There should be 9 muons produced for each reaction of a photon with a H in the dense hydrogen material. If the incoming photon has enough energy to exceed the binding energy holding one muon to the other 8 in a nucleon, then the dissassembly of the entire neucleon may happen spontaneously.
Hatt’s model may allow prediction of that energy and a validation via the number of muons produced by an interaction of 1 photon and one nucleon. A threshold energy for the incident laser photons , necessary to produce muons, should be expected, if the reaction is as suggested above. I may be that Holmlid already has the data on minimal energies for the photon flux need for production of muons. Asssuming a nucleon structure that can be aligned in a magnetic field, and a direction of the photon beam, the suggested reaction may be significantly enhanced and otherwise controlled. Bob Cook ________________________________ From: mix...@bigpond.com <mix...@bigpond.com> Sent: Friday, April 5, 2019 4:34:09 PM To: vortex-l@eskimo.com Subject: Re: [Vo]:A backdoor to proton annihilation? In reply to JonesBeene's message of Fri, 5 Apr 2019 15:31:57 -0700: Hi Jones, [snip] If such a mechanism exists, then it implies the relatively easy conversion of matter into anti-matter, and probably also the reverse. A slight asymmetry in the ease of conversion from one to the other may also explain the preponderance or ordinary matter in the universe. I.e. if it's easier for anti-matter to convert to ordinary matter than the reverse, then in the early universe, before the formation of elements higher than Hydrogen, when it was still very dense, almost all anti-matter would convert to ordinary matter. Perhaps the dense H where the electrons and protons are close enough, makes the reverse reaction to anti-matter possible with a little prodding? Regards, Robin van Spaandonk local asymmetry = temporary success
