English

Eulerian dynamics with a commutator forcing II: flocking

Analysis of PDEs 2017-01-27 v1

Abstract

We continue our study of one-dimensional class of Euler equations, introduced in \cite{ST2016}, driven by a forcing with a commutator structure of the form [\aLϕ,u](ρ)=ϕ(ρu)(ϕρ)u[\aL_\phi,u](\rho)=\phi*(\rho u)- (\phi*\rho)u, where uu is the velocity field and ϕ\phi belongs to a rather general class of \emph{influence} or interaction kernels. In this paper we quantify the large-time behavior of such systems in terms of \emph{fast flocking} for two prototypical sub-classes of kernels: bounded positive ϕ\phi's, and singular ϕ(r)=r(1+\a)\phi(r) = r^{-(1+\a)} of order α[1,2)\alpha\in [1,2) associated with the action of the fractional Laplacian \aLϕ=(xx)α/2\aL_\phi=-(-\partial_{xx})^{\alpha/2}. Specifically, we prove fast velocity alignment as the velocity u(,t)u(\cdot,t) approaches a constant state, uuˉu \to \bar{u}, with exponentially decaying slope and curvature bounds ux(,t)+uxx(,t)e\dt|u_x(\cdot,t)|_{\infty}+ |u_{xx}(\cdot,t)|_{\infty}\lesssim e^{-\d t}. The alignment is accompanied by exponentially fast flocking of the density towards a fixed traveling state ρ(,t)ρ(xuˉt)0\rho(\cdot,t) - {\rho_{\infty}}(x - \bar{u} t) \rightarrow 0.

Cite

@article{arxiv.1701.07710,
  title  = {Eulerian dynamics with a commutator forcing II: flocking},
  author = {R. Shvydkoy and E. Tadmor},
  journal= {arXiv preprint arXiv:1701.07710},
  year   = {2017}
}
R2 v1 2026-06-22T18:01:19.899Z