A critical regularity condition on the angular velocity of axially symmetric Navier-Stokes equations

Abstract

Let v be the velocity of Leray-Hopf solutions to the axially symmetric three-dimensional Navier-Stokes equations. It is shown that v is regular if the angular velocity vθ satisfies an integral condition which is critical under the standard scaling. This condition allows functions satisfying \[ |vθ(x, t)| Cr | r|2+ε, r<1/2, \] where r is the distance from x to the axis, C and ε are any positive constants. Comparing with the critical a priori bound \[ |vθ(x, t)| Cr, 0< r 1/2, \]our condition is off by the log factor | r|2+ε at worst. This is inspired by the recent interesting paper CFZ:1 where H. Chen, D. Y. Fang and T. Zhang establish, among other things, an almost critical regularity condition on the angular velocity. Previous regularity conditions are off by a factor r-1. The proof is based on the new observation that, when viewed differently, all the vortex stretching terms in the 3 dimensional axially symmetric Navier-Stokes equations are critical instead of supercritical as commonly believed.