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content/Math4201/Math4201_L8.md
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# Math4201 Lecture 8
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Recall from real analysis, a set is closed if and only if it has limit points.
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## New materials
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### Limit points
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Let $(X,\mathcal{T})$ be a topological space. $A$ is a subset of $X$, then we say $x\in X$ is a limit point of $A$ if any open set $U\subset X$ containing $x$ has another point $y\in A-\{x\}$.
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<details>
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<summary>Example of limit points</summary>
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Let $X=\mathbb{R}$ with standard topology.
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Let $A=(0,1)$, then set of limit points of $A$ is $[0,1]$.
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Let $A=\left{\frac{1}{n}\right}_{n\in \mathbb{N}}$, then set of limit points of $A$ is $\{0\}$.
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Let $A=\{0\}\cup (1,2)$, then set of limit points of $A$ is $[1,2]$
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Let $A=\mathbb{Z}$, then set of limit points of $A$ is $\emptyset$.
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</details>
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#### Proposition of limit points and closed sets
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A set is close if and only if it has limit points.
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Theorem: For any subset $A$ of a topological space $X$, the closure of $A$ is $\overline{A}=A\cup A'$.
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<details>
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<summary>Proof</summary>
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First we want to prove the theorem implies the proposition,
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$\Rightarrow$
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Let $A$ be a close set in $X$, then $\overline{A}=A$ because $A$ in the intersection of all closed subsets $Z\subseteq A$ in $X$ that contains $A$.
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So $Z=A$ is such a closed subset of $X$ that contains $A$.
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By the theorem, $\overline{A}=A\cup A'$. Combining this with the fact that $A$ is closed, we have $A=A\cup A'$.
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So $A'\subseteq A$.
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$\Leftarrow$
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Suppose $A\subseteq X$ is a set that includes all its limit points, then $A'\subseteq A$.Then $A'\cup A=A$.
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By the theorem, $\overline{A}=A\cup A'=A$.
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Since $\overline{A}$ is the smallest closed subset of $X$ that contains $A$, we have $A$ is closed.
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</details>
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#### Definition of neighborhood
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Let $(X,\mathcal{T})$ be a topological space. A neighborhood of a point $x\in X$ is an open set $U\in \mathcal{T}$ such that $x\in U$.
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#### Lemma of intersection of neighborhoods for closure of a set
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$x\in \overline{A}$ if and only if any neighborhood of $U$ of $x$ non-trivial intersects $A$. ($A\cap U\neq \emptyset$)
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<details>
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<summary>Proof of Lemma</summary>
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$\Leftarrow$
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We proceed by contradiction.
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Suppose $A\notin \overline{A}$, then $x\notin \overline{A}$.
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Then $\overline{A}=\bigcap_{A\subseteq Z, Z\text{ is closed}} Z$
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So, there is $A\subseteq Z\subset X$ and $Z$ is closed.
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So this implies that $x\in X-Z\coloneq U$ and $U$ is open since it a complement of a closed set $Z$.
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Since $A\subseteq Z$, we have $A\cap U= \emptyset$. (disjoint)
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So $U$ and $A$ are disjoint. So $U$ is an open neighborhood of $x$ that is disjoint from $A$.
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This contradicts the assumption that $x\in \overline{A}$.
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$\Rightarrow$
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Let $x\in \overline{A}$, and we want to show that any neighborhood of $U$ of $x$ non-trivial intersects $A$. ($A\cap U\neq \emptyset$)
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By contradiction, suppose that there is an open neighborhood of $x$ that is disjoint from $A$. Then $Z\coloneq X-U$ is closed and $A\subseteq Z$ because $U\cap A= \emptyset$.
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Also $x\notin Z$.
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By the definition of closure, $\overline{A}=\subset Z$.
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Since $x\notin Z$, we have $x\notin \overline{A}$.
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This contradicts the assumption that $x\in \overline{A}$.
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</details>
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#### Proof of theorem
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For any subset $A$ of a topological space $X$, the closure of $A$ is $\overline{A}=A\cup A'$.
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<details>
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<summary>Proof</summary>
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First we show $A\subseteq \overline{A}$.
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If $x\in A'$, then any open neighborhood $U$ of $x$ has a non-trivial intersection with $A$ by the lemma.
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So $x\in \overline{A}$.
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We already know $A\subseteq \overline{A}$.
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Therese two inductions implies $A\cup A'\subseteq \overline{A}$.
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Next we show that $\overline{A}\subseteq A\cup A'$.
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If $x\in \overline{A}$, then by the lemma, any open neighborhood $U$ of $x$ has a non-trivial intersection with $A$.
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If $x\in A$, then $x\in A\cup A'$.
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If $x\notin A$, then the intersection of any open neighborhood $U$ of $x$ with $A$ does not contain $x$.
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This implies that this intersection has to include a point $y$ that is not $x$.
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Since this holds for any open neighborhood $U$ of $x$, we have $x\in A'$. ($x$ is a limit point of $A$)
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So $x\in A'$.
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Therese two inductions implies $\overline{A}\subseteq A\cup A'$.
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</details>
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> [!TIP]
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>
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> Now the three definition of closure are equivalent.
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>
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> 1. The smallest closed subset of $X$ that contains $A$.
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> 2. $A\cup A'$.
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@@ -8,5 +8,7 @@ export default {
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Math4201_L3: "Topology I (Lecture 3)",
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Math4201_L4: "Topology I (Lecture 4)",
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Math4201_L5: "Topology I (Lecture 5) Bonus",
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Math4201_L6: "Topology I (Lecture 6)"
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Math4201_L6: "Topology I (Lecture 6)",
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Math4201_L7: "Topology I (Lecture 7)",
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Math4201_L8: "Topology I (Lecture 8)",
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}
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