I forgive you right up front for not believing in EMF analog black holes. Not even Einstein believed that black holes were real even though his maths said that they were possible. Science also believes that Bose-Einstein condensates can form only when clouds of gassy atoms cool to within a few billionths of a degree above absolute zero.
LENR is one step ahead of science since a polariton condensate is formed from a blend of light and electrons. The extremely light mass of the polariton: less than 10^-11 the mass of the electron, means that its condensate can form at temperatures over 100,000C. So a polariton condensate can form in plasma. The ultra-dense matter that is formed in LENR fuel can float around inside plasma or an oxyhydrogen flame unaffected by heat and produce the LENR reaction including all the exceeding weird QM and GR stuff that goes along with it. One of the states that a polariton condensate can enter is the dark mode. This is when the polaritons that make up the condensate begin producing x-waves. https://en.wikipedia.org/wiki/X-wave Electromagnetic X-waves travel faster than the speed of light, and X-wave pulses can have superluminal phase and group velocity. This superluminal behavior of light makes the development of an optical event horizon possible. An optical event horizon is described as the boundary within which the black hole's escape velocity is greater than the speed of light. However, a more accurate description is that within this horizon, all lightlike paths (paths that light could take) and hence all paths in the forward light cones of particles within the horizon, are warped so as to fall farther into the hole. Once a particle is inside the horizon, moving into the hole is as inevitable as moving forward in time, and can actually be thought of as equivalent to doing so, depending on the space time coordinate system used. Light that travels faster than light is needed to confine light inside an event horizon. So far, nonlinear X-waves have been only observed in nonlinearoptics experiments, and have been predicted to occur in a variety of nonlinear media including Bose–Einstein condensates. These special waveforms have been seen recently in polariton condensates. https://www.nature.com/articles/lsa2017119 Superluminal X-waves in a polariton quantum fluid This special black out condition causes the polariton condensate (PC) to absorb light thought the formation of an optical event horizon. The PC acts like a black hole and this is where all the weirdness in the LENR reaction comes from. When black hole behavior is mixed with quantum mechanical superposition (QMSP), then we are in for a wild ride indeed. There are two separate reaction types that occur when the LENR reaction is active: vacuum and nuclear/sub-nuclear reactions. Time stops at and inside the event horizon. This means that any reaction that happens inside the event horizon happens instantaneously at our reference frame. Inside the horizon, the nuclear reaction happens at normal speeds. But because the polarion condensate is in a state of superposition, the energy and particles that were produced by the nuclear reaction are not observed. This stuff is lost to us in our frame of reference when the state of superposition is long-lasting relative to the speed of the nuclear reaction. Neutrons, positron, and gamma rays could be produced by the nuclear reaction but we will never see them in our reference frame. The energy that the nuclear reaction generates is also lost to our reality, but what remains is the stabilized ash that the nuclear reaction has produced through transmutation. If the PC is disrupted fast enough in pico seconds, and the state of QM superposition is destroyed, then all the stuff that the nuclear reaction generates can be felt in our reality. The extraction of vacuum energy from outside the event horizon gets out to us because this extraction happens just outside of the horizon. So most likely, the LENR reaction only generates vacuum energy that we can experience in out frame of reference. Here is the punch line… electrons must always be accompanied by its negative energy partner (anti-particles) when it is created from the vacuum: the positron. The event horizon can extract electron/positron pairs from the vacuum but being negative mass, the positron is captured inside the event horizon. The positron therefore cannot be experienced by our reality and is therefore lost to us. The electrons that are extracted from the vacuum can be experienced by our reality because they were created just outside of the event horizon. Electrons will gradually build up as a static charge inside a LENR reactor and can be extracted as an electrical current. On Thu, Jul 4, 2019 at 5:38 PM Axil Axil <[email protected]> wrote: > LENR is a devilishly complicated process to get our heads around. The > nature of the electron that is the first stepping stone or a foundation > mechanism upon which the more complicated processes that goes on in the > LENR reaction is occurring. > > The first stage of the LENR reaction is the construction of the LENR > active agent or what Rossi calls in paragraph 4 of his theory paper > “Neutral pico-metric aggregates”. This structure is also called Holmlid’s > ultra-dense hydrogen. Yes, Rossi to his credit is drinking the Holmlid > Cool aid. > > > http://www.researchgate.net/publication/330601653_E-Cat_SK_and_long_range_particle_interactions > > This special form of hydrogen is also called metallic hydrogen because it > acts like a metal. It is superconducting and has a lot of hydrogen nucleons > consolidated in its core and lots of electrons that form a spin wave (like > a rolling ocean of electrons) scattered around the outside of this > positively charged core. > > Rossi mentions the formation of “bosonic electrons”. This is how that > works. All metal nanowires will develop a polariton bosonic cover when > light (infrared and/or visible) entangles with electrons on the surface of > the nanowire. This entanglement process is where light and electrons, each > having the same energy levels, resonate together to form a polariton, a new > combined light/electron waveform. This polariton has many of both the > properties of light and many of electrons. > > Rossi produces these “Neutral pico-metric aggregates” when he manufactures > his fuel. He must use some sort of high compression mechanism that is able > to transform either hydrogen and/or lithium into its ultra-dense form. It > is most likely lithium since lithium is four times easier to compress > through pressure than is hydrogen. > > Now we have a superconducting hydrogen/lithium nanowire that is coherent > and has formed a polariton Bose condensate where many millions of > polaritons are coherent, then live and quickly die is picoseconds but the > condensate lives on under it own special set of quantum mechanical rules. > This superconducting supported Bose condensate has its own special > properties that can do some very special things to both matter, time, > reality, energy, and the vacuum. > > One of the very weird properties of this condensate is that it can split > off the spin part of the polariton into “spinons” that can form a spin > based plasmoid that gives magnetism mobility and independence where the > plasmoid can travel on its own either in an active or a suspended state to > places far away from the matter that has given it birth. The hard to > understand workings of the polariton condensate is explained in the next > post. > > On Thu, Jul 4, 2019 at 4:31 PM JonesBeene <[email protected]> wrote: > >> >> >> *From: *Axil Axil <[email protected]> >> >> >> >> Quote from: Dr. Pamela Mosier-Boss >> SPAWAR Systems Center San Diego, CA >> >> “We believe the two phenomena, LENR and high T c superconductivity, are >> related and that both need to be investigated in order to gain an >> understanding of the processes occurring inside the Pd lattice... Tripodi >> et al developed a method of loading and stabilizing 50 µm diameter Pd >> wires with Pd loadings greater than one. These samples have exhibited near >> room temperature superconductivity. Examples of measured superconductivity >> … are shown in Figure 1-2.” End of quote >> >> >> >> In addition to this – and due to the implications of the recent Mizuno >> findings, there is a likelihood that one form of HTSC is present well above >> room temperature - up to several hundred degrees C. This could be lossless >> spin-current (as opposed to electron flux) and need not be a bulk effect >> but instead a local effect of the palladium nanoparticle in a plasmon >> environment. >> >> >> >> This explanation adds complexity but at least none of the details rises >> to the incredulity level of nuclear fusion events providing kilowatts of >> heat with zero radiation. Ample evidence exists for both Coulomb explosions >> and for the well-known “proximity effect” AKA Holm-Meissner effect which >> may apply to elevated temperature superconductivity in an interfacial >> plasmonic system. A good theory exists, as Jürg proposes, for spin-current >> superconductivity - which is a better fit for the experiment since it also >> provides the impetus behind the Coulomb explosion, the locus of gain.. >> >> >> >> As always, the proof of every hypothesis will be found in the >> reproducible experiment. We anxiously await replication of Mizuno’s >> breakthrough. >> >> >> >> Jones >> >> >> >> >> >> >> >> >
