Nonlocal Hyperdissipative Perturbations of the Three Dimensional Navier-Stokes System

Abstract

We study the three-dimensional incompressible Navier-Stokes system on R3 with an additional dissipative nonlocal term \[ ∂t u + (u·∇)u + ∇ p = u + Lu, div\, u = 0, \] where L is a self-adjoint Fourier multiplier whose symbol is comparable to -||2α for some α>1. We first identify a sharp Fourier-symbol criterion distinguishing lower-order convolution perturbations from genuinely regularizing nonlocal corrections. In the resulting hyperdissipative class we prove the exact L2 energy identity, global weak solvability for every α>1, and local strong well-posedness in Hs(R3) for s>52. We then show that the Lions exponent α=54 remains the critical energy-growth threshold in this nonlocal setting: if α 54, every Hs solution is global, while for every α>1 one has global strong solvability for sufficiently small Hs data. Finally, for the vanishing-hyperdissipation approximation of the classical three-dimensional Navier-Stokes equations, we prove a near-singular divergence principle: if the classical flow blows up at a first singular time T* in a continuation norm X, then the corresponding regularized family cannot remain uniformly bounded in X on any interval approaching T*. This identifies the precise point at which the fixed-parameter global theory degenerates in the Navier-Stokes limit.