Determining a Riemannian Metric from Minimal Areas

Abstract

We prove that if (M,g) is a topological 3-ball with a C4-smooth Riemannian metric g, and mean-convex boundary ∂ M then knowledge of least areas circumscribed by simple closed curves γ ⊂ ∂ M uniquely determines the metric g, under some additional geometric assumptions. These are that g is either a) C3-close to Euclidean or b) satisfies much weaker geometric conditions which hold when the manifold is to a sufficient degree either thin, or straight. %sufficiently thin. In fact, the least area data that we require is for a much more restricted class of curves γ⊂ ∂ M. We also prove a corresponding local result: assuming only that (M,g) has strictly mean convex boundary at a point p∈∂ M, we prove that knowledge of the least areas circumscribed by any simple closed curve γ in a neighbourhood U⊂ ∂ M of p uniquely determines the metric near p. Additionally, we sketch the proof of a global result with no thin/straight or curvature condition, but assuming the metric admits minimal foliations "from all directions". The proofs rely on finding the metric along a continuous sweep-out of M by area-minimizing surfaces; they bring together ideas from the 2D-Calder\'on inverse problem, minimal surface theory, and the careful analysis of a system of pseudo-differential equations.