That sorta goes to my point about looking for experimental results that either lend support or reduce support for a particular theory. I'm noticing that a lot of the experiments are veering towards testing nuclear products, which is going to be expensive. It won't matter much if Rossi is selling reactors, it soon becomes someone else's problem to properly theorize how it's happening. But it will matter a bunch if Rossi stalls and we need to know what's going on in order to get to production.
On Fri, Mar 21, 2014 at 8:53 AM, Axil Axil <janap...@gmail.com> wrote: > You should take a look at the table 2 and table 3 element list from the > DGT ICCF-17 document. > > > http://cdn.coldfusionnow.org/wp-content/uploads/2013/04/2012-08-13-ICCF-17__Paper_DGTGx.pdf > > The is a large increase in very light elements and not much nickel to > copper transmutation. > > This means that Cluster fusion of many nuclei including many protons and a > heavy metal nucleus is occurring per fusion event. > > In the Rossi ash, iron was 10% of the element assay. > > *1H+1H+62Ni => 4He + 4He + 56Fe + 3.495 MeV <==== this one produces iron.* > > Fusion cannot happen if the nucleon count is odd, e.g. Ni61. This > indicates photofusion. > > Gamma Radiation is converted to huge magnetic fields and will result in > EUV radiation from the eventual destruction of the EMF soliton that will be > thermalized by election capture. > > > > > > > > > On Fri, Mar 21, 2014 at 10:54 AM, Teslaalset > <robbiehobbiesh...@gmail.com>wrote: > >> I've been reading quite some theories and views on what exactly Rossi's / >> Defkalion's processes might be. >> Here's my current view focussing on the main effects only. Comments and >> (dis)agreements are welcome: >> >> The main chain of fusions/transmutations is in my view: Ni58+p > Cu59 + >> e- > Ni59 +p > Cu60 + e- > Ni59 + p > Cu60 + e- > - - - - - > Cu63 + e-. >> All Cu isotopes in the range of Cu59 - Cu62 have relative short half-life. >> The longest half-life is that of Cu61 (3.3 hours). This is why Rossi's >> process needs quite some time to shut down. The fusion/transmutation chain >> stops at Cu63 because Cu63 is stable with an extreem long half-life. >> Protons (p) are provided by (absorbed) Hydrogen ions. Electrons (e-) are >> released due to Vibrationally Promoted Electron Emission (VPEE). >> >> The released energy is caused by two sources: >> >> 1. The emitted electrons e- (with very high kinetic energy, 5 - 8 >> MeV); the electrons are absorbed by the reactor wall causing eddy currents >> that are converted into heat due to resistance of that wall material. >> Those >> eddy currents also may be the cause of the extreemly high magnetic fields >> that have been observed (Defkalion). >> 2. The ß+ decay energy of Cu(x) > Ni(x) + e+ + ve (2 -4 MeV) of each >> decay step in the chain, causing the Ni/Cu powder to heat up. >> >> Some ballpark figures on the total energy generated and the amount of >> fuel involved: >> Assuming all the Nickel in the reactor in the form Ni58 and finally all >> transmutted into Cu63: >> Ni58 mass is calculated to be 57.95380± 15 amu. The actual mass of a >> copper-Cu63 nucleus is 62.91367 amu. Mass of Ni58 plus 5 nucleons is >> 57.95380+5=62.95380 amu. Delta mass is 62.95380-62.91367=0.04013 amu. 1 amu >> = 931 MeV is used as a standard conversion 0.04013×931 MeV=37.36 MeV. So >> each transformation of Ni58 into Cu63 releases 37.36MeV of nuclear energy. >> So, without further energy losses it requires 2 - 3 grams of Ni and >> approx. 0.2 grams of H2 to produce 10KW of heat over a 6 months period >> continuously. >> > >
