Difference between revisions of "Poincaré Conjecture"

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The '''Poincaré Conjecture''' which was originally a [[conjecture]], was solved in 2003 and is now a [[theorem]]. It states that every closed topological three-dimensional [[manifold]] is [[homeomorphism|homeomorphic]] to a [[hypersphere|3-sphere]].
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The Poincaré conjecture is one of the seven Millennium Problems, and is the only one that has been solved, in 2003 by Grigori Perelman.
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In elementary terms, the Poincaré conjecture states that the only three-manifold with no "holes" is the three-sphere. This would also show that the only n-manifold with no "holes" is the n-sphere; the case <math>n=1</math> is trivial, the case <math>n=2</math> is a classic problem, and the truth of the statement for <math>n\ge 4</math> was verified by Stephen Smale in 1961. More rigorously, the conjecture is expressed as "Every simply connected, compact three-manifold (without boundary) is homeomorphic to the three-sphere."
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Latest revision as of 20:44, 29 September 2024

The Poincaré Conjecture which was originally a conjecture, was solved in 2003 and is now a theorem. It states that every closed topological three-dimensional manifold is homeomorphic to a 3-sphere.

The Poincaré conjecture is one of the seven Millennium Problems, and is the only one that has been solved, in 2003 by Grigori Perelman.

In elementary terms, the Poincaré conjecture states that the only three-manifold with no "holes" is the three-sphere. This would also show that the only n-manifold with no "holes" is the n-sphere; the case $n=1$ is trivial, the case $n=2$ is a classic problem, and the truth of the statement for $n\ge 4$ was verified by Stephen Smale in 1961. More rigorously, the conjecture is expressed as "Every simply connected, compact three-manifold (without boundary) is homeomorphic to the three-sphere." This article is a stub. Help us out by expanding it.