The magnetic field is atomic level. The next step in the research that the Ni/H reactor developers need to do is measure the magnetic fields that they are developing in their reactions. This can be done using sub-micron hall effect probes.
On Thu, Dec 19, 2013 at 1:10 PM, John Franks <[email protected]> wrote: > What's the magnitutde magnetic field and how do heavy hadrons display > these collective properties like light leptons? > > > > On Thu, Dec 19, 2013 at 6:05 PM, Axil Axil <[email protected]> wrote: > >> FQHE reduces the inherent charge of fermions as a function of increasing >> magnetic field. >> >> The nucleus is a fermion, the protons and neutrons are fermions and so >> are quarks. >> >> Why should a magnetic field make a distinction in the way it >> reduces charge is the various types of fermions? I won't. >> >> >> On Thu, Dec 19, 2013 at 12:59 PM, John Franks <[email protected]> wrote: >> >>> "Is like or maybe is" >>> >>> How so? Once again, QHE or FQHE is to do with cooperative properties of >>> light leptons. So how does this carry over to heavy hadrons and what does >>> that have to do with CF? >>> >>> >>> On Thu, Dec 19, 2013 at 5:53 PM, Axil Axil <[email protected]> wrote: >>> >>>> Cold fusion is like(or maybe is) the Factional Quantum Hall >>>> Effect(FQHE). Science did not believe that something like the FQHE was >>>> possible until it was shown experimentally. Cold fusion is the FQHE moved >>>> over to the fermions of the fermions of the atomic nucleus. >>>> >>>> >>>>> >>>>> If you are suggesting BEC, well electrons are leptons and light, how >>>>> can you get heavy hadrons into one coherent state at room temperature? If >>>>> this is the case, has CF been observed to occur spontaneously in liquid >>>>> H2? >>>>> >>>> >>> >> >
