Metrizable implies monotonically normal

This article gives the statement and possibly, proof, of an implication relation between two topological space properties. That is, it states that every topological space satisfying the first topological space property must also satisfy the second topological space property
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Statement

Any metrizable space is monotonically normal. In fact, we can construct an explicit monotone normality operator using the metric.

Definitions used

Metrizable space

Further information: Metrizable space

Monotonically normal space

Further information: Monotonically normal space

Proof

Construction of the operator

Suppose ${\displaystyle (X,d)}$ is a metric space. We construct a monotone normality operator on ${\displaystyle X}$ as follows. For any two closed subsets ${\displaystyle A}$ and ${\displaystyle B}$ of ${\displaystyle X}$:

• For every ${\displaystyle a\in A}$, let ${\displaystyle U_a}$ be the open ball about ${\displaystyle a}$ of radius ${\displaystyle d(a,B)/2}$. Here, ${\displaystyle d(a,B)}$ is the infimum of the distances ${\displaystyle d(a,b)}$ for ${\displaystyle b\in B}$. Note that since ${\displaystyle B}$ is closed and ${\displaystyle a\notin B}$, ${\displaystyle d(a,B)>0}$.
• Analogously, for every ${\displaystyle b\in B}$, define ${\displaystyle V_b}$ to be the open ball about ${\displaystyle b}$ of radius ${\displaystyle d(A,b)/2}$.

Then, the sets:

${\displaystyle U={\bigcup }_{a\in A}{U}_a,V={\bigcup }_{b\in B}{V}_b}$

are the required disjoint open subsets.

Proof of disjointness

The disjointness of ${\displaystyle U}$ and ${\displaystyle V}$ follows from the triangle inequality. It suffices to prove that for every ${\displaystyle a\in A}$ and ${\displaystyle b\in B}$, ${\displaystyle U_a\cap V_b=\mathrm{\varnothing }}$. To see this, note:

${\displaystyle d(a,b)\ge d(a,B),d(a,b)\ge d(A,b)}$

Thus:

${\displaystyle d(a,b)\ge d(a,B)/2+d(A,b)/2}$

This, along with the triangle inequality yields that the balls ${\displaystyle U_a}$ and ${\displaystyle V_b}$ cannot intersect.

Proof of monotonicity

We need to show that if ${\displaystyle A^{\prime }\subseteq A}$ and ${\displaystyle B^{\prime }\supseteq B}$, then the open set about ${\displaystyle A}$ becomes smaller, and the open set about ${\displaystyle B}$ becomes larger. This is clear from the definitions, because ${\displaystyle A^{\prime }}$ has fewer balls, and the radii of the balls also become smaller. Similarly ${\displaystyle B^{\prime }}$ has more balls, and the radii of the balls also become larger.