nLab
factorization lemma

Context

Model category theory

Homotopy theory

Idea
Statement
Corollaries
Examples
References

Idea

The factorization lemma is a fundamental tool in categories of fibrant objects (dually: of cofibrant objects). It mimics the factorization axioms in a model category.

Statement

Let $C$ be a category of fibrant objects.

Lemma

Every morphism $f : X \to Y$ in $C$ factors as

f : X \overset{i_{≃}}{\to} \hat{X} \overset{p}{\to} Y,

where

$i$ is a right inverse to a trivial fibration, hence in particular a weak equivalence;
$p$ is a fibration.

Proof

Let $Y \overset{≃}{\to} Y^{I} \overset{(d_{0}, d_{1})}{\to} Y \times Y$ be a path space object for $Y$ . Let $\hat{X} : = Y^{I} \times_{Y} X$ be the pullback of $f$ along one of its legs, to get the diagram

\begin{matrix} \hat{X} & \to & X \\ ↓ & ↓^{f} \\ Y^{I} & \overset{d_{1}}{\to} & Y \\ ^{d_{0}} ↓ \\ Y \end{matrix} .

Take $p$ to be the composite vertical morphism here:

p : \hat{X} \to Y^{I} \overset{d_{0}}{\to} Y .

To see that this is indeed a fibration, notice that, by the pasting law, the above pullback diagram can be refined to a double pullback diagram as follows

\begin{matrix} \hat{X} & \overset{}{\to} & X \times Y & \overset{p_{1}}{\to} & X \\ ↓ & ↓^{(f, Id)} & ↓^{f} \\ Y^{I} & \overset{(d_{0}, d_{1})}{\to} & Y \times Y & \overset{p_{1}}{\to} & Y \\ ↓^{d_{1}} & ↙_{p_{2}} \\ Y \end{matrix} .

Both squares are pullback squares. Since pullbacks of fibrations are fibrations, the morphism $\hat{X} \to X \times Y$ is a fibration. Similarly, since $Y$ is assumed to be fibrant, also the projection map $p_{i} : Y \times Y \to Y$ is a fibration.

Since $p$ is therefore the composite

\begin{aligned} p & : \hat{X} \to X \times Y \overset{(f, Id)}{\to} Y \times Y \overset{p_{2}}{\to} Y \end{aligned}

of two fibrations, it is itself a fibration.

Next, by the axioms of path space objects in a category of fibrant objects that $d_{1} : Y^{I} \to Y$ is a trivial fibration. Since these are stable under pullback, also $\hat{X} \to X$ is a trivial fibration.

But, by the axioms, $Y^{I} \to Y$ has a right inverse $Y \to Y^{I}$ . By the pullback property this induces a right inverse of $\hat{X} \to X$ fitting into a pasting diagram

\begin{matrix} X & \to & \hat{X} & \to & X \\ ^{f} ↓ & ↓ & ↓^{f} \\ Y & \to & Y^{I} & \overset{d_{1}}{\to} & Y \\ _{Id} ↘ & ^{d_{0}} ↓ \\ Y \end{matrix} .

That establishes the claim.

Corollaries

Corollary

Let $F : C \to D$ be a functor from a category of fibrant objects to any category with weak equivalences that sends trivial fibrations to weak equivalences. Then this functor necessarily sends all weak equivalences to weak equivalences, hence is a homotopical functor.

Proof

If $f : X \to Y$ is a weak equivalence, then by 2-out-of-3 also the $p : \hat{X} \to Y$ from the above proof is a weak equivalence, hence a trivial fibration.

Apply the functor $F$ to the diagram of the above proof

\begin{matrix} F (\hat{X}) & \to & F (X) \\ ↓ & ↓^{F (f)} \\ F (Y^{I}) & \overset{F (d_{1})}{\to} & F (Y) \\ ^{F (d_{0})} ↓ \\ F (Y) \end{matrix} .

By the assumption that $F$ preserves trivial fibrations we have that both horizontal morphisms as well as the total vertical morphism and the bottom vertical morphism are weak equivalences. By 2-out-of-3 it then follows that also the top left vertical morphism is a weak equivalence and then finally that $F (f)$ is.

Remark

If $C$ is the full subcategory of fibrant objects in a model category, then this corollary asserts that a right Quillen functor $F$ , which by its axioms is required only to preserve fibrations and trivial fibrations, preserves also weak equivalences between fibrant objects.

Corollary

Let $A \to C \leftarrow B$ be a diagram between fibrant objects in a model category. Then the ordinary pullback $A \times_{C}^{h} B$

\begin{matrix} A \times_{C}^{h} B & \to & C^{I} \\ ↓ & ↓ \\ A \times B & \to & C \times C \end{matrix}

presents the homotopy pullback of the original diagram.

See the section Concrete constructions at homotopy pullback for more details on this.

Examples

For $G$ an ∞-group object in $C$ with delooping $B G$ , applying the factorization lemma to the point inclusion $* \to B G$ yields a morphism $* \overset{≃}{\to} E G \overset{p}{\to} B G$ . This exhibits a universal principal ∞-bundle for $G$ .

References

For instance page 4 of

Kenneth Brown, Abstract Homotopy Theory and Generalized sheaf Cohomology .

Revised on February 25, 2012 02:40:44 by Stephan Alexander Spahn (79.219.122.169)

nLab factorization lemma

Context

Model category theory

Definitions

Morphisms

Universal constructions

Refinements

Producing new model structures

Presentation of (∞,1)-categories

Model structures

for ∞-groupoids

for n-groupoids

for ∞-groups

for ∞-algebras

general

specific

for stable/spectrum objects

for (∞,1)-categories

for stable (∞,1)-categories

for (∞,1)-operads

for (n,r)-categories

for (∞,1)-sheaves / ∞-stacks

Homotopy theory

Background

Variations

Definitions

Paths and cylinders

Homotopy groups

Theorems

Contents

Idea

Statement

Lemma

Proof

Corollaries

Corollary

Proof

Remark

Corollary

Examples

References

nLab
factorization lemma

Presentation of $(∞, 1)$ -categories

for $∞$ -groupoids

for $n$ -groupoids

for $∞$ -groups

for $∞$ -algebras

for $(∞, 1)$ -categories

for stable $(∞, 1)$ -categories

for $(∞, 1)$ -operads

for $(n, r)$ -categories

for $(∞, 1)$ -sheaves / $∞$ -stacks