Technically I should have written under compression instead of under strain. harry
On Tue, Mar 27, 2012 at 5:44 PM, Harry Veeder <hveeder...@gmail.com> wrote: > Might this be related to the piezonuclear activity (production of neutrons) > observed during the laboratory fracturing of granite under strain? > > "these locally extreme conditions could catalyse in the interpenetration > band the formation of a plasma from the gases which are > present in the solid materials (even at room conditions)." > > from > Piezonuclear neutrons from fracturing of inert solids > Physics Letters A 373 (2009) 4158–4163 > F. Cardone , A. Carpinteric, G. Lacidognac > > Harry > > > > On Tue, Mar 27, 2012 at 3:18 PM, Axil Axil <janap...@gmail.com> wrote: >> Novel Attractive Force Between Ions in Quantum Plasmas >> >> http://arxiv.org/pdf/1112.5556.pdf >> >> This is the paper behind the article. >> >> This paper explains the theoretical basis of a new form of matter called >> ionic crystals. >> >> Ionic crystals are the agent that causes cold fusion. >> >> The article says: Quantum plasmas extend the area of application to >> nano-scales, where quantum-mechanical effects gain significance. This is the >> case when, in comparison to normal plasmas, the plasma density is very high >> and the temperature is low. >> >> Axil says: >> >> This is what we have in the Rossi type reactor. The hydrogen envelope is >> very high density plasma with a very low temperature. The population of >> degenerate electrons in this envelope is high due to the high pressure of >> the hydrogen gas. >> >> These degenerate electrons force Rydberg atoms together into a condensate >> and keep this condensate together when the crystal ionizes. >> >> These degenerate electrons produce a force field at long range that pushes >> protons together to form cooper pairs. This attractive electron field also >> forces naked positively charges nuclei together that have had their coulomb >> barrier stripped as described in my post titled “the magnetic monopole.” >> >> When these naked nuclei come into contact, the nuclear force takes over to >> form new elements. >> >> Degenerate electrons are attributable to the Pauli Exclusion Principle. The >> pressure maintained by a body of degenerate matter is called the degeneracy >> pressure, and arises because the Pauli principle prevents the constituent >> particles from occupying identical quantum states. Any attempt to force them >> close enough together that they are not clearly separated by position must >> place them in different energy levels. Therefore, reducing the volume >> requires forcing many of the particles into higher-energy quantum states. >> This requires additional compression force, and is made manifest as a >> resisting pressure. >> >> Therefore, since according to the Heisenberg uncertainty principle ΔpΔx ≥ >> ħ/2 where Δp is the uncertainty in the particle's momentum and Δx is the >> uncertainty in position, then we must say that their momentum is extremely >> uncertain since the particles are located in a very confined space. >> Therefore, even though the plasma is cold, the electron must be moving very >> fast on average. This leads to the conclusion that if you want to compress >> an object into a very small space, you must use tremendous force to control >> its particles' momentum. >> >> This is what the micro-cavities in the micro powder do; compress electrons >> into the degenerate state. >> >> The article says: The new negative potential causes an attractive force >> between the ions, which then form lattices. >> >> Axil says: >> >> This is why Rydberg ions are formed so readily in a pressurized hydrogen >> envelope. >> >> The article says: They are compressed and the distances between them >> shortened, so that current can flow through them much faster. >> >> Axil says: >> >> This is why electrical resistances drops as the temperature increases in >> cold fusion material.