A Dynamical Approach to the Berezin-Li-Yau Inequality

Abstract

We develop a dynamical method for proving the sharp Berezin-Li-Yau inequality. The approach is based on the volume-preserving mean curvature flow and a new monotonicity principle for the Riesz mean RΛ(Ωt). For convex domains we show that RΛ is monotone non-decreasing along the flow. The key input is a geometric correlation inequality between the boundary spectral density QΛ and the mean curvature H, established in all dimensions: in d=2 via a near-disk Fourier analysis, and in d 3 via the boundary Weyl expansion together with a local spectral rigidity argument near the ball, with a first-zero exclusion principle closing the global step. Since the flow converges smoothly to the ball, the monotonicity implies the sharp Berezin-Li-Yau bound for every smooth convex domain. As an application, we obtain a sharp dynamical Cesàro-Pólya inequality for eigenvalue averages.