Stable and Minimizing Cones in the Alt-Phillips Problem
Abstract
We study homogeneous solutions to the Alt-Phillips problem when the exponent is close to 1. In dimension , we show that the radial cone is minimizing when is close to 1. In dimension , 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 . 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 . In particular our results show that, when is sufficiently close to 1, there are axis symmetric cones that exhibit the properties of both end point cases and .
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}
}