Yes: That pesky 'Spooky Action @ a Distance' again. Quantum spinning particles 'tailed'/quantum-singularitized through XO-PlasmicSpace(regardless of distance of separation) to be in multiple locations simultaneously interacting in 'real-time' with other particles aka quantum-units. This is also a better explanation that the 'common ion transition' explanations for the action within a HYDROGEN FUEL CELL for instance. Until this is grasped, Practical overunity-Cold Fusion will continue to allude practical application.
Date: Fri, 25 Jan 2013 21:18:12 -0500 Subject: Re: [Vo]:Chemonuclear Transitions From: janap...@gmail.com To: vortex-l@eskimo.com Energy can be transferred from one molecule to another threw a quantum mechanical mechanism. Yes http://lightyears.blogs.cnn.com/2011/12/07/diamonds-entangled-in-physics-feat/ In the case of Walmsley's study, photons were showing up in two spots at the same time and causing vibrations within a pair of diamonds. The researchers made it happen by placing two diamonds about 15 centimeters (about 6 inches) apart on a table and then shooting a series of photons at a device called a beam splitter. Most of them went toward one diamond or the other, but a few of the photons went both ways at the same time. When those multitasking photons struck the pair of diamonds, they caused vibrations called phonons with each of the crystals. The light from each of the beams recombines after exiting the crystals. And sometimes when the light is leaving the crystals, it has less energy than when it entered. That's how the researchers could tell that the photon had caused some vibrations. "We know that one diamond is vibrating, but we don't know which one," Walmsley said. "In fact, the universe doesn't know which diamond is vibrating – the diamonds are entangled, with one vibration shared between them, even though they are separated in space." Cheers: Axil On Fri, Jan 25, 2013 at 6:10 PM, Edmund Storms <stor...@ix.netcom.com> wrote: On Jan 25, 2013, at 3:49 PM, <torulf.gr...@bredband.net> <torulf.gr...@bredband.net> wrote: Excuse my grammar. English is not my native language. I will try to answer your questions as simply as possible. Can energy and momentum be transferred from the new He4 to another nucleus at some distains? No Energy can be transferred from one molecule to another threw a quantum mechanical mechanism. Yes, at chemical levels of energy This occurs in photo synthesis there excitations can jump between electrons in different molecules. Yes >From an older tread. http://www.mail-archive.com/vortex-l@eskimo.com/msg75294.html Maybe a similar phenomenon can occur between nucleus? This means the excitation from a He4 and momentum can be transferred The amount energy generated by a nuclear reaction requires direct emission of a particle, which can include a photon. This is observed fact. The magnitude is too great to use mechanisms available in a chemical structure. That is why most nuclear reactions are almost totally independent of the chemical environment. to one or more receiver nucleus. These receiver nucleus must be a special nuclide suitable for receive the energy and have a mechanism to get rid of it. If several nucleus can get energy from one He4 it may radiate it as UV. If this not is possible I suggest that the receiver nucleus is a C12 how decay to 3 He4 as an reversed triple alpha. In absence of receiver nucleus there will be no reactions. But this did not explain the overcome of the coulomb barrier and why its not works in absence of receiver nucleus. I have heard that the conservation of momentum in LENR is commonly explained to "something" how would be like the Mössbauer effect. But I understand this not so easily to explain more exactly. The Mossbauer effect involves a very small energy change. It works only because the target nucleus is very sensitive to the energy of the bombarding gamma. Therefore, the slight effect produced by the chemical lattice become visible. This effect is too small to influence energy being emitted by a fusion reaction in any meaningful way. Ed TG
