Next Order Asymptotics and Renormalized Energy for Riesz Interactions

TL;DR

This paper investigates the asymptotic behavior of point systems with Riesz interactions in various dimensions, introducing a renormalized energy concept to understand microscopic arrangements and potential crystallization.

Contribution

It introduces a next order asymptotic expansion for Riesz interaction energies using a new renormalized energy, extending previous studies and linking microscopic structure to energy minimization.

Findings

Derived the next order term in energy asymptotics as n approaches infinity.

Defined a renormalized energy that favors crystalline configurations.

Established point separation results for energy minimizers.

Abstract

We study systems of $n$ points in the Euclidean space of dimension $d \ge 1$ interacting via a Riesz kernel $|x|^{-s}$ and confined by an external potential, in the regime where $d-2\le s<d$. We also treat the case of logarithmic interactions in dimensions $1$ and $2$. Our study includes and retrieves all cases previously studied in \cite{ss2d,ss1d,rs}. Our approach is based on the Caffarelli-Silvestre extension formula which allows to view the Riesz kernel as the kernel of a (inhomogeneous) local operator in the extended space $\mathbb{R}^{d+1}$. As $n \to \infty$, we exhibit a next to leading order term in $n^{1+s/d}$ in the asymptotic expansion of the total energy of the system, where the constant term in factor of $n^{1+s/d}$ depends on the microscopic arrangement of the points and is expressed in terms of a "renormalized energy." This new object is expected to penalize the disorder of an infinite set of points in whole space, and to be minimized by Bravais lattice (or crystalline) configurations. We give applications to the statistical mechanics in the case where temperature is added to the system, and identify an expected "crystallization regime." We also obtain a result of separation of the points for minimizers of the energy.