Could it be that the majorana particle is the one that controls linear momentum 
by conserving its angular momentum in being its own anti-particle. 


Axil:  Your explantion of spin is nice.  I have not heard it said so simply 
before.  It still begs the issue of how linear momentum is conserved in the 
Higgs boson interactions.


Bob





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From: Axil AxilxTo: [email protected]






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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