Compact to Hausdorff implies closed: Difference between revisions
(New page: ==Statement== Any continuous map from a compact space to a [Hausdorff space]] is a closed map i.e. the image of any closed set is closed. ==Applications== * [[Surjection fro...) |
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==Statement== | ==Statement== | ||
Any [[continuous map]] from a [[compact space]] to a [Hausdorff space]] is a [[closed map]] i.e. the image of any closed set is closed. | Any [[continuous map]] from a [[compact space]] to a [[Hausdorff space]] is a [[closed map]] i.e. the image of any closed set is closed. | ||
==Applications== | ==Applications== | ||
Revision as of 17:18, 13 January 2008
Statement
Any continuous map from a compact space to a Hausdorff space is a closed map i.e. the image of any closed set is closed.
Applications
- Any surjective continuous map from a compact space to a Hausdorff space is a quotient map
- Any continuous injective map from a compact space to a Hausdorff space is a subspace embedding
Proof
We need to show that given any closed subset of the compact space, its image is closed in the Hausdorff space.
We reason in the following steps:
- The closed subset of the compact space, is itself compact in the subspace topology. This is because any closed subset of a compact space is compact. For full proof, refer: Compactness is weakly hereditary
- Thus, the image of this subset, in the target space, is also compact in the subspace topology. This follows from the fact that an image of a compact space under a continuous map is also compact. Further information: Compactness is continuous image-closed
- The image of this subset is a compact subset of a Hausdorff space, hence is closed in the Hausdorff space. This follows from the fact that any compact subset of a Hausdorff space is closed. Further information: Hausdorff implies KC