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Background

Model categories are an axiomization of the machinery underlying the study of topological spaces up to homotopy equivalence. They consist of a category $C$, together with three distinguished classes of morphism: Weak Equivalences, Fibrations, and Cofibrations. There are then a series of axioms this structure must satisfy, to guarantee that the classes behave analogously to the topological maps they are named after. The axioms can be found here.

(As far as I know...) The main practical advantage of this machinery is that it gives a rather concrete realization of the localization category $C/\sim$ where the Weak Equivalences have been inverted, which generalizes the homotopy category of topological spaces. The main conceptual advantage is that it is a first step towards formalizing the concept of "a category enriched over topological spaces".

A discussion of examples and intuition can be found at this question.

The Question

The examples found in the answers to Ilya's question, as well as in the introductory papers I have read, all have a model category structure that could be expected. They are all examples along the lines of topological spaces, derived categories, or simplicial objects, which are all conceptually rooted in homotopy theory and so their model structures aren't really surprising.

I am hoping for an example or two which would elicit disbelief from someone who just learned the axioms for a model category. Along the lines of someone who just learned what a category being briefly skeptical that any poset defines a category, or that '$n$-cobordisms' defines a category.

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  • $\begingroup$ Great question. I have also wondered this in the past. $\endgroup$ Commented Mar 16, 2010 at 22:29
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    $\begingroup$ Why would someone be skeptical that a poset defines a category? $\endgroup$ Commented Mar 17, 2010 at 15:22
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    $\begingroup$ "Why would someone be skeptical that a poset defines a category?"-- for the same reason that they would be skeptical that a group defines a category. Usually when people first encounter categories they are given examples like the category of sets or vector spaces. These are places that mathematics happens. This at first seem very different than things like groups and posets which are usually the objects of study, not the context. $\endgroup$ Commented Mar 17, 2010 at 19:12
  • $\begingroup$ posted to the arxiv six days ago: arxiv.org/abs/2101.03591 . Category of reflexive presentations of monoids is a model category with tietze transformations as trivial cofibrations. Its homotopy ctegory is isomorphic to the category of monoids. $\endgroup$ Commented Jan 16, 2021 at 17:26

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Here is an example that surprised me at some time in the past. Bisson and Tsemo introduce a nontrivial model structure on the topos of directed graphs. Here a directed graph is simply a $4$-tuple $(V,E,s,t)$ where an arc $e \in E$ starts at $s(e) \in V$ and ends at $t(e) \in V$. Fibrations are maps that induce a surjection on the set of outgoing arcs of each vertex, cofibrations are embeddings obtained by attaching a bunch of trees, and weak equivalences are maps that induce a bijection on the sets of cycles.

In this model structure fibrant objects are graphs without sinks and cofibrant objects are graphs with exactly one incoming arc for every vertex. Cofibrant replacement replaces a graph by the disjoint union of its cycles with the obvious morphism into the original graph.

We have a chain of inclusions of categories $A\to B \to C\to D$, where $D$ is the topos of directed graphs, $C$ is the full subcategory of $D$ consisting of all graphs with exactly one incoming arc for each vertex, $B$ is the full subcategory of $C$ consisting of all graphs with exactly one outgoing arc for each vertex, and $A$ is the full subcategory of $B$ consisting of all graphs such that $s=t$.

Each functor is a part of a Quillen adjunction and total left and right derived functors compute nontrivial information about graphs under consideration.

Two finite graphs are homotopy equivalent iff they are isospectral iff their zeta-functions coincide.

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  • $\begingroup$ Excellent, thats exactly the kind of example I was looking for. Do you happen to know if this model structure is something more familiar, if one thinks of the directed graphs in terms of the associated quiver? $\endgroup$ Commented Mar 16, 2010 at 13:51
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    $\begingroup$ The name is Tsemo, not Tserno. $\endgroup$ Commented Mar 16, 2010 at 15:44
  • $\begingroup$ @Greg: I have no idea whether this model structure can be related in any way to quivers. $\endgroup$ Commented Mar 16, 2010 at 19:27
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    $\begingroup$ The fibrations in this model structure at least are not surprising: they are very similar to the fibrations in the canonical (or folk) model structure on Cat. $\endgroup$
    – David Roberts
    Commented Jan 10, 2011 at 4:41
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The category of sets admits precisely nine model category structures, no more no less.

I learned this fact from Tom Goodwillie's comments on a different MO question. It always shocks people when I mention it to them, so I guess it is surprising. I am not sure which is more surprising, that you can actually compute all the model structures or that there are exactly nine of them. Working out the details is such a fun exercise that I don't want to spoil the fun here.

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    $\begingroup$ This is just great! $\endgroup$ Commented Mar 12, 2012 at 23:11
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There is a preprint (arXiv) by Finnur Larusson explaining a model structure on equivalence relations. From the abstract:

We give a detailed exposition of the homotopy theory of equivalence relations, perhaps the simplest nontrivial example of a model structure.

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There is a series of paper by Philippe Gaucher on the arxiv that deal with model categories in the context of theoretical computer science. E.g.:

  • Abstract homotopical methods for theoretical computer science (0707.1449)

The purpose of this paper is to collect the homotopical methods used in the development of the theory of flows initialized by author's paper ``A model category for the homotopy theory of concurrency''.

  • A model category for the homotopy theory of concurrency (math/0308054)

We construct a cofibrantly generated model structure on the category of flows such that any flow is fibrant and such that two cofibrant flows are homotopy equivalent for this model structure if and only if they are S-homotopy equivalent. This result provides an interpretation of the notion of S-homotopy equivalence in the framework of model categories.

I guess it is just because of my ignorance, but to me this was unexpected.

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(more detail on the answer by mmm: Gavrilovich in http://arxiv.org/abs/1006.4647 and then further works of Gavrilovich and Hasson http://arxiv.org/abs/1102.5562 and then Gavrilovich, Hasson and Kaplan http://arxiv.org/abs/1111.3489 explore in depth connections with pcf theory (a part of set theory, one could say) - in particular, they recover Shelah's covering number $cov(\lambda, \aleph_1,\aleph_1, 2)$)... How surprising it is depends (I guess) on how much you are used to "detect" homotopic content in areas where it was seemingly not present.

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Here is an example of a poset which is a model category. The construction is set-theoretic and mentions Continuum Hypothesis.

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  • $\begingroup$ The link is broken. $\endgroup$
    – Rasmus
    Commented May 7, 2012 at 17:12
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There is Krause and Nikolaus' model structure on the category of group presentations whose homotopy category is the category of groups.

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  • $\begingroup$ I'm not sure this is surprising if you know the general construction of model structures from (co)reflective subcategories... (The "classical" category of groups is a reflective subcategory of this category of group presentations.) $\endgroup$
    – Zhen Lin
    Commented May 3, 2023 at 7:34
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    $\begingroup$ @ZhenLin Sure. Model structures are like elephants -- if one of them is sneaking up on you, you probably will notice it coming from some distance away, before it actually reaches out and tags you with its trunk. This one is like the elephant who paints its toenails rainbow colors and approaches through a river of M & M 's to get the jump on us. By the way, under what conditions exactly does a reflective subcategory give rise to a model structure? $\endgroup$ Commented May 4, 2023 at 14:49
  • $\begingroup$ I thought this was well known. Basically the idea is to construct it as a left Bousfield localisation of the trivial (= discrete) model structure. The local equivalences are the morphisms inverted by the reflector. It is always the case that reflective subcategories are localisations, so the only thing to check is that we have the factorisations needed. This part I do not have a completely general argument for, but probably when the category is locally presentable and the reflector is accessible we can use Smith's theorem. If the reflector preserves (some) pullbacks we can do it by hand. $\endgroup$
    – Zhen Lin
    Commented May 5, 2023 at 1:46

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