Upper Closure is Strict Upper Closure of Immediate Predecessor

Theorem
Let $\struct {S, \preccurlyeq}$ be a totally ordered set.

Let $a, b \in S$ with $a \prec b$.

Suppose that:
 * $\set {x \in S: a \prec x \prec b} = \O$

Then:
 * $a^\succ = b^\succcurlyeq$

and
 * $b^\prec = a^\preccurlyeq$

where:
 * $a^\succ$ is the strict upper closure of $a$
 * $b^\succcurlyeq$ is the weak upper closure of $b$
 * $b^\prec$ is the strict lower closure of $b$
 * $a^\preccurlyeq$ is the weak lower closure of $a$.

Proof
Let:
 * $p \in a^\succ$

By the definition of strict upper closure:
 * $a \prec p$

By the definition of total ordering, $p \prec b$ or $p \succcurlyeq b$.

But if $p \prec b$ then $a \prec p \prec b$, contradicting the premise.

Thus $p \succcurlyeq b$, so $p \in b^\succcurlyeq$.

By definition of subset:
 * $a^\succ \subseteq b^\succcurlyeq$

Let:
 * $p \in b^\succcurlyeq$

By the definition of weak upper closure:
 * $b \preccurlyeq p$

Since $a \prec b$, Extended Transitivity shows that $a \prec p$.

Thus:
 * $p \in a^\succ$

By definition of subset:
 * $b^\succcurlyeq \subseteq a^\succ$

Therefore by definition of set equality:
 * $a^\succ = b^\succcurlyeq$

A similar argument shows that $b^\prec = a^\preccurlyeq$.