English

Regularity theory for general stable operators: parabolic equations

Analysis of PDEs 2017-03-09 v2

Abstract

We establish sharp interior and boundary regularity estimates for solutions to tuLu=f(t,x)\partial_t u - L u = f(t, x) in I×ΩI\times \Omega, with IRI \subset \mathbb{R} and ΩRn\Omega \subset\mathbb{R}^n. The operators LL we consider are infinitessimal generators of stable L\'evy processes. These are linear nonlocal operators with kernels that may be very singular. On the one hand, we establish interior estimates, obtaining that uu is C2s+αC^{2s+\alpha} in xx and C1+α2sC^{1+\frac{\alpha}{2s}} in tt, whenever ff is CαC^{\alpha} in xx and Cα2sC^{\frac{\alpha}{2s}} in tt. In the case fLf\in L^\infty, we prove that uu is C2sϵC^{2s-\epsilon} in xx and C1ϵC^{1-\epsilon} in tt, for any ϵ>0\epsilon > 0. On the other hand, we study the boundary regularity of solutions in C1,1C^{1,1} domains. We prove that for solutions uu to the Dirichlet problem the quotient u/dsu/d^s is H\"older continuous in space and time up to the boundary Ω\partial\Omega, where dd is the distance to Ω\partial\Omega. This is new even when LL is the fractional Laplacian.

Keywords

Cite

@article{arxiv.1511.06301,
  title  = {Regularity theory for general stable operators: parabolic equations},
  author = {Xavier Fernández-Real and Xavier Ros-Oton},
  journal= {arXiv preprint arXiv:1511.06301},
  year   = {2017}
}
R2 v1 2026-06-22T11:49:41.469Z