Conditional regularity of solutions of the three dimensional Navier-Stokes equations and implications for intermittency

Abstract

Two unusual time-integral conditional regularity results are presented for the three-dimensional Navier-Stokes equations. The ideas are based on L2m-norms of the vorticity, denoted by m(t), and particularly on Dm = mαm, where αm = 2m/(4m-3) for m≥ 1. The first result, more appropriate for the unforced case, can be stated simply : if there exists an 1≤ m < ∞ for which the integral condition is satisfied (Zm=Dm+1/Dm) ∫0t (1 + Zmc4,m) dτ ≥ 0 then no singularity can occur on [0, t]. The constant c4,m 2 for large m. Secondly, for the forced case, by imposing a critical lower bound on ∫0tDm dτ, no singularity can occur in Dm(t) for large initial data. Movement across this critical lower bound shows how solutions can behave intermittently, in analogy with a relaxation oscillator. Potential singularities that drive ∫0tDm dτ over this critical value can be ruled out whereas other types cannot.