Maximal Element of Complement of Filter is Meet Irreducible

Theorem
Let $L = \left({S, \vee, \wedge, \preceq}\right)$ be a lattice.

Let $F$ be a filter in $L$.

Let $p \in S$.

Let $p = \max \complement_S\left({F}\right)$.

Then $p$ is meet irreducible.

Proof
Let $x, y \in S$.


 * $p = x \wedge y$ and $p \ne x$ and $p \ne y$

By Meet Precedes Operands:
 * $p \preceq x$ and $p \preceq y$

By definition of $\prec$:
 * $p \prec x$ and $p \prec y$

We will prove that
 * $x \notin F$ or $y \notin F$


 * $x \in F \land y \in F$

By definition of filtered:
 * $\exists z \in F: z \preceq x \land z \preceq y$

By definition of infimum:
 * $z \preceq p$

By definition of upper set:
 * $p \in F$

Thus this contradicts $p \in \complement_S\left({F}\right)$ by definition of greatest element.

By definition of relative complement:
 * $x \in \complement_S\left({F}\right)$ or $y \in \complement_S\left({F}\right)$

Thus by definition of greatest element: this contradicts $p \prec x$ and $p \prec y$