English

Linear and nonlinear parabolic forward-backward problems

Analysis of PDEs 2025-10-23 v6

Abstract

The purpose of this paper is to investigate the well-posedness of several linear and nonlinear equations with a parabolic forward-backward structure, and to highlight the similarities and differences between them. The epitomal linear example will be the stationary Kolmogorov equation yxuyyu=fy\partial_x u -\partial_{yy} u=f in a rectangle. We first prove that this equation admits a finite number of singular solutions, of which we provide an explicit construction. Hence, the solutions to the Kolmogorov equation associated with a smooth source term are regular if and only if ff satisfies a finite number of orthogonality conditions. This is similar to well-known phenomena in elliptic problems in polygonal domains. We then extend this theory to a Vlasov--Poisson--Fokker--Planck system, and to two quasilinear equations: the Burgers type equation uxuyyu=fu \partial_x u - \partial_{yy} u = f in the vicinity of the linear shear flow, and the Prandtl system in the vicinity of a recirculating solution, close to the line where the horizontal velocity changes sign. We therefore revisit part of a recent work by Iyer and Masmoudi. For the two latter quasilinear equations, we introduce a geometric change of variables which simplifies the analysis. In these new variables, the linear differential operator is very close to the Kolmogorov operator yxyyy\partial_x -\partial_{yy}. Stepping on the linear theory, we prove existence and uniqueness of regular solutions for data within a manifold of finite codimension, corresponding to some nonlinear orthogonality conditions.

Keywords

Cite

@article{arxiv.2203.11067,
  title  = {Linear and nonlinear parabolic forward-backward problems},
  author = {Anne-Laure Dalibard and Frédéric Marbach and Jean Rax},
  journal= {arXiv preprint arXiv:2203.11067},
  year   = {2025}
}

Comments

114 pages; major revision wrt v3 ; includes 1) a new nonlinear change of variables, 2) simplified proof for Burgers, 3) construction of solutions for Prandtl, 4) minor enhancements wrt v5 (typos, figure)

R2 v1 2026-06-24T10:20:40.881Z