Global Well-Posedness of the 3D Navier-Stokes Equations under Multi-Level Logarithmically Improved Criteria

Abstract

This paper extends our previous results on logarithmically improved regularity criteria for the three-dimensional Navier-Stokes equations by establishing a comprehensive framework of multi-level logarithmic improvements. We prove that if the initial data u0 ∈ L2(R3) satisfies a nested logarithmically weakened condition \|(-)s/2u0\|Lq(R3) ≤ C0Πj=1n (1 + Lj(\|u0\|Hs))δj for some s ∈ (1/2, 1), where Lj represents j-fold nested logarithms, then the corresponding solution exists globally in time and is unique. The proof introduces a novel sequence of increasingly precise commutator estimates incorporating multiple layers of logarithmic corrections. We establish the existence of a critical threshold function (s,q,\δj\j=1n) that completely characterizes the boundary between global regularity and potential singularity formation, with explicit asymptotics as s approaches the critical value 1/2. This paper further provides a rigorous geometric characterization of potential singular structures through refined multi-fractal analysis, showing that any singular set must have Hausdorff dimension bounded by 1 - Σj=1n δj1+δj · 1j+1. Our results constitute a significant advancement toward resolving the global regularity question for the Navier-Stokes equations, as we demonstrate that with properly calibrated sequences of nested logarithmic improvements, the gap to the critical case can be systematically reduced.

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