Continuation of the first post:
This temperature control mechanism has a positive void nature. The hotter the nickel lattice gets, the more and bigger ions will be produced and admitted to the reaction area. If this positive feed back loop is not moderated, a meltdown of the reactor vessel at temperatures over 1600C will occur. The way to shut the Rossi reactor down is to cool both the nickel lattice and the hydrogen envelope below a critical temperature by increasing the flow of coolant. In this way, the lattice vibration is minimized or stopped. This will constrict both the average size of the lattice defect openings and also the production level of ions supported by the temperature of the hydrogen envelope below the level where heat can be produced in the lattice. On Wed, May 18, 2011 at 12:25 PM, Axil Axil <[email protected]> wrote: > *Temperature regulation mechanism.* > > * * > > High temperature is required to provide a vibrative movement in the walls > of the erosive cavities formed on the surface of the nickel oxide > nano-powder that are the epicenter of nuclear activity. > > > > These holes both open wide to allow the Rydburg hydrogen condensate > crystals to enter and constricted to compress them to the state of fusion. > The temperature of the metal lattice might well provide a gate keeping > function that regulates the flow of ions into the locus of the nuclear > reaction. > > > > A minimum temperature of the metal lattice is required to allow the > smallest sized ions to enter the reaction zone. As the temperature rises and > the mouths of the holes open wider, ever larger sized ions would be capable > of participating in the reaction. > > > > I would speculate that at low temperatures in the metal lattice only small > sized ions would enter and very light weight ash elements would be produced. > As the average temperature rises the ash content would favor the heavier > elements. > > > > * * > > >
