A Metric Sturm-Liouville theory in Two Dimensions

Abstract

A central result of Sturm-Liouville theory (also called the Sturm-Hurwitz Theorem) states that if φk is a sequence of eigenfunctions of a second order differential operator on the interval I ⊂ R, then any linear combination satisfies a uniform bound on the roots \# \x ∈ I:Σk ≥ n ak φk(x) = 0 \ ≥ n-1. We provide a sharp (up to logarithmic factors) generalization to two dimensions: let (M,g) be a compact two-dimensional manifold (with or without boundary), let (φk) denote the sequence of eigenfunctions of a uniformly elliptic operator -div(a(·) ∇) (with Dirichlet or Neumann boundary conditions). Then, for any linear combination of eigenfunctions above a certain index n, f = Σk ≥ nak φk ~ we have H1 \ x: f(x) = 0\ nn (n \|f\|L2(M)\|f\|L1(M) )-1/2 \|f\|L1(M)\| f \|L∞(M) . Examples on M=T2 and M=S2 shows that this is optimal up to the logarithmic factors. The proof is using optimal transport and a new inequality for the Wasserstein metric Wp: if f(x)dx and g(x)dx are two absolutely continuous measures on a two-dimensional domain M with continuous densities and the same total mass, then, for all 1 ≤ p <∞, Wp(f(x)dx, g(x) dx) · H1 \x ∈ M: f(x) = g(x) \ M,p \|f-g\|L1(M)1+1/p\|f-g\|L∞(M).