Higher integrability and the number of singular points for the Navier-Stokes equations with a scale-invariant bound

Abstract

First, we show that if the pressure p (associated to a weak Leray-Hopf solution v of the Navier-Stokes equations) satisfies \|p\|L∞t(0,T*; L32,∞(R3))≤ M2, then v possesses higher integrability up to the first potential blow-up time T*. Our method is concise and is based upon energy estimates applied to powers of |v| and the utilization of a `small exponent'. As a consequence, we show that if a weak Leray-Hopf solution v first blows up at T* and satisfies the Type I condition \|v\|L∞t(0,T*; L3,∞(R3))≤ M, then ∇ v∈ L2+O(1M)(R3× (12T*,T*)). This is the first result of its kind, improving the integrability exponent of ∇ v under the Type I assumption in the three-dimensional setting. Finally, we show that if v:R3× [-1,0]→ R3 is a weak Leray-Hopf solution to the Navier-Stokes equations with sn 0 such that n\|v(·,sn)\|L3,∞(R3)≤ M then v possesses at most O(M20) singular points at t=0. Our method is direct and concise. It is based upon known -regularity, global bounds on a Navier-Stokes solution with initial data in L3,∞(R3) and rescaling arguments. We do not require arguments based on backward uniqueness nor unique continuation results for parabolic operators.