There are two possible explanations for the Muon G-2 anomaly.
1) The unknown natural force affected that particle
2) Particle impacts with some unseen particle. So could that impact be the interaction between the dark matter particle?
The theory of axions bases the idea that this hypothetical particle forms thing, called dark matter. There is the possibility that dark matter is a material that has an extremely large quantum field with visible material. So similar but more high-energy quarks are forming that material. There is also the possibility. That the hypothetical axions are like some other well-known particles. That have different shapes or different sizes.
In some theories, the Big Bang that forms the visible universe was the collapse in the energy level of dark matter. When something caused the quantum fields of dark matter to collapse they send the radiation. So the dark matter could be a higher energetic material that has a larger quantum field than visible material.
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The Muon G-2 anomaly challenged the Standard model of physics. The reason why that anomaly is seen in the Fermilab. And other low-energy particles accelerators are an interesting thing.
In high-power particle accelerators, the effect that changes the trajectory of the particle must be far stronger than in low-energy particle accelerators. The thing that can change the trajectory of the particle can be the impact with another particle or it can be some kind of power- or quantum field.
When a particle accelerator accelerates a particle that particle acts like all other moving objects. The speed increases the kinetic energy and mass of the particle. So we can use a car as an example. What happens in a particle accelerator when the particle's speed is rising very high. When the car moves at a very high-speed impacts something that car continues in its track.
In the same way, the side wind effects are less strong if the car is moving at high speed. The side coming effect must be stronger than the kinetic energy of the car that it can affect the track of the vehicle. In the same way, when the car impacts something the energy asymmetry in the body must be so strong that it can change the car's track. When a car impacts something that impact causes the soundwave, thermal wave, and debris.
The same way happens in particle accelerators. If the speed of the particle is too high when it impacts something the particle just crushes its opponent. But that impact doesn't happen without a trace. The impact with another particle causes wave movement and debris. Those things are called virtual particles. The virtual particle is the bubble in the quantum field.
So the virtual particle is not forming from emptiness. There must be some kind of quantum field that forms those strange fields. So is the source of the virtual particles in CERN the impact with the dark matter. When the extremely fast-moving particles are moving in particle accelerators there are forming so-called ghost particles. So could the origin of the ghost particle be the yet unknown particle?
Se also:
Big Bang
Dark energy
Dark matter
Muon G-2 anomaly Fermilab
The standard model of physics
https://thoughtsaboutsuperpositions.blogspot.com/
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