Countable Compactness is Preserved under Continuous Surjection

Theorem
Let $T_A = \struct {S_A, \tau_A}$ and $T_B = \struct {S_B, \tau_B}$ be topological spaces.

Let $\phi: T_A \to T_B$ be a continuous surjection.

If $T_A$ is countably compact, then $T_B$ is also countably compact.

Proof
Let $T_A$ be countably compact.

Take a countable open cover $\UU$ of $T_B$.

From Preimage of Cover is Cover, $\VV := \set {\phi^{-1} \sqbrk U: U \in \UU}$ is a cover of $S_A$.

$\VV$ is a countable cover because there it is bijective with $\UU$.

By hypothesis, $\phi$ is continuous.

For all $U \in \UU$, $U$ is open in $T_B$.

It follows that $\forall U \in \UU: \phi^{-1} \sqbrk U$ is open in $T_A$.

So $\VV$ is a countable open cover of $T_A$.

$T_A$ is countably compact, so we take a finite subcover:
 * $\set {\phi^{-1} \sqbrk {U_1}, \ldots, \phi^{-1} \sqbrk {U_n} }$

We have that $\phi$ is surjective.

So from Surjection iff Right Inverse:
 * $\phi \sqbrk {\phi^{-1} \sqbrk A} = A$

So:
 * $\set {\phi \sqbrk {\phi^{-1} \sqbrk {U_1} }, \ldots, \phi \sqbrk {\phi^{-1} \sqbrk {U_n} } } = \set {U_1, \ldots, U_n} \subseteq \UU$

is a finite subcover of $\UU$ on $T_B$.

Also see

 * Compactness Properties Preserved under Continuous Surjection