This might be something KivaLabs could try, Frank. We are using radio
frequency for other purposes, which would make this use relatively
simple. However, since PdD is a conductor, the RF would induce a
current of that frequency in the metal surface. The interior where
diffusion occurs would see no effect. This might be a problem. I
expect a lower frequency would probably be necessary to influence the
interior of the diffusion barrier.
Ed
On Jun 19, 2009, at 1:43 PM, fznidar...@aol.com wrote:
Ed, this super-diffuser idea could lead to a good experiement to
test the Bose condensate idea.
The coherence length at thermal frequencies is 50nm. Assuming the
product that I get applies to this
system 1.094 megahertz-meters, the coherence length should be longer
with radio frequency stimulation.
At 10 mega hertz of stimulation the co-herence length should be .1
meters. The rate of diffusion should increase when a proton
conduction of this length is stimualted at that frequency. If I
were not on the road, living in a hotel in Knoxville, and here
working on CO2 capture, I would try this.
Cc: Edmund Storms <stor...@ix.netcom.com>
Sent: Fri, Jun 19, 2009 10:28 am
Subject: Re: [Vo]:Fringe
This is a nice imaginative theory described in the article, Frank,
but it does not prove that Bose Condensates of hydrogen exist. In
fact, such structure should show up as anomalies in diffusion, which
they do not. If a structure containing H(D) can move through the
lattice without resistance, the material should also become a super-
diffuser, which it is not. In addition, PdD is superconducting in
the normal way at about 10°K, not at room temperature where the BC
structures have to exist to be useful for CF. I still see no
evidence that these structures exist in PdD.
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