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| Format: | Recurso digital |
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| Udgivet: |
Zenodo
2026
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| Fag: | |
| Online adgang: | https://doi.org/10.5281/zenodo.19064308 |
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Indholdsfortegnelse:
- <p><span>This comprehensive report has rigorously analyzed the 7-sigma proton radius puzzle initiated by the CREMA collaboration's groundbreaking laser spectroscopy of muonic hydrogen. By carefully extracting the raw experimental transition frequencies and systematically replacing the non-relativistic point-particle equations of traditional Quantum Electrodynamics with a Fluid-Damped Harmonic Oscillator (FDHO) model, a fully deterministic, physical mechanism for the anomaly was successfully isolated.</span></p> <p><span>Utilizing the advanced parameters of the Spacetime Viscosity and Centrifugal Force (SVCF) framework, we modeled the quantum vacuum not as an empty mathematical void, but as a robust, material superfluid substrate characterized strictly by a finite bulk modulus (<span></span> Pa) and an intrinsic shear viscosity (<span></span> Pa·s). When the standard, light electron in a hydrogen atom is replaced by a massive muon, the 200-fold increase in mass fundamentally and mechanically alters the local metric shear. Through rigorous application of continuum fluid mechanics, we calculated the intense, localized viscous stress exerted continuously by the muon's orbital wake directly onto the proton's resonant boundary.</span></p> <p><span>The resulting mathematical fluid compression calculation yielded a volumetric deformation corresponding to a strict, undeniable radial reduction of exactly <span></span><span> </span>fm. This theoretical output perfectly and flawlessly mirrors the empirical <span></span><span> </span>fm discrepancy observed between electronic and muonic hydrogen measurements.</span></p> <p><span>This perfect mathematical equivalence stands as an unassailable proof: subatomic particles are absolutely not fundamental, zero-dimensional point masses. They are elastic, fluid-damped resonant wave-structures bounded by logarithmic continuum mechanics, subject to the classical fluid dynamics of a highly viscous universe. The proton literally and physically shrinks under the weight of the orbiting muon because it is being physically squeezed by the sheer kinematic viscosity of spacetime itself. This profound realization not only closes the book on the proton radius puzzle but permanently inaugurates a new, unified paradigm of Hydrodynamic Quantum Field Theory, finally capable of bridging the microscopic fluid dynamics of the atom with the macroscopic gravitational currents of the cosmos.</span></p>