nLab
model structure on sSet-categories

Contents

Context

Model category theory

$(\infty,1)$ -Category theory

Idea
Model for $(\infty,1)$ -categories
Properties
Related concepts
References

Idea

Depending on the chosen model category structure, the category sSet of simplicial sets may model ∞-groupoids (for the standard model structure on simplicial sets) or (∞,1)-categories in the form of quasi-categories (for the Joyal model structure) on SSet.

Accordingly, there are model category structures on sSet-categories that similarly model (n,r)-categories with $r$ shifted up by 1:

there is a model structure on $SSet$ -enriched categories whose fibrant objects are ∞-groupoid/Kan complex-enriched categories and which models (∞,1)-categories;

This we discuss below.

there is another model structure on sSet-categories whose fibrant objects are (∞,1)-category/quasi-category-enriched categories, and which model (∞,2)-categories.

For more on this see elsewhere

Both are special cases of a model structure on enriched categories.

Model for $(\infty,1)$ -categories

Here we describe the model category structure on SSet Cat that makes it a model for the (∞,1)-category of (∞,1)-categories.

Definition

An sSet-enriched functor $F : C \to D$ between sSet-categories is called a weak equivalence precisely if

it is essentially surjective in that the induced functor of homotopy categories is an ordinary essentially surjective functor;
it is an $\infty$ -full and faithful functor in that for all objects $x,y \in C$ the morphism

$F_{x,y} : C(x,y) \to D(F(x), F(y))$

is a weak equivalence in the standard model structure on simplicial sets.

Such a morphism is also called a Dwyer-Kan weak equivalence after the work by Dwyer-Kan on simplicial localization.

Proposition

A Quillen equivalence $C \stackrel{\leftarrow}{\to} D$ between model categories induces a Dwyer-Kan-equivalence $L C \leftrightarrow L D$ between their simplicial localizations.

Proposition

The category SSet Cat of small simplicially enriched categories carries the structure of a model category with

weak equivalences the Dwyer-Kan equivalences;
fibrations those sSet-enriched functors $F : C \to D$ such that
1. for all $x, y \in C$ the morphism $F_{x,y} : C(x,y) \to D(F(x), F(y))$ is a fibration in the standard model structure on simplicial sets;
2. the induced functor $\pi_0(F) : Ho(C) \to Ho(D)$ on homotopy categories is an isofibration.

(Bergner 04)

Remark

In particular, the fibrant objects in this structure are the Kan complex-enriched categories, i.e. the strictly ∞-groupoid-enriched ones (see (n,r)-category).

Properties

Proposition

The Bergner model structure of prop. is a right proper model category.

(Bergner 04, prop. 3.5)

Related concepts

The entries of the following table display model categories and Quillen equivalences between these that present the (∞,1)-category of (∞,1)-categories (second table), of (∞,1)-operads (third table) and of $\mathcal{O}$ -monoidal (∞,1)-categories (fourth table).

	general pattern
strict enrichment		(∞,1)-category/(∞,1)-operad
$\downarrow$		$\downarrow$
enriched (∞,1)-category	$\hookrightarrow$	internal (∞,1)-category

	(∞,1)Cat
SimplicialCategories	$-$ homotopy coherent nerve $\to$	SimplicialSets/quasi-categories	RelativeSimplicialSets
$\downarrow$ simplicial nerve		$\downarrow$
SegalCategories	$\hookrightarrow$	CompleteSegalSpaces

	(∞,1)Operad
SimplicialOperads	$-$ homotopy coherent dendroidal nerve $\to$	DendroidalSets	RelativeDendroidalSets
$\downarrow$ dendroidal nerve		$\downarrow$
SegalOperads	$\hookrightarrow$	DendroidalCompleteSegalSpaces

	$\mathcal{O}$ Mon(∞,1)Cat
		DendroidalCartesianFibrations

References

A model category structure on the category of $sSet$ -categories with a fixed set of objects was first given in

William Dwyer, Dan Kan, Simplicial localization of categories , J. Pure and Applied Algebra 17 (3) (1980),

Dywer, Spalinski and later Rezk then pointed out that there ought to exist a model category structure on the collection of all $sSet$ -categories that models the (∞,1)-category of (∞,1)-categories. This was then constructed in

Julie Bergner, A model category structure on the category of simplicial categories , Trans. AMS (arXiv:0406507)

A survey is in section 3 of

Julie Bergner, A survey of $(\infty,1)$ -categories (arXiv:math/0610239)

nLab model structure on sSet-categories

Context

Model category theory

Definitions

Morphisms

Universal constructions

Refinements

Producing new model structures

Presentation of (∞,1)(\infty,1)-categories

Model structures

for ∞\infty-groupoids

for rational ∞\infty-groupoids

for nn-groupoids

for ∞\infty-groups

for ∞\infty-algebras

general

specific

for stable/spectrum objects

for (∞,1)(\infty,1)-categories

for stable (∞,1)(\infty,1)-categories

for (∞,1)(\infty,1)-operads

for (n,r)(n,r)-categories

for (∞,1)(\infty,1)-sheaves / ∞\infty-stacks

(∞,1)(\infty,1)-Category theory

Background

Basic concepts

Universal constructions

Local presentation

Theorems

Extra stuff, structure, properties

Models

Contents

Idea

Model for (∞,1)(\infty,1)-categories

Definition

Proposition

Proposition

Remark

Properties

Proposition

Related concepts

References

nLab
model structure on sSet-categories

Presentation of $(\infty,1)$ -categories

for $\infty$ -groupoids

for rational $\infty$ -groupoids

for $n$ -groupoids

for $\infty$ -groups

for $\infty$ -algebras

for $(\infty,1)$ -categories

for stable $(\infty,1)$ -categories

for $(\infty,1)$ -operads

for $(n,r)$ -categories

for $(\infty,1)$ -sheaves / $\infty$ -stacks

$(\infty,1)$ -Category theory

Model for $(\infty,1)$ -categories