Positive Real Numbers under Max Operation form Monoid

Theorem
Let $\R_{\ge 0}$ be the set of positive (that is, non-negative) real numbers.

Let $\max: \R_{\ge 0}^2 \to \R_{\ge 0}$ be the max operation on $\R_{\ge 0}$.

Then $\left({\R_{\ge 0}, \max}\right)$ is a monoid whose identity is $0$.

Proof
From Real Numbers are Totally Ordered, $\R$ is a totally ordered set.

From Max Operation on Toset is Semigroup, $\left({\R_{\ge 0}, \max}\right)$ is a semigroup.

By definition of $\R_{\ge 0}$:
 * $\forall x \in \R_{\ge 0}: 0 \le x$

Thus by definition of the max operation:
 * $\forall x \in \R_{\ge 0}: \max \left({0, x}\right) = 0 = \max \left({x, 0}\right)$

So $0$ is the identity of $\left({\R_{\ge 0}, \max}\right)$ by definition.

The result follows by definition of monoid.