Furkejuvvon:
| Váldodahkkit: | , |
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| Materiálatiipa: | Recurso digital |
| Giella: | |
| Almmustuhtton: |
Zenodo
2025
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| Liŋkkat: | https://doi.org/10.5281/zenodo.17799766 |
| Fáddágilkorat: |
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Sisdoallologahallan:
- The global regularity problem for the three-dimensional incompressible Navier-Stokes equations remains one of the most significant unsolved challenges in mathematical physics. This paper addresses the potential absence of singularity formation by introducing a novel framework centered on new energy flux bounds. Traditional energy estimates provide insufficient control over the highest frequency components of the fluid velocity, which are believed to be the precursors to finite-time blow-up. Our methodology leverages a refined decomposition of the energy spectrum and derives bounds on the inter-scale energy transfer mechanisms that are demonstrably stronger than classical bounds. By meticulously analyzing the turbulent energy cascade at different scales, we establish conditions under which the rate of energy flux into high-frequency modes is strictly limited, preventing the catastrophic accumulation of enstrophy. The results demonstrate that, provided certain initial data conditions are met, these new flux bounds are sufficient to preclude the formation of finite-time singularities, thus implying global regularity. This approach offers a promising direction for resolving the Millennium Prize Problem, highlighting the crucial role of precise energy dissipation and transfer mechanisms in maintaining solution regularity.