Quotient Space of Real Line may be Indiscrete

Theorem
Let $\struct {\R, \tau}$ denote the real number line with the usual (Euclidean) topology.

Let $\Q$ be the rational numbers.

Let $\mathbb I$ be the irrational numbers.

Then $\set {\Q, \mathbb I}$ is a partition of $\R$.

Let $\sim$ be the equivalence relation induced on $\R$ by $\set {\Q, \mathbb I}$.

Let $T_\sim := \struct {\R / {\sim}, \tau_\sim} $ be the quotient space of $\R$ by $\sim$.

Then $T_\sim$ is an indiscrete space.

Proof
Let $\phi: \R \to \R/{\sim}$ be the quotient mapping.

Then:
 * $\forall x \in \Q: \map \phi x = \Q$
 * $\forall x \in \mathbb I: \map \phi x = \mathbb I$

$\set {\mathbb I} \in \tau_\sim$.

Then by the definition of the quotient topology:


 * $\O \subsetneqq \mathbb I = \phi^{-1} \sqbrk {\set {\mathbb I} } \in \tau$

Thus by Rationals Dense in Reals, $\mathbb I$ contains a rational number.

This is a contradiction.

$\set \Q \in \tau_\sim$.

Then:
 * $\O \subsetneqq \Q = \phi^{-1} \sqbrk {\set \Q} \in \tau$

Thus by Irrationals Dense in Reals, $\Q$ contains a irrational number.

This is a contradiction.

As $\R / {\sim}$ has exactly two elements, its only non-empty proper subsets are $\set \Q$ and $\set {\mathbb I}$.

As neither of these sets is $\tau_\sim$-open, $\struct {\R / {\sim}, \tau_\sim}$ is indiscrete.