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The dark matter and its quantum field can break other particles. And set the limit to the speed of light.
The particle accelerators are not creating particles like the Higgs boson. They just release them from other particles. The internal interaction inside the Higgs boson means there might be some more high-energetic particles inside that boson.
The Higgs boson interacts with the heaviest quarks. And there is a possibility that the Higgs boson interacts with its power or quantum field what means there are no other particles inside the Higgs boson waiting for release.
In a normal way to think there is no matter is the Higgs boson interacting with itself or with its power field. The internal interaction means that the form of the Higgs boson is chancing. But in the quantum world, that kind of thing has matter.
The internal interaction would prove the existence of the superstring. If the Higgs boson would be formed by superstring, that is the 1-dimension string. That could explain the internal interaction of that particle.
The enormous speed and energy that is targeted to the Higgs boson would make the superstring oscillate. And that thing would cause the effect, what looks like internal interaction.
The speed of the Higgs boson is enormous. And that means the quantum field around it would come real close to that particle. But the interesting thing is the possibility that in the Higgs boson is the particle, that can press itself out of the effect of those quantum fields of the dark matter.
The speed of light and its relationship with dark matter is an interesting thing. If we are thinking of dark matter as the thing, that resists the speed of photons. That thing means that the energy fields around axions and WIMPs (Weakly Interacting Massive Particles) are the thing that resists the speed of other particles. So we can think the same way that if the axions and WIMPs are similar particles with other particles in the universe if we are thinking about those particles as things like other particles that are surrounded by an electromagnetic field.
The frequency of those electromagnetic fields is different than other particles, so that means that the dark matter and its electric fields are the things, that are denying the collapse of the universe. But the thing is that when the universe is starting to collapse, the quantum fields would acting like rubber balls. And that thing makes the universe jump to its original size. But then we can think that those balls of the electromagnetic fields have the thing. What slows the speed of the photons and other particles.
The thing that supports that idea is the Higgs boson. When we are starting to accelerate electrons and positrons by using the LHC (Large Hadron Collider). And then collide them the energy load of the particles is enormous when they hit each other. The impact energy of each particle is about 13 teraelectronvolts. And that means the impact power is almost 26 teraelectronvolts.
The reason why that kind of power is needed is that the Higgs boson must make visible. Those bosons are with us all the time. But they are so small that the mass of them must rise to extremely high. So when the speed of the electrons is rising their mass is rising too. And then from that particle is released the sub-particles. That means that it seems like the electrons will lose their core when their speed and mass is rising. There are coming smaller and smaller particles.
And the reason why the Higgs boson can reach an enormous speed is about 99,99% of the speed of light is that the mass of that particle is in so small area that the particle can pass the quantum fields of the dark matter is that the size of it is so small, that it can slip between those power fields. The internal interaction of the Higgs boson is interesting. This means that there is probably some other more high-energetic particle waiting for the release inside the Higgs boson.
https://cms.cern/news/how-does-higgs-boson-interact-itself
https://www.energy.gov/science/hep/articles/atlas-experiment-uncovers-higgs-boson-interactions-heaviest-quarks
https://en.wikipedia.org/wiki/Higgs_boson
Image: https://sites.google.com/site/thesmallestofparticles/particle-accelerators
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