English

Eulerian dynamics with a commutator forcing

Analysis of PDEs 2016-12-14 v1

Abstract

We study a general class of Euler equations driven by a forcing with a \emph{commutator structure} of the form [L,u](ρ)=L(ρu)L(ρ)u[\mathcal{L},\mathbf{u}](\rho)=\mathcal{L}(\rho \mathbf{u})- \mathcal{L}(\rho)\mathbf{u}, where u\mathbf{u} is the velocity field and L\mathcal{L} is the "action" which belongs to a rather general class of translation invariant operators. Such systems arise, for example, as the hydrodynamic description of velocity alignment, where action involves convolutions with bounded, positive influence kernels, Lϕ(f)=ϕf\mathcal{L}_\phi(f)=\phi*f. Our interest lies with a much larger class of L\mathcal{L}'s which are neither bounded nor positive. In this paper we develop a global regularity theory in the one-dimensional setting, considering three prototypical sub-classes of actions. We prove global regularity for \emph{bounded} ϕ\phi's which otherwise are allowed to change sign. Here we derive sharp critical thresholds such that sub-critical initial data (ρ0,u0)(\rho_0,u_0) give rise to global smooth solutions. Next, we study \emph{singular} actions associated with L=(xx)α/2\mathcal{L}=-(-\partial_{xx})^{\alpha/2}, which embed the fractional Burgers' equation of order α\alpha. We prove global regularity for α[1,2)\alpha\in [1,2). Interestingly, the singularity of the fractional kernel x(n+α)|x|^{-(n+\alpha)}, avoids an initial threshold restriction. Global regularity of the critical endpoint α=1\alpha=1 follows with double-exponential W1,W^{1,\infty}-bounds. Finally, for the other endpoint α=2\alpha=2, we prove the global regularity of the Navier-Stokes equations with density-dependent viscosity associated with the \emph{local} L=Δ\mathcal{L}=\Delta.

Keywords

Cite

@article{arxiv.1612.04297,
  title  = {Eulerian dynamics with a commutator forcing},
  author = {Roman Shvydkoy and Eitan Tadmor},
  journal= {arXiv preprint arXiv:1612.04297},
  year   = {2016}
}

Comments

22 pages

R2 v1 2026-06-22T17:22:36.292Z