Appert topology

In general topology, a branch of mathematics, the Appert topology, named for Antoine Appert (1934), is a topology on the set X = {1, 2, 3, ...} of positive integers.^[1] In the Appert topology, the open sets are those that do not contain 1, and those that asymptotically contain almost every positive integer. The space X with the Appert topology is called the Appert space.^[1]

Construction[edit]

For a subset S of X, let N(n,S) denote the number of elements of S which are less than or equal to n:

\mathrm {N} (n,S)=\#\{m\in S:m\leq n\}.

S is defined to be open in the Appert topology if either it does not contain 1 or if it has asymptotic density equal to 1, i.e., it satisfies

\lim _{n\to \infty }{\frac {{\text{N}}(n,S)}{n}}=1

.

The empty set is open because it does not contain 1, and the whole set X is open since ${\text{N}}(n,X)/n=1$ for all n.

Related topologies[edit]

The Appert topology is closely related to the Fort space topology that arises from giving the set of integers greater than one the discrete topology, and then taking the point 1 as the point at infinity in a one point compactification of the space.^[1] The Appert topology is finer than the Fort space topology, as any cofinite subset of X has asymptotic density equal to 1.

Properties[edit]

The closed subsets S of X are those that either contain 1 or that have zero asymptotic density, namely $\lim _{n\to \infty }\mathrm {N} (n,S)/n=0$ .

Every point of X has a local basis of clopen sets, i.e., X is a zero-dimensional space.^[1]
Proof: Every open neighborhood of 1 is also closed. For any $x\neq 1$ , $\{x\}$ is both closed and open.

X is Hausdorff and perfectly normal (T₆).
Proof: X is T₁. Given any two disjoint closed sets A and B, at least one of them, say A, does not contain 1. A is then clopen and A and its complement are disjoint respective neighborhoods of A and B, which shows that X is normal and Hausdorff. Finally, any subset, in particular any closed subset, in a countable T₁ space is a G_δ, so X is perfectly normal.

X is countable, but not first countable,^[1] and hence not second countable and not metrizable.

A subset of X is compact if and only if it is finite. In particular, X is not locally compact, since there is no compact neighborhood of 1.

X is not countably compact.^[1]
Proof: The infinite set $\{2^{n}:n\geq 1\}$ has zero asymptotic density, hence is closed in X. Each of its points is isolated. Since X contains an infinite closed discrete subset, it is not limit point compact, and therefore it is not countably compact.

Notes[edit]

^ ^a ^b ^c ^d ^e ^f Steen & Seebach 1995, pp. 117–118

References[edit]

Appert, Antoine (1934), Propriétés des Espaces Abstraits les Plus Généraux, Actual. Sci. Ind., Hermann, MR 3533016.
Steen, L. A.; Seebach, J. A. (1995), Counterexamples in Topology, Dover, ISBN 0-486-68735-X.

[CEIT-1] ^ ^a ^b ^c ^d ^e ^f Steen & Seebach 1995, pp. 117–118

[1]

Construction[edit]

Related topologies[edit]

Properties[edit]

See also[edit]

Notes[edit]

References[edit]