I'm kind of late on this, but would spin conservation do what Ed Storm asked?
"However, why would only a few hydrons fuse leaving just enough unreacted hydrons available to carry all the energy without it producing energetic radiation? I would expect occasionally,many hydrons would fuse leaving too few unreacted hydrons so that the dissipated energy would have to be very energetic and easily detected." If I remember, Steve and Talbot Chubbs had proposed that bose band states could distribute the energy over many nucleons in the band state. In a 1D kronig-penny model of a periodic potential, H and D form bands and their band energy levels are separated by a 0.2eV, which means when 20MeV is spread across the band, the spectrum would be 20MeV / (n * 0.2eV) where n are the number of hyrons making up the band. That's just back of the envelope using a 2D kronig-penny period potential. And all of that photon energy spread over n-hydrons gets dumped right back into the lattice. Similar in a sense to the Mossbauer effect. On Tue, Jun 13, 2017 at 6:50 PM, Axil Axil <janap...@gmail.com> wrote: > http://physicsworld.com/cws/article/news/2017/jun/12/ > superfluid-polaritons-seen-at-room-temperature > > Superfluid polaritons seen at room temperature > > the polaritons behave like a fluid that can flow without friction around > obstacles, which were formed by using a laser to burn small holes in the > organic material. This is interpreted by the researchers as being a > signature of the superfluid behaviour. > > there might be some sort of link between a superfluid and a Bose–Einstein > condensate (BEC) – the latter being a state of matter in which all > constituent particles have condensed into a single quantum state. He was > proved right in 1995 when superfluidity was observed in BECs made from > ultracold atoms > > > > On Thu, Jun 8, 2017 at 1:54 PM, Axil Axil <janap...@gmail.com> wrote: > >> 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 >>> >>> >>> >>> >> >
