What is the alternative explanation for the Brookhaven (Fermilab) observations?

The image above portraits the g−2 storage-ring magnet. That system Located at Fermilab. Originally researchers created that system for the Brookhaven g−2 experiment. The geometry allows for a very uniform magnetic field to establish in the ring. (Wikipedia/Muon g-2)

So what causes the interesting anomaly in the Brookhaven (Fermilab)low-energetic particle accelerator? The answer could be also a very weak gravitational effect. That turns the trajectory of the particle in the Muon g-2 experiment. If the fifth force is not existing could that thing that causes too strong curving in the Brookhaven laboratory be the gravitational wave of another universe? 

The thing is that the "fifth force" is much much weaker than the gravity. It's harder to see than other natural interactions. And there is the possibility that it's not even existed. But there is also the possibility that the scale of the "fifth force" is extremely large. 

Maybe it's visible only in the interactions of galaxies. Or maybe we could see the effect of this mystery from outside the entire universe. There is the possibility that the fifth force is not seen inside the universe because its form is a monotonic hum. In that case, we cannot see the changes of that force. 

Or if the effect of the fifth force can measure only between extremely large entireties that means we cannot see that thing. The other interactions are covering the fifth force. 

So another explanation why the mysterious "fifth force" is hiding is this: because the force is stable there is a problem with how to measure it. The "fifth force", if it exists is a similar wave-particle duality with other forces. 

But let's go to business and try to find out why the Large Hadron Collider (LHC) of CERN has not seen the same things. Those are observed in the Brookhaven laboratory? The reason for that is simple. The LHC uses too much energy. And that means the weak interactions are not able to affect the trajectories of those particles. The Brookhaven laboratory uses much smaller energy loads than the LHC. And the weaker forces can affect the trajectories of the particles that are traveling in the accelerator of the Brookhaven laboratory. 

So if we are trying to compile why the Brookhaven accelerator is more suitable for observing weak natural interactions than the LHC we can use bullets as an example. The side wind would have more effect on the slow-flying bullet than the fast bullet. The reason for that is that the frontal pointing movement energy is higher in the fast-moving bullet. 

The wind effect of the slow-moving bullet is higher and the outcoming interaction like gravity wave is acting like the wind in the case of the bullet. At the first friction must slow the speed of the bullet so slow that the sidewind can push it out from the trajectory. 

The slow-moving low energetic particle is easier to push out from the trajectory than the fast-moving particle. The particle's speed in the LHC is near the speed of light. And the weak wave movement effect to so fast particles is harder to observe than the similar effect to the lower energetic and slower-moving particle. That's why Brookhaven laboratory sees anomalies that are not able to be seen by the LHC. 

()https://astronomy.com/news/2020/03/the-fifth-force-what-is-it

()https://www.quantamagazine.org/physicists-measure-the-magic-fine-structure-constant-20201202/#comments

()https://en.wikipedia.org/wiki/Brookhaven_National_Laboratory

()https://en.wikipedia.org/wiki/Fifth_force

()https://en.wikipedia.org/wiki/Fundamental_interaction

()https://en.wikipedia.org/wiki/Large_Hadron_Collider

()https://en.wikipedia.org/wiki/Muon_g-2

Image:()https://en.wikipedia.org/wiki/Muon_g-2

()https://visionsoftheaiandfuture.blogspot.com/