Exciting News on Three Dimensional Manifolds

The Virtually Haken Conjecture

A Haken 3-manifold is a compact 3-dimensional manifold M which is irreducible (in a certain strong sense) but contains an incompressible surface S. (An embedded surface S is incompressible if the embedding indices an injection of its fundamental group to the fundamental group of M. A 3-manifold is virtually finite Haken  if it has a finite cover which is Haken. (This is a typical way how the word “virtually” occurs in algebra and topology.)

The virtually Haken conjecture states that every compact, orientable, irreducible 3-dimensional manifold with infinite fundamental group is virtually Haken. The big news is that Ian Agol has just announced the proof of the virtually Haken conjecture!

Danny Calegary have just wrote three detailed posts about it over his blog “Geometry and the Imagination”:  Agol’s Virtual Haken Theorem (part 1),  Agol’s Virtual Haken Theorem (part 2): Agol-Groves-Manning strike back, and Agol’s Virtual Haken Theorem (part 3): return of the hierarchies. (Everything I say is taken from there.)

To quote Danny:

I think it is no overstatement to say that this marks the end of an era in 3-manifold topology, since the proof ties up just about every loose end left over on the list of problems in 3-manifold topology from Thurston’s famous Bulletin article (with the exception of problem 23 — to show that volumes of closed hyperbolic 3-manifolds are not rationally related — which is very close to some famous open problems in number theory).

Here are also few relevant posts from the blog: Low dimensional topology. A post about Wise conjecture  (that Agol proved)  with references and links;   An earlier post on Wise’s work; A post VHC post; Update (August ’14): Here is a post by Tim Gowers on Agol’s lecture at ICM2014. The videotaped lecture can be found here. Ian’s ICM paper can be found here. Dani Wises’s ICM talk is here.

Problems 16-18 in Thurston’s Bulletin paper.

A whole array of conjectures and a whole array of results: Wise, Haglund-Wise, Bergeron-Wise, Sageev, Kahn-Markovic, …

Perleman’s geometrization theorem reduces the conjecture to the case of hyperbolic manifolds. There were a whole list of related conjectures, and people had some beliefs about which conjectures are stronger. The works of Dani Wise (Done, in part, while he was visiting us at the Hebrew University!) proved various unexpected connections between these conjectures, and gave hope that the picture will be completely clarified.

Another crucial work is the proof by Vladimir Markovic and Jeremy Kahn  of the surface subgroup conjecture, that every complete hyperbolic 3-manifold M contains a closed \pi_1-injective surface. Equivalently, \pi_1(M) contains a closed surface subgroup. (Lewis Bowen had, some years ago, an incomplete proof with many good influential ideas.) Markovic and Kahn proved  (as discussed on Danny Calegary’s blog in 2009) the conjecture by showing that every closed hyperbolic 3-manifold contains many immersed surfaces S which are very nearly totally geodesic, and whose fundamental group therefore injects into that of M.

So this is a great event.

One additional thing that appeals to me is that cubical complexes (not only in three dimension!) are crucial, and so is the theory of CAT spaces described by combinatorial properties of cubical complexes.

More from Thurston’s paper:

A nice moment in mathematics

To our readers: After you practiced the meaning of virtually -P, you need to move to the term “residually-X” . And then you are almost ready for LERF (= locally extended residually finite)!

 

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2 Responses to Exciting News on Three Dimensional Manifolds

  1. Danny Calegari says:

    Dear Gil – in your first paragraph, second line from the end, you wrote “virtually finite” where you meant to write “virtually Haken”.

    best,

    Danny

    Thanks, Danny, corrected, Gil

  2. Danny Calegari says:

    By the way, I agree with you that one of the great things about the proof is that it makes use of methods (very high dimensional CAT(0) complexes) which are not at all related on the face of it to 3-dimensional topology. However (and this is a crucial point) they are perfectly suited to study *codimension 1* geometry/topology. This is one of the amazingly rich features of 3-manifold topology: 2-manifolds mapping to anything are interesting; codimension 1 objects in anything are interesting; only in 3-manifolds are these the same objects . . .

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