Jones,
I was speaking of IR affecting the Ni surface through the SS or Silicon
Carbide tube - where the hi Q of the geometry could be slaved to PWM driving
the heaters - counting on a weak Faraday reactor cage the plasmons would
slowly synchronize like the metronome and then subsequently the fractional
hydrogen states would also start to resonate as motion leads to change in
geometry/casimir force..
I don't think redundant ground states are contained by the reactor -
they are contained by the geometry and will cease to be redundant once the
vacuum wavelength suppression [geometry] ceases to exist. I think this is why
Mills can't show a hydrino - they only exist in situ and turn back into normal
ground states as they exit the cavity.
Fran
_____________________________________________
From: Jones Beene [mailto:[email protected]]
Sent: Monday, June 24, 2013 11:23 AM
To: [email protected]
Subject: EXTERNAL: RE: [Vo]:Rossi and DGT Similarity?
-----Original Message-----
From: Roarty, Francis X
> I also wonder if resonance can occur between fractional states where f/h2
> disassociates and recombines in synch with the plasmon resonance and that
> photons emitted from these fractional state hydrogen is responsible for the
> spectrum spread ...
This observation is interesting in the context of the HotCat and
Casimir/plasmon effects on SiC, if I understand what you are suggesting with
the molecular form (as opposed to other forms). We have mentioned several
papers on plasmonics and SiC in the past:
http://proceedings.spiedigitallibrary.org/proceeding.aspx?articleid=1329919
... but these studies usually involve nanoparticles of SiC, and the tube in the
HotCat was simply said to be a generic carborundum tube. The leap of faith,
therefore is that a typical SiC tube would have naturally occurring nanosized
surface features, as the location where the Casimir-plasmonics effect could
take place (when it is heated to an IR glow). In this version of events leading
to gain, hydrogen embrittlement is not required.
The (f/H)2 molecule would be the neutral fractional hydrogen molecule, as
opposed to the atom or hydride. This species, even at the first redundancy
level would have a reduced diameter but at the second level the species is
difficult to contain by any non-magnetic material, since the volume is reduced
by a factor of 27:1 over the normal hydrogen molecule. The grade of stainless
being used in the HotCat is non-magnetic.
Thus - if one wanted to invent a way to slowly release an active dense isomer
of hydrogen as the fuel, then there is no better way than to seal up a metal
hydride in a non-magnetic stainless steel tube, along with a Mills' catalyst
and heat it until a population of f/H forms and is reduced to the (f/H)2
molecule. This could take many days to "prime" and once the (f/H)2 molecule
forms it should be used immediately, or it will escape.
If you are lucky, or inspired, in the design choices - and your (f/H)2 molecule
forms slowly but preferentially at a regular rate, then it would disperse
through the walls of the tube and interact with plasmon on the interface. If
the interfacial layer between the stainless tube and the carborundum is
plasmonic, with the very high electric fields, then the fields will capture and
hold the (f/H)2 molecule in place for further reactivity.
That reactivity could include the Storms hypothesis of fusion to deuterium,
aided by the extreme electric field of the plasmon/polaritons; or it could
include further levels of Mills' electron redundancy; or it could include RPF -
reversible proton fusion; or several other forms of gain, OR any combination of
these operating together.
Jones
