I agree that the Boomsma thesis is a gold mine of information. NICE WORK AXIL!
Interesting that a key nuclear theory identified by Boomsma was available in 1961. . However, I do not think it will take a century to understand LENR unless the establishment cover-up conspiring factions increase their efforts by a lot—AHOaL. Bob Cook From: Axil Axil<mailto:janap...@gmail.com> Sent: Wednesday, April 12, 2017 6:36 PM To: vortex-l<mailto:vortex-l@eskimo.com> Subject: Re: [Vo]:The process by which the proton decays in LENR In this edition of EGO OUT (Tuesday, April 11, 2017) Peter has referenced a wonderful and impactful idea in this article: Proton-nuclei smashups yield clues about 'quark gluon plasma'Physicists probe exotic state of nuclear matter at Europe's LHC https://www.sciencedaily.com/releases/2017/04/170410130104.htm?utm_source=feedburner&utm_medium=email&utm_campaign=Feed%3A+sciencedaily%2Ftop_news%2Ftop_science+%28ScienceDaily%3A+Top+Science+News%29 Science is studying the "chiral magnetic effect" (CME) in Quark-gluon plasma, or QGP. The magnetic fields that are generated in the QGP have a similar effect on quarks that LENR has on protons. The CME that appeared after the big bang in the QGP that existed back then was strong enough to keep energy from condensing into protons. Now-a-days, such vacuum altering magnetic fields are only seen in LENR. As stated by Jorn Kerst Boomsma in the summary of his thesis: https://www.nikhef.nl/pub/services/biblio/theses_pdf/thesis_J_Boomsma.pdf Effects of instanton interactions on the phases of quark matter IMHO, this thesis is a goldmine for LENR theory. "Summary” “There are strong indications that in heavy-ion collisions a new phase of matter is created, quark matter, which is a state of matter with deconfined quarks. Besides being created in heavy-ion collisions, it is also believed to have existed in early universe. Today it might exist in the interior of very dense neutron stars. In this thesis we have studied how quark matter is influenced by instantons. These nonperturbative effects are closely related to the QCD vacuum angle θ. Because of the existence of instantons observables can become θ-dependent. In Nature θ appears to be very close zero, an additional argument for this was presented in Chapter 4 of this thesis. In heavy-ion collisions θ may effectively become nonzero, at least that conclusion is drawn from an effective low-energy theory of the strong interaction. When θ is different from 0 (mod π), the theory is not invariant under CP." As additional background on this subject, the following article explains why CP violation is important to how the universe was created after the big bang: http://cerncourier.com/cws/article/cern/28092
