For others here is the link and bodies of the thread: http://www.mail-archive.com/[email protected]/msg62033.html
In physics, Planck's law describes the amount of energy emitted by a black body in radiation of a certain wavelength (i.e. the spectral radiance of a black body). The law is named after Max Planck, who originally proposed it in 1900. The law was the first to accurately describe black body radiation, and resolved the ultraviolet catastrophe. It is a pioneer result of modern physics and quantum theory. For a given black body temperature, the wavelength at the peak of the Planck curve is called maximum lambda. This value gives a fell for the minimum relative size that an radiating object must be to optimally support photons associated with a give temperature. Like and antenna, a particle of nickel will best support the photons at a given temperature if the particle size is the adjusted to the ideal size. For a temperature of 700k or about 400C, the Lambda(max) must be 4.14 microns. This is why Rossi uses very large micro sized nickel particles in his reactor. Nano sized particles will not properly support the ideal photon wavelength needed to force protons into quantum mechanical coherence. Rossi undoubtedly found this optimal size through trial and error but science is easier. For a Planck function Infrared Radiance Calculator see the following: https://www.sensiac.org/external/resources/calculators/infrared_radiance_calculator.jsf%3bjsessionid=D08873244D6904EE654DBCDF0391F95E -------------------------------------------- Finally some one worth talking to. You are correct, however, you must adjust for the speed of sound withing the dissolved metal to be at c/(2*137) http://www.wbabin.net/Science-Journals-Papers/Author/913/Frank,%20Znidarsic Frank Znidarsic -------------------------------------------- Frank, The Ni metal is not dissolved is it? I also understand the smaller the Ni particle, the lower the melting temperature due to melting point depression. * * *Melting-point depression* is a term referring to the phenomenon of reduction of the melting point <http://en.wikipedia.org/wiki/Melting_point> of a material with reduction of its size. This phenomenon is very prominent in nanoscale materials <http://en.wikipedia.org/wiki/Nanotechnology>which melt at temperatures hundreds of degrees lower than bulk materials. -------------------------------------------- That is another good question. Why do we need protons in a proton conductor? The proton spacing is still measured in atomic distances not nuclear distances. The answer is The Dissolved Protons are not bound. The frequency is not determined by K sq root of K/M where K is measured to the next atom. The boundary condition is at the edge of the nickle crystal. This is very important. the size is more important than just for the absorption of hydrogen, it sets the boundary condition for resonance. When the speed of sound in the dissolved hydrogen protons = the speed of sound in the nucleus, bingo we have a macro atom and cold fusion. Of course the devil is in the details. Frank Znidarsic On Sun, Jun 30, 2013 at 6:32 PM, Axil Axil <[email protected]> wrote: > see post: > > Right Sizing Nickel Particles > > > On Sun, Jun 30, 2013 at 6:40 PM, James Bowery <[email protected]> wrote: > >> Google "phonon resonance temperature" and you'll come up dry. >> >> >> On Sun, Jun 30, 2013 at 1:27 PM, H Veeder <[email protected]> wrote: >> >>> Coincidental pressure drop or is Ni62 changing into Cu63 at the "first >>> phonon resonance" temperature of 489°C for Cu ? >>> Harry >>> >>> >>> >>> http://www.quantumheat.org/index.php/en/follow/follow-3/296-50-meters-of-constantan-in-one-cell >>> >>> quote >>> <<UPDATE#2 - STUNNING GRAPH >>> So the reactor is now at the 1st phonon resonance temp of Cu63 (the >>> target element) as put forward by one of our followers in his freely >>> published document you can review here >>> http://www.human-resonance.org/Qi.pdf >>> He suggested his research showed that if we hit the 489 degrees C in >>> pressured hydrogen atmosphere, over time the Ni62 would become Cu63. >>> From the text:- >>> "Precision heating of nickel powder to 489°C or 859°C resonance with >>> copper isotope Cu63 in the presence of pressurized H2 gas will target and >>> maximize conversion of nickel into stable copper. The nuclear fusion >>> reaction that produces excess heat can be specifically targeted by >>> precision heating of the reaction to 620°C or 966°C resonance with >>> meta-stable copper isomer Cu68m" >>> Now just look at what is going on in the cell! >>> >>> [see graph] >>> >>> You might note that the 2nd resonance temp is ballpark the December >>> rossi temp where the cell melted down and the second is ballpark the 2nd >>> COP 5.7 test... the 3rd test at a lower temp (in the range of our Celani >>> experiments) but much lower COP.>> >>> >> >> >
