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Classifying minimum energy states for interacting particles: Regular simplices

Mathematical Physics 2022-12-14 v3 Analysis of PDEs math.MP Optimization and Control

Abstract

Densities of particles on \Rn\Rn which interact pairwise through an attractive-repulsive power-law potential W\al,\bt(x)=x\al/\alx\bt/\btW_{\al,\bt}(x) = |x|^\al/\al-|x|^\bt/\bt have often been used to explain patterns produced by biological and physical systems. In the mildly repulsive regime \al>\bt2\al> \bt \ge 2 with n2n \ge 2, we show there exists a decreasing homeomorphism \alΔn\al_{\Delta^n} from [2,4][2,4] to itself such that: distributing the particles uniformly over the vertices of a regular unit diameter nn-simplex minimizes the potential energy if and only if \al\al\Den(\bt)\al\ge \al_{\De^n}(\bt). Moreover this minimum is uniquely attained up to rigid motions when \al>\al\Den(\bt)\al > \al_{\De^n}(\bt). We estimate \al\Den(\bt)\al_{\De^n}(\bt) above and below, and identify its limit as the dimension grows large. These results are derived from a new northeast comparison principle in the space of exponents. At the endpoint (\al,\bt)=(4,2)(\al,\bt)=(4,2) of this transition curve, we characterize all minimizers by showing they lie on a sphere and share all first and second moments with the spherical shell. Suitably modified versions of these statements are also established (i) for Wα,βW_{\alpha,\beta} and corresponding energies in the case where n=1n=1, and (ii) for the attractive-repulsive potentials D\al(x)=x\al(\allogx1)D_\al(x) = |x|^\al(\al\log |x|-1) that arise in the limit \bt\al\bt \nearrow \al.

Keywords

Cite

@article{arxiv.2109.07091,
  title  = {Classifying minimum energy states for interacting particles: Regular simplices},
  author = {Cameron Davies and Tongseok Lim and Robert J. McCann},
  journal= {arXiv preprint arXiv:2109.07091},
  year   = {2022}
}

Comments

Reference [15] has been added and Remark 1.6 revised in ver2. v3 updates its content and title and will be published in Comm.Math.Phys

R2 v1 2026-06-24T05:58:36.965Z