In order to explane the soliton solution to dark matter, physics has
invented particle ensembles with the count of members between 10^^15 and
10^^36 members. These ensembles are called Q-balls which carry large
numbers of a conserved global charge, B-balls which B-balls containing
baryonic charge which are stable because of the largeness of the nucleon
mass,,,these sound like micro black holes, and L-balls which contain a
large amount  of  leptonic charge.
No body that I have come across has imagined the S-ball that contains a
huge number of spin only particles. These S-balls would be well may well be
at work inside the NiH reactor producing LENR reactions. Such S-balls would
project a large anapole magnetic field which is ideally well suited to
produce behavior demonstrated by dark matter observations.

For reference:

http://en.wikipedia.org/wiki/Q-ball

http://www.hs.uni-hamburg.de/DE/Ins/Per/Banerjee/WWW-ita/publications/PhysLettB_484_278.pdf


On Fri, Jul 18, 2014 at 2:40 PM, Axil Axil <[email protected]> wrote:

> There is a connection between the nature of a particle and the mass that
> he Higgs field gives it.
>
> First some Higgs field  background, all the particles that make up matter
> have mass — from the lightest, the electron, to the heaviest, the top quark
> — and can be left- or right-handed, that is the direction in which they
> spin. This handedness of particles is the means of getting mass from the
> Higgs field.
>
> Although the Standard Model cannot predict their masses, it does provide a
> mechanism whereby elementary particles acquire mass. This mechanism
> requires us to accept that the universe is filled with particles that we
> have not seen yet or at least only at CERN.
>
> No matter how empty the vacuum looks, it is packed with particles called
> Higgs bosons that have zero spin (and are therefore neither left- or
> right-handed). Quantum field theory and Lorentz invariance show that when a
> particle is injected into the "vacuum", its handedness changes when it
> interacts with a Higgs boson. In that meeting with the Higgs boson, the
> particle starts to spin in the direction that is opposite to the way it was
> spinning originally.
>
> For example, a left-handed electron will become right-handed after the
> first collision, then left-handed following a second collision, and so on.
> Put simply, the electron cannot travel through the vacuum at the speed of
> light because the Higgs field would force it to become massive.
>
> Similarly, muons collide with Higgs bosons more frequently than electrons,
> making them 200 times heavier than the electron, while the top quark
> interacts with the Higgs boson almost all the time and this type of quark
> is just about all mass and very heavy.
>
> This picture also explains why neutrinos are originally thought to be
> massless. If a left-handed neutrino tried to collide with the Higgs boson,
> it would have to become right-handed. Since way back when it was thought
> that such a state exists, the left-handed neutrino was thought to be unable
> to interact with the Higgs boson and therefore did not acquire any mass. In
> this way, massless neutrinos go hand in hand with the absence of
> right-handed neutrinos in the Standard Model.
>
> More recently, it was found experimentally that the left handed neutrino
> could turn into a right handed neutrino.
>
> This neutrino spin flip observation now predicts that the neutrino must
> have mass.
>
> It is not the actual flipping of the particles spin that produced mass; it
> is just the fact that a particle could have the ability to flip its spin
> that gives it mass.
>
> The mass rule comes down to this: any particle that has an anti-particle
> or in other words, can flip its spin also has mass given to it by the Higgs
> boson. This includes particles that can be its own anti-particle call a
> Majorana fermion, also referred to as a Majorana particle. This is a
> fermion that is its own antiparticle.
>
> It is my contention that elementary particles like photons and electrons
> can form more complex compound particles called quasiparticles that can
> acquire mass from the Higgs field through their ability to flip their spin
> or be their own anti-particle. For example, protons and neutrons are
> compound particles of different quarks and they both get mass from the
> Higgs field.
>
> Photons and electrons can form a soliton of surface plasmon polaritons.
> This soliton like any soliton can be considered a particle
> indistinguishable from real elementary particles.
>
> If this SPP soliton is its own anti particle then it can acquire mass from
> the Higgs boson. This mechanism of SPP formation may be how light can
> acquire mass.
>
> If LENR is occurring all over the cosmos and producing SPP solitons, when
> photons join with electrons as a Majorana soliton particle, dark matter
> could be dynamically formed adding a new source of mass to the universe.
>

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