Title : Generation of a macroscopic number of compact massive electron (ee) pairs with increasing electron density and cold nuclear reactions
Abstract:
The intermediate quasi-molecular state (IQMS) model, which generalizes the philosophy of muonic catalysis, examines options for generating compact, massive electron (ee) - pairs, which are the basis of CRN - activators that bring nuclei together. When forming (ee) - pairs, preference is given to compressing the electron flow to distances between neighbors of the order of 10-11 m, at which point overcoming the Coulomb barrier through tunneling becomes effective. The physical essence of the legendary Energoniva facility, which enables the efficient, highperformance synthesis of elements from water, is described for the first time. The mechanism of transverse compression of the electric current in the facility's plasmoid is analyzed in detail. It is shown that the facility's high productivity is due to the abundance of generated (ee) - pairs, which form chain and two-dimensional mesh structures, and the activity of polar water molecules, which ensures the rapid formation of IQMS. With regard to Shoulders charge clusters (CCs), it was concluded that they are significantly enriched in (ee) - pairs, which immediately explains the observed formation of chemical elements during the interaction of CCs with palladium foil. Due to the limited electron drift velocity at the tip of the Shoulders cathode, the volume density of electrons increases, stimulating a field-emission pulse in the form of CCs. It was shown that under conditions of high relative permittivity, the stability of CCs and the network structuring of the plasmoid current cross-section are due to the dipole-dipole interaction of the magnetic moments of (ee)-pairs. Thus, this magnetic interaction must be taken into account.
