A simple proof of uniqueness of the particle trajectories for solutions of the Navier-Stokes equations

Abstract

We give a simple proof of the uniqueness of fluid particle trajectories corresponding to: 1) the solution of the two-dimensional Navier Stokes equations with an initial condition that is only square integrable, and 2) the local strong solution of the three-dimensional equations with an H1/2-regular initial condition i.e.\ with the minimal Sobolev regularity known to guarantee uniqueness. This result was proved by Chemin & Lerner (J Diff Eq 121 (1995) 314-328) using the Littlewood-Paley theory for the flow in the whole space d, d 2. We first show that the solutions of the differential equation X=u(X,t) are unique if u∈ Lp(0,T;H(d/2)-1) for some p>1 and t\,u∈ L2(0,T;H(d/2)+1). We then prove, using standard energy methods, that the solution of the Navier-Stokes equations with initial condition in H(d/2)-1 satisfies these conditions. This proof is also valid for the more physically relevant case of bounded domains.