He has the correct mechanism, thermal vibrations. He is way off on energy. Thermal vibrations contain only a small fraction of an electron volt in energy.
He has no clue as to the frequency of vibration as related to domain size which is 1,094,000 hertz meters Frank Z -----Original Message----- From: Blaze Spinnaker <[email protected]> To: vortex-l <[email protected]> Sent: Wed, Jul 8, 2015 1:43 pm Subject: [Vo]:Re: Thermal Resonance Fusion I am seeing some critique of this on e-catworld but nobody is saying why it has to be more complicated than this. Agreed, getting the thermal resonance might be hard to do, but why can't that just be all that's required to achieve tunneling? This is by far the most compelling concept I've read on this. Interesting to see someone at the Department of Nuclear Physics, China Institute of Atomic Energy making the assumption (without references!) that LENR is occurring. "Actually, low energy D fusion catalyzed by nickel can be investigated and con- firmed experimentally" On Wed, Jul 8, 2015 at 10:31 AM, Blaze Spinnaker <[email protected]> wrote: I love the references, lol: [1] Wikipedia, Nuclear Fusion, (http : // en.wikipedia.org/wiki/Nuclearf usion), 17 March 2015. [2] Wikipedia, Cold Fusion, (http : // en.wikipedia.org/wiki/Coldf usion), 25 September 2014. .. On Wed, Jul 8, 2015 at 10:28 AM, Blaze Spinnaker <[email protected]> wrote: Vorteceans - Looks really exciting: We first show a possible mechanism to create a new type of nuclear fusion, thermal resonance fusion, i.e. low energy nuclear fusion with thermal resonance of light nuclei or atoms, such as deuterium or tritium. The fusion of two light nuclei has to overcome the Coulomb barrier between these two nuclei to reach up to the interacting region of nuclear force. We found nuclear fusion could be realized with thermal vibrations of crystal lattice atoms coupling with light atoms at low energy by resonance to overcome this Coulomb barrier. Thermal resonances combining with tunnel effects can greatly enhance the probability of the deuterium fusion to the detectable level. Our low energy nuclear fusion mechanism research - thermal resonance fusion mechanism results demonstrate how these light nuclei or atoms, such as deuterium, can be fused in the crystal of metal, such as Ni or alloy, with synthetic thermal vibrations and resonances at different modes and energies experimentally. The probability of tunnel effect at different resonance energy given by the WKB method is shown that indicates the thermal resonance fusion mode, especially combined with the tunnel effect, is possible and feasible. But the penetrating probability decreases very sharply when the input resonance energy decreases less than 3 keV, so for thermal resonance fusion, the key point is to increase the resonance peak or make the resonance sharp enough to the acceptable energy level by the suitable compound catalysts, and it is better to reach up more than 3 keV to make the penetrating probability larger than 10^{-10}. http://arxiv.org/abs/1507.01650
