Čech cohomology extends cohomology theory to general spaces using open covers. It bridges local and global properties, making it a powerful tool in topology and geometry. This approach uses presheaves and sheaves to construct cochain complexes from open covers.
Čech cohomology's computational tractability and connection to sheaf theory make it valuable in various mathematical fields. It relates to other cohomology theories and has applications in complex analysis, algebraic geometry, and mathematical physics, providing insights into the global structure of spaces.
Čech cohomology extends the idea of cohomology to more general spaces by using open covers
Presheaves are contravariant functors from the category of open sets of a topological space to the category of abelian groups
Sheaves are presheaves satisfying the gluing axiom and the locality axiom
Gluing axiom ensures that local data can be uniquely glued together to obtain global data
Locality axiom guarantees that a section of a sheaf over an open set is determined by its values on any open cover of that set
Čech complex is a cochain complex constructed from an open cover of a topological space and a presheaf on that space
Refinement of an open cover is another open cover such that each open set in the new cover is contained in some open set of the original cover
Directed system is a collection of objects indexed by a directed set, along with morphisms between the objects that are compatible with the ordering of the indexing set
Historical Context and Development
Čech cohomology was introduced by Eduard Čech in the 1930s as a way to extend cohomology theory to more general spaces
Developed as a response to the limitations of singular cohomology, which works well for simplicial complexes but not for more general topological spaces
Čech's original definition used infinite covers and inverse limits, which made it difficult to compute
Later reformulated using finite open covers and direct limits, making it more accessible and computationally tractable
Became an important tool in the development of sheaf theory and the study of global properties of topological spaces
Čech cohomology played a crucial role in the proof of the de Rham theorem, which relates de Rham cohomology to singular cohomology
Čech Complexes and Coverings
Given a topological space X and an open cover U={Ui}i∈I of X, the Čech complex is a cochain complex Cˇ∗(U,F) associated to a presheaf F on X
The n-th cochain group Cˇn(U,F) consists of alternating functions α that assign to each (n+1)-tuple (i0,…,in) an element α(i0,…,in)∈F(Ui0∩…∩Uin)
Alternating property means that the value changes sign whenever two indices are swapped
The coboundary map δn:Cˇn(U,F)→Cˇn+1(U,F) is defined by the usual formula for the coboundary in a cochain complex
Refining the open cover leads to a morphism between the corresponding Čech complexes, which induces a morphism on cohomology
The Čech cohomology Hˇ∗(U,F) is defined as the cohomology of the Čech complex Cˇ∗(U,F)
Čech cohomology of X with coefficients in F is obtained by taking the direct limit of Hˇ∗(U,F) over all open covers U of X
Computing Čech Cohomology
To compute Čech cohomology, start by choosing an open cover U={Ui}i∈I of the topological space X
Construct the Čech complex Cˇ∗(U,F) associated to the open cover and a presheaf F on X
The cochain groups are given by Cˇn(U,F)=∏i0<…<inF(Ui0∩…∩Uin)
The coboundary maps are defined using the restriction maps of the presheaf
Compute the cohomology of the Čech complex by finding the kernel and image of the coboundary maps
The n-th Čech cohomology group is given by Hˇn(U,F)=ker(δn)/im(δn−1)
Refine the open cover and repeat the process, obtaining a directed system of cohomology groups
Take the direct limit of this directed system to obtain the Čech cohomology of X with coefficients in F
The direct limit captures the information that is preserved under refinement of open covers
In practice, it is often sufficient to compute the Čech cohomology with respect to a specific open cover, especially if the cover is fine enough to capture the relevant topological features of the space
Relation to Sheaf Cohomology
Čech cohomology is closely related to sheaf cohomology, which is another way of defining cohomology for sheaves on topological spaces
For a sheaf F on a topological space X, the sheaf cohomology groups H∗(X,F) are defined using injective resolutions of F
Čech cohomology provides a more concrete way to compute sheaf cohomology, using open covers and Čech complexes
The Leray theorem states that for a paracompact Hausdorff space X and a sheaf F on X, the Čech cohomology Hˇ∗(X,F) is isomorphic to the sheaf cohomology H∗(X,F)
This isomorphism is natural with respect to morphisms of sheaves
In many cases, Čech cohomology is easier to compute than sheaf cohomology, as it avoids the use of injective resolutions
The relation between Čech and sheaf cohomology has been generalized to other settings, such as étale cohomology in algebraic geometry
Applications in Topology and Geometry
Čech cohomology has numerous applications in topology and geometry, as it provides a way to study global properties of spaces using local data
In algebraic topology, Čech cohomology is used to define cohomology theories for general topological spaces, extending the reach of singular cohomology
Čech cohomology is particularly useful for studying spaces that are not well-behaved, such as non-paracompact spaces or spaces with bad local properties
In complex analysis and algebraic geometry, Čech cohomology is used to study the cohomology of sheaves on complex manifolds and algebraic varieties
The Dolbeault theorem relates Čech cohomology of holomorphic sheaves to Dolbeault cohomology, which is defined using differential forms
Čech cohomology is also used in the construction of the Picard group and the Brauer group of a scheme
In differential geometry, Čech cohomology appears in the study of characteristic classes and obstruction theory
The Chern-Weil homomorphism relates Čech cohomology to the de Rham cohomology of a smooth manifold, allowing the construction of characteristic classes from connection forms
Čech cohomology has also found applications in mathematical physics, particularly in the study of gauge theories and string theory
In these contexts, Čech cohomology is used to describe the global structure of gauge fields and to classify topological defects
Examples and Problem-Solving Techniques
To compute the Čech cohomology of the circle S1 with constant coefficients Z, use the open cover U={U,V} where U and V are slightly larger than semicircles
The Čech complex has non-zero terms Cˇ0(U,Z)=Z⊕Z and Cˇ1(U,Z)=Z, with the coboundary map given by the difference of the restriction maps
The resulting cohomology groups are Hˇ0(S1,Z)=Z and Hˇ1(S1,Z)=Z, agreeing with the singular cohomology of the circle
For the Möbius band M, use the open cover U={U,V} where U and V are slightly larger than the rectangular strips obtained by cutting the band along its centerline
The Čech complex with constant coefficients Z has terms Cˇ0(U,Z)=Z⊕Z and Cˇ1(U,Z)=Z⊕Z, with the coboundary map given by the difference of the restriction maps, taking into account the twist in the Möbius band
The resulting cohomology groups are Hˇ0(M,Z)=Z and Hˇ1(M,Z)=0, capturing the fact that the Möbius band is non-orientable
When solving problems involving Čech cohomology, it is often helpful to choose an open cover that is well-suited to the space and the coefficients
For spaces with a simple local structure, such as manifolds or CW complexes, it is often sufficient to use a cover by open sets that are contractible or have a simple cohomology
For more complicated spaces, such as spaces with bad local properties or spaces with a non-trivial fundamental group, it may be necessary to use more sophisticated covers or to refine the cover adaptively
It is also important to keep track of the relationships between different open covers and the induced maps on cohomology
Refining an open cover leads to a map between the corresponding Čech complexes, which induces a map on cohomology
Understanding these induced maps is crucial for computing the direct limit that defines the Čech cohomology of the space
Advanced Topics and Extensions
Čech cohomology can be generalized to the setting of simplicial sheaves, where the open sets in the cover are replaced by simplicial objects
This generalization is useful in algebraic geometry, where it is used to define étale cohomology and other cohomology theories for schemes
The Čech-to-derived functor spectral sequence relates Čech cohomology to derived functor cohomology, providing a way to compute sheaf cohomology using Čech cochains
This spectral sequence is a powerful tool for computing cohomology in various settings, including algebraic geometry and complex analysis
Deligne cohomology is a generalization of Čech cohomology that incorporates differential forms and allows for the construction of secondary characteristic classes
Deligne cohomology has applications in the study of Chern-Simons theory and other gauge-theoretic problems
Čech cohomology can also be extended to the setting of non-abelian cohomology, where the coefficients are taken in a non-abelian category, such as the category of groups or the category of sheaves of groups
Non-abelian Čech cohomology has applications in the study of principal bundles and gerbes, which are geometric objects that generalize line bundles and play a role in mathematical physics
In the setting of algebraic topology, Čech cohomology is related to other cohomology theories, such as Alexander-Spanier cohomology and Steenrod-Sitnikov cohomology
These cohomology theories are defined using different types of covers and limits, and they provide alternative approaches to studying the global properties of topological spaces
The relationship between Čech cohomology and other cohomology theories, such as de Rham cohomology and singular cohomology, has been the subject of extensive research
Understanding these relationships is important for computing cohomology in various settings and for understanding the connections between different branches of mathematics, such as topology, geometry, and analysis