English

Stable and Minimizing Cones in the Alt-Phillips Problem

Analysis of PDEs 2025-02-26 v1

Abstract

We study homogeneous solutions to the Alt-Phillips problem when the exponent γ\gamma is close to 1. In dimension d3d\ge3, we show that the radial cone is minimizing when γ\gamma is close to 1. In dimension d4d \ge 4, we construct an axially symmetric cone whose contact set has with positive density. We show that it is a global minimizer. It is analogous to the De Silva-Jerison \cite{DJ} cone for the Alt-Caffarelli functional which corresponds to exponent γ=0\gamma=0. The cone we construct bifurcates from another minimizing cone whose contact set has zero density, obtained as the trivial extension of the radial solution. This second cone is analogous to a quadratic polynomial solution in the classical obstacle problem which corresponds to exponent γ=1\gamma=1. In particular our results show that, when γ<1\gamma<1 is sufficiently close to 1, there are axis symmetric cones that exhibit the properties of both end point cases γ=0\gamma=0 and γ=1\gamma=1.

Keywords

Cite

@article{arxiv.2502.18192,
  title  = {Stable and Minimizing Cones in the Alt-Phillips Problem},
  author = {Ovidiu Savin and Hui Yu},
  journal= {arXiv preprint arXiv:2502.18192},
  year   = {2025}
}
R2 v1 2026-06-28T21:57:18.477Z