That's the final stage of his theory, which has a resonant requirement. The longest wavlength for a cavity with 1nm is 2nm or ~500eV. This is wavelength has a strong absorption in matter in general because it ressonates with the inner orbitals of atoms. So, it is a highly ionizing radiation which would soon heat and melt the surroundings. But that is not the only problem, since even if this wavelength is easily absorbed, a cavity that small is essentially transparent to it. So, there is no cavity.
Besides, I cannot see how that could exclude fractofusion. The breakdown potential for a subnanometer is extremely small to consider an acceleration to thousands of KeV. Consider that the electronics industry spends billions just to keep the off state current leak bellow 0.01% of the On state, and that is one of the main problems. Intel went "3D" transistors to increase the gate area so that leaks could be avoided. But let's say current could be contained, vacuum has an electric strength of up to 20-40MV/m, depending on the shape of the electrodes. That means that a 1nm breakdown would require 20-40mV of potential, hardly enough to accelerate any ion to fusion. The use of Mica could improve that to 0.1eV, so a separation of 0.1mm could indeed cause fusion. Now, I was calling for a pressure mechanism, that would require far less energy than what was stated above. Considering the size of what I had in mind (I didn't write yet), it would operate more or less like an enzyme. But, that doesn't matter anymore, right? 2012/8/19 Abd ul-Rahman Lomax <[email protected]> > Storms thinks that cracks create cavities of a necessary resonant size. > -- Daniel Rocha - RJ [email protected]
