Jump to content

Excision theorem: Difference between revisions

From Wikipedia, the free encyclopedia
Content deleted Content added
Add an additional application
Jxglen (talk | contribs)
I added one more application of the excision theorem.
Line 32: Line 32:
The excision theorem may be used to derive the suspension theorem for homology, which says <math>\tilde{H}_n(X) \cong \tilde{H}_{n+1}(SX)</math> for all <math>n</math>, where <math>SX</math> is the [[Suspension (topology)|suspension]] of <math>X</math>. <ref>See Hatcher 2002, p.132, for example</ref>
The excision theorem may be used to derive the suspension theorem for homology, which says <math>\tilde{H}_n(X) \cong \tilde{H}_{n+1}(SX)</math> for all <math>n</math>, where <math>SX</math> is the [[Suspension (topology)|suspension]] of <math>X</math>. <ref>See Hatcher 2002, p.132, for example</ref>


=== Invariance of Dimension===
If nonempty open sets <math> U\subset \mathbb{R}^n</math> and <math> V\subset \mathbb{R}^m</math>
are homeomorphic, then m = n. This follows from the excision theorem, the long exact sequence for the pair <math>(\mathbb{R}^n,\mathbb{R}^n-x)</math>, and the fact that <math> \mathbb{R}^n-x</math> deformation retracts onto a sphere.
In particular, <math>\mathbb{R}^n</math> is not homeomorphic to <math>\mathbb{R}^m</math>.<ref>See Hatcher 2002, p.135</ref>
== See also ==
== See also ==
*[[Homotopy excision theorem]]
*[[Homotopy excision theorem]]

Revision as of 01:50, 24 April 2023

In algebraic topology, a branch of mathematics, the excision theorem is a theorem about relative homology and one of the Eilenberg–Steenrod axioms. Given a topological space and subspaces and such that is also a subspace of , the theorem says that under certain circumstances, we can cut out (excise) from both spaces such that the relative homologies of the pairs into are isomorphic.

This assists in computation of singular homology groups, as sometimes after excising an appropriately chosen subspace we obtain something easier to compute.

Theorem

Statement

If are as above, we say that can be excised if the inclusion map of the pair into induces an isomorphism on the relative homologies:

The theorem states that if the closure of is contained in the interior of , then can be excised.

Often, subspaces that do not satisfy this containment criterion still can be excised—it suffices to be able to find a deformation retract of the subspaces onto subspaces that do satisfy it.

Proof Sketch

The proof of the excision theorem is quite intuitive, though the details are rather involved. The idea is to subdivide the simplices in a relative cycle in to get another chain consisting of "smaller" simplices, and continuing the process until each simplex in the chain lies entirely in the interior of or the interior of . Since these form an open cover for and simplices are compact, we can eventually do this in a finite number of steps. This process leaves the original homology class of the chain unchanged (this says the subdivision operator is chain homotopic to the identity map on homology). In the relative homology , then, this says all the terms contained entirely in the interior of can be dropped without affecting the homology class of the cycle. This allows us to show that the inclusion map is an isomorphism, as each relative cycle is equivalent to one that avoids entirely.

Applications

Eilenberg–Steenrod Axioms

The excision theorem is taken to be one of the Eilenberg–Steenrod Axioms.

Mayer-Vietoris Sequences

The Mayer–Vietoris sequence may be derived with a combination of excision theorem and the long-exact sequence.[1]

Suspension Theorem for Homology

The excision theorem may be used to derive the suspension theorem for homology, which says for all , where is the suspension of . [2]

Invariance of Dimension

If nonempty open sets and are homeomorphic, then m = n. This follows from the excision theorem, the long exact sequence for the pair , and the fact that deformation retracts onto a sphere. In particular, is not homeomorphic to .[3]

See also

References

  1. ^ See Hatcher 2002, p.149, for example
  2. ^ See Hatcher 2002, p.132, for example
  3. ^ See Hatcher 2002, p.135

Bibliography

  • Joseph J. Rotman, An Introduction to Algebraic Topology, Springer-Verlag, ISBN 0-387-96678-1
  • Allen Hatcher, Algebraic Topology. Cambridge University Press, Cambridge, 2002.