This work derives the fundamental parameters of a new, Yukawa-type force—the coupling constant and the mass—directly from the internal spiral geometry of the HLV theory, without fitting free parameters. * The coupling constant (g_{\chi}) is derived from the geometric ratio of electron and nucleon structures, scaled by the golden ratio (\varphi), and leads to a prediction for the King Plot anomaly (\delta\nu_{HLV} \approx 0.15-0.17 \text{ Hz}) that shows excellent agreement with experimental data (\approx 0.162 \text{ Hz}). * The mass of the force-mediating particle (\chi) also emerges from the theory's geometry at approximately 16.5 \text{ MeV/c}^2, which is consistent with the 10-20 MeV range inferred from experiments. * These results substantiate the internal consistency of the HLV model and elevate it from a conceptual framework to a quantitatively predictive physical theory.
- Posted
- Server
- Zenodo
- DOI
- 10.5281/zenodo.15777189
This work derives the fundamental parameters of a new, Yukawa-type force—the coupling constant and the mass—directly from the internal spiral geometry of the HLV theory, without fitting free parameters. * The coupling constant (g_{\chi}) is derived from the geometric ratio of electron and nucleon structures, scaled by the golden ratio (\varphi), and leads to a prediction for the King Plot anomaly (\delta\nu_{HLV} \approx 0.15-0.17 \text{ Hz}) that shows excellent agreement with experimental data (\approx 0.162 \text{ Hz}). * The mass of the force-mediating particle (\chi) also emerges from the theory's geometry at approximately 16.5 \text{ MeV/c}^2, which is consistent with the 10-20 MeV range inferred from experiments. * These results substantiate the internal consistency of the HLV model and elevate it from a conceptual framework to a quantitatively predictive physical theory.