The mechanism of autocatalytic synthesis of nuclei and CR-activators

Abstract

The symmetric binuclear model of quasi-molecular states (QMS) is presented as a theoretical framework extending muonic catalysis concepts to cold nuclear fusion phenomena. This model proposes nuclear convergence through attraction to high-density negative charge configurations formed by bound electron (ee) pairs occupying toroidal orbitals in the internuclear region. These structural formations, designated as CRN activators (where N indicates (ee) pair multiplicity), function as catalytic centers for nuclear processes. Experimental validation includes mass spectrometry analysis of titanium isotopes revealing anomalous mass peaks consistent with model predictions. Extension to trinuclear QMS systems demonstrates enhanced CR4 activator formation during nickel synthesis from silicon and oxygen, with observed production rates doubling those of baseline CR2 activators. The analysis identifies cold nuclear fusion as a potential clean energy source with dual capability: direct energy generation and production of fissile materials for conventional nuclear power applications. These findings suggest significant implications for future energy systems combining fusion and fission technologies. © The Authors, published by EDP Sciences.