Corrected… It is accepted in mainstream physics. This technology has just begun development. Because the field is new, the number of applications is few. The engineers have not taken full advantage of this type of basic scientific research.
If we can pack large numbers of electrons into a confined space, each electron would assume its own quantum number because these electrons are confined like the electrons confined to the orbitals of an atom. This collection of electrons will form an artificial atom but the collection doesn’t have nucleus and can also have a very large range of quantum numbers. When a gamma ray strikes this ensemble of electrons, the kinetic energy of this photon transfers it energy to the electrons and the quantum number of one or more electrons will increase. These newly excited electrons can reemit the energy at a lower wavelength, or lower energy electron can enter into the pile because the gamma has made some energy gap room in the electron group. A quantum dot can hold such a pile of electrons that do the functions so described. Large quantum dots have been created that can store 600 electrons and more. They can handle a photon of about 1 MeV and more. See page 42 www.physics.umanitoba.ca/nano/publications/comments.pdf This lack of gammas detected in the LENR reaction leads me to suspect that there are nano-cavities that hold large numbers of electrons that can downshift the gamma photons produced nearby. These gamma’s will also allow these cavities to pack more electrons in because the gammas increase the quantum numbers of the electrons already there to higher quantum levels allowing lower energy electrons to sneak into the pile. Glad to help: Axil On Sat, Feb 23, 2013 at 12:00 AM, Axil Axil <janap...@gmail.com> wrote: > It is accepted in mainstream physics. This technology has just begun > development. Because the field is new, there the number of applications is > few. He engineers have not taken full advantage of the basic scientific > research. > > > If we can pack large numbers of electrons into a confined space, each > electron would assume it’s on quantum number because it is confined like a > the orbitals of electrons in an atom. > > This pile of electrons form an artificial atom but it doesn’t have nucleus > and have a very large range of quantum numbers. > > When a gamma ray strikes this pile of electrons, the kinetic energy of the > photon transfers it energy to the electrons and the quantum number of one > or more electrons increases. > > These excited electrons can reemit the energy at a lower wavelength or > lower energy electron can enter into the pile because the gamma has made > some energy gap room. > > A quantum dot holds a pile of electrons that do this function. > > Large quantum dots have been created that can store 600 electrons and > handle a photon of about 1 MeV. > > See page 42 > > www.physics.umanitoba.ca/nano/publications/comments.pdf > > This lack of gammas in LENR leads me to suspect that there are cavities > that hold large numbers of electrons to downshift the gamma photons. > The gamma’s will also allow these cavities to pack more electrons in > because the gammas increase the quantum numbers of the electrons already > there to higher quantum levels allowing lower energy electrons to sneak > into the pile. > > Glad to help: Axil > > On Fri, Feb 22, 2013 at 8:36 PM, Kevin O'Malley <kevmol...@gmail.com>wrote: > >> A BIG peice of nano-material is at or under 100 nanometers. This is less >> than 61 microns so a nano-structure that small can convert a gamma ray to >> heat because it is less than the far wavelenth of the radiation. >> ***Much of current semiconductor research is well under 100 nm. Why >> haven't they seen this conversion of gammas to heat? >> >> Why hasn't it been accepted in mainstream physics? A google search for >> "conversion of gamma rays to heat" generates only cold fusion related >> hits. >> >> >>> >> >> >
