Title : The most efficient mechanism for generating compact massive electron pairs as a basis for low-temperature catalytic nuclear fusion
Abstract:
Mass spectrometer experiments confirmed the existence of atoms with increased masses, indicating the existence of compact massive electron (ee) - pairs. It is believed that efficient overcoming of Coulomb repulsion during the formation of (ee) - pairs is achieved through tunneling as electrons approach each other at distances of ≈ 10-11 m, when the barrier transparency coefficient is D ≈ 0.2542. A recent analysis of nuclear fusion mechanisms using specialized devices showed that the most efficient mechanism for bringing electrons together is the transverse compression of a sufficiently dense electron beam. Compression is achieved primarily through magnetic dipole-dipole interaction forces under conditions of high relative permittivity. The formation of one-dimensional chains and two-dimensional networks of (ee) pairs ensures the rapid formation of intermediate quasi-molecular states (IQMS). IQMS contain a catalytic ring in the internuclear space with a set of N (ee) - pairs in a ring-shaped orbit. The electron shells of positive ions or polar molecules are polarized in the presence of KKN - activators, leading to the capture of activators and the formation of IQMS. The performance of the unique Energoniva facility was analyzed. The analysis showed that producing macroscopic quantities of (ee) - pairs is a relevant and, most importantly, achievable goal. Massive, compact electron (ee) - pairs represent a powerful resource for the development of a new field of materials science. It can be said that the romantic era of studying low-temperature nuclear reactions, corresponding to Rutherford's classification of "...there's something in this...," has come to an end.
