Topological separation axioms

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Motivation

The indiscrete topology and discrete topology are not particularly useful, as first countable and second countable topological spaces show by trying to restrict the cardinality of the topology we may derive some interesting properties that are not true for topological spaces in general. Cardinality arguments are "weak" in the sense of they don't really provide a useful constraint on the topology. Consider for example the topology [ilmath]\mathcal{J} [/ilmath] defined as:

  • [ilmath]\mathcal{J}:=\{\mathcal{K}\}\cup\{ (1,+\infty),\ [0,+\infty)\}[/ilmath] where [ilmath]\mathcal{K} [/ilmath] is some topology on [ilmath][0,1]\subset\mathbb{R} [/ilmath] (power-set / discrete topology being a good example)

We can satisfy any cardinality argument with this (depending on the [ilmath]\mathcal{K} [/ilmath]) but for anything outside [ilmath][0,1][/ilmath] we have no information. This is what I mean by cardinality arguments are weak. They don't govern the space.

However, suppose that a topological space, [ilmath](X,\mathcal{ J })[/ilmath] is Hausdorff say, now we have a "strong" property (or requirement for the space), because it applies to ALL points equally well.


TODO: Flesh out


Overview

(Here [ilmath](X,\mathcal{ J })[/ilmath] is a topological space) Warning:Some authors alter the terms slightly, see the warnings at the bottom

Space Meaning Comment
[ilmath]T_1[/ilmath] [ilmath]\forall x,y\in X\exists U\in\mathcal{J}[x\ne y\implies (y\in U\wedge x\notin U)][/ilmath][1]
[ilmath]T_2[/ilmath] [ilmath]\forall x,y\in X\exists U,V\in\mathcal{J}[x\ne y\implies(U\cap V=\emptyset\wedge x\in U\wedge y\in V)][/ilmath][1] AKA: Hausdorff space. Every T2 space is a T1 space.
[ilmath]T_3[/ilmath] A regular [ilmath]T_1[/ilmath] space[1]. Every T3 space is a T2 space
[ilmath]T_4[/ilmath] A normal [ilmath]T_1[/ilmath] space[1]. Every T4 space is a T3 space

TODO: Picture


The [ilmath]T_i[/ilmath] notation exists because the German word for "separation axiom" is "Trennungsaxiome"[1]

Recall

Normal topological space

A topological space, [ilmath](X,\mathcal{ J })[/ilmath], is said to be normal if[1]:

  • [ilmath]\forall E,F\in C(\mathcal{J})\ \exists U,V\in\mathcal{J}[E\cap F=\emptyset\implies(U\cap V=\emptyset\wedge E\subseteq U\wedge F\subseteq V)][/ilmath] - (here [ilmath]C(\mathcal{J})[/ilmath] denotes the collection of closed sets of the topology, [ilmath]\mathcal{J} [/ilmath])

Regular topological space

A topological space, [ilmath](X,\mathcal{ J })[/ilmath] is regular if[1]:

  • [ilmath]\forall E\in C(\mathcal{J})\ \forall x\in X-E\ \exists U,V\in\mathcal{J}[U\cap V=\emptyset\implies(E\subset U\wedge x\in V)][/ilmath] - (here [ilmath]C(\mathcal{J})[/ilmath] denotes the closed sets of the topology [ilmath]\mathcal{J} [/ilmath])

Warning:Note that it is [ilmath]E\subset U[/ilmath] not [ilmath]\subseteq[/ilmath], the author ([1]) like me is pedantic about this, so it must matter

Warnings

According to[1] some authors define:

This rarely leads to problems as a lot of the topological spaces of interest are Hausdorff spaces ([ilmath]T_2[/ilmath]) and on such spaces the definitions coincide.

We shall use the definitions as given above, because we already have a term for "normal topological spaces" - that term is "normal topological space"

References

  1. 1.0 1.1 1.2 1.3 1.4 1.5 1.6 1.7 1.8 Introduction to Topology - Theodore W. Gamelin & Robert Everist Greene