Equivalence of Definitions of Component/Union of Connected Sets is Maximal Connected Set

Theorem
Let $T = \struct {S, \tau}$ be a topological space.

Let $x \in T$.

Let $\mathcal C_x = \set {A \subseteq S : x \in A \land A \text{ is connected in } T}$

Let $C = \bigcup \mathcal C_x$

Then $C$ is a maximal connected set of $T$.

Proof
From Union of Connected Sets with Common Point is Connected, $C$ is a connected set of $T$.

Furthermore, $x \in C$.

Hence $C \in \mathcal C_x$.

Let $\tilde C$ be any connected set such that:
 * $C \subseteq \tilde C$

Then $x \in \tilde C$.

Hence $\tilde C \in \mathcal C_x$.

From Set is Subset of Union,
 * $\tilde C \subseteq C$.

It follows that $\tilde C = C$.

Also see

 * Connectedness of Points is Equivalence Relation