The Shukla-Eliasson (SE) force is one of the main actors in cold fusion. The other is charge screening which is the triggering process .
Also high electric charge concentration produces degenerate electrons. http://arxiv.org/pdf/1209.0914 Clustering of Ions at Atomic-Dimensions in Quantum Plasmas IV. SUMMARY AND CONCLUSIONS In summary, we have carried out particle simulations to demonstrate clustering of ions due to the newly found SE attractive force arising from collective interactions between ensembles of degenerate electrons that shield ions in HED quantum plasmas. Specially, the SE attractive force leads to clustering/condensation or coagulation of ions in the absence of an external conning potential for charged particles. *This part is very important to cold fusion.* We believe that the formation of ion clusters are going to play valuable roles in the area of compressed plasmas with degenerate electrons [42, 47, 48] for ICF to succeed, and also in the emerging eld of nano-material sciences (e.g. nanodiodes, metallic nanostructures for thin films [30], nanowires, tabletop quantum free-electron- lasers [49{51] to be used as tunable coherent radiation sources for practical applications), where closely-packed ions will lend support to enhanced fusion probabilities (with anomalous fusion crosssections) for controlled thermonuclear ICF, and may also influence the electric properties (e.g. resistivity) of new super-condensed plasma materials. Specially, we stress that the Cooper pairing of ions at atomic dimensions shall provide possibility of novel superconducting plasma based nanotechnology, since the electron transport in nanostructures would be rapid due to shortened distances between ions in the presence of the novel SE attractive force. Cheers: Axil On Wed, Sep 12, 2012 at 1:36 AM, <[email protected]> wrote: > Jeff, > > The reports cited in the presentation are of hi-temp superconductivity (I > believe), rather than just non-monotonic resistivity vs. temp phenomena. > > It may be worth looking at the recently reported hi-temp superconductivity > seen in fractal materials - e.g., > > "High-temperature superconductivity: The benefit of fractal dirt" > http://www.nature.com/nature/journal/v466/n7308/full/466825a.html > > "Fractals make better superconductors" > http://www.nanotech-now.com/news.cgi?story_id=39593 > > "Fractals promise higher-temperature Superconductors" > http://www.stealthskater.com/Documents/Fractals_04.pdf > > "X-rays control disorder in superconductor" > > http://physicsworld.com/cws/article/news/2011/aug/31/x-rays-control-disorder-in-superconductor > > "Fractals boost superconductivity" > > http://physicsworld.com/cws/article/news/2010/aug/13/fractals-boost-superconductivity > > -- Lou Pagnucco > > > > Jeff Berkowitz wrote: > > To answer my own question: yes, here > > http://lenr-canr.org/acrobat/CelaniFcunimnallo.pdf on page 3, in item > (3) > > of the numbered list. > > > > Of course, it could be some unrelated effect; but decreasing electrical > > resistance with increasing temperature is very odd, and it certainly is > an > > interesting coincidence. > > > > Jeff > > > > On Tue, Sep 11, 2012 at 10:06 PM, Jeff Berkowitz <[email protected]> > wrote: > > > >> Lasers not necessary? Hasn't Celani been reporting a negative > >> temperature > >> coefficient of resistance that appears about the time his processed > >> wires > >> begin producing heat? I might have this wrong ... > >> > >> Jeff > >> > >> > >> On Tue, Sep 11, 2012 at 9:59 PM, <[email protected]> wrote: > >> > >>> "Low Energy Neutron Reaactions (LENRs)" > >>> > >>> http://www.slideshare.net/lewisglarsen > >>> -- or at -- > >>> > >>> > http://www.slideshare.net/slideshow/embed_code/14256059?hostedIn=slideshare&referer=http%3A%2F%2Fwww.slideshare.net%2Flewisglarsen# > >>> > >>> - proposes that high temp superconductivity may develop in surface > >>> plasmons when very high (10^11 V/m) E-field gradients develop at the > >>> interface between collectively oscillating electrons and collectively > >>> oscillating protons. > >>> > >>> Perhaps this is testable using laser pulses, as described in - > >>> > >>> "Surface plasmon enhanced electron acceleration with few-cycle laser > >>> pulses" > >>> http://www.szfki.hu/~dombi/DombiLPB27_291.pdf > >>> > >>> - since they can create field gradients of at least 3.7 X 10^11 V/m > >>> (p.293) > >>> > >>> -- Lou Pagnucco > >>> > >>> > >>> > >> > > > > >
