Finite time blowup for an averaged three-dimensional Navier-Stokes equation

Abstract

The Navier-Stokes equation on the Euclidean space R3 can be expressed in the form ∂t u = u + B(u,u), where B is a certain bilinear operator on divergence-free vector fields u obeying the cancellation property B(u,u), u=0 (which is equivalent to the energy identity for the Navier-Stokes equation). In this paper, we consider a modification ∂t u = u + B(u,u) of this equation, where B is an averaged version of the bilinear operator B (where the average involves rotations and Fourier multipliers of order zero), and which also obeys the cancellation condition B(u,u), u = 0 (so that it obeys the usual energy identity). By analysing a system of ODE related to (but more complicated than) a dyadic Navier-Stokes model of Katz and Pavlovic, we construct an example of a smooth solution to such a averaged Navier-Stokes equation which blows up in finite time. This demonstrates that any attempt to positively resolve the Navier-Stokes global regularity problem in three dimensions has to use finer structure on the nonlinear portion B(u,u) of the equation than is provided by harmonic analysis estimates and the energy identity. We also propose a program for adapting these blowup results to the true Navier-Stokes equations.