Eulerian dynamics with a commutator forcing II: flocking

Abstract

We continue our study of one-dimensional class of Euler equations, introduced in ST2016, driven by a forcing with a commutator structure of the form [φ,u]()=φ*( u)- (φ*)u, where u is the velocity field and φ belongs to a rather general class of influence or interaction kernels. In this paper we quantify the large-time behavior of such systems in terms of fast flocking for two prototypical sub-classes of kernels: bounded positive φ's, and singular φ(r) = r-(1+) of order α∈ [1,2) associated with the action of the fractional Laplacian φ=-(-∂xx)α/2. Specifically, we prove fast velocity alignment as the velocity u(·,t) approaches a constant state, u u, with exponentially decaying slope and curvature bounds |ux(·,t)|∞+ |uxx(·,t)|∞ e- t. The alignment is accompanied by exponentially fast flocking of the density towards a fixed traveling state (·,t) - ∞(x - u t) → 0.