Axil,
thanks for the citation re decay acceleration, You are adding support for
relativistic effects in this environment, It does appear that appropriate laser
application multiplies the measured effect, I would posit that it accelerates
the medium transport through the geometry and multiplies the number of gas
atoms exposed to the changes in geometry. I think plasmonic resonance is a
reasonable description of what can occur inside this geometry.
In thinking about the Naudts paper re relativistic hydrogen it
occurred to me that perhaps we should view this effect from the opposite
direction..from the quantum foam level below the plank scale to the quantum
level where this geometry appears to allow the same sort of breaks in time and
isotropy that occur at the quantum foam level [Cavity QED] where tiny wormholes
form to average out the fabric of space time magnitudes of scale below the
formation of physical building blocks... I am suggesting these tiny hot spots
are already normalized into chemistry under the heading of catalytic action..
identified by surface areas and figures of merit I would suggest said merit is
actually based upon conductivity, where we already know metals are best, and
nano geometry. I am positing that careful creation of geometry in a permanent
inert gas blanket environment with permanent heat sinking could allow for a
new class of super catalysts where only small amounts of reactive gas is added
and pumped through the system. Without these precautions we would classify the
reaction as pyrophoric.
Fran
From: Daniel Rocha [mailto:[email protected]]
Sent: Thursday, May 16, 2013 2:29 AM
To: John Milstone
Subject: EXTERNAL: Re: [Vo]:'Slow' arcing electrons can gain relativistic mass
Axil,
I hope you just notice that the energy scale at which these phenomena occur are
puny in comparison to what is needed for fusion.
2013/5/16 Axil Axil <[email protected]<mailto:[email protected]>>
Dear Ed:
http://www.google.com/url?sa=t&rct=j&q=&esrc=s&frm=1&source=web&cd=2&cad=rja&ved=0CDQQFjAB&url=http%3A%2F%2Fwww.phy-astr.gsu.edu%2Fstockman%2Fdata%2FStockman_Phys_Today_2011_Physics_behind_Applications.pdf&ei=KWKUUd2bMe610AHSy4CQBQ&usg=AFQjCNHdcmFaRe9tfcLMzk1V8uwPQ8OvXA&sig2=BHsFSNJUGxJ8Cs9T3pBlJA&bvm=bv.46471029,d.dmQ
A primer on Nanoplasmonics.
The concentration mechanism is a resonant constructive interference process
called Fano interference discovered a few years ago. It produces the "hot
spot", which is the most significant and exciting process in Nanoplasmonics.
Much current research into hot spots is currently underway.
Laser light is used to produce dipole vibrations in the nanoparticles. A Laser
only produces plain waves and excites dipole excitation poorly.
The lattice of a metal produces dipole vibrations in the deep infrared far
better than a laser ever can.
The Ni/H reactor couples heat with surface electrons to produce polaritons at
high efficiency and then the nano-particles concentrate the EMF in extreme
concentrations.
--
Daniel Rocha - RJ
[email protected]<mailto:[email protected]>
