Electron properties Electrons have three fundamental properties: charge, mass, and spin. By definition, the electric charge on an electron is −1. The mass of an electron has been measured and found to be 9.109389 × 10 −31 kilograms. Electrons also spin on their axes in much the same way that planets do. Spinning electrons, like any other moving electric charge, create a magnetic field around themselves. That magnetic field affects the way electrons arrange themselves in atoms and how they react with each other. The field is also responsible for the magnetic properties of materials.
Read more: http://www.scienceclarified.com/El-Ex/Electron.html#ixzz5LM0K5rOj These electron properties can be removed from each other in terms of position. The spins of many electrons can be concentrated in a location that are far away from the locations of their electron component properties: orbit and charge. These electron spins can also be entangled with the spins of photons. These entangled spins form a condensate that can move in an independent fashion that is decoupled from the other properties of both the constituent electrons and photons. See https://amolf.nl/wp-content/uploads/2018/05/PhysicsToday_ExcitonPolariton.pdf The new era of polariton condensates David W. Snoke, and Jonathan Keeling One important characteristic of the polariton condensate that the LENR experimenter should be aware of is its transition point. There is a point in the input power that is input into the polariton aggregation that will cause the polariton condensate to form. This threshold is when gamma radiation is converted into heat by the polariton condensate. In the condensate, the energy content of the gamma is distributed equally among all the members of the condensate's aggregation and is thus thermalized. . FIGURE 3. THE BOSE–EINSTEIN CONDENSATION OF POLARITONS carries clear, experimentally observable hallmarks. (a) As polariton density increases (left to right) above the condensation threshold, the polaritons’ in-plane momenta, evidenced by the angular distribution of their light emission, peaks sharply at zero (top), and their energies and momenta converge on the minimum of the dispersion curve (bottom). That curve shifts slightly upward due to interaction effects as the polariton density increases. Here, regions of parameter space colored red correspond to those that produced the highest density of photon counts. (Adapted from ref. 5.) (b) In experiments that achieve full equilibrium, the evolution of the observed energy distribution (dots), plotted as a function of wave number k∥, is well described by the Bose–Einstein distribution (curves). Here, polariton density increases as curves change from purple to orange, with the orange curve corresponding to a system on the verge of condensation. The inset shows the sharp decrease in the spectral width of the polariton emission line *as pump **power crosses the threshold for condensation,* indicated by the dashed line. (Adapted from ref. 7.) ----------------------------------------------------------------------------------------------- I just read Russ's blog "Huygens Synchronicity Observed In Atom-Ecology And Cold Fusion <http://atom-ecology.russgeorge.net/2018/07/09/huygens-synchronicity-observed-in-atom-ecology-and-cold-fusion/> " http://atom-ecology.russgeorge.net/2018/07/09/huygens-synchronicity-observed-in-atom-ecology-and-cold-fusion/ This two reactor experiment is astonishing. This may be an example of the "mouse and cat" method employed by Rossi. This method is how one powered "mouse" reactor powers through entanglement "N" numbers of fueled but unpowered "cat" reactors. My explanation of this seeming transfer of power between reactors is through quantum entanglement of polaritons. As I have explained previously, the density of polaritons is the parameter that defines the condition when a Bose condensate of polaritons will form. This condensate is what converts gamma radiation into heat. The two reactors are most likely sitting on the threshold of the polariton condensation point. These two systems can transfer energy between them that polariton generation is sensitive to. One reactor passes energy to the other whereupon that reactor passes the polariton condensation point and heat is then produced from gammas. This heat producing rector then passes energy back to the gamma producing reactor which then moves its energy pumping level beyond the polariton condensation point. The oscillation in entangled energy transfer sets up a periodic transfer of polariton energy between reactors to drive heat production back and forth from the gamma stage to the heat stage. This quantum energy transfer between reactors is similar to what happens in in the transfer of mechanical energy in Newton's cradle. https://en.wikipedia.org/wiki/Newton%27s_cradle [image: Newtons_cradle_animation_book_2.gif]
