POINCARÉ CONJECTURE

This article documents a current event. Information may change rapidly as the event progresses.

In mathematics, the Poincaré conjecture (IPA: [pwɛ̃kaˈʀe])^[1] is a conjecture about the characterization of the three-dimensional sphere amongst three-dimensional manifolds. Loosely speaking, the conjecture surmises that if a closed three-dimensional manifold is sufficiently like a sphere in that each loop in the manifold can be tightened to a point, then it is really just a three-dimensional sphere. The analogous result has been known to be true in higher dimensions for some time.

The Poincaré conjecture is widely considered one of the most important questions in topology. It is one of the seven Millennium Prize Problems for which the Clay Mathematics Institute is offering a $1,000,000 prize for a correct solution.

After nearly a century of effort by mathematicians all over the world, a series of papers made available in 2002 and 2003 by Grigori Perelman, following the program of Richard Hamilton, produced an outline for a solution. Following Perelman's work, several groups of mathematicians have produced works filling in the details for the full proof, though review by the mathematics community is ongoing.

Statement detail

At the beginning of the 20th century, Henri Poincaré was working on the foundations of topology — what would later be called combinatorial topology and then algebraic topology. He was particularly interested in what topological properties characterized a sphere.

Poincaré claimed in 1900 that homology, a tool he had devised based on prior work by Enrico Betti, was sufficient to tell if a 3-manifold was a 3-sphere. In a 1904 paper he described a counterexample, now called the Poincaré sphere, that had the same homology as a 3-sphere. Poincaré was able to show the Poincaré sphere had a fundamental group of order 120. Since the 3-sphere has trivial fundamental group, he concluded this was a different space. The Poincaré sphere was the first example of a homology sphere, of which many others have since been constructed.

In the same paper, Poincaré wondered whether a 3-manifold with the homology of a 3-sphere but also trivial fundamental group had to be a 3-sphere. Poincaré's new condition, i.e. "trivial fundamental group", can be phrased as "every loop can be shrunk to a point".

The original phrasing was as follows:

Consider a compact 3-dimensional manifold V without boundary. Is it possible that the fundamental group of V could be trivial, even though V is not homeomorphic to the 3-dimensional sphere?

Poincaré never declared whether he believed this additional condition would characterize the 3-sphere, but nonetheless, the statement that it does is known as the Poincaré conjecture. Here is the standard form of the conjecture:

Every simply connected closed (i.e. compact and without boundary) 3-manifold is homeomorphic to a 3-sphere.

Attempted solutions

20th century

For a time, this problem seems to have lain dormant, until J. H. C. Whitehead revived interest in the conjecture, when in the 1930s he first claimed a proof, and then retracted it. In the process, he discovered some interesting examples of 3-manifolds, the prototype of which is now called the Whitehead manifold.

In the 1950s and 1960s other famous mathematicians were to claim proofs only to discover a fatal flaw at the last minute. Influential mathematicians such as Bing, Haken, Moise, and Papakyriakopoulos expended great efforts at tackling the conjecture. This period was important to the growth of what would later be called low-dimensional topology.

Over time, the conjecture gained the reputation of being particularly tricky to tackle. Milnor commented that sometimes the errors in false proofs can be "rather subtle and difficult to detect."^[2] Overall, work on the conjecture has improved understanding of 3-manifolds. Experts in the field have been most reluctant to announce proofs, and have viewed any such announcement with skepticism. The 1980s and 1990s witnessed some well-publicized fallacious proofs (which were not actually published in peer-reviewed form). Sometimes mathematicians obsessed with this problem are described as suffering from Poincaritis.

21st century

In 2000 the Clay Mathematics Institute selected the Poincaré conjecture as one of seven Millennium Prize Problems and offered a $1,000,000 prize for its solution. Undoubtedly its difficulty and the expectation that a significant breakthrough would be needed were important factors in this selection.

In late 2002, Grigori Perelman of the Steklov Institute of Mathematics, Saint Petersburg was rumoured to have found a proof.^[3] He claimed to have proven a more general conjecture, Thurston's geometrization conjecture, carrying out a program outlined earlier by Richard Hamilton. Perelman had made a preprint paper available, which treated the geometrization conjecture by an application of the Ricci flow theory. In 2003, Perelman released two more "Ricci flow" preprint papers and gave a series of lectures in the United States.

The Poincaré conjecture, and Perelman's three publications on the subject are on the agenda of the International Congress of Mathematicians (ICM), August 2006 in Madrid. Apparently in April 2006, at the time of the publication of the 20th Bulletin of the ICM, some of the content of Perelman's papers was still in the process of acquiring full endorsement by the scientific community:

[Perelman] already published three papers on the subject, general agreement having been reached on the fact that the first and much of the second are correct, leaving a “technically more difficult” part still to be checked.^[4]

However, according to Vicente Miquel, professor of Geometry and Topology at the University of Valencia, quoted in that April 2006 info bulletin regarding the ICM2006 Congress: "Everyone understands the third paper, which together with the verified parts of the first two would seem to provide a proof of the Poincaré Conjecture, and would be enough for Perelman to receive the Clay Institute million-dollar prize."^[4]

From May to July 2006, several groups have presented papers that claim to have filled in the details or complete the proof of the Poincaré conjecture. After which the home page of the website of the Clay Mathematics Institute listed following papers that give a "detailed exposition" regarding Perelman's work:

• In May 2006, Bruce Kleiner and John Lott, both of the University of Michigan, posted a paper on arXiv titled "Notes on Perelman's Papers".^[5] They claim to fill in the details of Perelman's proof of the Geometrization conjecture.
• In June 2006, the Asian Journal of Mathematics published a paper by Zhu Xiping of Sun Yat-sen University in China and Cao Huaidong of Lehigh University in Pennsylvania,^[6] claiming:

  Abstract. In this paper, we give a complete proof of the Poincaré and the geometrization conjectures. This work depends on the accumulative works of many geometric analysts in the past thirty years. This proof should be considered as the crowning achievement of the Hamilton-Perelman theory of Ricci flow.^[7]

  According to the Fields medalist Shing-Tung Yau this was "putting the finishing touches to the complete proof of the Poincaré Conjecture".^[8] Yau's involvement was however criticised in an August 2006 article in The New Yorker.^[9] It is pointed out that Yau is both an editor-in-chief of the Asian Journal of Mathematics as well as Cao's doctoral advisor.^[10] The article further suggests that Yau was intent on being associated, directly or indirectly, with the proof of the conjecture and pressured the journal's editors to accept Zhu and Cao's paper on unusually short notice. The article quotes MIT mathematician Dan Stroock as saying, "I find it a little mean of [Yau] to seem to be trying to get a share of this as well."

• In July 2006, John Morgan of Columbia University and Gang Tian of the Massachusetts Institute of Technology posted a paper on the arXiv titled, "Ricci Flow and the Poincaré Conjecture." In this paper, they claim to provide a "detailed proof of the Poincaré Conjecture".^[11] Morgan will speak at the ICM in Madrid on the Poincaré conjecture.

On August 22, 2006, the ICM awarded Perelman the Fields Medal for his work on the conjecture. Perelman refused the medal.^[9][12][13] As for the $1 million Clay Institute prize, Perelman's work is under review: prize money could be awarded if the proof is considered valid two years after publication.^[14] According to the New York Times Perelman said he wants no part of the Clay institute prize money.^[12] A Chinese newspaper cites however John Ball, president of the International Mathematical Union organising the ICM, who met Perelman in June:

Ball said he asked Perelman if he would accept the money. Perelman said that if he won, he would talk to the Clay institute.^[13]

Also the interview with Perelman published in the August 2006 issue of the New Yorker records that Perelman has made no decision yet what would happen if he were offered the Clay institute prize:

I’m not going to decide whether to accept the prize until it is offered.^[9]

In other dimensions

Analogues of the Poincaré conjecture in dimensions other than 3 can also be formulated:

Every closed n-manifold which is homotopy equivalent to the n-sphere is homeomorphic to the n-sphere.

The Poincaré conjecture as given above is equivalent to the case n = 3. The difficulty of low-dimensional topology is highlighted by the fact that these analogues had all been proven (with dimension n = 4 being the hardest one by far) by the 1980s, while an apparent solution to the original 3-dimensional version of Poincaré's conjecture was just submitted in 2003. The case n = 1 is easy and the case n = 2 has long been known. Stephen Smale solved the cases n ≥ 7 in 1960 and subsequently extended his proof to n ≥ 5; he received a Fields Medal for his work in 1966. Michael Freedman solved n = 4 in 1982 and received a Fields Medal in 1986.

An n-manifold homotopy equivalent to an n-sphere is sometimes called a homotopy sphere. Restated, the Poincaré conjecture states that the only homotopy spheres are actual spheres.

In the smooth category, the analogue of the Poincaré conjecture is usually false (see exotic sphere). For dimensions 1,2,3,5, and 6 there is only one smooth structure on the sphere, but Milnor showed that the oriented 7-sphere has 28 different smooth structures (or 15 ignoring orientations), and in higher dimensions there are usually many different smooth structures on a sphere. It is suspected that certain differentiable structures on the 4-sphere are not isomorphic to the standard one, but at the moment there are no known invariants capable of distinguishing different smooth structures on a 4-sphere.

References

1. ^ Poincaré pronunciation example at Bartleby.com
2. ^ "The Poincaré Conjecture 99 Years Later: A Progress Report" by John Milnor, February 2003 - PDF file
3. ^ By April 2003 the press was reporting on these developments Mathematical Digest
4. ^ ^a b ICM, Bulletin 20, April 10, 2006: "Poincaré’s Conjecture Will Be the Highlight of the ICM2006"
5. ^ "Notes on Perelman's papers", Bruce Kleiner and John Lott.
6. ^ Asian Journal of Mathematics Volume 10, Number 2 (June 2006)
7. ^ Cao, Huai-Dong, Zhu, Xi-Ping (June 2006). "A Complete Proof of the Poincaré and Geometrization Conjectures — Application of the Hamilton-Perelman theory of the Ricci flow" (PDF) 10 (2): 165–498. Retrieved on 2006-07-31.
8. ^ "Chinese mathematicians solve global puzzle", China View (Xinhua), 2006-06-03
9. ^ ^a b c Sylvia Nasar and David Gruber, "Manifold destiny", The New Yorker, August 28, 2006, pp. 44–57.
10. ^ Shing-Tung Yau at the website of Mathematics Genealogy Project, a service of the Department of Mathematics, North Dakota State University.
11. ^ "Ricci Flow and the Poincaré Conjecture", John W. Morgan and Gang Tian
12. ^ ^a b Highest Honor in Mathematics Is Refused by Kenneth Chang in the New York Times, August 22, 2006
13. ^ ^a b Reclusive Russian solves 100-year-old maths problem, China Daily, 08/23/2006, page 7
14. ^ "Before consideration, a proposed solution must be published in a refereed mathematics publication of worldwide repute (or such other form as the SAB shall determine qualifies), and it must also have general acceptance in the mathematics community two years after." from Rules for the Millennium Prizes, Revision of January 19, 2005, available at the website of the Clay Mathematics Institute

External links

• Description of the Poincaré conjecture by the Clay Mathematics Institute
• Eric W. Weisstein et al., "Poincaré conjecture" at MathWorld
• John Milnor: "The Poincaré Conjecture 99 Years Later: A Progress Report", February 2003 - PDF file
• John Milnor: "Towards the Poincaré Conjecture and Classification of 3-Manifolds" (version of 6-14-03) - PDF file
• Preprints of Grisha Perelman's papers at arXiv.org:
  • The entropy formula for the Ricci flow and its geometric applications, 2002
  • Ricci flow with surgery on three-manifolds, 2003
  • Finite extinction time for the solutions to the Ricci flow on certain three-manifolds, 2003
• Bruce Kleiner (Yale) and John Lott (University of Michigan):
  • "Notes on Perelman's papers"
  • "Notes and commentary on Perelman's Ricci flow papers"
• Gang Tian and John Morgan "Ricci Flow and the Poincare Conjecture"
• Jascha Hoffman, Boston Globe Correspondent, 12/30/2003: "Century-old math problem may have been solved"
• Mo Hong'e in China View, 2006-06-04: "Unraveling toughest puzzle outstanding"
• Sharon Begley, Major math problem is believed solved, Wall Street Journal, Jul. 21, 2006
• Joshua Plotkin, a concise summary (PDF) of the proof of the generalized Poincaré conjecture in dimensions five and higher.
• New York Times story: Elusive Proof, Elusive Prover: A New Mathematical Mystery, August 15, 2006
• AOL News Story, 8/24/2006