Study on 4D/Tetrahedral Symmetric Condensate Condensation Motion by Non-Linear Langevin Equation

Abstract

Tetrahedral symmetric condensate (TSC) with 4 deuterons and 4 electrons has been proposed as a seed of clean 4D fusion with 4 He product in condensed matter in our previous works. To solve molecular dynamics motion of 4D/TSC condensation, a nonlinear Langevin equation was formulated with a Coulombic main condensation force term under Platonic symmetry, 6 balancing forces of dde*(2,2) EQPET molecules on 6 faces of TSC cube, and a random quantum mechanical fluctuation term f(t) for deuteron-to-deuteron distance R dd . The form of ensemble average becomes C/R dd 2 type deceleration force as positive bias to main condensation force, to be about 15% bias. Molecular dynamics calculation with TSC Langevin equation by the Verlet time-step method was then done. Barrier factors for fusion reactions as a function of R dd (t) and 4D fusion rate per TSC generation were calculated using modeled potentials and Fermi's golden rule. We found that 4D/TSC got to the TSC-minimum state with 10 fm-20 fm radius in 1.4007 fs and 4D fusion rate was about 100% per 4D/TSC generation-condensation. Thus we concluded that 4 He production rate by 4D/TSC was equal to two times the 4D/TSC generation rate in condensed matter (e.g., PdDx).