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In 1991, Kapranov and Voevodsky published a proof of a now famously false result, roughly saying that the homotopy category of spaces is equivalent to the homotopy category of strict infinity categories that are weak infinity groupoid.

In 1998 Carlos Simpson showed that their main result could not be true, but did not explain what was precisely wrong in the paper of Kapranov and Voevodsky.

In fact, as explained by Voevodsky here, for a long time after that, Voevodsky apparently thought his proof was correct and that Carlos Simpson made a mistake, until he finally found a mistake in his paper in 2013 !

Despite being false, the paper by Kapranov and Voevodsky contains a lot of very interesting things, moreover, the general strategy of the proof to use Johnson's Higher categorical pasting diagram as generalized Moore path to strictify an infinity groupoid sound like a very reasonable idea and it is a bit of a surprise, at least to me, that it does not work.

In fact when Carlos Simpson proved that the main theorem of Kapranov and Voevodsky's paper was false he conjectured that their proof could allow one to obtain that the homotopy category of spaces is equivalent to the homotopy category of strict non unital infinity category that are weak (unital) infinity groupoid (this is now known as Simpson's conjecture).

So:

Can someone explain what precisely goes wrong in this paper ?

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    $\begingroup$ In a typical mathematician fashion, yes. Someone can explain what is wrong in the paper. The fact someone has claimed to find a mistake, and that mistake has been eventually acknowledged by one of the authors means that at least two people can explain what's wrong. :-) $\endgroup$
    – Asaf Karagila
    Commented Mar 25, 2016 at 12:08
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    $\begingroup$ Well, that is true, but we are only sure for one person in this case : Carlos Simpson only gave a counterexample to the main result and was not sure (at least at the time he wrote his 1998 paper) what was Kapranov and Voevodsky mistakes and what could be salvaged from their paper. $\endgroup$ Commented Mar 25, 2016 at 12:13
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    $\begingroup$ Well. Not being a constructivist I am free to say "Yes, there is such person. But its existence might not be constructive!" ;-) $\endgroup$
    – Asaf Karagila
    Commented Mar 25, 2016 at 12:29
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    $\begingroup$ The way Simpson actually states his conjecture is to say that he thinks that's what the correct parts in Kapranov-Voevodsky actually prove. So Simpson's conjecture is a guess of an answer to your question of what can be salvaged. $\endgroup$ Commented Mar 25, 2016 at 15:22
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    $\begingroup$ I have no idea what goes wrong in the KV paper, but here's why units might be bad. It is because of our arch-enemy, the Eckmann-Hilton argument, which says given a set with two binary unital operations which commute with each other, they are actually both the same commutative monaid law. This shows, for instance, that n-endomorphisms of an object in a strict infinity category always form a commutative monoid, for $n\geq2$. ... $\endgroup$ Commented Mar 25, 2016 at 16:44

4 Answers 4

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Here is my guess. To compare spaces with their notion of strict $\infty$-groupoids (in which everything is strict except inverses) Kapranov and Voevodsky use an intermediate category of Kan diagrammatic sets, which they show to be equivalent to both spaces and strict $\infty$-groupoids (after inverting a suitable collection of weak equivalences). Whatever Kan diagrammatic sets are, they seem to be a non-strict model, and so let's assume that they do form a model for spaces. In this case the mistake must be in the comparison of Kan diagrammatic sets and strict $\infty$-groupoids (Theorem 3.7). This theorem relies on Proposition 3.5 which compares the homotopy groups of a Kan diagrammatic set $X$ and the homotopy groups of the strict $\infty$-groupoid $\Pi(X)$ generated from $X$. This comparison, in turn, is based on Lemma 3.4 which says that any morphism in $\Pi(X)$ can be realized via a single pasting diagram in $X$, which are in some sense the cells of $X$ (since $X$ is a presheaf on pasting diagrams). But this claim doesn't seem to be true, and the reason is that when one generates the $\infty$-groupoid $\Pi(X)$ one doesn't only freely add morphisms, but also identifies pairs of morphisms which are supposed to be the same in a strict $\infty$-category structure. This means, for example, that if two different pasting diagrams coincide after this identification, then the identity morphism between them might not be a pasting diagram in $X$ (or at least, one would have to explicitly argue why this would be the case). The proof of Lemma 3.4 seems to be vague enough to allow for this subtlety to slip. All of this could be wrong of course, but if I had to pick one possibly problematic lemma it would be this Lemma 3.4.

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    $\begingroup$ It is not definitive, but I am quite convinced by your argument. I am going to try to make some computation soon to find examples where this lemma actually fails... it shouldn't be too hard. I was also very intrigued by the fact that the $\Pi$ functor of the paper was a left adjoint, while the informal explanation given in the beginning in terms generalized Moore path suggest it should be a (parametric) right adjoint functor... which is closely related to your answer. $\endgroup$ Commented Mar 31, 2016 at 9:32
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    $\begingroup$ @SimonHenry, The overall functor from spaces to $\infty$-groupoids is a composition of a right adjoint functor from spaces to Kan diagrammatic sets followed by a left adjoint functor $\Pi$ from Kan diagrammatic sets to $\infty$-groupoids. The former is the one which intuitively looks like the Moore path functor, but I suspect the problem is with the latter. $\endgroup$ Commented Mar 31, 2016 at 10:48
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The MathSciNet review (by Julie Bergner) of Simpson's book: Homotopy theory of higher categories, New Mathematical Monographs, 19. Cambridge University Press, Cambridge, 2012, has a note about the counterexample.

REVIEWER'S ADDENDUM (October, 2015): While not explicitly stated as such, this book contains a counterexample of a result of M. M. Kapranov and V. Voevodsky (stated in Uspekhi Mat. Nauk 45 (1990), no. 5(275), 183–184; MR1084995 and presented in Cahiers Topologie Géom. Différentielle Catég. 32 (1991), no. 1, 29–46; MR1130401) that any n-type can be obtained as the realization of a strict n-groupoid. R. Brown and P. J. Higgins proved in Cahiers Topologie Géom. Différentielle 22 (1981), no. 4, 371–386; MR0639048 that the Whitehead products vanish for the realization of a strict n-groupoid, and C. Berger proved in Higher homotopy structures in topology and mathematical physics (Poughkeepsie, NY, 1996), 49–66, Contemp. Math., 227, Amer. Math. Soc., Providence, RI, 1999; MR1665460 that this result holds even if inverses are taken to be weak; the result was also mentioned by Grothendieck in his letter Pursuing Stacks. Simpson's argument in this book shows that, even under a slightly more general realization functor, these results imply that one cannot obtain the 3-type of $S^2$ as the realization of any strict 3-groupoid, contradicting the claim of Kapranov and Voevodsky.

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    $\begingroup$ This should be a comment, not an answer as it does not attempt to point out what the mistake in the paper might be. $\endgroup$ Commented Mar 31, 2016 at 20:24
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    $\begingroup$ @Omar, what with the 600-character limit on comments.... $\endgroup$ Commented Mar 31, 2016 at 21:44
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    $\begingroup$ The Executive Editor for Math Reviews has provided a relevant portion of a review which would otherwise not be freely available to everyone. This seems worthwhile to me, even if it doesn't answer the question fully. Why are people downvoting this answer? $\endgroup$
    – Lucia
    Commented Apr 1, 2016 at 4:00
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It's been more than a year and a half since I asked this question and I had a lot of thought about it so I decided I will post my own answer.

First I entirely agree with Yonatan that the main problem is with lemma 3.4. The specific problem that he mentions appears exactly because of the "degeneracy maps" that are added by Voevodsky and Kapranov to their category of diagrams. More precisely, one can, using the degeneracies, construct a diagrammatic set whose realization will "collapse" because of the Eckman-Hilton argument, and quite interestingly if one modifies their definition so that the category has no degeneracies then this no longer happens (the free $\infty$-category is just obtained by "freely adding arrows" gradually as they assume it behaves in the paper). So if one thinks that degeneracies correspond exactly to units, this is very encouraging for the Simpson conjecture. I haven't been able to make this into a clear counterexample of the lemma, but only because the lemma actually has other problems that appear before that.

In the end, I believe the main obstruction to their proof is the following: the initial idea to use "generalized Moore homotopy" parametrized by some class of diagrams seems (at least intuitively) to need the following two properties of the class of diagrams:

  1. One should be able to formally "compose" the diagrams (and that it corresponds to pushout on the level of geometric realization) so that when you look at all the continuous functions $|D| \rightarrow X$ for all diagrams $D$ you indeed get an $\infty$-category.

  2. That given two "parallel" $n$-diagrams, you can construct an $(n+1)$-diagram whose source and target are the two given $n$-diagrams, so that if two diagram shapes are used to represent homotopically equivalent $n$-arrows then one can actually have an $(n+1)$-arrow that represents this homotopy.

It appears that both these properties fail for the kind of diagrams (Johnson diagrams) they are using! Unfortunately, due to the fact that they actually use a slightly different construction than the one they explain in the introduction, these do not immediately translate into mistakes in their paper.

This being said, they actually seem to use that Johnson diagrams can be composed within the proof of Lemma 3.4 mentioned above, so that it is probably a second reason for which this lemma fails.

It is not clear to me if (and where) they use the second property somewhere, but I expect some property of this kind should be important in order to prove that the geometric realization of diagrammatic sets indeed induces an equivalence with the category of spaces (and they are extremely imprecise about how this equivalence is obtained, they just say that "one does exactly as for simplicial and cubical sets"!).

For more details (and a third reason why Lemma 3.4 fails) I have a very recent preprint (Non-unital polygraphs form a presheaf category) which constructs a category of diagrams that has the two properties mentioned above as soon as you work in a 'non-unital' framework, unfortunately this category of diagrams is a lot more complicated than the category of Johnson diagrams (and it is unique so this complication is unavoidable) and this prevents from using the exact same strategy as they do. I discus in details in the appendix of the paper the proof of Kapranov and Voevodsky (this will expand a lot on this answer) and explain some ideas on how to make it into a proof of the Simpson conjecture using the category of diagrams that I constructed. This new version also has the advantage to make the two ways of explaining the construction (in terms of generalized Moore homotopies and using two adjunctions with a presheaf category of diagrams in the middle) actually equivalent.

Update : In fact, in a subsequent preprint, I did proved a version of the Simpson conjecture using essentially the strategy of Kapranov and Voevodsky with a modified category of diagrams.

Note that there are still some difficulties appearing (due to the increased complexity of the category of diagram) and at the moment I'm still not capable of proving the most general version of the Simpson conjecture. To be precise, at this point I'm only able to strictify a certain set of composition operations, which I call the "regular composition operations", (informally they are those whose pasting diagram is "topologically regular") which are such that any kind of composition operation that you have in an $\infty$-category can be obtained as a regular composition of identities and non identities arrow. So it does gives a notion where you have a bunch of operations that are strictly compatible, and only weak identities on top of that, but one can still hope to find stronger statement with more strict operations.

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    $\begingroup$ Simon, thanks a lot for your answer; thoughtful as always. I think maybe the word "expend" in the last paragraph ought to be "expand", but I'll leave it to you to confirm. $\endgroup$ Commented Nov 29, 2017 at 13:08
  • $\begingroup$ Thank you ! and I'll have to apologize again for my truly awful english writing. $\endgroup$ Commented Nov 29, 2017 at 13:11
  • $\begingroup$ Glad to see this paper finally on the arXiv! $\endgroup$ Commented Nov 29, 2017 at 13:13
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    $\begingroup$ @SimonHenry Thank you for sharing your new insight. $\endgroup$
    – Nik Weaver
    Commented Nov 29, 2017 at 14:02
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For the record, a precise disproof of Lemma 3.4 seems to be in this preprint of Amar Hadzihasanovic Diagrammatic sets and rewriting in weak higher categories. Further recent developments involving diagrammatic sets are gathered in the book Combinatorics of higher-categorical diagrams by the same author, and the preprint Diagrammatic sets as a model of homotopy types by Chanavat and Hadzihasanovic.

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