Poincaré Duality Spaces

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Revision as of 18:17, 23 March 2011

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1 Introduction

1 Definition

A Poincaré pair of dimension $d$ ${{Authors|Klein}}{{Stub}} ==Introduction== <wikitex>; ==Definition== A ''Poincaré pair'' of dimension $d$ consists of a finitely dominated pair $(X,\partial X)$ of spaces for which there exists $$(\mathcal{L},[X])$$ in which $\mathcal{L}$ is a bundle of local coefficients on $X$ which is free abelian of rank one and $[X] \in H_d(X,\partial X;\mathcal {L})$ are such that $$ \cap [X] : H^*(X;\mathcal{B}) \to H_{d-*}(X,\partial X;\mathcal{B} \otimes \mathcal{L})$$ and $$ \cap [X] : H^*(X,\partial X;\mathcal{B}) \to H_{d-*}(X;\mathcal{B} \otimes \mathcal{L})$$ are isomorphisms. is an isomorphism. Here, $\mathcal B$ is allowed to range over all local coefficient bundles on $X$, but in fact it is sufficient to check the condition when $\mathcal{B}$ is local coefficient bundle over $X$ defined by $\Bbb Z[\pi]$, with $\pi$ the fundamental groupoid of $X$. ==Notes== * If $\partial X = \emptyset$, one says that $X$ is a ''Poincaré duality space.'' (In view of this, perhaps better terminology would be to call $(X,\partial X)$ a ''Poincaré space with boundary.'') * $\mathcal L$ is called an ''orientation sheaf'' and $[X]$ is called a ''fundamental class.'' The pair $(\mathcal L,[X])$ is unique up to unique isomorphism. * If $(X,\partial X)$ with respect to $(\mathcal{L},[X])$ a Poincar\'e pair of dimension $d$, then $\partial X$ is a Poincaré space of dimension $d-1$ with respect to $(\mathcal {L}_{|\partial X},\partial [X])$, where $\partial: H_d(X;\mathcal{L}) \to H_{d-1}(\partial X;\mathcal{L}_{|\partial X})$ is the boundary homomorphism. ==Example== A compact (smooth, PL, TOP or homology) manifold $(X,\partial X)$ of dimension $d$ is a Poincaré duality pair of dimension $d$, where $\mathcal L$ is the orientation sheaf of $X$ and $[X]$ is the manifold fundamental class. </wikitex> ==References== {{#RefList:}} [[Category:Theory]]d$ consists of a finitely dominated CW pair $(X,\partial X)$ $(X,\partial X)$ for which there exists

$\displaystyle (\mathcal{L},[X])$ $\displaystyle (\mathcal{L},[X])$

in which

$\mathcal{L}$ is a bundle of local coefficients on $X$ which is free abelian of rank one, and

$[X] \in H_d(X,\partial X;\mathcal {L})$ is a class such that

$\displaystyle \cap [X] : H^*(X;\mathcal{B}) \to H_{d-*}(X,\partial X;\mathcal{B} \otimes \mathcal{L})$ $\displaystyle \cap [X] : H^*(X;\mathcal{B}) \to H_{d-*}(X,\partial X;\mathcal{B} \otimes \mathcal{L})$

and

$\displaystyle \cap [X] : H^*(X,\partial X;\mathcal{B}) \to H_{d-*}(X;\mathcal{B} \otimes \mathcal{L})$ $\displaystyle \cap [X] : H^*(X,\partial X;\mathcal{B}) \to H_{d-*}(X;\mathcal{B} \otimes \mathcal{L})$

are isomorphisms.

Here, $\mathcal B$ is allowed to range over all local coefficient bundles on $X$ , but in fact it is sufficient to check the condition when $\mathcal{B}$ is local coefficient bundle over $X$ defined by $\Bbb Z[\pi]$ , with $\pi$ the fundamental groupoid of $X$ .

2 Notes

If $\partial X = \emptyset$ , one says that $X$ is a Poincaré duality space. (In view of this, perhaps better terminology would be to call $(X,\partial X)$ a Poincaré space with boundary.)

$\mathcal L$ is called an orientation sheaf and $[X]$ is called a fundamental class. The pair $(\mathcal L,[X])$ is unique up to unique isomorphism.

If $(X,\partial X)$ with respect to $(\mathcal{L},[X])$ a Poincar\'e pair of dimension $d$ , then $\partial X$ is a Poincaré space of dimension $d-1$ with respect to $(\mathcal {L}_{|\partial X},\partial [X])$ , where $\partial: H_d(X;\mathcal{L}) \to H_{d-1}(\partial X;\mathcal{L}_{|\partial X})$ is the boundary homomorphism.

3 Example

A compact (smooth, PL, TOP or homology) manifold $(X,\partial X)$ of dimension $d$ is a Poincaré duality pair of dimension $d$ , where $\mathcal L$ is the orientation sheaf of $X$ and $[X]$ is the manifold fundamental class.

2 References

Poincaré Duality Spaces

Revision as of 18:17, 23 March 2011

1 Introduction

1 Definition

2 Notes

3 Example

2 References

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@@ Line 6: / Line 6: @@
-A ''Poincaré pair'' of dimension $d$ consists of a finitely dominated pair $(X,\partial X)$ of spaces for which there exists $$(\mathcal{L},[X])$$ in which  $\mathcal{L}$ is a bundle of local coefficients on $X$ which is free abelian of rank one and $[X] \in H_d(X,\partial X;\mathcal {L})$ are such that
+A ''Poincaré pair'' of dimension $d$ consists of a finitely dominated CW pair $(X,\partial X)$ for which there exists $$(\mathcal{L},[X])$$ in which
+*$\mathcal{L}$ is a bundle of local coefficients on $X$ which is free abelian of rank one, and
+* $[X] \in H_d(X,\partial X;\mathcal {L})$ is a class such that
 $$ \cap [X] : H^*(X;\mathcal{B}) \to H_{d-*}(X,\partial X;\mathcal{B} \otimes \mathcal{L})$$
@@ Line 13: / Line 17: @@
 are isomorphisms.
-is an isomorphism. Here, $\mathcal B$ is allowed to range over all local coefficient bundles on $X$,
+Here, $\mathcal B$ is allowed to range over all local coefficient bundles on $X$,
 but in fact it is sufficient to check the condition when $\mathcal{B}$ is  local coefficient bundle over $X$ defined by
 $\Bbb Z[\pi]$, with $\pi$ the fundamental groupoid of $X$.