Eric,
See Guglinski at: http://www.journal-of-nuclear-physics.com/?p=462
The helical trajectory is related to cold fusion too, because in QRT
the neutron is composed by proton+electron. Into the structure of the
neutron the electron loses its helical trajectory, and the energy of the
Thanks, Ron, for providing this link. I'm pretty excited.
Here's the abstract from Science:
Tunneling of electrons through a potential barrier is fundamental to
chemical reactions, electronic transport in semiconductors and
superconductors, magnetism, and devices such as THz-oscillators. While
http://www.sciencedaily.com/releases/2012/04/120405142156.htm
According to team leader, Professor Jeremy Baumberg, the trick to telling electrons how to pass
through walls, is to now marry them with light.
This marriage is fated because the light is in the form of cavity photons, packets of
That's fantastic.
I'm a complete amateur, so I have to ask for clarification -- is
the phenomenon behind the tunneling of en electron through a semiconductor,
as described in the article, the same one involved in the quantum tunneling
of an electron into a proton? Or are the two processes
On Sat, Apr 7, 2012 at 11:59 AM, Eric Walker eric.wal...@gmail.com wrote:
What is the wavelength of the photons being used in the experiment being
discussed, and what is its relationship to the energy barrier being
overcome? What happens if you increase the wavelength significantly?
Sorry --
Eric,
See what hydride ion (proton and 2 electrons) looks like when locked
into Ni lattice here; http://chan.host-ed.me/ Now oscillate by
reversing the magnetic vector using a RFG.
Last year I saved this ortiz clip as possible source of parts if I
ever
On Sat, Apr 7, 2012 at 2:41 PM, integral.property.serv...@gmail.com
fusion.calo...@gmail.com wrote:
Another quote from Vortex which may clarify the concept: it was pointed
out by someone the importance of Fe powder influenced by RFG to both
align Ni lattice structure and oscillate the hydride
I was imagining a high energy photon (maybe in the gamma range?) binding
with an electron, thereby creating a dipolariton which then would tunnel
into a nearby neutron (a sort of inverse beta decay).
Sorry -- proton, not neutron: the dipolariton would tunnel into a
nearby proton, creating a
From the article:
*One of the features of these new particles, which the team christened
'dipolaritons', is that they are stretched out in a specific direction
rather like a bar magnet. *
*And just like magnets, they feel extremely strong forces between each
other.*
*Such strongly interacting
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