An Optimal Differentiable Sphere Theorem for Complete Manifolds

Hong-Wei Xu; Juan-Ru Gu

An Optimal Differentiable Sphere Theorem for Complete Manifolds

Hong-Wei Xu, Juan-Ru Gu

Abstract

A new differentiable sphere theorem is obtained from the view of submanifold geometry. An important scalar is defined by the scalar curvature and the mean curvature of an oriented complete submanifold $M^n$ in a space form $F^{n+p}(c)$ with $c\ge0$. Making use of the Hamilton-Brendle-Schoen convergence result for Ricci flow and the Lawson-Simons-Xin formula for the nonexistence of stable currents, we prove that if the infimum of this scalar is positive, then $M$ is diffeomorphic to $S^n$. We then introduce an intrinsic invariant $I(M)$ for oriented complete Riemannian $n$-manifold $M$ via the scalar, and prove that if $I(M)>0$, then $M$ is diffeomorphic to $S^n$. It should be emphasized that our differentiable sphere theorem is optimal for arbitrary $n(\ge2)$.

An Optimal Differentiable Sphere Theorem for Complete Manifolds

Abstract

in a space form

with

. Making use of the Hamilton-Brendle-Schoen convergence result for Ricci flow and the Lawson-Simons-Xin formula for the nonexistence of stable currents, we prove that if the infimum of this scalar is positive, then

is diffeomorphic to

. We then introduce an intrinsic invariant

for oriented complete Riemannian

-manifold

via the scalar, and prove that if

, then

is diffeomorphic to

. It should be emphasized that our differentiable sphere theorem is optimal for arbitrary

An Optimal Differentiable Sphere Theorem for Complete Manifolds

Abstract

An Optimal Differentiable Sphere Theorem for Complete Manifolds

Abstract

Paper Structure

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