Scattered space

In mathematics, a scattered space is a topological space X that contains no nonempty dense-in-itself subset.^[1][2] Equivalently, every nonempty subset A of X contains a point isolated in A.

A subset of a topological space is called a scattered set if it is a scattered space with the subspace topology.

Examples

• Every discrete space is scattered.
• Every ordinal number with the order topology is scattered. Indeed, every nonempty subset A contains a minimum element, and that element is isolated in A.
• A space X with the particular point topology, in particular the Sierpinski space, is scattered. This is an example of a scattered space that is not a T₁ space.
• The closure of a scattered set is not necessarily scattered. For example, in the Euclidean plane ${\displaystyle \mathbb {R} ^{2}}$ take a countably infinite discrete set A in the unit disk, with the points getting denser and denser as one approaches the boundary. For example, take the union of the vertices of a series of n-gons centered at the origin, with radius getting closer and closer to 1. Then the closure of A will contain the whole circle of radius 1, which is dense-in-itself.

Properties

• In a topological space X the closure of a dense-in-itself subset is a perfect set. So X is scattered if and only if it does not contain any nonempty perfect set.
• Every subset of a scattered space is scattered. Being scattered is a hereditary property.
• Every scattered space X is a T₀ space. (Proof: Given two distinct points x, y in X, at least one of them, say x, will be isolated in ${\displaystyle \{x,y\}}$. That means there is neighborhood of x in X that does not contain y.)
• In a T₀ space the union of two scattered sets is scattered.^[3][4] Note that the T₀ assumption is necessary here. For example, if ${\displaystyle X=\{a,b\}}$ with the indiscrete topology, ${\displaystyle \{a\}}$ and ${\displaystyle \{b\}}$ are both scattered, but their union, ${\displaystyle X}$, is not scattered as it has no isolated point.
• Every T₁ scattered space is totally disconnected.
  (Proof: If C is a nonempty connected subset of X, it contains a point x isolated in C. So the singleton ${\displaystyle \{x\}}$ is both open in C (because x is isolated) and closed in C (because of the T₁ property). Because C is connected, it must be equal to ${\displaystyle \{x\}}$. This shows that every connected component of X has a single point.)
• Every second countable scattered space is countable.^[5]
• Every topological space X can be written in a unique way as the disjoint union of a perfect set and a scattered set.^[6][7]
• Every second countable space X can be written in a unique way as the disjoint union of a perfect set and a countable scattered open set.
  (Proof: Use the perfect + scattered decomposition and the fact above about second countable scattered spaces, together with the fact that a subset of a second countable space is second countable.)
  Furthermore, every closed subset of a second countable X can be written uniquely as the disjoint union of a perfect subset of X and a countable scattered subset of X.^[8] This holds in particular in any Polish space, which is the contents of the Cantor–Bendixson theorem.

Notes

References

• Engelking, Ryszard, General Topology, Heldermann Verlag Berlin, 1989. ISBN 3-88538-006-4
• Steen, Lynn Arthur; Seebach, J. Arthur Jr. (1995) [1978]. Counterexamples in Topology (Dover reprint of 1978 ed.). Berlin, New York: Springer-Verlag. ISBN 978-0-486-68735-3. MR 0507446.
• Willard, Stephen (2004) [1970], General Topology (Dover reprint of 1970 ed.), Addison-Wesley

This page was last edited on 24 December 2023, at 21:51