Monotone normality is hereditary: Difference between revisions

Revision as of 23:05, 24 October 2009

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

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

$G'(A,B)=Y\cap \bigcup _{a\in A}G(\{a\},{\overline {B}})$ .

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, ${\overline {B}}$ 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 $G({\overline {A}},\{b\})$ for $b\in B$ . This is an open subset of $X$ by definition, and $G(\{a\},{\overline {B}})\subseteq G({\overline {A}},b)$ for all $a\in A,b\in B$ . Thus, we obtain that $G'(A,B)\subseteq \bigcup _{a\in A}G(\{a\},{\overline {B}})\subseteq \bigcap _{b\in B}G({\overline {A}},\{b\})\subseteq \bigcap _{b\in B}{\overline {G({\overline {A}},\{b\})}}$ . 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 ${\overline {B'}}\subseteq {\overline {B}}$ , so $G(\{a\},{\overline {B}})\subseteq G(\{a\},{\overline {B'}})$ 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, $G(A,B)\subseteq G(A',B')$ .

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 # <math>G'(A,B)</math> is open in <math>Y</math>: Note first that since <math>X</math> is <math>T_1</math>, the point <math>\{ a \}</math> is closed. Also, <math>\overline{B}</math> is closed, and disjoint from <math>\{ a \}</math>. Thus, <math>G(\{a \},B)</math> is open for each <math>a \in A</math>. Thus, the union of all of these is open in <math>X</math>, and so, by the definition of subspace topology, the intersection with <math>Y</math> is open in <math>Y</math>.
 # The closure of <math>G'(A,B)</math> in <math>Y</math> is disjoint from <math>B</math>: Consider <math>G(\overline{A},\{b\})</math> for <math>b \in B</math>. This is an open subset of <math>X</math> by definition, and <math>G(\{a \},\overline{B}) \subseteq G(\overline{A},b)</math> for all <math>a \in A, b \in B</math>. Thus, we obtain that <math>G'(A,B) \subseteq \bigcup_{a \in A} G(\{a\},\overline{B}) \subseteq \bigcap_{b \in B} G(\overline{A},\{b \}) \subseteq \bigcap_{b \in B} \overline{G(\overline{A},\{ b \})}</math>. The last set is closed, and does not contain any of the elements <math>b \in B</math>, so is disjoint from <math>B</math>. Thus, <math>G'(A,B)</math> is contained in a closed subset of <math>X</math> that is disjoint from <math>B</math>. Intersecting with <math>Y</math>, we obtain that <math>G'(A,B)</math> is contained in a closed subset of <math>Y</math> that is disjoint from <math>B</math>. Thus, the closure of <math>G'(A,B)</math> in <math>Y</math> is disjoint from <math>B</math>.
-# If <math>A \subseteq A'</math> and <math>B' \subseteq B</math>, with <math>A,B,A',B'</math> all closed in <math>Y</math>, <math>A \cap B = A' \cap B' = \emptyset</math>, then <math>G(A,B) \subseteq G(A',B')</math>: Since <math>B' \subseteq B</math>, we have <math>\overline{B'} \subseteq \overline{B}</math>, so <math>G(\{a \}, overline{B}) \subseteq G(\{a\}, \overline{B'})</math> for all <math>a \in A</math>. Thus, <math>G(A,B) \subseteq G(A,B')</math>. In turn, it is clear that <math>G(A,B') \subseteq G(A',B')</math>. Thus, <math>G(A,B) \subseteq G(A',B')</math>.
+# If <math>A \subseteq A'</math> and <math>B' \subseteq B</math>, with <math>A,B,A',B'</math> all closed in <math>Y</math>, <math>A \cap B = A' \cap B' = \emptyset</math>, then <math>G(A,B) \subseteq G(A',B')</math>: Since <math>B' \subseteq B</math>, we have <math>\overline{B'} \subseteq \overline{B}</math>, so <math>G(\{a \}, \overline{B}) \subseteq G(\{a\}, \overline{B'})</math> for all <math>a \in A</math>. Thus, <math>G(A,B) \subseteq G(A,B')</math>. In turn, it is clear that <math>G(A,B') \subseteq G(A',B')</math>. Thus, <math>G(A,B) \subseteq G(A',B')</math>.