On the integrability properties of Leray-Hopf solutions of the Navier-Stokes equations on R3
Abstract
Let r,s ∈ [2,∞] and consider the Navier-Stokes equations on R3. We study the following two questions for suitable s-homogeneous Banach spaces X ⊂ S': does every u0 ∈ L2σ have a weak solution that belongs to Lr(0,∞;X), and are the Lr(0,∞;X) norms of the solutions bounded uniformly in viscosity? We show that if 2r + 3s < 32-12r, then for a Baire generic datum u0 ∈ L2σ, no weak solution u belongs to Lr(0,∞;X). If 32-12r ≤ 2r + 3s < 32 instead, global solvability in Lr(0,∞;X) is equivalent to the a priori estimate \|u\|Lr(0,∞;X) ≤ C 3-5/r-6/s \|u0\|L24/r+6/s-2. Furthermore, we can only have 0 \|u\|Lr(0,∞;Z) < ∞ for all u0 ∈ L2σ if 2r + 3s= 32-12r. The above results and their variants rule out, for a Baire generic L2σ datum, L4(0,T;L4) integrability and various other known sufficient conditions for the energy equality. As another application, for suitable 2-homogeneous Banach spaces Z L2σ, each u0 ∈ Z has a Leray-Hopf solution u ∈ L3(0,∞;B3,∞1/3) if and only if a uniform-in-viscosity bound \|u\|L3(0,∞;B3,∞1/3) ≤ C \|u0\|Z2/3 holds. As a by-product we show that if global regularity holds for the Navier-Stokes equations, then for a Baire generic L2σ datum, the Leray-Hopf solution is unique and satisfies the energy equality. We also show that if global regularity holds in the Euler equations, then anomalous energy dissipation must fail for a Baire generic L2σ datum. These two results also hold on the torus T3.
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