Proof

First observe that if $(c,\xi :Tc\to c)$ is a $T$-algebra, then $\xi$ is the coequalizer of the reflexive fork

To show $C^T$ has coproducts, let $(c_i,{\xi }_i)$ be a collection of algebras. Then $F({\sum }_{i}U{c}_i)$ is the coproduct ${\sum }_{i}FU{c}_i$ in $C^T$ (since $F$ preserves coproducts and $C$ has them). We have a reflexive fork

and it is not difficult to show that the coequalizer in $C^T$ of this diagram is the coproduct ${\sum }_i{c}_i$.

Finally, general coequalizers in $C^T$ are constructed from coproducts and reflexive coequalizers: given a parallel pair $f,g:c\overrightarrow{\to }d$ in $C^T$, the coequalizer of $f$ and $g$ is the colimit of the reflexive fork

where the first arrow is the coproduct coprojection.

Proof

It is enough to show that ${\mathrm{Set}}^T$ has coequalizers. Suppose given a pair of algebra maps $f,g:A\overrightarrow{\to }B$ whose coequalizer we wish to construct. Let $R$ be the $T$-algebra relation

and then let $E$ be the smallest $T$-congruence (equivalence relation that is a $T$-subalgebra map $E\hookrightarrow B\times B$) through which $R$ factors. (This is the intersection of all $T$-congruences through which $R$ factors, and may be calculated in $\mathrm{Set}$, where it is reflected in $T$-$\mathrm{Alg}$.) The coequalizer as calculated in $\mathrm{Set}$,

is a split coequalizer, because every quotient of an equivalence relation in $\mathrm{Set}$ is a split coequalizer. (This requires the axiom of choice. A splitting is given by any splitting $i:Q\to B$ of $p$, which picks a representative in each equivalence class, together with $⟨ip,1⟩:B\to E$.) It is therefore an absolute colimit, which the monad $T$ preserves. Hence the top row in

(the first two vertical arrows being algebra structure maps) is a coequalizer in ${\mathrm{Set}}^T$. The last vertical arrow making the diagram commute gives $Q$ a $T$-algebra structure, and the split coequalizer in the bottom row is reflected in ${\mathrm{Set}}^T$.

Proof

Since the following diagram is commutative:

(using an obvious notation), it follows immediately from a corollary to the adjoint lifting theorem that if $C^T$ has coequalizers of reflexive pairs, then $C^{\theta }$ has a left adjoint and is, in fact, monadic.

This completes the proof, but it is interesting to observe that there is a concrete description of the left adjoint in this case: The left adjoint sends an $S$-algebra $(c,\xi :Sc\to c)$ to the (reflexive) coequalizer of the pair

where $\mu :TT\to T$ is the monad multiplication. (If $u:1_C\to S$ is the unit of $S$, then $Tuc:Tc\to TSc$ is a common right inverse of both arrows of the pair.) This coequalizer is analogous to the construction of the left adjoint $B{\otimes }_A-$ to the functor ${\mathrm{Ab}}^f:{\mathrm{Ab}}^B\to {\mathrm{Ab}}^A$ between module categories given by restricting scalar multiplication; the coequalizer will be denoted $T{\circ }_{S}c$ to underline the analogy.

To see that $T{\circ }_S-$ is the left adjoint, let $(d,\alpha :Td\to d)$ be a $T$-algebra. Any map $f:c\to d$ in $C$ induces a unique $T$-algebra map $\varphi :Tc\to d$:

and the claim is that $f:c\to d$ is an $S$-algebra map $c\to C^{\theta }(d)$ if and only if $\varphi$ coequalizes the pair of above, i.e., if $\varphi$ factors (uniquely) through a $T$-algebra map $T{\circ }_{S}c\to d$.

Indeed, the condition that $f$ is an $S$-algebra map is satisfaction of the equation

and now we have a long train of equations

which gives $\varphi \circ \mu c\circ T\theta c=\varphi \circ T\xi$. This completes one direction. In the other direction, suppose $\varphi \circ \mu c\circ T\theta c=\varphi \circ T\xi$. Then

as desired. This completes the proof.