This paper presents the complete resolution of the regularity and turbulence statistical structure of the Navier–Stokes equations. By introducing the hierarchical multiscale decomposition—a refinement of Littlewood–Paley theory—we prove global regularity: the three-dimensional Navier–Stokes equations are globally well-posed in the critical Sobolev space Ḣ^1/2. We also establish turbulence closure: the energy cascade E (k) k^-5/3 is derived from first principles without phenomenological assumptions. In addition, we show computational feasibility: finite hierarchical truncations converge to the true solution with controllable error. The core method involves precise estimates for the hierarchical projection operators P^ () and scale-coupling functionals C^ (, +1), transforming multiscale interactions into a closed system of hierarchical equations. The approach is inspired by the framework of Hyperology (Wang, 2026), wherein physical reality is understood as a cumulative hierarchy V_, with self-consistency achieved through Gödelian transitions across scales.
Yaao Wang (Mon,) studied this question.
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