Borel–Moore homology

In topology, Borel−Moore homology or homology with closed support is a homology theory for locally compact spaces, introduced by Armand Borel and John Moore in 1960.^[1]

For reasonable compact spaces, Borel−Moore homology coincides with the usual singular homology. For non-compact spaces, each theory has its own advantages. In particular, a closed oriented submanifold defines a class in Borel–Moore homology, but not in ordinary homology unless the submanifold is compact.

Note: Borel equivariant cohomology is an invariant of spaces with an action of a group G; it is defined as $H_{G}^{*}(X)=H^{*}((EG\times X)/G).$ That is not related to the subject of this article.

Definition[edit]

There are several ways to define Borel−Moore homology. They all coincide for reasonable spaces such as manifolds and locally finite CW complexes.

Definition via sheaf cohomology[edit]

For any locally compact space X, Borel–Moore homology with integral coefficients is defined as the cohomology of the dual of the chain complex which computes sheaf cohomology with compact support.^[2] As a result, there is a short exact sequence analogous to the universal coefficient theorem:

0\to {\text{Ext}}_{\mathbb {Z} }^{1}(H_{c}^{i+1}(X,\mathbb {Z} ),\mathbb {Z} )\to H_{i}^{BM}(X,\mathbb {Z} )\to {\text{Hom}}(H_{c}^{i}(X,\mathbb {Z} ),\mathbb {Z} )\to 0.

In what follows, the coefficients $\mathbb {Z}$ are not written.

Definition via locally finite chains[edit]

The singular homology of a topological space X is defined as the homology of the chain complex of singular chains, that is, finite linear combinations of continuous maps from the simplex to X. The Borel−Moore homology of a reasonable locally compact space X, on the other hand, is isomorphic to the homology of the chain complex of locally finite singular chains. Here "reasonable" means X is locally contractible, σ-compact, and of finite dimension.^[3]

In more detail, let $C_{i}^{BM}(X)$ be the abelian group of formal (infinite) sums

u=\sum _{\sigma }a_{\sigma }\sigma ,

where σ runs over the set of all continuous maps from the standard i-simplex Δⁱ to X and each a_σ is an integer, such that for each compact subset S of X, only finitely many maps σ whose image meets S have nonzero coefficient in u. Then the usual definition of the boundary ∂ of a singular chain makes these abelian groups into a chain complex:

\cdots \to C_{2}^{BM}(X)\to C_{1}^{BM}(X)\to C_{0}^{BM}(X)\to 0.

The Borel−Moore homology groups $H_{i}^{BM}(X)$ are the homology groups of this chain complex. That is,

H_{i}^{BM}(X)=\ker \left(\partial :C_{i}^{BM}(X)\to C_{i-1}^{BM}(X)\right)/{\text{im}}\left(\partial :C_{i+1}^{BM}(X)\to C_{i}^{BM}(X)\right).

If X is compact, then every locally finite chain is in fact finite. So, given that X is "reasonable" in the sense above, Borel−Moore homology $H_{i}^{BM}(X)$ coincides with the usual singular homology $H_{i}(X)$ for X compact.

Definition via compactifications[edit]

Suppose that X is homeomorphic to the complement of a closed subcomplex S in a finite CW complex Y. Then Borel–Moore homology $H_{i}^{BM}(X)$ is isomorphic to the relative homology H_i(Y, S). Under the same assumption on X, the one-point compactification of X is homeomorphic to a finite CW complex. As a result, Borel–Moore homology can be viewed as the relative homology of the one-point compactification with respect to the added point.

Definition via Poincaré duality[edit]

Let X be any locally compact space with a closed embedding into an oriented manifold M of dimension m. Then

H_{i}^{BM}(X)=H^{m-i}(M,M\setminus X),

where in the right hand side, relative cohomology is meant.^[4]

Definition via the dualizing complex[edit]

For any locally compact space X of finite dimension, let $D X$ be the dualizing complex of $X$ . Then

H_{i}^{BM}(X)=\mathbb {H} ^{-i}(X,D_{X}),

where in the right hand side, hypercohomology is meant.^[5]

Properties[edit]

Borel−Moore homology is a covariant functor with respect to proper maps. That is, a proper map f: X → Y induces a pushforward homomorphism $H_{i}^{BM}(X)\to H_{i}^{BM}(Y)$ for all integers i. In contrast to ordinary homology, there is no pushforward on Borel−Moore homology for an arbitrary continuous map f. As a counterexample, one can consider the non-proper inclusion $\mathbb {R} ^{2}\setminus \{0\}\to \mathbb {R} ^{2}.$

Borel−Moore homology is a contravariant functor with respect to inclusions of open subsets. That is, for U open in X, there is a natural pullback or restriction homomorphism $H_{i}^{BM}(X)\to H_{i}^{BM}(U).$

For any locally compact space X and any closed subset F, with $U=X\setminus F$ the complement, there is a long exact localization sequence:^[6]

\cdots \to H_{i}^{BM}(F)\to H_{i}^{BM}(X)\to H_{i}^{BM}(U)\to H_{i-1}^{BM}(F)\to \cdots

Borel−Moore homology is homotopy invariant in the sense that for any space X, there is an isomorphism $H_{i}^{BM}(X)\to H_{i+1}^{BM}(X\times \mathbb {R} ).$ The shift in dimension means that Borel−Moore homology is not homotopy invariant in the naive sense. For example, the Borel−Moore homology of Euclidean space $\mathbb {R} ^{n}$ is isomorphic to $\mathbb {Z}$ in degree n and is otherwise zero.

Poincaré duality extends to non-compact manifolds using Borel–Moore homology. Namely, for an oriented n-manifold X, Poincaré duality is an isomorphism from singular cohomology to Borel−Moore homology,

H^{i}(X){\stackrel {\cong }{\to }}H_{n-i}^{BM}(X)

for all integers i. A different version of Poincaré duality for non-compact manifolds is the isomorphism from cohomology with compact support to usual homology:

H_{c}^{i}(X){\stackrel {\cong }{\to }}H_{n-i}(X).

A key advantage of Borel−Moore homology is that every oriented manifold M of dimension n (in particular, every smooth complex algebraic variety), not necessarily compact, has a fundamental class $[M]\in H_{n}^{BM}(M).$ If the manifold M has a triangulation, then its fundamental class is represented by the sum of all the top dimensional simplices. In fact, in Borel−Moore homology, one can define a fundamental class for arbitrary (possibly singular) complex varieties. In this case the set of smooth points $M^{\text{reg}}\subset M$ has complement of (real) codimension at least 2, and by the long exact sequence above the top dimensional homologies of $M$ and $M^{\text{reg}}$ are canonically isomorphic. The fundamental class of $M$ is then defined to be the fundamental class of $M^{\text{reg}}$ .^[7]

Examples[edit]

Compact Spaces[edit]

Given a compact topological space $X$ its Borel-Moore homology agrees with its standard homology; that is,

H_{*}^{BM}(X)\cong H_{*}(X)

Real line[edit]

The first non-trivial calculation of Borel-Moore homology is of the real line. First observe that any $0$ -chain is cohomologous to $0$ . Since this reduces to the case of a point $p$ , notice that we can take the Borel-Moore chain

\sigma =\sum _{i=0}^{\infty }1\cdot [p+i,p+i+1]

since the boundary of this chain is $\partial \sigma =p$ and the non-existent point at infinity, the point is cohomologous to zero. Now, we can take the Borel-Moore chain

\sigma =\sum _{-\infty <k<\infty }[k,k+1]

which has no boundary, hence is a homology class. This shows that

H_{k}^{BM}(\mathbb {R} )={\begin{cases}\mathbb {Z} &k=1\\0&{\text{otherwise}}\end{cases}}

Real n-space[edit]

The previous computation can be generalized to the case $\mathbb {R} ^{n}.$ We get

H_{k}^{BM}(\mathbb {R} ^{n})={\begin{cases}\mathbb {Z} &k=n\\0&{\text{otherwise}}\end{cases}}

Infinite Cylinder[edit]

Using the Kunneth decomposition, we can see that the infinite cylinder $S^{1}\times \mathbb {R}$ has homology

H_{k}^{BM}(S^{1}\times \mathbb {R} )={\begin{cases}\mathbb {Z} &k=1\\\mathbb {Z} &k=2\\0&{\text{otherwise}}\end{cases}}

Real n-space minus a point[edit]

Using the long exact sequence in Borel-Moore homology, we get (for $n>1$ ) the non-zero exact sequences

0\to H_{n}^{BM}(\{0\})\to H_{n}^{BM}(\mathbb {R} ^{n})\to H_{n}^{BM}(\mathbb {R} ^{n}-\{0\})\to 0

and

0\to H_{1}^{BM}(\mathbb {R} ^{n}-\{0\})\to H_{0}^{BM}(\{0\})\to H_{0}^{BM}(\mathbb {R} ^{n})\to H_{0}^{BM}(\mathbb {R} ^{n}-\{0\})\to 0

From the first sequence we get that

H_{n}^{BM}(\mathbb {R} ^{n})\cong H_{n}^{BM}(\mathbb {R} ^{n}-\{0\})

and from the second we get that

H_{1}^{BM}(\mathbb {R} ^{n}-\{0\})\cong H_{0}^{BM}(\{0\})

and

0\cong H_{0}^{BM}(\mathbb {R} ^{n})\cong H_{0}^{BM}(\mathbb {R} ^{n}-\{0\})

We can interpret these non-zero homology classes using the following observations:

There is the homotopy equivalence $\mathbb {R} ^{n}-\{0\}\simeq S^{n-1}.$
A topological isomorphism $\mathbb {R} ^{n}-\{0\}\cong S^{n-1}\times \mathbb {R} _{>0}.$

hence we can use the computation for the infinite cylinder to interpret $H_{n}^{BM}$ as the homology class represented by $S^{n-1}\times \mathbb {R} _{>0}$ and $H_{1}^{BM}$ as $\mathbb {R} _{>0}.$

Plane with Points Removed[edit]

Let $X=\mathbb {R} ^{2}-\{p_{1},\ldots ,p_{k}\}$ have $k$ -distinct points removed. Notice the previous computation with the fact that Borel-Moore homology is an isomorphism invariant gives this computation for the case $k=1$ . In general, we will find a $1$ -class corresponding to a loop around a point, and the fundamental class $[X]$ in $H_{2}^{BM}$ .

Double Cone[edit]

Consider the double cone $X=\mathbb {V} (x^{2}+y^{2}-z^{2})\subset \mathbb {R} ^{3}$ . If we take $U=X\setminus \{0\}$ then the long exact sequence shows

{\begin{aligned}H_{2}^{BM}(X)&=\mathbb {Z} ^{\oplus 2}\\H_{1}^{BM}(X)&=\mathbb {Z} \\H_{k}^{BM}(X)&=0&&{\text{ for }}k\not \in \{1,2\}\end{aligned}}

Genus Two Curve with Three Points Removed[edit]

Given a genus two curve (Riemann surface) $X$ and three points $F$ , we can use the long exact sequence to compute the Borel-Moore homology of $U=X\setminus F.$ This gives

{\begin{aligned}H_{2}^{BM}(F)\to &H_{2}^{BM}(X)\to H_{2}^{BM}(U)\\\to H_{1}^{BM}(F)\to &H_{1}^{BM}(X)\to H_{1}^{BM}(U)\\\to H_{0}^{BM}(F)\to &H_{0}^{BM}(X)\to H_{0}^{BM}(U)\to 0\end{aligned}}

Since $F$ is only three points we have

H_{1}^{BM}(F)=H_{2}^{BM}(F)=0.

This gives us that $H_{2}^{BM}(U)=\mathbb {Z} .$ Using Poincare-duality we can compute

H_{0}^{BM}(U)=H^{2}(U)=0,

since $U$ deformation retracts to a one-dimensional CW-complex. Finally, using the computation for the homology of a compact genus 2 curve we are left with the exact sequence

0\to \mathbb {Z} ^{\oplus 4}\to H_{1}^{BM}(U)\to \mathbb {Z} ^{\oplus 3}\to \mathbb {Z} \to 0

showing

H_{1}^{BM}(U)\cong \mathbb {Z} ^{\oplus 6}

since we have the short exact sequence of free abelian groups

0\to \mathbb {Z} ^{\oplus 4}\to H_{1}^{BM}(U)\to \mathbb {Z} ^{\oplus 2}\to 0

from the previous sequence.

Notes[edit]

^ Borel & Moore 1960.
^ Birger Iversen. Cohomology of sheaves. Section IX.1.
^ Glen Bredon. Sheaf theory. Corollary V.12.21.
^ Birger Iversen. Cohomology of sheaves. Theorem IX.4.7.
^ Birger Iversen. Cohomology of sheaves. Equation IX.4.1.
^ Birger Iversen. Cohomology of sheaves. Equation IX.2.1.
^ William Fulton. Intersection theory. Lemma 19.1.1.

References[edit]

Survey articles[edit]

Goresky, Mark, Primer on Sheaves (PDF), archived from the original (PDF) on 2017-09-27

Books[edit]

Borel, Armand; Moore, John C. (1960). "Homology theory for locally compact spaces". Michigan Mathematical Journal. 7 (2): 137–159. doi:10.1307/mmj/1028998385. ISSN 0026-2285. MR 0131271.
Bredon, Glen E. (1997). Sheaf Theory (2nd ed.). Berlin, New York: Springer-Verlag. ISBN 978-0-387-94905-5. MR 1481706.
Fulton, William (1998). Intersection Theory (2nd ed.). Berlin, New York: Springer-Verlag. ISBN 978-3-540-62046-4. MR 1644323.
Iversen, Birger (1986). Cohomology of Sheaves. Berlin: Springer-Verlag. ISBN 3-540-16389-1. MR 0842190.

[FOOTNOTEBorelMoore1960-1] Borel & Moore 1960.

[2] Birger Iversen. Cohomology of sheaves. Section IX.1.

[3] Glen Bredon. Sheaf theory. Corollary V.12.21.

[4] Birger Iversen. Cohomology of sheaves. Theorem IX.4.7.

[5] Birger Iversen. Cohomology of sheaves. Equation IX.4.1.

[6] Birger Iversen. Cohomology of sheaves. Equation IX.2.1.

[7] William Fulton. Intersection theory. Lemma 19.1.1.

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