Post revised and extended as follows: One critical facet of LENR is the production of a special type of nanoparticle: a superconductive hydride. This particle is produced by the extremely high pressure exerted by the chemical bonds in the lattice of a transition metal substrate lattice. Lithium hydride is an example of such a nanoparticle.
Under extreme pressure, the hydrogen chemical bonds become symmetric, that is the hydrogen bonds become equal in length and symmetric around the proton. This metallization of the hydride produces topological superconductivity. Like in any nanowire, the SPPs will populate the surface of this superconductive nanowire. The superconductivity of the hydride nanowire will catalyze the entire ensemble of SPPs to readily form a Bose condensate which converts many individual SPPs into one super-SPP where the monopole magnetic beam that this BEC SPP projects is focused forward from the front of the hydride nanowire. This magnetic beam is very powerful as a result of super-radiance. The power of this super-radiance goes as the total number of SPPs. The production of this metalized hydride is what converts the weak LENR reaction into the powerful LENR+ reaction. Because of the BEC, the SPPs are concentrated, focused, and amplified. The monopole flux tubes produced by the SPPs generate a magnetic shield that locks the SPPs in place and solidifies the structure of the hydride nanowire. These nanowires and their superconductive nature are protected by this monopole magnetism even at temperatures (tens of thousands C) that would completely ionize any other type of matter. There is an amazing positive feedback mechanism in play between the energy that the metalized hydride produces and its structural integrity. The metalize hydride is meta stable but as the SPP BEC absorbed power, the associated magnetic fields increasingly resist any disruptive force. This feature of the LENR reaction permits the metalized hydride to produce LENR effects even in a plasma environment. This is one of the little recognize miracles of the LENR reaction. This BEC on the nanowire becomes a quasiparticle acting as an analog monopole. As we all know, a monopole produces nucleon decay into mesons as seen by Holmlid. On Wed, Apr 13, 2016 at 2:55 PM, Axil Axil <janap...@gmail.com> wrote: > One critical facet of LENR is the production of a special type of > nanoparticle: a superconductive hydride. This particle is produced by the > extremely high pressure exerted by the chemical bonds in the lattice of a > transition metal substrate lattice. Lithium hydride is an example of such a > nanoparticle. > > SPPs will populate the surface of this superconductive nanowire. The > entire ensemble of SPPs readily form a Bose condensate which converts many > individual SPPs into one super-SPP where the monopole magnetic beam that > this BEC SPP projects is focused forward from the front of the hydride > nanowire. This magnetic beam is very powerful as a result of > super-radiance. > > Because of the BEC, the SPPs are concentrated, focused, and amplified. > > This BEC on the nanowire becomes a quasiparticle acting as an analog > monopole. As we all know, a monopole produces nucleon decay into mesons as > seen by Holmlid. > > On Wed, Apr 13, 2016 at 12:19 PM, a.ashfield <a.ashfi...@verizon.net> > wrote: > >> Axil Axil wrote. "Monopole magnetic flux tubes produced by Surface >> Plasmon Polaritons embedded inside a superconductive environment produces >> nucleon decay into mesons and subsequent nuclear reconfiguration. It's as >> simple as that." >> >> That is not at all simple, I know you have written about this many times >> but it is not simple, at least for me. >> A clear explanation of the process, like Chiefio's, of what you mean >> would be most helpful. >> > >
