Equivalence of Definitions of Closure of Topological Subspace

Theorem
Let $T = \struct {S, \tau}$ be a topological space.

Let $H \subseteq S$.

Definition $1$ is equivalent to Definition $2$
This is proved in Set Closure as Intersection of Closed Sets.

Definition $2$ is equivalent to Definition $3$
This is proved in Set Closure is Smallest Closed Set.

Definition $1$ is equivalent to Definition $4$
By the definition of the interior, and Set is Subset of its Topological Closure, it easily follows that
 * $H^\circ \subseteq H \subseteq H^-$

Then:

Definition $1$ is equivalent to Definition $5$
Every isolated point of $H$ is a point of $H$.

So by Set Union Preserves Subsets:
 * $(1): \quad H^i \cup H' \subseteq H \cup H'$

If $S \setminus \paren {H^i \cup H'} = \O$, then $(1)$ yields $H^i \cup H' = H \cup H'$ and so the proof is complete.

Otherwise, let $x \in S \setminus \paren {H^i \cup H'} \ne \O$.

From De Morgan's Laws:
 * $S \setminus \paren {H^i \cup H'} = \paren {S \setminus H^i} \cap \paren {S \setminus H'}$

Thus $x$ is a point of $S$ that is neither an isolated point of $H$ nor a limit point of $H$.

Then there exists an open set $U$ that contains $x$ such that:
 * $U \cap H \ne \set x$

and:
 * $H \cap \paren {U \setminus \set x} = \O$

This implies that
 * $U \cap H = \O$

By Condition for Point being in Closure:
 * $x \notin H \cup H'$

It has been shown that:
 * $x \notin H^i \cup H' \implies x \notin H \cup H'$

From Rule of Transposition:
 * $x \in H \cup H' \implies x \in H^i \cup H'$

And so
 * $(2): \quad H \cup H' \subseteq H^i \cup H'$

Combining $(1)$ and $(2)$:
 * $H \cup H' = H^i \cup H'$

Hence the result.

Definition $1$ is equivalent to Definition $6$
By one of the equivalent definitions of an adherent point:
 * A point $x \in S$ is an adherent point of $H$ every open neighborhood $U$ of $x$ satisfies $H \cap U \ne \O$

From Condition for Point being in Closure:
 * $x \in H^-$ every open set of $T$ which contains $x$ contains a point in $H$

where:
 * $H^-$ is the union of $H$ and all the limit points of $H$ in $T$

The equivalence follows.