English

The Gaussian core model in high dimensions

Metric Geometry 2023-03-29 v6 Number Theory

Abstract

We prove lower bounds for energy in the Gaussian core model, in which point particles interact via a Gaussian potential. Under the potential function teαt2t \mapsto e^{-\alpha t^2} with 0<α<4π/e0 < \alpha < 4\pi/e, we show that no point configuration in Rn\mathbf{R}^n of density ρ\rho can have energy less than (ρ+o(1))(π/α)n/2(\rho+o(1))(\pi/\alpha)^{n/2} as nn \to \infty with α\alpha and ρ\rho fixed. This lower bound asymptotically matches the upper bound of ρ(π/α)n/2\rho (\pi/\alpha)^{n/2} obtained as the expectation in the Siegel mean value theorem, and it is attained by random lattices. The proof is based on the linear programming bound, and it uses an interpolation construction analogous to those used for the Beurling-Selberg extremal problem in analytic number theory. In the other direction, we prove that the upper bound of ρ(π/α)n/2\rho (\pi/\alpha)^{n/2} is no longer asymptotically sharp when α>πe\alpha > \pi e. As a consequence of our results, we obtain bounds in Rn\mathbf{R}^n for the minimal energy under inverse power laws t1/tn+st \mapsto 1/t^{n+s} with s>0s>0, and these bounds are sharp to within a constant factor as nn \to \infty with ss fixed.

Keywords

Cite

@article{arxiv.1603.09684,
  title  = {The Gaussian core model in high dimensions},
  author = {Henry Cohn and Matthew de Courcy-Ireland},
  journal= {arXiv preprint arXiv:1603.09684},
  year   = {2023}
}

Comments

30 pages, 1 figure

R2 v1 2026-06-22T13:22:33.924Z