This is a wonderful video, so thanks for pointing us to watch it. However, the molten Li-Al is not in a super-critical phase, but as he said, it doesn't have to be supercritical - just hot and high pressure. He also demonstrated a chemical mixing that produced nanoparticles as a precipitate. That kind of chemical mixing is not taking place in the Parkhomov/Rossi reactor as near as I am able to identify.
That having been said, and as I posted before, the Li-Al-Ni-H alloy becomes saturated with Ni. It may be possible to cycle the temperature (up to dissolve and down to precipitate) and get the Ni to precipitate on the surface of the remaining solid Ni like a co-deposition - taking H- anions with it into the Ni surface at an accelerated rate. Dennis Cravens pointed me to a very interesting paper that has many similarities to this process: http://lenr-canr.org/acrobat/LiawBYelevatedte.pdf See the paper by Liaw. On Tue, Mar 3, 2015 at 10:57 PM, Axil Axil <janap...@gmail.com> wrote: > > There is no hydrogen plasma or lithium vapor for that matter. Lithium at > that pressure will not boil at the temperatures being used. If you read > Langmuir's work, you will see that it takes over 2500C for any significant > hydrogen molecule dissociation, and it would be much hotter still to get a > hydrogen plasma. > > > https://www.youtube.com/watch?v=6zurHSq4CB4 > > This video shows how a super critical medium produces nanoparticles from > dissolved ionic substances when there is a super critical phase transition > caused by cooling the super critical medium so that the dissolved solids > nucleate and form nanoparticles. Both dissolved Lithium, > aluminum, and hydrides will nucleate and form nanoparticle in a cooled > region of the supercritical hydrogen gas. >
