“The final (world average) result for the muon's anomalous magnetic moment after a series of experiments at major laboratories. Credit: Physics magazine, American Physical Society” (Phys.org, Final experimental result for the muon still challenges theorists)
The final experiment of the muon experiment. Still challenges physics. The muon g-2 experiment. Still causes discussions. Those anomalies in the Muon trajectory exist. Those anomalies fit into the predicted limit. But they simultaneously continue. And that causes work for theorists. The Muon is a high-energy. And a smaller version of an electron. The anomaly is curvature in the muon trajectory means. That something. That researchers cannot detect. affect the muon itself. Or the magnetic field that controls muons in particle accelerators. This means that there should be something that we cannot predict.
There is a possibility that:
1)There is some kind of unknown force that affects muons' trajectory. Maybe that thing is the mythic fifth force.
2) It’s possible that the particle accelerator that is the low-energy synchrotron creates some kind of mass effect in the middle of it. When a particle runs in the low-energy synchrotron, or ring-shaped accelerator, that thing packs energy in the middle of the ring. That energy can impact the particle. That is in the middle of the synchrotron, and that can form a similar form as some kind of neutron star form.
The image above. Introduces how plasma field injects energy into black holes. The ring-shaped structures can always inject energy into particles or other objects. In the same way. We can imagine that the synchrotron is in the place of that dark belt. And it transfers energy into an object. That is in the middle of the synchrotron.
But the energy level in those other reactions is lower. And the energy object, or mass effect, in the middle of the ring-shaped synchrotron could behave in a way that this thing supports the muon g-2 anomaly model. The object in the field doesn’t deliver its energy all the time. The energy level in the particle must rise so high. That. It's higher than in the environment. When the energy level in a particle turns high enough. It can deliver its energy from the equator. Normally, it will deliver energy only from the spin axle.
“The g − 2 storage-ring magnet at Fermilab, which was originally designed for the Brookhaven g − 2 experiment. The geometry allows for a very uniform magnetic field to be established in the ring.” (Wikipedia, Muon g-2)
This means the energy that this particle delivers must break the magnetic fields in the accelerator. And that requires that the particle or object can store enough energy in it. In that model, the object delivers its energy from the equator. That which affects the muons' route in pulses. And those pulses can explain the curvature in the muon’s trajectory.
The particle in the middle of the synchrotron can have more mass when it gets symmetrical energy loads. And then that particle, whose energy level rises. Can change the muon trajectory. When energy impulses hit that particle, it sends it from its poles. That effect is similar to relativistic jets. But it's on a much lower energy level.. That can cause an anomaly in the magnetic field.
3) The muon can collide with dark matter. Those things are one of the things. That causes grey hair for researchers.
The remarkable thing is that the muon g-2 anomaly happens in the low-energy synchrotrons. This means that it's possible that the accelerator form. Some kind of mass center in the middle of it. These kinds of mass centers can be seen. Only in the low-energy accelerators. In high-energy systems, the kinetic energy is in those particles. And their speed will be too high, and those mass centers will not be detected. Or, they cannot affect those particles in the way that those sensors can detect them.
https://phys.org/news/2025-11-experimental-result-muon-theorists.html
https://en.wikipedia.org/wiki/Muon_g-2
