Locally closed sets and submaximal spaces
Abstract
A topological space X is called submaximal if every dense subset of X is open. In this paper, we show that if β X, the Stone-Cech compactification of X, is a submaximal space, then X is a compact space and hence β X=X. We also prove that if X, the Hewitt realcompactification of X, is submaximal and first countable and X is without isolated point, then X is realcompact and hence X=X. We observe that every submaximal Hausdorff space is pseudo-finite. It turns out that if X is a submaximal space, then X is a pseudo-finite μ-compact space. An example is given which shows that X may be submaximal but X may not be submaximal. Given a topological space (X, T), the collection of all locally closed subsets of X forms a base for a topology on X which is denotes by Tl. We study some topological properties between (X, T) and (X, Tl), such as we show that a) (X, Tl) is discrete if and only if (X, T) is a TD-space; b) (X, T) is a locally indiscrete space if and only if T= Tl; c) (X, T) is indiscrete space if and only if (X, Tl) is connected. We see that, in locally indiscrete spaces, the concepts of T0, TD, T12, T1, submaximal and discrete coincide. Finally, we prove that every clopen subspace of an lc-compact space is lc-compact.
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