nLab holomorphic de Rham complex

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Contents

Context

Complex geometry

Differential cohomology

Idea
Properties

Relation to complex cohomology
Filtering and Relation to Hodge filtation

Related concepts
References

Idea

On a complex analytic space $\Sigma$ , the holomorphic de Rham complex is the restriction of the de Rham complex to holomorphic differential forms $\Omega^p$

\Omega^\bullet_\Sigma \coloneqq \left( \mathcal{O}_\Sigma \stackrel{\partial}{\longrightarrow} \Omega^1_\Sigma \stackrel{\partial}{\longrightarrow} \Omega^2_\Sigma \longrightarrow \cdots \right) \,.

Notice here that since $\Omega^k$ denotes the holomorphic forms, this is the kernel of the Dolbeault operator $\bar \partial$ and hence the de Rham differential $\mathbf{d} = \partial + \bar \partial$ restricts to the holomorphic component $\partial$ as above.

Often considered is a version of this with singularities (“logarithmic de Rham complex”) where one consideres instead meromorphic differential forms which are holomorphic in the bulk with logarithmic singularities towards compactification boundaries of $X$ .

Properties

Relation to complex cohomology

For $\Sigma$ a complex manifold then the ordinary cohomology of $\Sigma$ with coefficients in the complex numbers is naturally isomorphic to the hyper-abelian sheaf cohomology with coefficients in the holomorphic de Rham complex:

H^k(\Sigma,\mathbb{C}) \simeq H^k(\Sigma, \Omega_\Sigma^\bullet)

(e.g. Voisin 02, theorem 8.1).

Filtering and Relation to Hodge filtation

The holomorphic de Rham complex is naturally filtered by degree with the $p$ th filtering stage being

F^p \Omega^\bullet_X \coloneqq (0 \to \cdots \to \Omega^p_X \stackrel{\partial}{\longrightarrow} \Omega^{p+1} \stackrel{\partial}{\longrightarrow} \cdots) \,.

Notice that here $\Omega^p$ is still regarded as sitting in degree $-p$ , one just replaces by 0 in the holomorphic de Rham complex the groups of differential forms of degree less than $p$ .

With this, the Hodge filtration on $H^\bullet(X,\mathbb{C})$ is defined to be the filtration with $p$ th stage the image of the hyper-abelian sheaf cohomology with coefficients in the $p$ th filtering stage of the holomorphic de Rham complex inside that with coefficients the full de Rham complex:

F^p H^k(X,\mathbb{C}) \coloneqq im \left( H^k(X, F^p \Omega^\bullet_X) \to H^k(X, \Omega^\bullet_X) \right)

(e.g. Voisin 02, def. 8.2).

If $X$ happens to be a Kähler manifold then the Frölicher spectral sequence shows that this coincides with the more traditional definition via harmonic differential forms (e.g. Voisin 02, remark 8.29).

Related concepts

References

Claire Voisin, section 8.2 of Hodge theory and Complex algebraic geometry I,II, Cambridge Stud. in Adv. Math. 76, 77, 2002/3
Alexander Beilinson, Higher regulators and values of L-functions, J. Soviet Math. 30 (1985), 2036-2070 (reviewed in Esnault-Viehweg 88) (doi)
Hélène Esnault, Eckart Viehweg, section 2.5 of: Deligne-Beilinson cohomology, in: Michael Rapoport, Norbert Schappacher, Peter Schneider (eds.), Beilinson's Conjectures on Special Values of L-Functions, Perspectives in Mathematics 4, Academic Press, Inc. (1988) [ISBN:978-0-12-581120-0, pdf]

On holomorphic de Rham cohomology of Stein manifolds (where it coincides with ordinary de Rham cohomology, see there):

Jean-Pierre Serre: Quelques problemes globaux relatifs aux varietes de Stein, Colloque sur les fonctions de plusieurs variables (1953) [doi:10.1007/978-3-642-39816-2_23]
Jean-Pierre Serre: §2.1 in: Cohomologie et fonctions de variables complexes, Séminaire Bourbaki 2 71 (1954) [numdam:SB_1951-1954__2__213_0]

Last revised on October 22, 2023 at 10:09:10. See the history of this page for a list of all contributions to it.

nLab holomorphic de Rham complex

Context

Complex geometry

Variants

Structures

Examples

Differential cohomology

Ingredients

Connections on bundles

Higher abelian differential cohomology

Higher nonabelian differential cohomology

Fiber integration

Application to gauge theory