Why photons and neutrino interaction with their environment are so weak?

Cherenkov's radiation is forming. In a case, where a neutron or some other particle hits the water or some other thicker medium. Because a neutron has a mass slowing that thing cannot happen immediately. Neutron needs to send their kinetic energy somewhere. And it releases it in the form of a blue light shockwave. Or what happens when we think that thing more accurately?

When neutrons hit the water. Quarks inside it move forward and hit to neutron's quantum field. That means the neutron's quantum field sends a blue light flash to the water. And that thing means that the particle that is in the WARP bubble acts like those quarks inside the neutron.

So the quantum field that ties quarks to neutrons forms a short-term WARP bubble that causes a situation. That quarks are crossing the speed of light in a very short moment. And that causes an idea that other particles act similar way but that short-term flash is too short for measurement.

The neutrinos send similar blue light flashes like neutrons when they hit atoms in neutron detectors. Or actually, those flashes are forming in particles where the neutrino impacts. The reason for that flash is that neutrino moves energy to that atom. And that atom or subatomic particle must release that extra energy, in the form of a blue light flash. The neutrino must precisely impact the subatomic particle so that sensor can detect the flash.

The question is: why photons and neutrinos are interacting so weakly?

If energy travels away from the particle very slowly. That makes it hard to detect it.

The neutrino's energy level may be only a little bit higher than its environment. So that makes the energy flows from that particle extremely slowly. And that means the neutrino is very hard to detect. The reason for that is the wave movement that moves away from the neutrino is so weak that the particle is like a ghost.

The speed of energy flow away from a particle makes it visible. And energy difference between that particle and its environment determines how fast energy flows away from the particle.

There is the possibility that a similar effect causes the weak interaction between photons, neutrinos, and their environment.

The idea is that the particle is like a whisk around the axle. That thing means that in the middle of that whisk-looking structure is particle pair that is forming an axle where the whisk-shaped structure of quantum strings or quantum lightning is forming. So there are two versions of the thing how the quantum field must behave, that it's the interaction is extremely weak. Maybe the first one is the neutrino. And the second one is the photon.

Neutrino's possible form.

1) The particle rotates around its axle so fast that there forms electromagnetic low-pressure at its poles. The poles are the head of the axle where the particles are forming. Electromagnetic low-pressure causes the situation that wave movement or the superstrings are falling in the particle from those poles.

When the particle moves forward. It pulls wave movement inside it. And then the rotation movement pulls the energy out from the sides of that particle.

Maybe that thing explains why the interaction between the neutrino and its environment is so weak. The reason for that is that the energy that travels away from that particle pushes quantum fields away from it.

And that makes the particle warm so when the particle is warm. Its energy level is higher than its the environment. And that makes it possible to see that particle. The energy or wave movement that travels out from a particle makes it visible. The weak interaction between the neutrino and its environment means that the neutrinos energy level is just a little bit higher than its environment. And that makes the energy flow away from that particle very slowly.

Photon's possible form.

2) The energy can travel inside the particle from the sides. There is a small electromagnetic or quantum tornado inside that particle. The wave movement comes out from particles from its poles. That thing forms the radiation pike ahead of the particle.

This radiation pike pushes the other quantum fields away from the route of that particle. So that structure turns the particle look like stealth. There could be some kind of wrap at the energy pike. And that means there is the possibility that this kind of structure causes a situation that behind the visible photon is some yet unknown particle.

https://shorttextsofoldscholars.blogspot.com/

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Cogito ergo sum. I think; therefore I am (René Descartes, French philosopher)

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