Fusion is a two step process. The first step is the tunneling of the one or more He2 nuclei into the as yet to be realized resultant nucleus. This process may occur as a superposition of many separate nuclear events where multiple nuclei tunnel into the resultant nucleus and yet still be at a distance from that the future resultant nucleus.
Many individual protons can be at many different places at the same point in time The instant of fusion is the de-entanglement of the these multiple incoming subordinate nuclei. This is the time of energy transfer of the binding energy over the EMF strong coupling. The time that the EMF strong coupling must remain in place begins when the first nuclei of all the tunneling of the multiple nuclei begins until the transfer of the liberated binding energy marks the de-entanglement(energy transfer) of the reaction via the EMF strong coupling. Superposition is how tunneling works. In other words, superposition of all the participating nuclei can buy enough time for the cluster fusion to occur. This superposition can exist for a very long time. See http://en.wikipedia.org/wiki/Quantum_superposition for a video see https://www.youtube.com/watch?v=3E3QT-QU0bw On Fri, Sep 12, 2014 at 9:00 PM, <mix...@bigpond.com> wrote: > In reply to Axil Axil's message of Fri, 12 Sep 2014 20:33:47 -0400: > Hi, > >If the reaction energy of 6 MeV is mostly transferred to the lattice > >(soliton) via EMF strong coupling, the second proton of the He2 pair can > >drift out of the reaction zone with a energy of just a few KeV. > > > >With strong EMF coupling, an expelled particle need not be the primary > >carrier of the binding energy excess. > [snip] > Consider distance. An EMF coupling is bound to the speed of light, and if > the > reaction happens in a time frame on the order of 1E-22 seconds, then the > distance over which such an interaction could occur is limited to > c*1E-22*sec = > 16 fm. That means interactions with other parts of the nucleus are > possible, but > not with other atoms. This is why most nuclear reactions involve ejection > of > particles. > Regards, > > Robin van Spaandonk > > http://rvanspaa.freehostia.com/project.html > >
