Quotient Topological Vector Space is Hausdorff iff Linear Subspace is Closed/Proof 1

Proof
Let $\pi : X \to X/N$ be the quotient mapping.

Necessary Condition
Suppose that $\struct {X/N, \tau_N}$ is Hausdorff.

From Characterization of Hausdorff Topological Vector Space, $\set { {\mathbf 0}_{X/N} }$ is closed in $\struct {X/N, \tau_N}$.

From the definition of the quotient topology, $\pi$ is continuous.

Hence $\pi^{-1} \sqbrk {\set { {\mathbf 0}_{X/N} } }$ is closed in $\struct {X, \tau}$.

From Kernel of Quotient Mapping, we have $\pi^{-1} \sqbrk {\set { {\mathbf 0}_{X/N} } } = N$.

Hence $N$ is closed in $\struct {X, \tau}$.

Sufficient Condition
Suppose that $N$ is closed in $\struct {X, \tau}$.

Then $X \setminus N$ is open in $\struct {X, \tau}$.

From Quotient Mapping on Quotient Topological Vector Space is Open Mapping, $\pi$ is an open mapping.

Hence $\pi \sqbrk {X \setminus N}$ is open in $\struct {X/N, \tau_N}$.

Since $\pi$ is surjective by construction and $\pi^{-1} \sqbrk {\set { {\mathbf 0}_{X/N} } } = N$, we have:
 * $\pi \sqbrk {X \setminus N} = \paren {X/N} \setminus \set { {\mathbf 0}_{X/N} }$

So $\paren {X/N} \setminus \set { {\mathbf 0}_{X/N} }$ is open in $\struct {X/N, \tau_N}$.

So $\set { {\mathbf 0}_{X/N} }$ is closed in $\struct {X/N, \tau_N}$.

From Characterization of Hausdorff Topological Vector Space, we have that $\struct {X/N, \tau_N}$ is Hausdorff.