Thank you Jones. I believe you understand. Take the sea for an example. The speed sound is fixed at 2 kilo meters per second or so. Waves on the surface can go slower or faster. Tidal waves can exceed the speed of sound in water.
That the concept that I want to apply. Instead of using air to generate the waves I want to use electric vibrations. I am looking for loose (did I use the right word Jed?) non coupled hydrogen atoms. The ones that vibrate at high frequency Their vibrations are called optical phonons on a dispersion chart. I want couple them with the electronic lattice. I am done writing books for a wile and its time to get out my equipment once again. Everyday I learn more, but I will not make another revision for at least 6 months. (its peak blackbody frequency of ~40 THz) Jones without giving to much away, I do not want thermal vibrations. The peak blackbody wavelength would be around 7 microns. Yes you understand. Black body is a collection of frequencies. I am trying to tune with a coherent source. No saying more about this either. I suspect that this is where the fine structure constant comes into play. Yes indeed. Maxwell's use of eo and uo of Coulomb's equation gave the speed of light. My factoring gave 1/2 the speed of the ground state electron in hydrogen. The ratio of these to numbers is the fine structure constant. The velocity is the speed of sound in the nucleus. When the cluster speed equals the nuclear speed we have coupling. Velocity needed = 2/alpha -----Original Message----- From: Jones Beene <jone...@pacbell.net> To: vortex-l <vortex-l@eskimo.com> Sent: Mon, Jan 14, 2013 12:02 am Subject: RE: [Vo]:I feel really good about what I have done From: Frank Z It predicts that if you can induce a wave motion in the dissolved hydrogen or deuterium with a velocity of one mega meter per second cold fusion will progress. Normal sound velocity in a solid is 2 kilo meters per second. Now we reduced the cold fusion process down to a material condition. We must apply external stimulation at 1 million meters per second. We must transfer that velocity to the dissolved protons. The problem now become how can we increase the external stimulation. Laser, radio wave, or thermal. How can we get the dissolved deuterium to resonate with and effectively couple with a velocity of one mega-meter per second. The applied transverse vibrations must induce a wave motion of 1,094,000 meters per second in the dissolve protons. I don't know the answer of how to do this yet. One possible suggestion for analyzing hydrogen gain to accommodate megahertz-meter, since we have the luxury of working backwards from some known values which are thought to work - would be based on having uniform pore size of Casimir dimensions for containing hydrogen - say 8-10 nm in diameter. There is evidence of relativistic hydrogen in such pores so they could easily couple to photons which were in semi-coherence with phonons at the peak blackbody frequency. You would want the cavities and the encompassing nickel alloy to vibrate at roughly a frequency equivalent to the trigger temperature of the reaction (its peak blackbody frequency of ~40 THz). The needed wavelength would therefore be much longer than the cavity diameter, but photons would couple to the protons in the cavity in a known way which would be related to the fine structure constant. Around 40 THz and 600+ K is within the range of mid-IR frequencies/temperature which is applicable to trigger a Celani type experiment using a nickel alloy. The peak blackbody wavelength would be around 7 microns. This wavelength times the frequency is about 300 times too long for megahertz-meter of course -- but we would never expect heat alone to suffice. Assuming that the frequency times the cavity diameter were to equal about 3200 meters per second - that is 300 times too low, but a combination of both is about right - one megahertz meter. How you verbalize that so that it makes sense is not clear. I suspect that this is where the fine structure constant comes into play. Bottom line - I could envision a reactor working gainfully with 8 nm cavities and 40 THz thermal semi-coherency based on positive feedback of semi-coherent photons at that frequency - with very high net gain. If the energy gain is found to be especially robust at roughly those parameters, Frank should be congratulated. Jones