That super absorption sounds familiar. There was a study done with lattices that thermalized gamma rays and broke them down into X-rays according to the number "N" of the items in the lattice. I'll try to find it.
On Thu, Jun 8, 2017 at 10:54 AM, 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 >> >> >> >> >
