Nuclear Fission: Numerical Demonstrations of Equivalence Between the Standard Model and Quarkbase Cosmology

This work presents a direct numerical demonstration that the energy released in nuclear fission—as traditionally computed in the Standard Model through mass defects and binding-energy differences—is exactly reproduced by the pressure-based formulation of Quarkbase Cosmology. Without introducing new parameters and using only measured nuclear data, the Quarkbase framework recovers the canonical 200 MeV per fission of ²³⁵U, the density of nuclear energy (8 × 10¹³ J/kg), the liquid–drop surface coefficient, and the hydrogen-level resonant energy scale. The equivalence emerges from a single geometric identity: the etheric-plasma surface tension σ ΔA encodes the same energy that the Standard Model attributes to Δm c². Mass defects become pressure gradients; binding energy becomes geometric tension; and E = mc² becomes a macroscopic summary of ether-pressure storage. The numerical matches are exact. The interpretations are not. This is the point.