At @interzone 's suggestion, I will make this part of one of my comments a separate answer: Any new theory of interactions of fundamental particles *must* agree with all the existing experimental observations at least as well as the existing theories. The reality is that positrons are easily observable, since they are the product of the radioactive decay of a number of naturally occurring isotopes. All observations to date show that they are identical to electrons except for charge.
If they didn't behave like electrons in a magnetic field, a lot of particle accelerators would not work nearly as well as expected. The most notable example of electron-positron colliders is SLAC, which uses magnetic fields to alter the paths of electrons and positrons (en.wikipedia.org/wiki/SLAC). That's probably a sufficient counter-example to negate the proposed theory.
1. A positron is the anti-matter component of an electron 2. Collision of a positron and electron will either annihilate each other or scatter 3.
If a positron has high energy it will have to slow down before an electron can capture it. 4. When an electron and positron combined and transform into energy 5.
Conservation law have been upheld in the reaction 6. When an electron-positron annihilate, if they have no velocity then 2 photons of 511 Kev is produce. The energy is greater if the electron positron velocities are faster.7.
If the energy is right, the quark and antiquark will stick together 8. If two electrons collide at high energy, they can create a number particle and antiparticle pairs.9. When high energy photons collide with soft photons they create additional electron-positron pairs Book = Black holes: the membrane paradigm 1.In the magnetosphere of a supermassive black hole the resulting electron-positron plasma can easily provide enough charge to slide around on the magnetic field lines and cancel the electric field.
Quarks glafreniere.com/sa_quarks.htm Quote Electrons and positrons close together should overcome their electrostatic charge and form a structure. Quote The wave mechanics indicate that an electron and a positron can produce two or more quark pairs because the gluonic field can attract additional positrons or electrons in the vicinity.
As I said in my answer to your other question concerning this matter: positron and electron will annihilate each other if they come in contact, producing an emission of gamma photons. Positron is an antimatter, more precisely, an antimatter counterpart of an electron - an interaction between matter and antimatter leads to mutual annihilation. Is your theory available for closer inspection?
I cant really gove you an answer,but what I can give you is a way to a solution, that is you have to find the anglde that you relate to or peaks your interest. A good paper is one that people get drawn into because it reaches them ln some way.As for me WW11 to me, I think of the holocaust and the effect it had on the survivors, their families and those who stood by and did nothing until it was too late.