Monotone normality is hereditary

This article gives the statement, and possibly proof, of a topological space property (i.e., monotonically normal space) satisfying a topological space metaproperty (i.e., subspace-hereditary property of topological spaces)
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Statement

Suppose $X$ is a monotonically normal space with a monotone normality operator $G$ . Suppose $Y$ is a subspace of $X$ . Then, $Y$ is also a monotonically normal space, with a monotone normality operator defined in terms of $G$ .

Related facts

Proof

Given: A monotonically normal space $X$ with monotone normality operator $G$ . A subspace $Y$ of $X$ .

To prove: We can define a monotone normality operator on $Y$ in terms of $G$ .

Proof: Note that the part about $X$ being $T_{1}$ implying $Y$ being $T_{1}$ is immediate.

Suppose $A$ and $B$ are disjoint closed subsets of $Y$ . Then, by the definition of subspace topology, we have that $\bar{A} \cap B$ is empty and $A \cap \bar{B}$ is empty.

We define the monotone normality operator on $Y$ as follows:

$G^{'} (A, B) = Y \cap ⋃_{a \in A} G ({a}, \bar{B})$ .

We claim the following:

$G^{'} (A, B)$ is open in $Y$ : Note first that since $X$ is $T_{1}$ , the point ${a}$ is closed. Also, $\bar{B}$ is closed, and disjoint from ${a}$ . Thus, $G ({a}, B)$ is open for each $a \in A$ . Thus, the union of all of these is open in $X$ , and so, by the definition of subspace topology, the intersection with $Y$ is open in $Y$ .
The closure of $G^{'} (A, B)$ in $Y$ is disjoint from $B$ : Consider $G (\bar{A}, {b})$ for $b \in B$ . This is an open subset of $X$ by definition, and $G ({a}, \bar{B}) \subseteq G (\bar{A}, b)$ for all $a \in A, b \in B$ . Thus, we obtain that $G^{'} (A, B) \subseteq ⋃_{a \in A} G ({a}, \bar{B}) \subseteq ⋂_{b \in B} G (\bar{A}, {b}) \subseteq ⋂_{b \in B} \bar{G (\bar{A}, {b})}$ . The last set is closed, and does not contain any of the elements $b \in B$ , so is disjoint from $B$ . Thus, $G^{'} (A, B)$ is contained in a closed subset of $X$ that is disjoint from $B$ . Intersecting with $Y$ , we obtain that $G^{'} (A, B)$ is contained in a closed subset of $Y$ that is disjoint from $B$ . Thus, the closure of $G^{'} (A, B)$ in $Y$ is disjoint from $B$ .
If $A \subseteq A^{'}$ and $B^{'} \subseteq B$ , with $A, B, A^{'}, B^{'}$ all closed in $Y$ , $A \cap B = A^{'} \cap B^{'} = \emptyset$ , then $G (A, B) \subseteq G (A^{'}, B^{'})$ : Since $B^{'} \subseteq B$ , we have $\bar{B^{'}} \subseteq \bar{B}$ , so $G ({a}, \bar{B}) \subseteq G ({a}, \bar{B^{'}})$ for all $a \in A$ . Thus, $G (A, B) \subseteq G (A, B^{'})$ . In turn, it is clear that $G (A, B^{'}) \subseteq G (A^{'}, B^{'})$ . Thus, $G (A, B) \subseteq G (A^{'}, B^{'})$ .