Abstract: The classical Navier-Stokes equations rely on the continuum hypothesis, assuming fluids remain infinitely divisible under all stress conditions. However, this assumption leads to finite-time singularities ("blow-up") when energy cascades to atomic scales. This paper proposes the Electro-Atomic Rupture Theory (EAR Theory) as a physical resolution to the Millennium Prize problem. Key Contributions of Version 4: This updated version includes rigorous numerical verification based on Lagrangian Particle Dynamics simulations. The results demonstrate that: Laminar Consistency: Under low velocities (v < vcrit), the model perfectly aligns with classical Navier-Stokes predictions. Rupture Singularity: At the critical velocity threshold (vcrit = 1. 5), the simulation captures a definitive "Rupture Event" at t = 1. 38s, where acceleration diverges (a → aₘax). Energy Release: The post-rupture phase exhibits a kinetic energy surge approximately 400% higher than classical predictions, confirming the mechanism of the singularity. Methodology: We introduce a "Critical Rupture Function" (χ) based on the Heaviside Step Function into the effective viscosity term. This operator mathematically models the breaking of intermolecular electromagnetic bonds (Van der Waals forces), transforming the continuous viscous flow into a discrete, chaotic particle system. Conclusion: The study proves that turbulence is not a random chaotic event but a deterministic phase transition caused by the failure of the fluid's binding field. This provides a physically rigorous cutoff for the energy cascade, resolving the finite-time blow-up problem.
Ahmet Ünal (Tue,) studied this question.