nLab Dolbeault cohomology

Contents

under construction

Context

Cohomology

Complex geometry

Idea
Properties

Dolbeault theorem
Hodge isomorphism
Serre duality
Hodge decomposition
Hodge symmetry
Dolbeault resolution
Double complex and Frölicher spectral sequence

Related concepts
References

Idea

Dolbeault cohomology of a complex manifold $X$ is the chain cohomology of the Dolbeault complex of $X$ (see there for more).

Properties

Dolbeault theorem

By the Dolbeault theorem (see there) Dolbeault cohomology is equivalently the abelian sheaf cohomology $H^q(X;\Omega_X^p)$ , of the abelian sheaf $\Omega_X^p$ which is the Dolbeault complex of holomorphic p-forms.

Hodge isomorphism

For $X$ a Hermitian manifold write $\mathcal{H}^{p,q}(X)$ for the space of $(p,q)$ -harmonic differential forms and write $H^{p,q}$ for its Dolbeault cohomology in the bidegree.

Proposition

There is a canonical homomorphism

\mathcal{H}^{p,q}(X) \longrightarrow H^{p,q}(X) \,.

If $X$ is compact, then this is an isomorphism, the Hodge isomorphism

Also

\mathcal{H}^k(X,\mathbb{C}) \longrightarrow H^k_{dR}(X,\mathbb{C})

is an isomorphism

(e.g. Maddock, prop. 4.2.7)

Serre duality

Serre duality: On a Hermitian manifold $X$ of complex dimension $dim_{\mathbb{C}}(X) = n$ the Hodge star operator induces isomorphisms

\mathcal{H}^{p,q}(X)\simeq \mathcal{H}^{n-p, n-q}(X) \,.

(e.g. Maddock, prop. 4.2.8)

Hodge decomposition

If $X$ is a compact Kähler manifold then

\mathcal{H}^k(X) \simeq \underset{p+q = k}{\oplus} \mathcal{H}^{p,q}(X)

(e.g. Maddock, prop. 4.2.9)

This is called the Hodge decomposition.

Hodge symmetry

Over complex manifolds $X$ , Hodge symmetry is the property that the Dolbeault cohomology groups $H^{p,q}(X)$ are taken into each other under complex conjugation followed by switching the bidegree:

H^{p,q}(X) \simeq \overline{H^{q,p}(X)} \,.

In particular this means that the dimension of the cohomology groups in degree $(p,q)$ coincides with that in bidegree $(q,p)$ .

Dolbeault resolution

Given any holomorphic vector bundle $E$ , one can form the Dolbeault resolution $E \otimes \Omega^{0,q}$ , where $\Omega^{0,q}$ is the sheaf of $C^\infty$ $(0,q)$ -forms. This is an acyclic resolution of $E$ and hence computes its sheaf cohomology.

(…)

Double complex and Frölicher spectral sequence

The Dolbeault complexes naturall fit into a double complex

\array{ \Omega^{p,0} &\stackrel{\bar \partial}{\to}& \Omega^{p-1,1} &\stackrel{\bar \partial}{\to}& \cdots \\ \downarrow^{\mathrlap{\partial }} && \downarrow^{\mathrlap{\partial }} \\ \Omega^{p+1,0} &\stackrel{\bar \partial}{\to}& \Omega^{p,1} &\stackrel{\bar \partial}{\to}& \cdots \\ \downarrow^{\mathrlap{\partial }} && \downarrow^{\mathrlap{\partial }} \\ \vdots && \vdots } \,.

The corresponding spectral sequence of a double complex is called the Frölicher spectral sequence. On a Kähler manifold it exhibits the Hodge filtration.

Related concepts

References

Zachary Maddock, Dolbeault cohomology (pdf)

Last revised on June 18, 2020 at 07:30:24. See the history of this page for a list of all contributions to it.

nLab Dolbeault cohomology

Context

Cohomology

Special and general types

Special notions

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Extra structure

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Theorems