On another thread, Edmund Storms posted how many nuclear fusion atoms must take place to generate 1 Watt of power. We can work backwords from that number, knowing that a certain number of Watts are generated. Then we know how many atoms/second are fusing. From that calculation you can figure out how many OTHER atoms need to be involved with the BEC in order for it to have the frequency being observed. I doubt the entire device needs to be involve. I think it would be hundreds of BECs forming with thousands of atoms.
http://www.mail-archive.com/[email protected]/msg81244.html This paper verifies that a photon eradiated Bose-Einstein condensate will cut the frequency of incoming photons by dividing that frequency between N numbers of atoms. http://arxiv.org/pdf/1203.1261v1.pdf On 6/7/13, Axil Axil <[email protected]> wrote: > References: > > > http://phys.org/news/2013-05-einstein-spooky-action-common-large.html > > > *Einstein's 'spooky action' common in large quantum systems, mathematicians > find* > > > If you like mathematics that can choke an elephant try this as follows: > > > http://arxiv.org/pdf/1106.2264v3.pdf > > > *ENTANGLEMENT THRESHOLDS FOR RANDOM INDUCED STATES* > > Why does a Ni/H reactor form a Bose-Einstein condensate throughout its > entire volume? STANIS LAW J. SZAREK provides the answer; the dipoles > throughout the reactor are forced to become totally entangled when the > percentage of dipole entanglement exceeds 20%. > > > > The Ni/H reactor will formulate a very large entangled system when it is in > operation. As a large system, it has no choice but to become totally > entangled. > > > Infrared Photon tunneling between the individual Nano-cavities is the > method by which quantum entanglement is spread Josephson like from one > nano-cavity to its immediate neighbors. > > > When the Ni/H reactor is not totally entangled, it renders the nuclear > energy it produces from the decoherent nano-cavities as gamma radiation. > However, if the 20% entanglement threshold is reached, the energy produced > by the LENR reaction is thermalized through the process of frequency > sharing as in a large super atom. > > When a Ni/H reactor is not yet totally entangled, it will produce gamma > radiation. This can happen when the reactor is heating up upon startup or > cooling down at shutdown. > > In the LeClair reactor, the 20% entanglement threshold is never reached and > a significant proportion of its energy output is rendered as gamma > radiation. > > A Ni/H reactor must exceed this 20% dipole entanglement threshold before > its energy production phase is initiated to avoid the inconvenience of > gamma production. >
