Complement of Irreducible Topological Subset is Prime Element

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

Let $X$ be an irreducible subset of $S$ such that:
 * $\relcomp S X \in \tau$

Let $L = \struct {\tau, \preceq}$ be an inclusion ordered set of topology $\tau$.

Then $\relcomp S X$ is prime element in $L$.

Proof
Let $Y, Z \in \tau$ such that
 * $Y \wedge Z \preceq \relcomp S X$

By definition of topological space:
 * $Y \cap Z \in \tau$

By Meet in Inclusion Ordered Set:
 * $Y \cap Z = Y \wedge Z$

By definition of inclusion ordered set:
 * $Y \cap Z \subseteq \relcomp S X$

By Relative Complement inverts Subsets and Relative Complement of Relative Complement:
 * $X \subseteq \relcomp S {Y \cap Z}$

By De Morgan's Laws: Relative Complement of Intersection:
 * $X \subseteq \relcomp S Y \cup \relcomp S Z$

By Intersection with Subset is Subset:
 * $X = \paren {\relcomp S Y \cup \relcomp S Z} \cap X$

By Intersection Distributes over Union:
 * $X = \paren {\relcomp S Y \cap X} \cup \paren {\relcomp S Z \cap X}$

By definition of closed set and Relative Complement of Relative Complement:
 * $X$, $\relcomp S Y$, and $\relcomp S Z$ are closed sets.

By Intersection of Closed Sets is Closed in Topological Space:
 * $\relcomp S Y \cap X$, $\relcomp S Z \cap X$ are closed sets.

By definition of irreducible:
 * $\relcomp S Y \cap X = X$ or $\relcomp S Z \cap X = X$

By Intersection with Subset is Subset:
 * $X \subseteq \relcomp S Y$ or $X \subseteq \relcomp S Z$

By Relative Complement inverts Subsets and Relative Complement of Relative Complement:
 * $Y \subseteq \relcomp S X$ or $Z \subseteq \relcomp S X$

Thus by definition of inclusion ordered set:
 * $Y \preceq \relcomp S X$ or $Z \preceq \relcomp S X$