Baire property is open subspace-closed: Difference between revisions

Revision as of 00:19, 25 January 2012

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

Verbal statement

Every open subset of a Baire space is itself a Baire space, under the subspace topology.

Definitions used

Baire space

Further information: Baire space

A topological space is termed a Baire space if an intersection of countably many open dense subsets is dense.

Subspace topology

Further information: Subspace topology

Proof

Given: A Baire space $X$ , an open subset $A$ . A countable family of open dense subsets, $U_{n}, n \in N$ of $A$

To prove: The intersection $⋂_{n \in N} U_{n}$ is dense in $A$

Proof:

Step no.	Assertion/construction	Given data used	Previous steps used	Explanation
1	Consider the set $B = X ∖ \bar{A}$ , where $\bar{A}$ is the closure of $A$ in $X$ . $B$ is an open subset of $X$ .			the complement of a closed subset is open by definition.
2	Each $U_{n}$ is open in $X$ .	$A$ is open in $X$ Each $U_{n}$ is open in $A$ .
3	Each $U_{n} \cup B$ is open in $X$ with $B$ defined in Step (1).		Steps (1), (2)	Step-combination, and the observation that a union of open subsets is open
4	Each $U_{n} \cup B$ is dense in $X$ . In other words, for any open subset $V$ of $X$ , the intersection $(U_{n} \cup B) \cap V$ is nonempty.			[SHOW MORE] Consider any open subset $V$ of $X$ . If the open subset intersects $B$ , we are done. Otherwise the open subset is in $\bar{A}$ . Hence, by definition, it intersects $A$ in a nonempty open subset, say $W$ . Then $W$ is an open subset of $A$ . Since $U_{n}$ is dense in $A$ , it intersects $W$ nontrivially, so it intersects $V$ nontrivially, completing the proof of density.
5	Consider the collection of subsets $U_{n} \cup B$ . This is a countable collection of open dense subsets of $X$		Steps (3), (4)	Step-combination direct
6	The intersection $⋂_{n \in N} (U_{n} \cup B)$ is dense in $X$ >	$X$ is a Baire space.	Step (5)	Step-given direct

The rest of the proof needs to be converted to tabular form too!

so their intersection is dense in $X$ . This intersection is of the form $B \cup T$ , where $T$ is an open subset of $A$ . We now need to argue that $T$ is a dense subset of $A$ .

Let $S$ be a nonempty open subset of $A$ ; we need to show that $S \cap T$ is nonempty. Since $S$ is open in $A$ , $S$ is also open in $X$ , so $S \cap (T \cup B)$ is nonempty, because $T \cup B$ is dense in $X$ . But since $S \subset A$ , $S \cap B$ is empty, so $S \cap T$ must be nonempty, completing the proof.

References

Textbook references

Topology (2nd edition) by James R. Munkres, ^{More info}, Page 297, Lemma 48.4, Chapter 4, Section 48

@@ Line 23: / Line 23: @@
 ==Proof==
-'''Given''': A Baire space <math>X</math>, an open subset <math>A</math>
+'''Given''': A Baire space <math>X</math>, an open subset <math>A</math>. A countable family of open dense subsets, <math>U_n, n \in \mathbb{N}</math> of <math>A</math>
-'''To prove''': An intersection of a countable family of open dense subsets, <math>U_n, n \in \mathbb{N}</math> of <math>A</math> is dense in <math>A</math>
+'''To prove''': The intersection <math>\bigcap_{n \in \mathbb{N}} U_n</math> is dense in <math>A</math>
-'''Proof''': First, consider the set <math>B = X \setminus \overline{A}</math>, where <math>\overline{A}</math> is the closure of <math>A</math> in <math>X</math>. Clearly <math>B</math> is open in <math>X</math>.
+'''Proof''':
-Since <math>A</math> is open in <math>X</math>, and each <math>U_n</math> is open in <math>A</math>, each <math>U_n</math> is open in <math>X</math>. Hence, each <math>U_n \cup B</math> is open in <math>X</math>.
+{| class="sortable" border="1"
+! Step no. !! Assertion/construction !! Facts used !! Given data used !! Previous steps used !! Explanation
+|-
+| 1 || Consider the set <math>B = X \setminus \overline{A}</math>, where <math>\overline{A}</math> is the closure of <math>A</math> in <math>X</math>. <math>B</math> is an '''open''' subset of <math>X</math>. || || || || the complement of a closed subset is open by definition.
+|-
+| 2 || Each <math>U_n</math> is open in <math>X</math>. || || <math>A</math> is open in <math>X</math><br>Each <math>U_n</math> is open in <math>A</math>. || ||
+|-
+| 3 || Each <math>U_n \cup B</math> is open in <math>X</math> with <math>B</math> defined in Step (1). || || || Steps (1), (2) || Step-combination, and the observation that a union of open subsets is open
+|-
+| 4 || Each <math>U_n \cup B</math> is dense in <math>X</math>. In other words, for any open subset <math>V</math> of <math>X</math>, the intersection <math>(U_n \cup B) \cap V</math> is nonempty. || || || || <toggledisplay>Consider any open subset <math>V</math> of <math>X</math>. If the open subset intersects <math>B</math>, we are done. Otherwise the open subset is in <math>\overline{A}</math>. Hence, by definition, it intersects <math>A</math> in a nonempty open subset, say <math>W</math>. Then <math>W</math> is an open subset of <math>A</math>. Since <math>U_n</math> is dense in <math>A</math>, it intersects <math>W</math> nontrivially, so it intersects <math>V</math> nontrivially, completing the proof of density.</toggledisplay>
+|-
+| 5 || Consider the collection of subsets <math>U_n \cup B</math>. This is a countable collection of open dense subsets of <math>X</math> || || || Steps (3), (4) || Step-combination direct
+|-
+| 6 || The intersection <math>\bigcap_{n \in \mathbb{N}} (U_n \cup B)</math> is dense in <math>X</math>> || || <math>X</math> is a Baire space. || Step (5) || Step-given direct
+|}
-Next, we want to argue that each <math>U_n \cup B</math> is dense in <math>X</math>. For this, consider any open subset <math>V</math> of <math>X</math>. If the open subset intersects <math>B</math>, we are done. Otherwise the open subset is in <math>\overline{A}</math>. Hence, by definition, it intersects <math>A</math> in a nonempty open subset, say <math>W</math>. Then <math>W</math> is an open subset of <math>A</math>. Since <math>U_n</math> is dense in <math>A</math>, it intersects <math>W</math> nontrivially, completing the proof of density.
+The rest of the proof needs to be converted to tabular form too!
-Thus, consider the collection of subsets <math>U_n \cup B</math>. This is a countable collection of open dense subsets of <math>X</math>, so their intersection is dense in <math>X</math>. This intersection is of the form <math>B \cup T</math>, where <math>T</math> is an open subset of <math>A</math>. We now need to argue that <math>T</math> is a dense subset of <math>A</math>.
+so their intersection is dense in <math>X</math>. This intersection is of the form <math>B \cup T</math>, where <math>T</math> is an open subset of <math>A</math>. We now need to argue that <math>T</math> is a dense subset of <math>A</math>.
 Let <math>S</math> be a nonempty open subset of <math>A</math>; we need to show that <math>S \cap T</math> is nonempty. Since <math>S</math> is open in <math>A</math>, <math>S</math> is also open in <math>X</math>, so <math>S \cap (T \cup B)</math> is nonempty, because <math>T \cup B</math> is dense in <math>X</math>. But since <math>S \subset A</math>, <math>S \cap B</math> is empty, so <math>S \cap T</math> must be nonempty, completing the proof.