\displaystyle A^{*}}$ , i.e. ${\displaystyle (A,A^{*})}$  is a Lie bialgebroid if and only if ${\displaystyle (A^{*},A)}$  is.

1. A Lie bialgebra consists of two Lie algebras ${\displaystyle ({\mathfrak {g}},[\cdot ,\cdot ]_{\mathfrak {g}})}$  and ${\displaystyle ({\mathfrak {g}}^{*},[\cdot ,\cdot ]_{*})}$  on dual vector spaces ${\displaystyle {\mathfrak {g}}}$  and ${\displaystyle {\mathfrak {g}}^{*}}$  such that the Chevalley–Eilenberg differential ${\displaystyle \delta _{*}}$  is a derivation of the ${\displaystyle {\mathfrak {g}}}$ -bracket.
2. A Poisson manifold ${\displaystyle (M,\pi )}$  gives naturally rise to a Lie bialgebroid on ${\displaystyle TM}$  (with the commutator bracket of tangent vector fields) and ${\displaystyle T^{*}M}$  (with the Lie bracket induced by the Poisson structure). The ${\displaystyle T^{*}M}$ -differential is ${\displaystyle d_{*}=[\pi ,\cdot ]}$  and the compatibility follows then from the Jacobi identity of the Schouten bracket.

It is well known that the infinitesimal version of a Lie groupoid is a Lie algebroid (as a special case, the infinitesimal version of a Lie group is a Lie algebra). Therefore, one can ask which structures need to be differentiated in order to obtain a Lie bialgebroid.

A Poisson groupoid is a Lie groupoid ${\displaystyle G\rightrightarrows M}$  together with a Poisson structure ${\displaystyle \pi }$  on ${\displaystyle G}$  such that the graph ${\displaystyle m\subset G\times G\times (G,-\pi )}$  of the multiplication map is coisotropic. An example of a Poisson-Lie groupoid is a Poisson-Lie group (where ${\displaystyle M}$  is a point). Another example is a symplectic groupoid (where the Poisson structure is non-degenerate on ${\displaystyle TG}$ ).

Remember the construction of a Lie algebroid from a Lie groupoid. We take the ${\displaystyle t}$ -tangent fibers (or equivalently the ${\displaystyle s}$ -tangent fibers) and consider their vector bundle pulled back to the base manifold ${\displaystyle M}$ . A section of this vector bundle can be identified with a ${\displaystyle G}$ -invariant ${\displaystyle t}$ -vector field on ${\displaystyle G}$  which form a Lie algebra with respect to the commutator bracket on ${\displaystyle TG}$ .

We thus take the Lie algebroid ${\displaystyle A\to M}$  of the Poisson groupoid. It can be shown that the Poisson structure induces a fiber-linear Poisson structure on ${\displaystyle A}$ . Analogous to the construction of the cotangent Lie algebroid of a Poisson manifold there is a Lie algebroid structure on ${\displaystyle A^{*}}$  induced by this Poisson structure. Analogous to the Poisson manifold case one can show that ${\displaystyle A}$  and ${\displaystyle A^{*}}$  form a Lie bialgebroid.

For Lie bialgebras ${\displaystyle ({\mathfrak {g}},{\mathfrak {g}}^{*})}$  there is the notion of Manin triples, i.e. ${\displaystyle c={\mathfrak {g}}+{\mathfrak {g}}^{*}}$  can be endowed with the structure of a Lie algebra such that ${\displaystyle {\mathfrak {g}}}$  and ${\displaystyle {\mathfrak {g}}^{*}}$  are subalgebras and ${\displaystyle c}$  contains the representation of ${\displaystyle {\mathfrak {g}}}$  on ${\displaystyle {\mathfrak {g}}^{*}}$ , vice versa. The sum structure is just

${\displaystyle [X+\alpha ,Y+\beta ]=[X,Y]_{g}+\mathrm {ad} _{\alpha }Y-\mathrm {ad} _{\beta }X+[\alpha ,\beta ]_{*}+\mathrm {ad} _{X}^{*}\beta -\mathrm {ad} _{Y}^{*}\alpha }$ .

It turns out that the naive generalization to Lie algebroids does not give a Lie algebroid any more. Instead one has to modify either the Jacobi identity or violate the skew-symmetry and is thus lead to Courant algebroids.^[1]

The appropriate superlanguage of a Lie algebroid ${\displaystyle A}$  is ${\displaystyle \Pi A}$ , the supermanifold whose space of (super)functions are the ${\displaystyle A}$ -forms. On this space the Lie algebroid can be encoded via its Lie algebroid differential, which is just an odd vector field.

As a first guess the super-realization of a Lie bialgebroid ${\displaystyle (A,A^{*})}$  should be ${\displaystyle \Pi A+\Pi A^{*}}$ . But unfortunately ${\displaystyle d_{A}+d_{*}|\Pi A+\Pi A^{*}}$  is not a differential, basically because ${\displaystyle A+A^{*}}$  is not a Lie algebroid. Instead using the larger N-graded manifold ${\displaystyle T^{*}[2]A[1]=T^{*}[2]A^{*}[1]}$  to which we can lift ${\displaystyle d_{A}}$  and ${\displaystyle d_{*}}$  as odd Hamiltonian vector fields, then their sum squares to ${\displaystyle 0}$  iff ${\displaystyle (A,A^{*})}$  is a Lie bialgebroid.

• C. Albert and P. Dazord: Théorie des groupoïdes symplectiques: Chapitre II, Groupoïdes symplectiques. (in Publications du Département de Mathématiques de l’Université Claude Bernard, Lyon I, nouvelle série, pp. 27–99, 1990)
• Y. Kosmann-Schwarzbach: The Lie bialgebroid of a Poisson–Nijenhuis manifold. (Lett. Math. Phys., 38:421–428, 1996)
• K. Mackenzie, P. Xu: Integration of Lie bialgebroids (1997),
• K. Mackenzie, P. Xu: Lie bialgebroids and Poisson groupoids (Duke J. Math, 1994)
• A. Weinstein: Symplectic groupoids and Poisson manifolds (AMS Bull, 1987),