The negative charge concentration is focused into a volume of just 1 cubic nanometer, it is not hot fusion but screening of the coulomb barrier and the polaritons are readily formed into a system wide Bose Einstein condensate. Look up the term “spaser”. All this helps to lower the coulomb barrier. By the way, the main LENR reaction is not fusion but fission.
I have referenced papers here on vortex that show how this mechanism can change the half-life of U232 from 69 years to 6 microseconds. It also causes thorium to fission. On Thu, May 16, 2013 at 2:29 AM, Daniel Rocha <[email protected]> wrote: > Axil, > > I hope you just notice that the energy scale at which these phenomena > occur are puny in comparison to what is needed for fusion. > > > 2013/5/16 Axil Axil <[email protected]> > >> Dear Ed: >> >> >> http://www.google.com/url?sa=t&rct=j&q=&esrc=s&frm=1&source=web&cd=2&cad=rja&ved=0CDQQFjAB&url=http%3A%2F%2Fwww.phy-astr.gsu.edu%2Fstockman%2Fdata%2FStockman_Phys_Today_2011_Physics_behind_Applications.pdf&ei=KWKUUd2bMe610AHSy4CQBQ&usg=AFQjCNHdcmFaRe9tfcLMzk1V8uwPQ8OvXA&sig2=BHsFSNJUGxJ8Cs9T3pBlJA&bvm=bv.46471029,d.dmQ >> >> >> *A primer on Nanoplasmonics.* >> >> The concentration mechanism is a resonant constructive interference >> process called Fano interference discovered a few years ago. It produces >> the “hot spot”, which is the most significant and exciting process in >> Nanoplasmonics. >> >> Much current research into hot spots is currently underway. >> Laser light is used to produce dipole vibrations in the nanoparticles. A >> Laser only produces plain waves and excites dipole excitation poorly. >> >> The lattice of a metal produces dipole vibrations in the deep infrared >> far better than a laser ever can. >> >> The Ni/H reactor couples heat with surface electrons to produce >> polaritons at high efficiency and then the nano-particles concentrate the >> EMF in extreme concentrations. >> >> -- > Daniel Rocha - RJ > [email protected] >
