If you read Mileys results, he produced 39 elements many new with diverging isotopic concentrations.
One of the most interesting parts of Miley’s work (presented in the slides) is that he has created a unique analysis tool to do precise but broad based analysis of content of elements within the nickel powder. He checks the powder, sets up the machine, heats up the device, then lets it run wherein it generates more energy than is put into it. Then he takes the powder and analyzes its content again. He finds that 39 different elements have statistically significant shifts of isotope abundance. That’s interesting to say the least. The results really haven’t been processed by anyone yet in terms of what it means for a theory describing how these things work, I have my own ideas but that doesn’t mean much. But Miley wants the test run on Rossi’s device and I sure would like to see that also. On Mon, Nov 14, 2011 at 12:17 AM, Daniel Rocha <danieldi...@gmail.com>wrote: > What about other elements than tritium? Tritium is a consequence of the > decay of Lithium and Berilium formed by the successive stages of deuterium > fusion or hydrogen, for example. I am thinking more about heavier elements, > that should be formed by transmutation of the containing lattice. > > > 2011/11/14 Axil Axil <janap...@gmail.com> > >> See >> Reports of tritium production from Rossi-like experiments >> >> Jones Beene >> http://www.mail-archive.com/vortex-l@eskimo.com/msg49057.html >> >> On Sun, Nov 13, 2011 at 11:10 PM, Daniel Rocha >> <danieldi...@gmail.com>wrote: >> >>> Oh! Nice! Would you mind showing a paper with such transmutation? >>> Perhaps an example in each order of magnitude in the interval. >>> >>> >>> 2011/11/14 Jones Beene <jone...@pacbell.net> >>> >>>> *From:* Daniel Rocha **** >>>> >>>> ** ** >>>> >>>> **Ø **Before seeing it, I am referring to transmutations of cold >>>> fusion. I wonder why such isotopes haven't been seen, as far as I could >>>> search the literature. **** >>>> >>>> ** ** >>>> >>>> Not sure what you are referring to, but there are many isotopes in that >>>> stability range – notably radium 226 (1,600 years half-life) which was >>>> commercially important many years ago for clock and watch dials.**** >>>> >>>> ** ** >>>> >>> >>> >> >