http://www.news.vcu.edu/article/Protecting_Groups_Go_Rogue_in_Aluminum_Superatoms
“This work offers new intuition on what criteria allow the formation of stable clusters, and how to induce these clusters into becoming effective catalysts,” said Khanna. Chemistry works at a higher level than the atom. Stable clusters of atoms act as if they were new elements. This chemical property of atomic clusters involve how electrons flow around the cluster of atoms. On Sun, Sep 6, 2015 at 2:45 PM, Axil Axil <janap...@gmail.com> wrote: > If the key to LENR activity is the configuration of valance electrons in a > chemical compound, then a single ion of silicon oxide may be just as good > as potassium or lithium as a LENR catalyst. > > The goal of LENR based chemistry might be to find what configuration of > valance electrons work and how to create that configuration. Maybe this is > what Mills has been doing all this years. > > On Sun, Sep 6, 2015 at 2:16 PM, Jones Beene <jone...@pacbell.net> wrote: > >> *From:* Axil >> >> Ø >> >> Ø … Aluminum monoxide can form rydberg matter just like potassium can >> because the valance electron configuration between the aluminum compound >> and the potassium is the same. >> >> >> >> It is fair to assume that in all of our discussions about “dense >> hydrogen” where the electron is in a stable redundant ground state – that >> all of the various terms given to the species are more-or-less synonymous, >> including: hydrino, f/H (fractional hydrogen), IRH (inverted Rydberg >> hydrogen), DDL (deep Dirac level), pychno-hydrogen, femtohydrogen, virtual >> neutron, Dark Matter hydrogen, metallic hydrogen, sub-orbital hydrogen… and >> probably a few others. >> >> >> >> AFAIK, Mills does not agree with this assessment, which makes it all the >> more important – since the species would fall outside his IP unless he can >> realistically distinguish it. Notably AlO is not even listed by Mills as >> catalytic. >> >> >> >> There are many implications – should it be proved that AlO is a catalyst >> for forming f/H - including in the geology of earth. Since aluminum is the >> second most abundant element in the mantle of earth (as Al2O3) and oxygen >> is first - we could assume that there is constant formation of f/H from >> organic material – which then can migrate to the core of earth – or on >> occasion migrate to the surface, over geologic time. >> >> >> >> The mining of f/H is not out of the question – should we learn where to >> look for it and how to retain it. Perhaps some nickel has natural, >> primordial levels of f/H (ppm quantity) - which does not show up in >> chemical analysis and survives refining. >> >> >> >> >> > >
