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An Eigenvalue Pinching Theorem for Compact Hypersurfaces in A Sphere

Differential Geometry 2015-08-28 v1

Abstract

In this article, we prove an eigenvalue pinching theorem for the first eigenvalue of the Laplacian on compact hypersurfaces in a sphere. Let (Mn,g)(M^n,g) be a closed, connected and oriented Riemannian manifold isometrically immersed by ϕ\phi into §n+1\S^{n+1}. Let q>nq>n and A>0A>0 be some real numbers satisfying M1n(1+Bq)A|M|^\frac{1}{n}(1+\|B\|_q)\leq A. Suppose that ϕ(M)B(p0,R)\phi(M)\subset B(p_0,R), where p0p_0 is a center of gravity of MM and radius R<π2R<\frac{\pi}{2}. We prove that there exists a positive constant \e\e depending on qq, nn, RR and AA such that if n(1+H2)\e\l1n(1+\|H\|_\infty^2)-\e\leq \l_1, then MM is diffeomorphic to §n\S^n. Furthermore, ϕ(M)\phi(M) is starshaped with respect to p0p_0, Hausdorff close and almost-isometric to the geodesic sphere S\(p_0,R_0\), where R0=arcsin11+H2R_0=\arcsin\frac{1}{\sqrt{1+\|H\|_\infty^2}}.

Keywords

Cite

@article{arxiv.1508.06975,
  title  = {An Eigenvalue Pinching Theorem for Compact Hypersurfaces in A Sphere},
  author = {Yingxiang Hu and Hongwei Xu},
  journal= {arXiv preprint arXiv:1508.06975},
  year   = {2015}
}

Comments

13 pages

R2 v1 2026-06-22T10:43:11.016Z