Properties of the category of compact Hausdorff spaces

Question

What, from a categorical rather than topological point of view, are the interesting properties of the category of compact Hausdorff spaces?

In particular, is it the case that every monomorphism is actually the inclusion of a subspace, ie with the subspace topology?

Also, what is the relationship of this category to that of sets?

[This question previously read: Why in the category of compact Hausdorff spaces the subspaces are equivalent to subobjects? That is, if $Z\to X$ is an injective map of compact Hausdorff spaces, why does $Z$ automatically have the subspace topology from $X$?]

Answer 1

I don't see what the question is here, but instead of getting into an argument about closing the question, I'll tell you something about the category of compact Hausdorff spaces.

It's pretopos, which roughly means that it has the finitary properties of the category of sets.

For example, all monos are regular, so there is an unambiguous notion of subobject, namely closed subspace.

However, whilst the category of compact Hausdorff spaces also has infinitary limits and colimits, the latter are not stable under pullback as they are for sets.

Answer 2

Let $\mathcal{C}$ be a category, and let $X$ be an object of $\mathcal{C}$. A subobject of $X$ is by definition an equivalence class of pairs $(Y,i)$, where $Y$ is another object and $i\colon Y\to X$ is a monomorphism. Here $(Y_0,i_0)$ and $(Y_1,i_1)$ are considered equivalent if there is an isomorphism $f\colon Y_0\to Y_1$ with $i_1f=i_0$.

Now take $\mathcal{C}$ to be the category of compact Hausdorff spaces. The claim is that the subobjects of $X$ biject with the closed subsets.

The first point is to understand the monomorphisms in $\mathcal{C}$. By definition, a monomorphism is a continuous map $i\colon Y\to X$ of compact Hausdorff spaces such that $i_*\colon\mathcal{C}(T,Y)\to\mathcal{C}(T,X)$ is injective for all $T\in\mathcal{C}$. If $i$ itself is injective, then this clearly holds. Conversely, if $i$ is a monomorphism, we can take $T$ to be a one-point space, and we find that $i$ must be injective.

Next, it is a standard lemma that a subset of a compact Hausdorff space is closed iff it is compact in the subspace topology. If $i\colon Y\to X$ is a continuous map between compact Hausdorff spaces, then it certainly sends compact subsets to compact subsets, so it also sends closed subsets to closed subsets. Using this, we see that if $i$ is injective, then $i(Y)$ is closed, and if we give $i(Y)$ the subspace topology, then the map $i\colon Y\to i(Y)$ is a homeomorphism. Thus, in the class of subobjects, we have $[Y,i]=[i(Y),\text{inc}]$. This makes it clear that the subobjects of $X$ biject with the closed subsets.

As the question has been edited to ask about general categorical properties of $\mathcal{C}$, I will mention some more:

1. Manes' Theorem: $\mathcal{C}$ is equivalent to the category of algebras for the Stone-Cech monad. Many properties stated below follow immediately from this, but they can also be proved more directly.
2. $\mathcal{C}$ has all set-indexed limits and colimits.
3. The monomorphisms are precisely the injective morphisms, and they are all equalisers.
4. The epimorphisms are precisely the surjective morphisms, and they are all coequalisers.
5. If $E\subseteq X\times X$ is an equivalence relation that is also closed as a subset of $X\times X$, then $X/E$ is a compact Hausdorff space, and is the coequaliser in $\mathcal{C}$ of the two evident maps $E\to X$.
6. The injective objects are precisely the retracts of powers of the unit interval.
7. An object $X$ is projective iff it is extremally disconnected, i.e. the closure of every open set is open.
8. The dual category $\mathcal{C}^{\text{op}}$ is equivalent to a certain full subcategory of rings. The relevant rings are ordered, but we do not need to consider that as an extra ingredient, because it is determined by the ring structure: we have $a\leq b$ iff $b-a$ is a square. The relevant rings are also topologised, but we do not need to consider that as an extra ingredient, because it is determined by the order. Because of this, each of the relevant rings has a unique $\mathbb{R}$-algebra structure.

Many of these facts can be found in Johnstone's book "Stone Spaces".

Answer 3

I'm not completely sure how germane to the present discussion this is, but I have always found the title of this paper by Herrlich and Strecker a bit intriguing: $\mathrm{Algebra}\cap\mathrm{Topology}=\mathrm{Compactness}$.