English

Interface dynamics in semilinear wave equations

Analysis of PDEs 2020-01-08 v1

Abstract

We consider the wave equation ε2(t2+Δ)u+f(u)=0\varepsilon^2(-\partial_t^2 + \Delta)u + f(u) = 0 for 0<ε10<\varepsilon\ll 1, where ff is the derivative of a balanced, double-well potential, the model case being f(u)=uu3f(u) = u-u^3. For equations of this form, we construct solutions that exhibit an interface of thickness O(ε)O(\varepsilon ) that separates regions where the solution is O(εk)O(\varepsilon^k) close to ±1\pm 1, and that is close to a timelike hypersurface of vanishing {\em Minkowskian} mean curvature. This provides a Minkowskian analog of the numerous results that connect the Euclidean Allen-Cahn equation and minimal surfaces or the parabolic Allen-Cahn equation and motion by mean curvature. Compared to earlier results of the same character, we develop a new constructive approach that applies to a larger class of nonlinearities and yields much more precise information about the solutions under consideration.

Keywords

Cite

@article{arxiv.1808.02471,
  title  = {Interface dynamics in semilinear wave equations},
  author = {Manuel del Pino and Robert Jerrard and Monica Musso},
  journal= {arXiv preprint arXiv:1808.02471},
  year   = {2020}
}

Comments

34 pages

R2 v1 2026-06-23T03:27:05.492Z