Cartan-Hadamard theorem: Difference between revisions
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Here are some equivalent formulations: | Here are some equivalent formulations: | ||
* Any complete [[ | * Any complete [[nonpositively curved manifold]], viz any manifold which has negative sectional curvature everywhere, has the property that its universal cover is diffeomorphic to real Euclidean space | ||
* Any complete simply connected | * Any complete simply connected nonpositively curved manifold is diffeomorphic to <math>\R^n</math> (such a manifold is termed a [[CH-manifold]]) | ||
The equivalence follows from the fact that the universal cover of a Riemannian manifold can be given the pullback metric, in which case the range of values taken by the sectional curvature is the same for both spaces. | The equivalence follows from the fact that the universal cover of a Riemannian manifold can be given the pullback metric, in which case the range of values taken by the sectional curvature is the same for both spaces. | ||
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The Bonnet-Myers theorem states that the universal cover of a [[complete Riemannian manifold]] with [[Ricci curvature]] bounded below by a positive number, is compact. | The Bonnet-Myers theorem states that the universal cover of a [[complete Riemannian manifold]] with [[Ricci curvature]] bounded below by a positive number, is compact. | ||
==Proof== | |||
===Main ingredient of proof=== | |||
The main ingredient is to show that the exponential map from the tangent space at any point, to the manifold, is a well-defined covering map. | |||
Nonpositive curvature comes of use because it tells us that the manifold does not have [[conjugate points]] (viz, it is a [[conjugate-free Riemannian manifold]]). | |||
Revision as of 06:24, 12 July 2007
This article describes a result related to the sectional curvature of a Riemannian manifold
This result relates information on curvature to information on topology of a manifold
This article makes a prediction about the universal cover of a manifold based on given data at the level of a:Riemannian manifold
This result is valid in all dimensions
Statement
Here are some equivalent formulations:
- Any complete nonpositively curved manifold, viz any manifold which has negative sectional curvature everywhere, has the property that its universal cover is diffeomorphic to real Euclidean space
- Any complete simply connected nonpositively curved manifold is diffeomorphic to (such a manifold is termed a CH-manifold)
The equivalence follows from the fact that the universal cover of a Riemannian manifold can be given the pullback metric, in which case the range of values taken by the sectional curvature is the same for both spaces.
Relation with other results
Bonnet-Myers theorem
Further information: Bonnet-Myers theorem
The Bonnet-Myers theorem states that the universal cover of a complete Riemannian manifold with Ricci curvature bounded below by a positive number, is compact.
Proof
Main ingredient of proof
The main ingredient is to show that the exponential map from the tangent space at any point, to the manifold, is a well-defined covering map.
Nonpositive curvature comes of use because it tells us that the manifold does not have conjugate points (viz, it is a conjugate-free Riemannian manifold).