FASER or Foward Search Experiment is designed to collide and observe weakly interacting particles. Those collisions happen in LHC (Large Hadron Collider). And it should open yey to a world that is unknown to us. The neutrino collisions should open the secrets of dark matter, dark energy, and yet unknown particles like hypothetical dark photons.
So that system might make even more interesting findings than the Higgs boson. A dark photon or an antiphoton is a hypothetical particle. The reason why researchers believe that this particle exists is that all other particles have their anti-particle pair.
The dark photon would pull energy in it. That makes it at least hard to detect. And if that hypothetical particle exists, it would be the big step to finding gravitons and other hypothetical particles.
The weakly interacting particles are the thing that can open the secrets of dark matter and dark energy. In some theories, dark matter is a flat particle. If that 2D material or elementary particle exists and it can be proven that thing would be a sensation. Two ways can make things like quarks flat.
A) Energy level of the particle can be so low that the particle turns flat.
B) The spin of a particle can be so high that it pulls the particle to the flat form.
There is a model of three types of material.
1) Visible materials like quarks, electrons, and other particles.
2) "Grey material" like neutrinos and other weakly interacting material.
3) Dark matter. The matter that only known interaction is gravitation. There is a theory that dark matter is forming of particles called WIMP (Weakly Interacting Massive Particles).
Sometimes is introduced that neutrinos are strong or grey WIMP. And dark matter is the weak or black WIMP.
"The FASER collaboration has made its first observation of neutrinos produced at the Large Hadron Collider (LHC) during its measurement campaign, with statistical significance exceeding the threshold for a discovery in particle physics. The observation includes muon neutrinos and candidate events of electron neutrinos". (ScitechDaily.com/Exploring the Dark Matters of Physics: Large Hadron Collider Enters Uncharted Territory)
"Additionally, the collaboration presented results on searches for dark photons, which enabled the exclusion of regions motivated by dark matter. FASER aims to collect more data to allow more searches and neutrino measurements. The detection of neutrinos produced in proton collisions at the LHC can contribute to the study of high-energy neutrinos from astrophysical sources and test the universality of the interaction mechanism of different neutrino species". (ScitechDaily.com/Exploring the Dark Matters of Physics: Large Hadron Collider Enters Uncharted Territory)
There is a possibility that dark matter is so-called virtual material like extremely short-term skyrmions. And in some other models, the dark matter is the wave movement.
The Schwinger theory is that dark material can form when the Schwinger effect forms the particle-antiparticle pair. Because, the energy level of those crossing waves is so low those particle-antiparticle pairs will annihilate immediately.
That means dark energy can form in an annihilation reaction where those short-term particles or particle-antiparticle pairs impact each other and turn to energy. There is a possibility that high-power magnets can separate those particles and form stable dark matter. But that requires that those particles exist.
The thing that makes dark photons interesting is the thing that makes those photons invisible. The energy flow travels in them or travels passing them. And that means those particles' energy level is lower or the same as their environment.
If the electromagnetic radiation travels past those dark photons there is a possibility that this radiation closes the photon inside the radiation channel that looks like the airflow that travels over the aircraft wings. So that radiation will lock the dark photon inside it. And that denies the ability to detect that radiation. That comes out from that supermassive photon. So those dark photons could be a gate to the world of dark matter.
https://faser.web.cern.ch/index.php/
https://en.wikipedia.org/wiki/Magnetic_skyrmion
https://scitechdaily.com/exploring-the-dark-matters-of-physics-large-hadron-collider-enters-uncharted-territory/
https://en.wikipedia.org/wiki/Dark_photon
https://en.wikipedia.org/wiki/Neutrino
https://en.wikipedia.org/wiki/Skyrmion
https://en.wikipedia.org/wiki/Weakly_interacting_massive_particle
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