Projection on Real Euclidean Plane is not Closed Mapping

Theorem
Let $\struct {\R^2, d}$ be the real number plane with the usual (Euclidean) topology.

Let $\rho: \R^2 \to \R$ be the first projection on $\R^2$ defined as:
 * $\forall \tuple {x, y} \in \R^2: \map \rho {x, y} = x$

Then $\rho$ is not a closed mapping.

The same applies with the second projection on $\R^2$.

Proof
Consider the set $A \subseteq R^2$ of all points defined as:
 * $A := \set {\tuple {x, y} \in \R^2: x y \ge 1}$

By Subset of Euclidean Plane whose Product of Coordinates are Greater Than or Equal to 1 is Closed:
 * $A$ is a closed set in $\struct {\R^2, d}$.

By inspection, it can be seen that the image of $A$ under $\rho$ is:
 * $\rho \sqbrk A = \openint \gets 0 \cup \openint 0 \to$

which by Union of Open Sets of Metric Space is Open is open.

Hence the result by definition of closed mapping.