Log-free estimate for the resonant paraproduct in the 3D Navier-Stokes equations

Abstract

We consider the resonant paraproduct (high-high low regime) in the nonlinearity (u·∇)u for the three-dimensional Navier-Stokes equations. For sufficiently smooth, divergence-free u, we establish the a priori estimate without logarithmic loss \|RN(u)\| H-1 N-1\,\|u\| H1/2\,\|u\| H1, with a constant independent of the dyadic frequency N. The proof combines phase-geometric integration by parts along an adapted frame, wave-packet discretization at scale N-1/2, and an anisotropic Strichartz estimate on time windows of length N-1/2. In the wide angular region we apply bilinear decoupling on a rank-3 phase surface; in the geometry at hand the minimal curvature yields a gain of order N-1/6+o(1) (with o(1) 0 as N∞), which suffices to remove the logarithmic loss. The contribution from the narrow region is handled separately by an energy argument in H-1 using null-form suppression near the interaction diagonal. The resulting bound is scale-consistent and requires no smallness assumptions, only the divergence-free condition on u. The analysis is restricted to a single resonant component of the paraproduct; potential extensions are discussed.

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