Proof

We establish the hom-isomorphism of the adjunction and its construction by the unit of the adjunction: For any $Z \in Alg C$ and $\phi : X \to U(Z)$ any morphism in $C$, we need to show that there is a unique commuting diagram

Since by assumption $Z$ has all fillers we have commuting diagrams

By the universality of the pushout these induce unique morphisms

By induction this induces morphisms $\phi_n : X_n \to Z$ that form a cocone under $(X \to X_1 \to X_2 \to \cdots )$. Therefore there is a unique morphusm $\phi_\infty$ as indicated.

Proof

Since $F$ is left adjoint to $U$ the condition that $F A_j \to F B_j \stackrel{r}{\to} F A_j$ is the identity is equivalent to its adjunct, the diagonal in

being the unit of the adjunction $A_j \to U F A_j$. Take $\tilde r$ to be the (unique) filler for this morphism.

Proof

By one of the equivalent statements of Beck's monadicity theorem we have to check that

1. $U$ has a left adjoint,
2. $U$ reflects isomorphisms (i.e. it is conservative), and
3. $D$ has, and $U$ preserves, coequalizers of $U$-split pairs.

The first item we already checked above.

For the second item it is sufficient to observe that if $f : X \to Y$ is a morphism in $Alg C$ such that $U f$ has an inverse $g : U Y \to U X$, then it follows that $g$ must preserve fillers, hence itself constitutes the underlying morphism of an inverse if $f$ in $Alg C$.

For the third item, let $f,g : X \to Y$ be two morphisms in $Alg C$ such that the coequalizer

exists in $C$, together with sections $s$ of $\pi$ and $t$ of $U(f)$ such that $s \circ \pi = U(t) \circ t$. We need to equip $Q$ with fillers such that it becomes the coequalizer of $f,g$ in $Alg C$.

For $h : A_j \to Q$ a horn, declare that its filler is the the chosen filler of $s \circ h$

We check now that this choice indeed makes $Q$ the coequalizer in $Alg C$.

First of all we need to check that $\pi$ preserves the chosen fillers.

So given a filler

it is sent by $\pi$ to the filler

of $\pi k$. This is supposed to be the same as

Now use the relation $U(f) t = Id$ to rewrite the first diagram equivalently as

and the relation $U(g) t = s \pi$ to rewrite the second diagram equivalently as

This show that the fillers $\hat k$ and $\hat r$ are images under $U(f)$ and $U(g)$, respectively, of a single filler in $X$. Since $\pi$ coequalizes, it follows that $\pi \hat k = \pi \hat r$.

Finally we need to show that the coequalizing morphism $\pi$ in $Alg C$ thus established is indeed universal with this property.

For $\phi : Y \to Z$ a coequalizing morphism in $Alc C$, the fact that $Q$ is a coequalizer in $C$ already gives a unique morphism $\phi_Q$ in

So it is sufficient to observe that $\phi_Q$ preserves chosen fillers. But this is true be the above construction, which says that the chosen fillers in $Q$ are the images of the chosen fillers in $Y$.

Proof

Let $H$ be the set of morphisms of the form $h : A_j \to X$ that factor through $f : Y \to X$. For each $h \in H$ let $F_h$ be the set of images of distinuished fillers $B_j \to X$.

Set

where on the right we take the colimit over the diagram with one object $(B_j)_h$ per morphism $h : A_j \to X$ that factors through $Y$, and one morphism $(B_j)_h \to X$ per induced distinguished filler obtained from a choice of factorization through $Y$.

This comes with a canonica cocone-morphism $X \to X_H$. Continue this way to build $X_{H'}$ by coequalizing the different ways morphisms into $X_H$ may factor through $X$, etc. to obtain a sequence

and set

Notice that if $f$ is a monomorphism then all factorizations are unique and hence $X \to X_0^f$ is an isomorphism.

The object $X_0^f$ can be seen to have the desired universal factorization property. But it may not yet be itself algebraically fibrant. So we conclude by essentially applying the construction of the left adjoint $F$. But we start with letting $X_1^f$ be the pushout

where now the coproduct is over all morphisms that do not factor through $Y$. After that we proceed exactly as we did for the construction for $F$ and obtain a sequence

Finally we set

One checks that this has the claimed properties (…).

As before, the inclusion $X_0^f \to X_\infty^f$ is an acyclic cofibration. Hence by the above remarks in the case that $f$ is a monomorphism also $X \to X_\infty^f$ is an acyclic cofibration.

Proof

Consider first limits: for $K : J \to Alg C$ a diagram and $\lim_{\leftarrow} U K$ its limit in $C$, let $A_j \to \lim_{\leftarrow} U K$ be a horn. Since all the composite maps $A_J \to \lim_{\leftarrow} U K \to U K(j)$ have distinguished fillers and since the morphisms between these respect these fillers, we get a cone of fillers with tip $B_j$ over $U K$. The universal cone morphism $B_j \to \lim_{\leftarrow} U K$ provides then a distinguished filler for the limit. By the same argument, any cone $const_T \to \lim_{\leftarrow} U K$ in $Alg_C$ whose underlying cone in $C$ is a limiting cone is also limiting in $Alg C$.

Now consider filtered colimits. By assumption the domains $A_j$ are small objects. Therefore for $K : I \to C$ a filtered diagram and $L := \lim_{\to} K$ its filtered colimit, any morphism $A_j \to L$ factors through one of the $K_i$. This provides a filler $B_j \to K_i \to L$. Observe that while neither $i$ nor the filler $B_j \to K_i$ are uniquely determined, its image in $L$ is. This makes $L$ an object in $Alg C$. By the same argument one finds that it is the universal cocone under $K$ in $Alg C$.

Now for $K : J \to Alg C$ a general diagram with colimit $X := \lim_\to U K$ in $C$, we use the above fact that $U$ is a solid functor to deduce that $X_\infty^f$ is the colimit of $K$ in $Alg C$.

Proof

First check that $(B \coprod_A U Y)_\infty^f$ has the universal property of the pushout: for any $Z \in Alg C$ we have by the above proposition that morphisms $(B \coprod_A U Y)_\infty^f \to Z$ are in bijection to morphisms $B \coprod_A U Y \to U Z$ in $C$ such that the composition

preserves distinguished fillers.

This in turn is the same as a morphism $g_1 : Y \to Z$ in $Alg C$ and a morphism $g_2 : B \to U Z$ in $C$ that agree on $A$. By adjunction $(F \dashv U)$ this corresponds to an adjunct $\tilde g_2: F B \to Z$. This establishes the pushout property of $(B \coprod_A U Y)_\infty^f$.

To show that $Y \to (B \coprod_A U Y)_\infty^f$ is an acyclic cofibration of $i : A \to B$ is, recall that this morphism is the composite

Here the first morphism $f$ is an acyclic cofibration because it is the pushout of the acyclic cofibration $i$. Therefore by assumption $f$ is a monomorphism and by the remarks in the solidity lemma the morphism $B \coprod_A U Y \to (B \coprod_A U Y)_\infty^f$ is an acyclic cofibration. Hence so is the composite of the two.

Proof

This follows from the above result that $U$ is a solid functor as described in detail at solid functor by observing that the acyclicity condition required there follows as in the discussion of the solidity of $U$ above, using the assumption that all acyclic cofibrations in $C$ are monomorphisms.

We spell out the argument, following (Nikolaus).

By the conditions listed at transferred model structure it is sufficient to check that

1. $U$ preserves small object, which is the case in particular if it preserves filtered colimits;

2. $U$ sends sequential colimits of pushouts of images under $F$ of generating acyclic cofibrations to weak equivalences.

The first item is true by the above discussion of filtered colimits in $Alg C$.

That the second item holds follows from the above pushout lemma which asserts that $U$-images of pushouts of $F$-images of generating acyclic cofibrations are acylic cofibrations, and again by the fact that $U$ preserves filtered colimits, which implies that it preserves the transfinite composition of these acyclic cofibrations.

Proof

We observe that the unit and counit of $(F \dashv U)$ are both weak equivalences:

the unit of the adjunction is $X \to X_\infty$ is by the above construction a transfinite composition of acyclic cofibrations (in fact a fibrant replacement) hence in particular a weak equivalence. Moreover, the unit is a section of the counit in that

Hence by 2-out-of-3 also $X \to F X$ is a weak equivalence.

This implies that $(F \dashv U)$ induces an equivalence of categories on the homotopy categories. Since $R$ equals its total right derived functor (since every object in $Alg C$ is fibrant) this means that $(F \dashv)$ is a Quillen equivalence.

Proof

By the above we know that $Alg C$ is the category of algebras over a monad $U\circ F : C \to C$.

We invoke the theorem on local presentability of categories of algebras discussed at locally presentable category. This says that it is sufficient to check that $U \circ F$ is an accessible functor, hence that it preserves filtered colimits. Now $F$ is a left adjoint and hence preserves all colimits, while we checked above that $U$ preserves filtered colimits.