Čech cohomology

A Penrose triangle depicts a nontrivial element of the first cohomology of an annulus with values in the group of distances from the observer[1]

In mathematics, specifically algebraic topology, Čech cohomology is a cohomology theory based on the intersection properties of open covers of a topological space. It is named for the mathematician Eduard Čech.

Motivation

Let X be a topological space, and let \mathcal{U} be an open cover of X. Let N(\mathcal{U}) denote the nerve of the covering. The idea of Čech cohomology is that, for an open cover \mathcal{U} consisting of sufficiently small open sets, the resulting simplicial complex N(\mathcal{U}) should be a good combinatorial model for the space X. For such a cover, the Čech cohomology of X is defined to be the simplicial cohomology of the nerve. This idea can be formalized by the notion of a good cover. However, a more general approach is to take the direct limit of the cohomology groups of the nerve over the system of all possible open covers of X, ordered by refinement. This is the approach adopted below.

Construction

Let X be a topological space, and let \mathcal{F} be a presheaf of abelian groups on X. Let \mathcal{U} be an open cover of X.

Simplex

A q-simplex σ of \mathcal{U} is an ordered collection of q+1 sets chosen from \mathcal{U}, such that the intersection of all these sets is non-empty. This intersection is called the support of σ and is denoted |σ|.

Now let \sigma = (U_i)_{i \in \{ 0 , \ldots , q \}} be such a q-simplex. The j-th partial boundary of σ is defined to be the (q-1)-simplex obtained by removing the j-th set from σ, that is:

\partial_j \sigma := (U_i)_{i \in \{ 0 , \ldots , q \} \setminus \{j\}}.

The boundary of σ is defined as the alternating sum of the partial boundaries:

\partial \sigma := \sum_{j=0}^q (-1)^{j+1} \partial_j \sigma.

Cochain

A q-cochain of \mathcal{U} with coefficients in \mathcal{F} is a map which associates with each q-simplex σ an element of \mathcal{F}(|\sigma|) and we denote the set of all q-cochains of \mathcal{U} with coefficients in \mathcal{F} by C^q(\mathcal U, \mathcal F). C^q(\mathcal U, \mathcal F) is an abelian group by pointwise addition.

Differential

The cochain groups can be made into a cochain complex (C^{\textbf{.}}(\mathcal U, \mathcal F), \delta) by defining the coboundary operator \delta_q : C^q(\mathcal U, \mathcal F) \to  C^{q+1}(\mathcal{U},
 \mathcal{F}) by

 \quad (\delta_q \omega)(\sigma) := \sum_{j=0}^{q+1} (-1)^j \mathrm{res}^{|\partial_j \sigma|}_{|\sigma|} \omega (\partial_j \sigma),

where \mathrm{res}^{|\partial_j \sigma|}_{|\sigma|} is the restriction morphism from \mathcal F(|\partial_j \sigma|) to \mathcal F(|\sigma|).

A calculation shows that \delta_{q+1} \circ \delta_q = 0 .

The coboundary operator is also sometimes called the codifferential.

Cocycle

A q-cochain is called a q-cocycle if it is in the kernel of δ, hence Z^q(\mathcal{U}, \mathcal{F}) := \ker \left( \delta_q : C^q(\mathcal U, \mathcal F) \to  C^{q+1}(\mathcal{U}, \mathcal{F}) \right) is the set of all q-cocycles.

Thus a (q-1)-cochain f is a cocycle if for all q-simplices σ the cocycle condition \sum_{j=0}^{q-1} (-1)^j \mathrm{res}^{|\partial_j \sigma|}_{|\sigma|} f (\partial_j \sigma) = 0 holds. In particular, a 1-cochain f is a 1-cocycle if

\forall_{\{A, B, C\} \subset \mathcal{U}}\ U:=A \cap B \cap C,\ f(B \cap C)|_U - f(A \cap C)|_U + f(A \cap B)|_U = 0.

Coboundary

A q-cochain is called a q-coboundary if it is in the image of δ and B^q(\mathcal{U}, \mathcal{F}) := \mathrm{im} \left( \delta_{q-1} : C^{q-1}(\mathcal{U}, \mathcal{F}) \to  C^{q}(\mathcal{U}, \mathcal{F}) \right) is the set of all q-coboundaries.

For example, a 1-cochain f is a 1-coboundary if there exists a 0-cochain h such that \forall_{\{A, B\} \subset \mathcal{U}}, U:=A \cap B, f(U) = (\delta h)(U) = h(A)|_U - h(B)|_U.

Cohomology

The Čech cohomology of \mathcal{U} with values in \mathcal{F} is defined to be the cohomology of the cochain complex (C^{\textbf{.}}(\mathcal{U}, \mathcal{F}), \delta). Thus the qth Čech cohomology is given by

\check{H}^q(\mathcal{U}, \mathcal{F}) := H^q((C^{\textbf{.}}(\mathcal U, \mathcal F), \delta)) = Z^q(\mathcal{U}, \mathcal{F}) / B^q(\mathcal{U}, \mathcal{F}).

The Čech cohomology of X is defined by considering refinements of open covers. If \mathcal{V} is a refinement of \mathcal{U} then there is a map in cohomology \check{H}^*(\mathcal U,\mathcal F) \to \check{H}^*(\mathcal V,\mathcal F). The open covers of X form a directed set under refinement, so the above map leads to a direct system of abelian groups. The Čech cohomology of X with values in \mathcal{F} is defined as the direct limit \check{H}(X,\mathcal F) := \varinjlim_{\mathcal U} \check{H}(\mathcal U,\mathcal F) of this system.

The Čech cohomology of X with coefficients in a fixed abelian group A, denoted \check{H}(X;A), is defined as \check{H}(X,\mathcal{F}_A) where \mathcal{F}_A is the constant sheaf on X determined by A.

A variant of Čech cohomology, called numerable Čech cohomology, is defined as above, except that all open covers considered are required to be numerable: that is, there is a partition of unityi} such that each support \{x|\rho_i(x)>0\} is contained in some element of the cover. If X is paracompact and Hausdorff, then numerable Čech cohomology agrees with the usual Čech cohomology.

Relation to other cohomology theories

If X is homotopy equivalent to a CW complex, then the Čech cohomology \check{H}^{*}(X;A) is naturally isomorphic to the singular cohomology  H^*(X;A) \,. If X is a differentiable manifold, then \check{H}^*(X;\mathbb{R}) is also naturally isomorphic to the de Rham cohomology; the article on de Rham cohomology provides a brief review of this isomorphism. For less well-behaved spaces, Čech cohomology differs from singular cohomology. For example if X is the closed topologist's sine curve, then \check{H}^1(X;\mathbb{Z})=\mathbb{Z}, whereas H^1(X;\mathbb{Z})=0.

If X is a differentiable manifold and the cover \mathcal{U} of X is a "good cover" (i.e. all the sets Uα are contractible to a point, and all finite intersections of sets in \mathcal{U} are either empty or contractible to a point), then \check{H}^{*}(\mathcal U;\mathbb{R}) is isomorphic to the de Rham cohomology.

If X is compact Hausdorff, then Čech cohomology (with coefficients in a discrete group) is isomorphic to Alexander-Spanier cohomology.

In algebraic geometry

Čech cohomology can be defined more generally for objects in a site C endowed with a topology. This applies, for example, to the Zariski site or the etale site of a scheme X. The Čech cohomology with values in some sheaf F is defined as

\check H^n (X, F) := \varinjlim_{\mathcal U} \check H^n(\mathcal U, F).

where the colimit runs over all coverings (with respect to the chosen topology) of X. Here \check H^n(\mathcal U, F) is defined as above, except that the r-fold intersections of open subsets inside the ambient topological space are replaced by the r-fold fiber product

\mathcal U^{\times^r_X} := \mathcal U \times_X \dots \times_X  \mathcal U.

As in the classical situation of topological spaces, there is always a map

H^n(X, F) \rightarrow \check H^n(X, F)

from sheaf cohomology to Čech cohomology. It is always an isomorphism in degrees n = 0 and 1, but may fail to be so in general. For the Zariski topology on a Noetherian separated scheme, Čech and sheaf cohomology agree for any quasi-coherent sheaf. For the etale topology, the two cohomologies agree for any sheaf, provided that any finite set of points in the base scheme X are contained in some open affine subscheme. This is satisfied, for example, if X is quasi-projective over an affine scheme.[2]

The possible difference between Cech cohomology and sheaf cohomology is a motivation for the use of hypercoverings: these are more general objects than the Cech nerve

N_X \mathcal U : \dots \rightarrow \mathcal U \times_X \mathcal U \times_X \mathcal U \rightarrow \mathcal U \times_X \mathcal U \rightarrow \mathcal U.

A hypercovering K of X is a simplicial object in C, i.e., a collection of objects Kn together with boundary and degeneracy maps. Applying a sheaf F to K yields a simplicial abelian group F(K) whose n-th cohomology group is denoted Hn(F(K)). (This group is the same as \check H^n(\mathcal U, F) in case K equals N_X \mathcal U .) Then, it can be shown that there is a canonical isomorphism

H^n (X, F) = \varinjlim_{K_*} H^n(F(K_*)),

where the colimit now runs over all hypercoverings.[3]

References

  1. Penrose, Roger (1992), "On the Cohomology of Impossible Figures", Leonardo 25 (3/4): 245–247, doi:10.2307/1575844. Reprinted from Penrose, Roger (1991), "On the Cohomology of Impossible Figures / La Cohomologie des Figures Impossibles", Structural Topology 17: 11–16, retrieved January 16, 2014
  2. Milne, James S. (1980), Étale cohomology, Princeton Mathematical Series 33, Princeton University Press, ISBN 978-0-691-08238-7, MR 559531, section III.2
  3. Artin, Michael; Mazur, Barry (1969), Etale homotopy, Lecture Notes in Mathematics, No. 100, Berlin, New York: Springer-Verlag, Theorem 8.16
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