σ-compact space

In mathematics, a topological space is said to be σ-compact if it is the union of countably many compact subspaces.^[1]

A space is said to be σ-locally compact if it is both σ-compact and (weakly) locally compact.^[2] That terminology can be somewhat confusing as it does not fit the usual pattern of σ-(property) meaning a countable union of spaces satisfying (property); that's why such spaces are more commonly referred to explicitly as σ-compact (weakly) locally compact, which is also equivalent to being exhaustible by compact sets.^[3]

Properties and examples

Every compact space is σ-compact, and every σ-compact space is Lindelöf (i.e. every open cover has a countable subcover).^[4] The reverse implications do not hold, for example, standard Euclidean space (Rⁿ) is σ-compact but not compact,^[5] and the lower limit topology on the real line is Lindelöf but not σ-compact.^[6] In fact, the countable complement topology on any uncountable set is Lindelöf but neither σ-compact nor locally compact.^[7] However, it is true that any locally compact Lindelöf space is σ-compact.
(The irrational numbers) $\mathbb {R} \setminus \mathbb {Q}$ is not σ-compact.^[8]
A Hausdorff, Baire space that is also σ-compact, must be locally compact at at least one point.
If G is a topological group and G is locally compact at one point, then G is locally compact everywhere. Therefore, the previous property tells us that if G is a σ-compact, Hausdorff topological group that is also a Baire space, then G is locally compact. This shows that for Hausdorff topological groups that are also Baire spaces, σ-compactness implies local compactness.
The previous property implies for instance that R^ω is not σ-compact: if it were σ-compact, it would necessarily be locally compact since R^ω is a topological group that is also a Baire space.
Every hemicompact space is σ-compact.^[9] The converse, however, is not true;^[10] for example, the space of rationals, with the usual topology, is σ-compact but not hemicompact.
The product of a finite number of σ-compact spaces is σ-compact. However the product of an infinite number of σ-compact spaces may fail to be σ-compact.^[11]
A σ-compact space X is second category (respectively Baire) if and only if the set of points at which is X is locally compact is nonempty (respectively dense) in X.^[12]

Notes

^ Steen, p. 19; Willard, p. 126.
^ Steen, p. 21.
^ "A question about local compactness and $\sigma$-compactness". Mathematics Stack Exchange.
^ Steen, p. 19.
^ Steen, p. 56.
^ Steen, p. 75–76.
^ Steen, p. 50.
^ Hart, K.P.; Nagata, J.; Vaughan, J.E. (2004). Encyclopedia of General Topology. Elsevier. p. 170. ISBN 0 444 50355 2.
^ Willard, p. 126.
^ Willard, p. 126.
^ Willard, p. 126.
^ Willard, p. 188.

References

Steen, Lynn A. and Seebach, J. Arthur Jr.; Counterexamples in Topology, Holt, Rinehart and Winston (1970). ISBN 0-03-079485-4.
Willard, Stephen (2004). General Topology. Dover Publications. ISBN 0-486-43479-6.

[1] Steen, p. 19; Willard, p. 126.

[2] Steen, p. 21.

[3] "A question about local compactness and $\sigma$-compactness". Mathematics Stack Exchange.

[4] Steen, p. 19.

[5] Steen, p. 56.

[6] Steen, p. 75–76.

[7] Steen, p. 50.

[8] Hart, K.P.; Nagata, J.; Vaughan, J.E. (2004). Encyclopedia of General Topology. Elsevier. p. 170. ISBN 0 444 50355 2.

[9] Willard, p. 126.

[10] Willard, p. 126.

[11] Willard, p. 126.

[12] Willard, p. 188.

[1]

[2]

[3]

[4]

[5]

[6]

[7]

[8]

[9]

[10]

[11]

[12]

Properties and examples

See also

Notes

References