Determines infinitesimal structure at boundary singular points and Hausdorff dimensions of boundary singular sets in limits of manifolds with boundary under sectional curvature, second fundamental form, and diameter bounds when inradii are bounded below.
A Compactness Theorem for Riemannian Manifolds with Boundary and Applications
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abstract
In this paper we prove weak L^{1,p} (and thus C^{\alpha}) compactness for the class of uniformly mean-convex Riemannian n-manifolds with boundary satisfying bounds on curvature quantities, diameter, and (n-1)-volume of the boundary. We obtain two stability theorems from the compactness result. The first theorem applies to 3-manifolds (contained in the aforementioned class) that have Ricci curvature close to 0 and whose boundaries are Gromov-Hausdorff close to a fixed metric on S^2 with positive curvature. Such manifolds are C^{\alpha} close to the region enclosed by a Weyl embedding of the fixed metric into \R^3. The second theorem shows that a 3-manifold with Ricci curvature close to 0 (resp. -2, 2) and mean curvature close to 2 (resp. 2\sqrt 2, 0) is C^{\alpha} close to a metric ball in the space form of constant curvature 0 (resp -1, 1), provided that the boundary is a topological sphere.
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A new Dynkin-type condition on manifolds with boundary implies bi-Lipschitz equivalence to a time-changed Bakry-Émery weighted manifold, giving local doubling, Neumann spectral gap lower bounds, and a precompactness theorem.
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Limits of manifolds with boundary I
Determines infinitesimal structure at boundary singular points and Hausdorff dimensions of boundary singular sets in limits of manifolds with boundary under sectional curvature, second fundamental form, and diameter bounds when inradii are bounded below.