Sobolev inequalities and convergence for Riemannian metrics and distance functions

Abstract

If one thinks of a Riemannian metric, $$g_1$$ , analogously as the gradient of the corresponding distance function, $$d_1$$ , with respect to a background Riemannian metric, $$g_0$$ , then a natural question arises as to whether a corresponding theory of Sobolev inequalities exists between the Riemannian metric and its distance function. In this paper, we study the sub-critical case $$p < \frac{m}{2}$$ where we show a Sobolev inequality exists between a Riemannian metric and its distance function. In particular, we show that an $$L^{\frac{p}{2}}$$ bound on a Riemannian metric implies an $$L^q$$ bound on its corresponding distance function. We then use this result to state a convergence theorem and show how this theorem can be useful to prove geometric stability results by proving a version of Gromov’s conjecture for tori with almost non-negative scalar curvature in the conformal case. Examples are given to show that the hypotheses of the main theorems are necessary.