Dedicated to the memory of Paulette LibermannWe study holomorphic Poisson manifolds and holomorphic Lie algebroids from the view- In the case when (X, π ) is a holomorphic Poisson manifold and A = (T * X) π , such an elliptic Lie algebroid coincides with the Dirac structure corresponding to the associated generalized complex structure of the holomorphic Poisson manifold.
For any regular Courant algebroid, we construct a characteristic class à la Chern-Weil. This intrinsic invariant of the Courant algebroid is a degree-3 class in its naive cohomology. When the Courant algebroid is exact, it reduces to the Ševera class (in H 3 DR (M )). On the other hand, when the Courant algebroid is a quadratic Lie algebra g, it coincides with the class of the Cartan 3-form (in H 3 (g)). We also give a complete classification of regular Courant algebroids and discuss its relation to the characteristic class.
We introduce the notion of Poisson quasi-Nijenhuis manifolds generalizing the
Poisson-Nijenhuis manifolds of Magri-Morosi. We also investigate the
integration problem of Poisson quasi-Nijenhuis manifolds. In particular, we
prove that, under some topological assumption, Poisson (quasi)-Nijenhuis
manifolds are in one-one correspondence with symplectic (quasi)-Nijenhuis
groupoids. As an application, we study generalized complex structures in terms
of Poisson quasi-Nijenhuis manifolds. We prove that a generalized complex
manifold corresponds to a special class of Poisson quasi-Nijenhuis structures.
As a consequence, we show that a generalized complex structure integrates to a
symplectic quasi-Nijenhuis groupoid recovering a theorem of Crainic.Comment: 18 pages, title changed, introduction rewritten, order of sections
changed, references added, minor changes to body text, to appear in Comm.
Math. Phy
A celebrated theorem of Kapranov states that the Atiyah class of the tangent
bundle of a complex manifold $X$ makes $T_X[-1]$ into a Lie algebra object in
$D^+(X)$, the bounded below derived category of coherent sheaves on $X$.
Furthermore Kapranov proved that, for a K\"ahler manifold $X$, the Dolbeault
resolution $\Omega^{\bullet-1}(T_X^{1,0})$ of $T_X[-1]$ is an $L_\infty$
algebra. In this paper, we prove that Kapranov's theorem holds in much wider
generality for vector bundles over Lie pairs. Given a Lie pair $(L,A)$, i.e. a
Lie algebroid $L$ together with a Lie subalgebroid $A$, we define the Atiyah
class $\alpha_E$ of an $A$-module $E$ (relative to $L$) as the obstruction to
the existence of an $A$-compatible $L$-connection on $E$. We prove that the
Atiyah classes $\alpha_{L/A}$ and $\alpha_E$ respectively make $L/A[-1]$ and
$E[-1]$ into a Lie algebra and a Lie algebra module in the bounded below
derived category $D^+(\mathcal{A})$, where $\mathcal{A}$ is the abelian
category of left $\mathcal{U}(A)$-modules and $\mathcal{U}(A)$ is the universal
enveloping algebra of $A$. Moreover, we produce a homotopy Leibniz algebra and
a homotopy Leibniz module stemming from the Atiyah classes of $L/A$ and $E$,
and inducing the aforesaid Lie structures in $D^+(\mathcal{A})$.Comment: 36 page
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