My guess is that the 2-D layers create 2-D systems of Pd with high magnetic fields and resulting in a BEC of paired D which are coupled to the electrons of the Ni mesh. The spin energy of the Ni isotopes and maybe the Pd isotopes is given up to the lattice electrons of the Ni isotopes with nuclear transmutations and respective energy loss.
I am not sure I understand the reaction Jones suggests regarding D emissions at 630 ev. I think the nuclear transmissions are all EM involving nuclear spin states and associated energy differentials of the various isotopic spin energy. A modification of the magnetic field and resonant conditions which are probably a function of temperature would provide data related to the nuclear reactions taking place. A controlled frequency laser or other fine-tuned EM radiation should be applied with monitoring of energy production. Isotopic shifts should also be monitored as a function of time. Some nuclear magnetic resonance monitors may be gainfully employed to look for isotopic changes. (I doubt Mizuno has such equipment, but no doubt it is readily available from vendors in Japan.} The capabilities of the NMR machines should be available from vendors such as Nananalysis. http://www.nanalysis.com/?gclid=EAIaIQobChMIp9G37uf14gIVlcJkCh0e1gyvEAAYASAAEgJEwvD_BwE Bob Cook From: JonesBeene<mailto:jone...@pacbell.net> Sent: Wednesday, June 19, 2019 7:01 AM To: vortex-l@eskimo.com<mailto:vortex-l@eskimo.com> Subject: RE: [Vo]:Mizuno reports increased excess heat Robin, Another looming possibility is that only sparse nuclear fusion reactions are happening but most of the thermal gain comes from BEC dominated processes where mass is converted into energy in such a way that the thermal gain is more than chemical but less than fusion. Most likely the excess mass being converted is related to strong force dynamics via Quantum Chromodynamics. It seems likely that nickel does not promote fusion and the tiny amount of palladium is insufficient for the large amount of heat Mizuno is seeing. The possibility of non-fusion QCD reactions is hinted at in the previously cited Hora paper but it is not their interpretation. “Surface Effect for Gas Loading Micrograin Palladium for Low Energy Nuclear Reactions LENR” By Heinrich Hora, George H Miley, Mark A Prelas, Kyu Jung Kim and Xiaoling Yang This paper keeps turning up because of the “micrograin palladium” parameter – in contrast to bulk Pd. It is all about clustering of bosons which can lead to fusion on rare occasion, but otherwise most of the heat of the process can derive from the clustering dynamics of the high temperature BEC. Curiously, the microcracking structure popularized by Ed Storms could relate to the same NON-fusion pathway for gain despite his insistence otherwise. Quantum Chromodynamics can be seen a natural outcome of a disturbance in the large deuterium cluster – the very tight packing in the BEC which can be hundreds of atoms. According to the paper - deuterons collect in the cracks as a condensate, in extremely dense accumulations at room temperature but fuse rarely due to their low colliding energy of several 10 meV. However, this is sufficiently high that van-der-Waals forces or the increased Casimir forces at the pm distance may lead to the fluid state where deuterons clinch together tp form clusters and then oscillate in and out of the BEC state. It should be noted, that clusters with 100 deuterons of the size of one crystal void (Schottky defect) were measured in palladium ... These states could directly be identified from the deuteron emission energy of 630 eV from clear measured mass spectrometry. Wow – they clearly measured this level of gain which cannot be related to fusion. 630 eV is a huge amount of energy compared to chemical but tiny for a nuclear processl - and yet it can derive from a bulk clustering process where the only radiation would be extreme UV radiation and eventually lots of heat. ----------------------------------------------------- Should separation distance between metals prove to be important, then a very small separation between two metal sheets can be obtained by etching a honeycomb pattern into fine gold leaf, and using it to separate the two target metal sheets. This could allow gas pressures as high as 17 atm. to be used if so desired. Regards, Robin van Spaandonk local asymmetry = temporary success
