Quotient Theorem for Epimorphisms

Theorem
Let $\left({S, \circ}\right)$ and $\left({T, *}\right)$ be algebraic structures.

Let $\phi: \left({S, \circ}\right) \to \left({T, *}\right)$ be an epimorphism.

Let $\mathcal R_\phi$ be the equivalence induced by $\phi$.

Let $S / \mathcal R_\phi$ be the quotient of $S$ by $\mathcal R_\phi$.

Let $q_{\mathcal R_\phi}: S \to S / \mathcal R_\phi$ be the quotient mapping induced by $\mathcal R_\phi$.

Let $\left({S / \mathcal R_\phi}, {\circ_{\mathcal R_\phi}}\right)$ be the quotient structure defined by $\mathcal R_\phi$.

Then:


 * The induced equivalence $\mathcal R_\phi$ is a congruence relation for $\circ$
 * There is one and only one isomorphism $\psi: \left({S / \mathcal R_\phi}, {\circ_{\mathcal R_\phi}}\right) \to \left({T, *}\right)$ which satisfies $\psi \bullet q_{\mathcal R_\phi} = \phi$.


 * where, in order not to cause notational confusion, $\bullet$ is used as the symbol to denote composition of mappings.

Also known as
Some authors call this the Factor Theorem for Epimorphisms.