Also, if you seek a transient effect, does heat exist in a moment? Heat is a chaotic form of random microscopic changes in kinetic energy, if so there should be windows where there is no change in momentum which could be argued to be as localized moments of zero heat?
Additionally maybe the requirement for extreme cold can be overcome by an enhancement somehow in the background quantum field? It seems to me that heat is just noise, if the noise is too high you could just increase the 'signal'. The signal in this case is the nature of quantum effects in the vacuum, so maybe the vacuum can be enhanced to produce a more robust effect? Maybe various LENR experiments condition the vacuum quite unknowingly. John On Thu, Nov 6, 2014 at 4:41 AM, Jones Beene <jone...@pacbell.net> wrote: > An interesting possibility about FQHE – in the context of LENR, is that > there could be a transient version inside a Casimir cavity. > > The phenomenon of the fractional quantum Hall effect (FQHE) occurs when > electrons are contained in two dimensions, cooled to near absolute zero > temperature, and exposed to a strong magnetic field. > > On the surface, it would seem that this cannot happen in LENR as a static > phenomenon, as the temperature is way too high… but electrons confined > inside a dielectric Casimir cavity, which is inside a metal matrix - even > at 500C could experience a transient version of FQHE in a situation where > SPP are supplying the strong magnetic field, and virtual photon exclusion > by the cavity walls provides the cooling effect, and the inside of a > Casimir cavity can be modeled as 2-D. > > The first and last are found in prior scientific studies, but the cooling > effect is not seen in the literature, AFAIK. > > Jones > > Kevin, > > Not sure what direction you are going with this – but in 2010 – we were > talking about fractional electron charge (AKA: FQHE) as being the driving > force behind one form of LENR – at least the non-nuclear version of LENR > and possibly the Mills’ version - which happens at the nanoscale or in > Casimir cavities. Several times since then, the fractional Hall effect has > been tied to thermal anomalies. > > *https://www.mail-archive.com/vortex-l%40eskimo.com/msg40603.html* > <https://www.mail-archive.com/vortex-l%40eskimo.com/msg40603.html> > > “I won't go into all of the lore of monatomic hydrogen, going back to > > Langmuir, or the Mills' version of fractional hydrogen called the hydrino - > > except to say that there is another possibility that encompasses both of > > these phenomena - and it can explain other "hot hydrogen" (HH) phenomena or > > anomalies, so long as we limit it to two dimensions. > > > > This possibility would also suggest that a Casimir cavity is or acts 'as > if' > > it were a two dimensional space. There are a number of papers on this > second > > prerequisite, many of them by Calloni, but I will save that for another > > time. The argument is sound. > > According to Laughlin, electrons can form an exotic state with fractional > > charge in two dimensions. Unlike the putative hydrino, this seemingly odder > > beast is accepted by the mainstream. It has even won a Nobel. Consequently, > > taking this bit of insight to the next level - given that all electrons are > > happy to form pairs, it is suggested that HH is itself related to FQHE via > > paired electrons.” >
