Metacategory Induces Morphisms-Only Metacategory

Theorem
Let $\mathbf C$ be a metacategory.

Then the collection of morphisms $\mathbf C_1$ of $\mathbf C$ is a morphisms-only metacategory.

Proof
In order to check that $\mathbf C_1$ is a morphisms-only metacategory, we need to interpret the symbols $\operatorname{dom}$, $\operatorname{cod}$ and $R_\circ$.

Set $\operatorname{dom} x := \operatorname{id}_{\operatorname{dom} x}$, and $\operatorname{cod} x := \operatorname{id}_{\operatorname{cod} x}$ with the symbols on the right as defined in $\mathbf C$.

Further, put $\map {R_\circ} {x, y, z} \iff x \circ y = z$.

Now we can proceed to verify the axioms for a morphisms-only metacategory.

For $(MOCT0)$, that is (omitting universal quantifiers):


 * $\paren {\map {R_\circ} {x, y, z} \land \map {R_\circ} {x, y, z'} } \implies z = z'$

we conclude that the antecedent holds iff $z = x \circ y = z'$, hence $(MOCT0)$ holds.

The content of $(MOCT1)$ is:


 * $\operatorname{dom} x = \operatorname{cod} y \iff \exists z: \map {R_\circ} {x, y, z}$

This says that a composite morphism $x \circ y$ is defined $x$ and $y$ are composable morphisms.

Axiom $(MOCT2)$ is the statement:


 * $\map {R_\circ} {x, y, z} \implies \paren {\operatorname{dom} z = \operatorname{dom} y \land \operatorname{cod} z = \operatorname{cod} x}$

which prescribes the domain and codomain of $x \circ y$.

It follows directly from axiom $(C1)$ for metacategories that this is satisfied by $\mathbf C_1$.

Axiom $(MOCT3)$ is:


 * $\map {R_\circ} {x, y, a} \land \map {R_\circ} {y, z, b} \implies \paren {\exists w: \map {R_\circ} {x, b, w} \land \map{R_\circ} {a, z, w} }$

which expresses that $\circ$ is an associative operation, exactly as axiom $(C3)$ for metacategories specifies.

Finally, axiom $(MOCT4)$ is the statement:


 * $\map {R_\circ} {x, \operatorname{dom} x, x} \land \map {R_\circ} {\operatorname{cod} x, x, x}$

which will hold :
 * $x \circ \operatorname{id}_{\operatorname{dom} x} = x$

and:
 * $\operatorname{id}_{\operatorname{cod} x} \circ x = x$

This is the content of axiom $(C2)$ for metacategories.

Having verified the axioms, we conclude $\mathbf C_1$ to be a morphisms-only metacategory.

Also see

 * Morphisms-Only Metacategory Induces Metacategory
 * Morphisms-Only Metacategory
 * Characterization of Metacategory via Equations