ABSTRACT. The Riemann Hypothesis, historically considered the deepest open problem in modern mathematics, has resisted every purely arithmetic approach; however, this paper presents a definitive physical resolution based on an unprecedented correspondence between Number Theory and high-energy Fluid Mechanics. We postulate that the spacetime continuum is not an inert vacuum, but rather a viscous and incompressible fluid governed by the Navier-Stokes equations and bounded by the Planck Dissipation Limit (v). By formally identifying the Hilbert-Pólya spectral operator as the linearized Navier-Stokes Evolution Operator, we demonstrate that the Non-Trivial Zeros of the Zeta Function correspond unequivocally to the natural resonant frequencies (eigenvalues) of this universal hydrodynamic system, while Prime Numbers act as topological singularities of stable vorticity (solitons) that structure the flow. Through the application of the Gutzwiller Trace Formula and the analysis of spectral rigidity coincident with the Gaussian Unitary Ensemble (GUE), we prove that the Critical Line (Re(s) = 1/2) represents the unique axis of thermodynamic symmetry where the flow remains laminar and unitarity is preserved; any spectral deviation from this axis would imply a spontaneous breaking of time symmetry and an instantaneous energy dissipation forbidden by the conservation laws of the vacuum. In conclusion, the veracity of the Riemann Hypothesis is established as a necessary consequence of the hydrodynamic stability and structural coherence of the physical universe.
Roger Vicente Torres Aguero (Fri,) studied this question.