hacking radiation should read
Hawking radiation On Sat, May 5, 2018 at 2:44 PM, Axil Axil <[email protected]> wrote: > The polariton BEC acts as a analog black hole. It thermalizes gamma via > hacking radiation which is a thermal level emmision. The heat produced by > hacking radiation is recovered as energy from the vacuum since the anti > photon falls back into the BEC. This BEC also produces light whose > frequency is a function of the density of the polariton condensate. It has > been said that Rossi's QX reactor produces light from red to blue based on > its power level. > > The final emission type is muon production. > > for more info, see > > https://tel.archives-ouvertes.fr/tel-00822148/file/Flayac-2012CLF22262.pdf > > 2.4 Sonic black holes and wormholes in spinor polariton condensates (page > 116) > > On Sat, May 5, 2018 at 11:53 AM, Roarty, Francis X < > [email protected]> wrote: > >> Axil, would your scenario support effects on gas atoms between these >> surfaces and Casimir/London forces? I like that it explains thermalizing >> the gamma. >> >> >> >> Fran >> >> >> >> *From:* Axil Axil [mailto:[email protected]] >> *Sent:* Friday, May 04, 2018 11:42 PM >> *To:* vortex-l <[email protected]> >> *Subject:* EXTERNAL: [Vo]:Gamma radiation from LENR >> >> >> >> Sometimes radiation is produced by the LENR reaction. Why does this occur? >> >> >> >> It is my belief that the LENR process that thermalizes nuclear level >> radiation is Bose Einstein Condensation (BEC). If a condition of BEC >> circumscribes the LENR reaction, the BEC will absorb that nuclear level >> radiation and downshift it into the thermal frequency range. >> >> >> >> But for a BEC to be created, doesn’t the temperature need to be at super >> low temperatures near absolute zero? >> >> >> >> There are two kinds of BEC. The BEC that requires super low temperatures >> involves atoms. The other kind of BEC is the polariton BEC. >> >> >> >> See for background see: >> >> >> >> https://warwick.ac.uk/fac/sci/physics/staff/academic/szymans >> ka/research/polaritonbec/ >> >> >> >> This kind of BEC is a Condensate that forms in nonequilibrium >> driven-dissipative systems. The polariton needs to be pumped with energy >> because it loses energy from the cavity that contains it. If more energy >> feeds the polaritons than leaks out of the cavity in which the polariton >> forms, it can live and grow in power. The amount of nuclear energy that the >> polariton BEC can thermalize is a function of the power that is feed into >> the Polariton BEC and the amount of power that the Polariton BEC loses over >> a given time(AKA the Q factor). >> >> >> >> https://en.wikipedia.org/wiki/Q_factor >> >> >> >> What affects the Q factor of a polariton substrate? >> >> >> >> Polaritons are a form of light…actually a mixture of matter and light. >> >> >> >> Polaritons cannot exist unless they form on a substrate of a metal. The Q >> factor is a character of the substrate; it is a function of how the >> substrate lets light escape the surface of the metal. A rough and pitted >> metal surface will produce a higher Q factor than a shiny smooth mirror >> like metal surface because a rough metal surface reflects light less well >> than a shining mirror like metal surface. In general, this Q factor of >> surfaces applies to any type of wave based EMF including electrons. >> Superconducting surfaces support the highest Q factor. Very little power >> loss occurs from the surface of a superconductor. A polariton condensate >> will retain it power for months when the polaritons are supported on the >> surface of a superconductor. >> >> >> >> A collection of polaritons will form a Condensate when their density >> reaches a critical value based on the quantum gas theory. The formation of >> a polariton condensate has nothing to fo with temperature. >> >> >> >> https://journals.aps.org/prl/abstract/10.1103/PhysRevLett.118.016602 >> >> >> >> This theory of polariton condensation boils down to these LENR design >> rule associated with eliminating gamma radiation from the LENR reaction. >> >> >> >> For a non-fueled reactor. >> >> >> >> If you are using the surface of a metal to produce your polaritons, then >> roughen up that surface to make it dull and pitted. This is what Mizuno >> does to his metal surfaces. Mizumo processes his metal surfaces with an >> electric arc until that surface is well pitted. >> >> >> >> You can increase the input power pumping of energy onto the surface of >> the metal so that the extra power increases the number of polaritons >> produced by the metal surface thereby causing a polariton condensate to >> form. >> >> When Rossi had gamma radiation problems, he added a heater to his reactor >> to make sure he stated up a HOT reactor. The thermal pumping to the micro >> particles was increased by the heater so that on startup, the Rossi E-Cat >> did not produce gamma from a cold reactor. >> >> >> >> If metal particles are used instead of a metal surface (as per >> Piantelli), use a mix of very wide range of various particles sizes from >> micro to nano sizes. >> >> >> >> For a fueled reactor. >> >> >> >> A fueled reactor uses a hydride fuel that contains ultra-dense >> hydrogen(UDH) or ultra-dense lithium to support the LENR reaction. UDH is a >> superconductor and the hydride fuel that supports it will support the LNER >> reaction at any temperature and/or polariton pumping level due to the >> extremely high Q of the surface of the UDH superconductor. >> >> >> >> The production of positrons in a LENR reactor. >> >> Without a polariton BEC to thermalize gamma radiation, the LENR reaction >> will produce gamma as a result of positron production. >> >> The LENR reaction is a weak force reaction. When the LENR reaction adds >> mass to the protons and neutrons, they will become excited and decay when >> the LENR reaction adds energy/mass to the quarks inside these nucleons. >> >> As a decay process of these nucleons, both positive and negative muons >> are produced as a decay product. The positive muons come from the decay of >> anti-quarks in the nucleons. >> >> The decay of the positive muon will produce positrons as a decay product. >> >> >> > >
