good advice. The strontium ferrite BILLET is a Perovskite. They are known to support shallow potential wells.
________________________________ From: Axil Axil <janap...@gmail.com> Sent: Friday, May 5, 2017 2:53 PM To: vortex-l Subject: Re: [Vo]:The Kerr effect >From what is described in the response to the application of an intense high >voltage electrostatic field observed by experimenters, the bullet seems to be >more responsive to demagnetization when a weak magnetic field is applied to >it. The electrostatic field exposure might affect the nanostructure of the >magnetic domain boundaries and/or the nanoparticles that comprise the >composition of the magnet material. The experimenter describes behavior of the bubble that forms at the center of the bullet moves around like a liquid when an external magnetic field is applied to that region of the bullet. This liquid like behavior only occurs after the application of the electrostatic field and is a pertinent feature thereafter. Place some magnetic plastic on your active bullet to visualize the behavior of its magnetic field at its center. Then expose that area to a weak magnetic field from a refrigerator magnet. Do the same test on a unprocessed bullet that can be gotten from the marketplace. Check to see if the bubble at the center of that unprocessed bullet behaves in the same way...as a liquid. If the behavior of the magnets are different then a point of comparison is now possible. To understand what is going on at the nano level of that bubble needs some specialized sensitive magnetic sensor equipment I suspect. On Fri, May 5, 2017 at 1:44 PM, Brian Ahern <ahern_br...@msn.com<mailto:ahern_br...@msn.com>> wrote: Can anyone describe how this applies to the Manelas billet. It is ferromagnetic and highly resistive. Here is what I have learned from my decade accompanying Keith Johnson (MIT prof. retired 1997) 1.Magnetism arise from the alignment of spins. 2.The spin is quantized and the electrons are in orbitals that can be predicted. 3.Some ferromagnets have spins that are associated with loose bonding (shallow potential wells) 4. Shallow wells enable a relaxation of the Born-Oppenheimer condition (Electron motion is independent of ion movement.) 5. Ferromagnetism with shallow potential wells allows for interaction between spin alignment and vibrational modes. 6. This condition allows for cooling with the application of pulses to interplay with the vibrational modes and spin alignment. ________________________________ From: bobcook39...@hotmail.com<mailto:bobcook39...@hotmail.com> <bobcook39...@hotmail.com<mailto:bobcook39...@hotmail.com>> Sent: Friday, May 5, 2017 11:52 AM To: vortex-l@eskimo.com<mailto:vortex-l@eskimo.com> Subject: RE: [Vo]:The Kerr effect Axil, Those references are quite instructive. The idea of power transfer vectors as a coupling mechanism is a new concept for me, I hope that this is being taught in undergraduate physics chemistry and EE courses. The magnetic field and spin energy transfer all closely connected IMHO. Engineering coherent systems in the solid state to allow the coupling to the nuclear part of the potential energy of the system is the crux of achieving LENR+. Bob Cook From: Axil Axil<mailto:janap...@gmail.com> Sent: Saturday, April 29, 2017 10:04 AM To: vortex-l<mailto:vortex-l@eskimo.com> Subject: Re: [Vo]:The Kerr effect The following reference actually shows the monopole magnetic field produce by the polariton. If you cannot understand that picture, I cannot do more. The Ni/H reactor produces the same effect using polariton vortexes that form on the surface of nickel micro particles and in clusters of lithium hydride nanoparticles. There is also the condensation of these polariton solitons that provide super-radiance as another powerful amplification mechanism. see figure 2 for a picture of the monopole magnetic beam Half-solitons in a polariton quantum fluid behave like magnetic monopoles http://arxiv.org/ftp/arxiv/papers/1204/1204.3564.pdf Nanoparticles produce Surface Plasmon Polaritons (SPP) which are the optical cavities that produce that magnetic fields that result in meson emission. Sorry if the line of connections is long, Here is how nanoparticles produce EMF amplification of light. http://arxiv.org/ftp/arxiv/papers/1405/1405.1657.pdf Plasmonics with a twist: taming optical tornadoes on the nanoscale Nanoplasmonics provide many types of EMF amplification mechanisms. One of the more difficult mechanisms to understand is how a pile of nano and micro particles greatly amplify EMF. The reference provided in this post shows how the topology in the way particles aggregate explain how EMF is concentrated through vortex formation. The reference defines an analogy between a vortex and a gear. Like a funnel, a large particle gathers the energy from a wave of EMF far larger than its diameter, In the case of the Rossi system, this type particle is the 5 micron nickel particle. https://vimeo.com/36691535 This large particle produces a relatively huge vortex. Other particles of various sizes accumulate around the nickel particle. Each of these particles produce a vortex proportional to the size of the particle. These vortexes fit together like gears where the large vortex provides a large amount of power, and the other smaller vortexes provide a gear train that speeds up the rotation rate of the smaller gears down the train. https://www.youtube.com/watch?v=IkxXheV748U Finally, the smallest vortexes associated with hydrogen crystals, spin at high rates of speed providing large EMF power amplification. The take away is that a large spread of particles sizes produced within an aggregation of particles generates the most powerful EMF amplification effects. This fact explaines why the “secret sauce” effect provides such a large EMF power amplification result. These alkali metal hydrides supply the intermediatly sized gears that allows the large nickel gears to transfer their vast store of energy with little loss to the smallest hydrogen based gears down a smoothly running vortex power transmission chain. I venture to say that there is randomness associated with this particle aggregation process that enables a sort of natural selection where the most effective dust pile configurations provide the most EMF amplification. When there are an abundance of particles, the chances are good that some of these piles will be LENR capable. That is to say, when there are a large number of particles, the chances are good that some of their aggregates will produce EMF amplication great enough to catalyze nuclear effects. There is also a certain lifetime associated with particle formation. Particle piles are constantly falling apart. These particle aggregates must be constantly rebuilt to maintain a sustained reaction rate. The SunCell is an example of dusty plasma based LENR where silver vapor condenses into nanoparticles that produce the LERN reaction.