The Exotic Vacuum Object (EVO) is the soliton that produces the static chiral magnetic electroweak field that generates the LENR reaction.
I judge that enough theory has been accumulated to layout the process that explains the steps involved in the creation of the EVO by an electric arc or explosion and the EVOs subsequent maturation process, and lifetime maintenance
The first step that the electric explosion must achieve is the production of an ultra dense form of matter that seeds the EVO soliton. This compression of matter is most likely accomplished through the generation of a shock wave initiated by the explosion.
The types of materials that can form this seed is wide ranging and includes both elements and chemical compounds. Carbon, copper, lithium, hydrogen, noble gases, and water are among the materials that support the formation of this ultra dense material seed.
This ultra dense material forms a nanoparticle that is comprised of a positively charged core that in tern is comprised of a lattice of proton cooper pairs surrounded by a core of very low lying electrons that form a non orbiting stationary spin wave. The electron spin wave is kept in place by a balance between spin attraction and the magnetic repulsion of the Meissner effect.
In the next step, the light produce by the electric explosion is captured within the spin wave layer for a period of time that is long enough for the electrons that have been captured in the spin layer to disassociate into Dirac spinors through the entanglement of light and matter.
How about the photons produced by the explosion themselves? Can anything slow a photon down so that these photons can interact with the electrons? It turns out that a BEC can. In fact, it can even stop a photon (in effect) for a few seconds, then reconstitute it (with all the quantum information it contains still intact) and allow it to resume its course. This behavior of the photon nearing the BEC allows the photons and the electrons to become entangled with high efficiency.
The Dirac spinors have now been purged of the quantum charge property of the electron.
Consistent with the hole theory of superconductivity, to balance the charge of the positive proton core, more free electrons are attracted to the positively charged nanoparticle. These electrons are now converted to more Dirac spinors in a chain reaction that continues only constrained by the availability of free electrons without limits until an electroweak singularity is eventually reached.
Since the nanoparticle is a superconductor and also a superfluid, no energy is lost by the EVO through dispersion. As the EVO accumulates more spin, a supersolid lattice of Dirac spinors form. When the amount of available free electrons is large, this spin accretion process continues until a tipping point is reached where the EVO explodes in a Bosenova. Bosenova explosion has also been seen and verified in experiment.
Experiments has shown through the examination of their tracks and marks created in solids that the EVO can become macroscopically large before Bosenova explosion occurs. This explosion of Dirac spinors is the mechanism whereby the energy stored in the EVO is released to the environment in the non nuclear form of excited electron energy transfer.
It has also been shown that cavitation can produce a form of ultra dense water that behaves is a similar way to the nanoparticles produced by electric explosion in solid matter.
What is that nature of the energy that is derived from the Bosenova quantum mechanical explosion? Where does the energy that the Bosenova releases come from? In the earliest days of the formation of the universe, this energy release mechanism occurred when the Higgs field came into existence and when the weak force separated from the EMF, and when electrons acquired mass.
The EVO replicates in reverse the processes that occurred in the formation of the universe when the combined forces of nature separated. The Bosenova replicates the release of energy when the forces separated.
Implosion and explosion of a Bose-Einstein condensate "Bosenova"
https://www.nist.gov/news-e...
QuoteThe condensate first shrinks as expected, but rather than gradually clumping together in a mass, there is instead a sudden explosion of atoms outward. This "explosion," which actually corresponds to a tiny amount of energy by normal standards, continues for a few thousandths of a second. Left behind is a small cold remnant condensate surrounded by the expanding gas of the explosion. About half the original atoms in the condensate seem to have vanished in that they are not seen in either the remnant or the expanding gas cloud.
Since the phenomenon looks very much like a tiny supernova, or exploding star, the JILA team dubbed it a "Bosenova." The most surprising thing about the Bosenova is that the fundamental physical process behind the explosion is still a mystery.