Bose condensation of polaritons is what thermalized gamma radiation (super absorption) produced by LENR based nuclear reactions.
Before a BEC of polaritons is established in the LENR reaction, the LENR reaction lets gamma radiation pass through the individual polaritons. But after the BEC of polaritons is established, a state change occurs and a Bremsstrahlung signal is generated in a polariton synchronization process where the polaritons synchronize the energy between each other. This Bremsstrahlung has been detected in MFMP tests just before excess heat was produced in the LENR reaction. It has been called "the Signal" by MFMP. After the polariton BEC is established a single radiation frequency is produced by the BEC. That frequency is a function of the density of polaritons in the BEC. This frequency can change second to second as the density of polaritons in the BEC varies. See "They tackled this problem by highly exciting exciton-polaritons, which are particle-like excitations in a semiconductor systems and formed by strong coupling between electron-hole pairs and photons. They observed high-energy side-peak emission that cannot be explained by two mechanisms known to date: Bose-Einstein condensation of exciton-polaritons, nor conventional semiconductor lasing driven by the optical gain from unbound electron hole plasma." Marrying superconductors, lasers, and Bose-Einstein condensates Read more at: https://phys.org/news/2016-06-superconductors-lasers-bose-einstein-condensates.html#jCp This polariton based emission of light is where the XUV light emissions comes from in the SunCell. On Fri, Jun 9, 2017 at 2:37 PM, Axil Axil <janap...@gmail.com> wrote: > https://arxiv.org/pdf/1509.05264 > > Disorder, synchronization and phase locking in non-equilibrium > Bose-Einstein condensates > > There is a kind of Bose condinsation that can exist at any temperature and > applies to polaritons. > > To draw an analogy, consider an array of funnels that are each being > filled at a different rate. But the funnels are entangled in a condinsate. > These funnels are losing liquid at the same rate but are being filled at > different rates. We would expect that there would be some funnels that > would overflow, but all the funnels maintain the same liquid level. All the > funnels share liquid between each other to maintain the same level of > fluid. The liquid that would have overflowed is shared between the funnels > through and entangled liquid transfer interface. Any funnel that has a low > level of liquid input would maintain its level through the additional > entangled transfer of liquid with and between other funnels with a more > that average liquid filling rates. > > This is how a collection of "N" polaritons act like one huge single > polariton with N members. This huge single polariton can store a > huge amount of energy in its condinsate. It can absorb a huge amount of > energy (super-absorption) but most importantly, any single polariton can > access all the energy stored in the condinsate (super-radiance) and can > use that energy to disrupt nuclear functions in a single nucleus. > > This Bose condinsate condition can exist at ANY temperature and depends > only on the special nature of polaritons to exist. > > On Fri, Jun 9, 2017 at 12:15 PM, bobcook39...@hotmail.com < > bobcook39...@hotmail.com> wrote: > >> Ftrank— >> >> >> >> To add to Axil’s comments, it is my understanding that Bose particles (0 >> or +/- integral intrinsic spin) can occupy the same energy states in a >> coherent system. This implies that that it is possible for two particles >> to be at the same location at the same time. For Bose particles with a >> magnetic moment—non-0 spin—a magnetic field will degenerate (reduce the >> possible locations and energy states) the coherent system “allows” for its >> constituent particles. >> >> >> >> This may make it more likely that the wave function of 2Bose particles >> over lap and promote a system reaction involving no immediate loss of >> energy, only a change in the coherent system’s configuration of constituent >> particles with greater kinetic energy and less potential energy tied up in >> force fields. >> >> >> >> The new kinetic energy is spin angular momentum, exhibited as phonic >> energy (thermal energy) of the entire coherent system—the nickel lattice. >> >> >> >> The nickel latticed is cooled by some mechanism or mechanisms. IMHO Li >> vapor and hydrogen gas or Cooper pairs of hydrogen are part of a convective >> cooling medium surrounding each nano- particle or clumps of particles. >> >> >> >> The complex engineering of the coherent systems, the control system which >> changes the probability of a reaction, anti-clumping conditions, and the >> cooling system suggested by the above conceptual reactor design is the >> reason why LENR+ has taken so long for folks with small budgets to succeed. >> >> >> >> Bob Cook >> >> >> >> >> >> *From: *Axil Axil <janap...@gmail.com> >> *Sent: *Thursday, June 8, 2017 9:54 AM >> *To: *vortexallows for-l <vortex-l@eskimo.com> >> *Subject: *Re: [Vo]:Bose Einstein Condensate formed at Room Temperature >> >> >> >> A Bose condinsate brings super radiance and super absorption into play. >> These mechanisms produce concentration, storage, and amplification of low >> level energy and goes as "N", the number of items in the condinsate. >> >> >> >> On Thu, Jun 8, 2017 at 9:46 AM, Frank Znidarsic <fznidar...@aol.com> >> wrote: >> >> Why is a Bose Condensate needed? Its a matter of size and energy. The >> smaller the size of something we want to see the more energy it takes. >> Using low energy radar you will never be able to read something as small as >> this text. You need to go to UV energies to study atoms. Higher ionizing >> energies are needed to study the nuclear forces. Really high energy >> accelerator energies are required to look at subatomic particles. >> >> >> >> The common complaint physicists have with cold fusion is that the energy >> levels are to low to induce any type of nuclear reaction. They never, >> however, considered the energy levels of a large hundreds of atoms wide >> condensed nano-particle. Its energy levels are quite low. Warm thermal >> vibrations appear to the nano particle as a high energy excitation. This >> again is a matter of its size. It's not cracks, or shrunken atoms at >> work. It is the thermal excitation of a nano particle that yields the >> required energy. >> >> >> >> Again the simulation induces a velocity of one million meters per second. >> >> >> >> Frank Z >> >> >> >> >> >> >> > >
