English

Second order estimates for a free boundary phase transition

Analysis of PDEs 2025-08-11 v2

Abstract

It is well known that minimizers of the Allen-Cahn-type functional Jϵ(u):=Ωϵu22+W(u)ϵ, J_\epsilon(u):=\int_\Omega\frac{\epsilon|\nabla u|^2}{2}+\frac{W(u)}{\epsilon}, where WW is a double-well potential, resemble minimal surfaces in the sense that their level sets converge to a minimal surface as ϵ0\epsilon\rightarrow 0. In this work, we consider the indicator potential W(τ)=χ(1,1)(τ)W(\tau)=\chi_{(-1,1)}(\tau), which leads to the Bernoulli-type free-boundary problem {Δu=0in{u<1}u=ϵ1on{u<1}. \left\{ \begin{alignedat}{2} \Delta u&=0&\quad&\textrm{in}\quad\{|u|<1\}\\ |\nabla u|&=\epsilon^{-1}&\quad&\textrm{on}\quad\partial \{|u|<1\}. \end{alignedat} \right. We provide a short proof that the transition layers are uniformly C2,αC^{2,\alpha} regular, up to the free boundary. In addition to the uniform C2,αC^{2,\alpha} estimate, we also obtain improved CαC^\alpha mean curvature bound that decays in an algebraic rate of ϵ\epsilon, which confirms the convergence of interfaces to the minimal surface in a very strong sense. We present a simple elliptic equation Δϕ=H2A2 \Delta\phi=H^2-|\mathbf{A}|^2 where ϕ=log(1/u)\phi=\log(1/|\nabla u|) is the log-gradient of uu, HH and A\mathbf{A} are the mean curvature and the second fundamental form of level surfaces, respectively. From this, the uniform estimates readily follow. The whole argument is performed in a general Riemannian manifold setting.

Keywords

Cite

@article{arxiv.2507.03810,
  title  = {Second order estimates for a free boundary phase transition},
  author = {Jingeon An},
  journal= {arXiv preprint arXiv:2507.03810},
  year   = {2025}
}

Comments

13 pages

R2 v1 2026-07-01T03:47:15.366Z