Nuclear Fission: Numerical Demonstrations of Equivalence Between the Standard Model and Quarkbase Cosmology presents a direct numerical demonstration that nuclear-fission energetics—traditionally explained through mass defects and binding-energy differences—are exactly reproduced by the pressure-based formulation of Quarkbase Cosmology. Using only experimentally measured nuclear data, the analysis shows: the canonical ~200 MeV released per fission of ²³⁵U, the standard nuclear-energy density ~8×10¹³ J/kg, the liquid-drop surface-energy coefficient, and the hydrogen-level resonant energy scale are all obtained identically in both frameworks. The equivalence emerges from a single geometric identity: σ ΔA in Quarkbase (etheric surface tension × change in nuclear surface area) encodes exactly the same energy that the Standard Model attributes to Δm c². The paper computes all quantities explicitly: nuclear radii and areas, surface-area changes in asymmetric fission, effective σ consistent with the liquid-drop model, pressure–volume work in the quarkic medium, and the correspondence between E = mc², σΔA, and ΔP_bind·v_q. The key conclusion is not that the Standard Model is wrong, but that its numerical predictions can be reinterpreted as geometric pressure relaxations in a continuous etheric plasma. The numbers are identical. The interpretation is radically different. This result strengthens the consistency of Quarkbase Cosmology by showing that nuclear observables do not discriminate between the two theories—only the physical ontology does.
Date: Dez 07, 2025
Author: Carlos Omeñaca Prado
ORCID: https://orcid.org/0009-0001-9750-5827
Resource type: Preprint
Publisher: Zenodo
License: CC BY-SA 4.0 International
Related links:
- https://zenodo.org/records/17716663
- https://archive.org/details/nuclear-fission-numerical-demonstrations-of-equivalence-between-the-standard-mod
- https://www.academia.edu/145262162/Nuclear_Fission_Numerical_Demonstrations_of_Equivalence_Between_the_Standard_Model_and_Quarkbase_Cosmology