In Spontaneous parametric down-conversion (SPDC) as a process in quantum optics, a nonlinear crystal is used to split photons into pairs of other photons. The efficiency of that process is proportional to the amount of quantum mechanical entanglement that is produced by the incident laser on the nonlinear crystal lattice used to split photons into pairs of photons.
The frequency at which this entanglement is produced is low as a funtion of the number of photons that are contained in the incident UV laser beam. On the other hand, we known from the copper isotopes that are produced as ash in the Rossi reactor, thanks to the analysis of both DR, Kim and Horace Heffner, almost all cold fusion nuclear reactions involve the fusion of entangled cooper pairs of protons in the nucleus of nickel atoms. So in the case of the Rossi reaction, the probability of entanglement is very high. Therefore the probability of power and frequency splitting of the radiation produced by the cold fusion nuclear reactions in the nickel lattice as well as its teleportation into the surrounding hydrogen envelope is almost certain. On Mon, Dec 26, 2011 at 10:10 AM, David Roberson <[email protected]> wrote: > This is an interesting discussion but I have one question. The reference > you mentioned suggests that the process of down conversion is > extraordinarily inefficient and that the probability of a gamma being down > converted is virtually nil. Did I misunderstand this for some reason? Is > the process much more efficient for high energy photons? > > Dave > > -----Original Message----- > From: Axil Axil <[email protected]> > To: vortex-l <[email protected]> > Sent: Mon, Dec 26, 2011 3:47 am > Subject: [Vo]:Spontaneous parametric down-conversion (SPDC) > > Some insights from quantum mechanics… > Spontaneous parametric down-conversion > Reference: > http://en.wikipedia.org/wiki/Spontaneous_parametric_down-conversion > The rule that comes out of this quantum mechanical process is that energy > is shared approximately equally between N entangled particles with each > entangled particle getting 1/N amount of the energy. > The originating frequency of the nuclear radiation is also shared between > the N particles and is therefore divided approximately equally between the > N particles and is therefore also divided in its calculation by 1/N. > Spontaneous parametric down-conversion (SPDC) is an important process in > quantum optics, used especially as a source of entangled photon pairs, and > of single photons. > In quantum optics, when energy is shared between two entangled particles > with one particle being excited and the other standing off at a distance, > that energy is not equally divided into 1/2 the energy of the original > excited particle. > Energy is conserved though, and the division is *very* close to equal. > When entangled particles share energy from a nuclear reaction, that energy > emerges from the nuclear reaction, but the photons come out slightly off > axis. The actual variation in this angle is, to a small extent, a measure > of the variation of the energy/wavelength of the photon stream. To say it > another way: what is collected and used in experiments is extremely close > to equal, but there is a dispersion of particles which are not collected > which is less close to equal. > Rserence: > http://people.whitman.edu/~beckmk/QM/grangier/Thorn_ajp.pdf > See equations 15 and 16 in the reference. > The above consideration explains how the lattice does not melt after a > cold fusion nuclear reaction and there is no gamma rays that emanate from a > cold fusion nuclear reaction involving N entangled particles. > More specifically, those entangled particles are one or more entangled > copper pairs of protons configured in an entangle proton ensemble > comprising N protons. > > >
