Engineering varying LENR reaction strengths. The plasmoid is another engineering mechanism that can be added to the design of a LENR system to increase the intensity of power production by amplifying long duration electric charge separation.
This charge separation is the underlying cause of LENR reactions, either as a consequence of charge masking of the coulomb barrier and/or the reduction of the permittivity of space far below the norm of 1. IMHO, experimentation conducted over the years associated with the LENR reaction makes it apparent that there is a direct relationship between the various LENR reaction engineering tools applied to produce charge separation and the variation in the strength of the LENR reaction. This LENR reaction strength is directly proportional to the level of charge separation intensity that can be achieved in the various implantations of the LENR systems. For example, Deuterium/palladium systems have low LENR reaction level because palladium supports relatively few absorbed hydrogen ions. In this low strength regime, the LENR reaction becomes apparent when the loading of ions goes beyond a certain loading level (.7) The same is true in the nickel/hydrogen systems. These hydrogen ion reactions can be strengthened with the addition of various externally applied catalytic ionic clusters. Still further LENR reaction strengthening can be achieved when plasmoids are added as a product of burst high current spark discharges that include currents of catalytic ionic clusters providing a positive nucleus surrounded with a cloud of electron currents. When coupled with plasmoid production, such cluster generation catalysts such as water, Potassium, Cesium, Krypton, Argon, and Xenon are used as ionic cluster producing reaction enhancers. Combining all these various types of Plasmoid enabled cluster based LENR system tools has produce the most powerful LENR reactions so far engineered. Cheers: Axil
