*Attosecond Protonic Quantum Entanglement in Collision Experiments with Neutrons and Electrons***
http://www.maik.ru/full/lasphys/05/6/lasphys6_05p780full.pdf Several neutron Compton scattering (NCS) experiments on liquid and solid samples containing protons or deuterons show a striking anomaly, namely, a shortfall in the intensity of energetic neutrons scattered by the protons. In condensed matter containing hydrogen, theoretical considerations suggest the presence of attosecond entanglement, in which the quantum dynamics of the scattering protons and the surrounding particles are all connected; this in turn changes the nature of the scattering results. The take away: Quantum entanglement(QE) of protons in condensed matters systems containing hydrogen is significant even at room temperature. QE will significantly absorbed and dissipate the kinetic energy of the colliding high speed neutrons (NCS) and protons/elections (ECS). Quantum entanglement will reestablish itself after decoherence. QE will persist for at least attoseconds at a minimum. On Wed, Dec 7, 2011 at 8:35 PM, <[email protected]> wrote: > In reply to Axil Axil's message of Wed, 7 Dec 2011 15:21:38 -0500: > Hi, > [snip] > >In this low temperature lattice case, coulomb shielding from the ultra > >strong dipole moments of Rydberg matter produced by the internal heater > >will still occur and cold fusion will still result in a cold lattice. But > >in this case, large amounts of unthermalized gamma radiation will be > >released because there will be no coherent protons to thermalize that > >radiation. > [snip] > Why should coherent protons be any better at thermalizing gamma radiation > than > ordinary protons? (Especially if that coherence is limited to pairs). > Regards, > > Robin van Spaandonk > > http://rvanspaa.freehostia.com/project.html > >
