Cofiniteness

Last updated February 19, 2024

In mathematics, a cofinite subset of a set $X$ is a subset $A$ whose complement in $X$ is a finite set. In other words, $A$ contains all but finitely many elements of $X.$ If the complement is not finite, but is countable, then one says the set is cocountable.

Boolean algebras

The set of all subsets of $X$ that are either finite or cofinite forms a Boolean algebra, which means that it is closed under the operations of union, intersection, and complementation. This Boolean algebra is the finite–cofinite algebra on $X.$

In the other direction, a Boolean algebra $A$ has a unique non-principal ultrafilter (that is, a maximal filter not generated by a single element of the algebra) if and only if there exists an infinite set $X$ such that $A$ is isomorphic to the finite–cofinite algebra on $X.$ In this case, the non-principal ultrafilter is the set of all cofinite subsets of $X$ .

Cofinite topology

The cofinite topology (sometimes called the finite complement topology) is a topology that can be defined on every set $X.$ It has precisely the empty set and all cofinite subsets of $X$ as open sets. As a consequence, in the cofinite topology, the only closed subsets are finite sets, or the whole of $X.$ Symbolically, one writes the topology as

{\mathcal {T}}=\{A\subseteq X:A=\varnothing {\mbox{ or }}X\setminus A{\mbox{ is finite}}\}.

This topology occurs naturally in the context of the Zariski topology. Since polynomials in one variable over a field $K$ are zero on finite sets, or the whole of $K,$ the Zariski topology on $K$ (considered as affine line) is the cofinite topology. The same is true for any irreducible algebraic curve; it is not true, for example, for $XY=0$ in the plane.

Properties

Subspaces: Every subspace topology of the cofinite topology is also a cofinite topology.
Compactness: Since every open set contains all but finitely many points of $X,$ the space $X$ is compact and sequentially compact.
Separation: The cofinite topology is the coarsest topology satisfying the T₁ axiom; that is, it is the smallest topology for which every singleton set is closed. In fact, an arbitrary topology on $X$ satisfies the T₁ axiom if and only if it contains the cofinite topology. If $X$ is finite then the cofinite topology is simply the discrete topology. If $X$ is not finite then this topology is not Hausdorff (T₂), regular or normal because no two nonempty open sets are disjoint (that is, it is hyperconnected).

Double-pointed cofinite topology

The double-pointed cofinite topology is the cofinite topology with every point doubled; that is, it is the topological product of the cofinite topology with the indiscrete topology on a two-element set. It is not T₀ or T₁, since the points of each doublet are topologically indistinguishable. It is, however, R₀ since topologically distinguishable points are separated. The space is compact as the product of two compact spaces; alternatively, it is compact because each nonempty open set contains all but finitely many points.

For an example of the countable double-pointed cofinite topology, the set $\mathbb {Z}$ of integers can be given a topology such that every even number $2n$ is topologically indistinguishable from the following odd number $2n+1$ . The closed sets are the unions of finitely many pairs $2n,2n+1,$ or the whole set. The open sets are the complements of the closed sets; namely, each open set consists of all but a finite number of pairs $2n,2n+1,$ or is the empty set.

Other examples

Product topology

The product topology on a product of topological spaces $\prod X_{i}$ has basis $\prod U_{i}$ where $U_{i}\subseteq X_{i}$ is open, and cofinitely many $U_{i}=X_{i}.$

The analog without requiring that cofinitely many factors are the whole space is the box topology.

Direct sum

The elements of the direct sum of modules $\bigoplus M_{i}$ are sequences $\alpha _{i}\in M_{i}$ where cofinitely many $\alpha _{i}=0.$

The analog without requiring that cofinitely many summands are zero is the direct product.

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References

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 (See example 18)

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