English

Regularity and Uniqueness for a Model of Active Particles with Angle-Averaged Diffusions

Analysis of PDEs 2025-09-09 v2

Abstract

We study the regularity and uniqueness of weak solutions of a degenerate parabolic equation, arising as the limit of a stochastic lattice model of self-propelled particles. The angle-average of the solution appears as a coefficient in the diffusive and drift terms, making the equation nonlocal. We prove that, under unrestrictive non-degeneracy assumptions on the initial data, weak solutions are smooth for positive times. Our method rests on deriving a drift-diffusion equation for a particular function of the angle-averaged density and applying De Giorgi's method to show that the original equation is uniformly parabolic for positive times. We employ a Galerkin approximation to justify rigorously the passage from divergence to non-divergence form of the equation, which yields improved estimates by exploiting a cancellation. By imposing stronger constraints on the initial data, we prove the uniqueness of the weak solution, which relies on Duhamel's principle and gradient estimates for the periodic heat kernel to derive LL^\infty estimates for the angle-averaged density.

Keywords

Cite

@article{arxiv.2501.11488,
  title  = {Regularity and Uniqueness for a Model of Active Particles with Angle-Averaged Diffusions},
  author = {Luca Alasio and Simon Schulz},
  journal= {arXiv preprint arXiv:2501.11488},
  year   = {2025}
}

Comments

48 pages. Corrected version

R2 v1 2026-06-28T21:11:20.963Z