On Sun, Apr 21, 2013 at 5:22 PM, <[email protected]> wrote:

> In reply to  Axil Axil's message of Sun, 21 Apr 2013 14:11:00 -0400:
> Hi Axil,
> [snip]
> >If  polaritons as used for coulomb screening, because the polariton is a
> >boson, the Pauli Exclusion Principle and  the chemical potential gradient
> >that it generates are not applicable.
> >
> I see several problems with this approach.
>
> 1) The electron in a SPP is part of an exciton. The other part of the
> exciton is
> positively charged, so the ensemble is neutral. That doesn't make for very
> good
> screening.
>
> 2) The fact that SPPs are Bosons only means that they can occupy the same
> energy
> state, not that they can be physically packed into a small volume. In fact,
> since the positive half of the exciton is essentially a charge absence in
> the
> lattice, it will probably have a spatial density proportional to that of
> the
> lattice itself, implying that the spatial density of the SPPs will also be
> proportional to that of the lattice itself. This in turn, means that the
> density
> of the exciton electrons is not likely to be much greater than lattice atom
> density.
>
>
The SPP is part of a dipole. The positive charge is delocalized at the
other end of the micro-particle some 5 microns distant.

The negative dipole charge of one micro-particle is antiparallel to the
negative charge of the adjoining particle. This is like two magnets
positioned North Pole to North Pole so that they repel each other.

The dipoles on the two micro-particles repel each other electrostatically
but their negative charge is concentrated near the particle junction.

This charge configuration produces “dark mode” radiation where the EMF is
directed inward toward the center of the hot spot between the two
micro-particles.
In this situation, no EMF radiation escapes to the far field.


The polaritons are free to move in an electron density wave. Because their
electron temperature is near absolute zero, the polaritons will readily
form BEC where they become coherent and entangled.

The polariton condensate will concentrate in the hot spot at high density.


> 3) In order for significant shielding to exist at the femtometer distances
> required for fusion to occur in a human lifetime, at least one electron
> needs to
> be at least occasionally, between the target nucleus and the approaching
> proton/deuteron.
>
The LENR reaction is an electroweak reaction where a neutron turns into a
proton. This looks like fusion but it is more like radioactive decay
mediated by the electroweak force.

>
> 4) Lattice atomic spacing is tens of thousands of times larger than the
> separation distance needed for fusion.
>
The range of the charge carrying photons is infinite and their intensity
goes as the inverse square law just like light.

>
> Conclusion:-
>
> SPPs can't provide any meaningful shielding above and beyond that afforded
> by
> conductance band electrons in a metal.
>
> Please show me the error of my ways. ;)
>

SPPs can provides everything needed to affect the nucleus of the atom to
both produce and thermalize nuclear energy.


>
> Regards,
>
> Robin van Spaandonk
>
> http://rvanspaa.freehostia.com/project.html
>
>

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