In geometric topology, the Borel conjecture (named for Armand Borel) asserts that an aspherical closed manifold is determined by its fundamental group, up to homeomorphism. It is a rigidity conjecture, asserting that a weak, algebraic notion of equivalence (namely, homotopy equivalence) should imply a stronger, topological notion (namely, homeomorphism).

Precise formulation of the conjecture

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Let   and   be closed and aspherical topological manifolds, and let

 

be a homotopy equivalence. The Borel conjecture states that the map   is homotopic to a homeomorphism. Since aspherical manifolds with isomorphic fundamental groups are homotopy equivalent, the Borel conjecture implies that aspherical closed manifolds are determined, up to homeomorphism, by their fundamental groups.

This conjecture is false if topological manifolds and homeomorphisms are replaced by smooth manifolds and diffeomorphisms; counterexamples can be constructed by taking a connected sum with an exotic sphere.

The origin of the conjecture

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In a May 1953 letter to Jean-Pierre Serre,[1] Armand Borel raised the question whether two aspherical manifolds with isomorphic fundamental groups are homeomorphic. A positive answer to the question "Is every homotopy equivalence between closed aspherical manifolds homotopic to a homeomorphism?" is referred to as the "so-called Borel Conjecture" in a 1986 paper of Jonathan Rosenberg.[2]

Motivation for the conjecture

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A basic question is the following: if two closed manifolds are homotopy equivalent, are they homeomorphic? This is not true in general: there are homotopy equivalent lens spaces which are not homeomorphic.

Nevertheless, there are classes of manifolds for which homotopy equivalences between them can be homotoped to homeomorphisms. For instance, the Mostow rigidity theorem states that a homotopy equivalence between closed hyperbolic manifolds is homotopic to an isometry—in particular, to a homeomorphism. The Borel conjecture is a topological reformulation of Mostow rigidity, weakening the hypothesis from hyperbolic manifolds to aspherical manifolds, and similarly weakening the conclusion from an isometry to a homeomorphism.

Relationship to other conjectures

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  • The Borel conjecture implies the Novikov conjecture for the special case in which the reference map   is a homotopy equivalence.
  • The Poincaré conjecture asserts that a closed manifold homotopy equivalent to  , the 3-sphere, is homeomorphic to  . This is not a special case of the Borel conjecture, because   is not aspherical. Nevertheless, the Borel conjecture for the 3-torus   implies the Poincaré conjecture for  .[3]

References

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  1. ^ Extract from a letter from Armand Borel to Jean-Pierre Serre (2 May 1953). "The birth of the Borel conjecture" (PDF).
  2. ^ Rosenberg, Jonathan (1986). "C-algebras, positive scalar curvature, and the Novikov conjecture. III". Topology. 25 (3): 319–336. doi:10.1016/0040-9383(86)90047-9. MR 0842428.
  3. ^ Farrell, F. T. (2002). "The Borel conjecture". In Farrell, F.T.; Goettshe, L.; Lueck, W. (eds.). Topology of high-dimensional manifolds, No. 1, 2 (Trieste, 2001) (PDF). ICTP Lecture Notes. Vol. 9. Trieste: Abdus Salam International Centre for Theoretical Physics. pp. 225–298. ISBN 92-95003-12-8. MR 1937017. See remark, pp. 233–234.

Further reading

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  • Matthias Kreck, and Wolfgang Lück, The Novikov conjecture. Geometry and algebra. Oberwolfach Seminars, 33. Birkhäuser Verlag, Basel, 2005.