To get back to the original topic (the GS3 experiment), in two
successive reheat tests with the fuel intact, no excess heat was seen.
The final reheat was after 24+ hours of degassing at below 1 torr
vacuum. Results of that test are summarized in my report at
https://goo.gl/guRhzl
Comments are welcome, of course.
Alan Goldwater
On 7/1/2015 8:32 PM, mix...@bigpond.com wrote:
In reply to James Bowery's message of Tue, 30 Jun 2015 12:55:47 -0500:
Hi,
[snip]
On Tue, Jun 30, 2015 at 8:04 AM, Jones Beene <jone...@pacbell.net> wrote:
*From:* James Bowery
Ø I must have misunderstood what you just said because hydrinos are ash,
not fuel, so the reaction will stop.
There is a progressive range of 137 stable fractional levels (Rydberg
multiples) which hydrogen electron orbitals can assume, according to Mills’
theory – each one more energetic than the one before. None of them are the
functional equivalent of ash, even the last.
In the Millsian theory "the functional equivalent" of ash is context
dependent: a catalyst with energy transition "equal" (to what precision?)
to that of the fractional Rydberg state transition.
That was the source of my comment about ash.
James:
Hydrinos can autocatalyze, something Mills calls "disproportionation", where one
Hydrino expands while another, with which it is in contact, shrinks. The net
result is a further energy release. (Though one has to wonder why this wouldn't
lead to an explosion.)
Jones:
While there are 137 Hydrino levels, only the first 24 of them can form a
negative ion, the most likely form in which they would be bound in a lattice
IMO.
Nevertheless, shrinkage to level 24 releases a total of 24^2 x 13.6 eV = 7834 eV
per Hydrino. There is of course also magnetic bonding as you suggest, which
would be valid for Hydrinos of any size.
It's also possible that Hydrinohydride ions get bound to Li ions, as I suggested
previously, creating an entity that is either neutral of negatively charged,
depending on the number of bound Hydrinohydride ions, and possibly capable of
mediating neutron transfer reactions.
(However, again one has to wonder why the neutral version wouldn't exit the
reactor just like Hydrino molecules.) (Perhaps they catalyze enough neutron
transfer reactions before they leave to make it worth while??)
Regards,
Robin van Spaandonk
http://rvanspaa.freehostia.com/project.html
