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The neutrino fog can disturb dark matter observations.


"The race to find dark matter could grow more complex with high-energy neutrino interference." (Big Think, Signs of “neutrino fog” emerge, complicating searches for dark matter)

"Scientists have long hypothesized dark matter as an invisible force explaining galaxy rotations, yet direct detection remains elusive. Now, highly sensitive detectors are picking up hints of high-energy solar neutrinos — known as the “neutrino fog” — which could overwhelm potential dark matter signals. This new interference complicates efforts to detect dark matter particles, though alternative models beyond WIMPs may still provide viable detection paths."(Big Think, Signs of “neutrino fog” emerge, complicating searches for dark matter)

Neutrino fog means high-energy neutrinos that get their energy from other energy sources. Neutrino is one of the elementary particles, and it can travel through the entire planet without impacting anything. Sun and other stars create neutrinos in fusion reactions. The neutrino interacts with its environment as all other particles. 

Neutrino takes energy into its quantum field like all other particles. And when the environment turns into a lower energy level neutrinos send their extra energy as energy impulses. That radiation is the neutrino radiation. The birth process of that radiation is similar to neutron radiation in a neutron bomb. The idea is that the particle sends its extra energy as radiation, as well as, other particles. 

The difference between elementary and other particles like baryons protons and neutrons is that the elementary particle is "harder" and there is not so much space where the energy can go. Things like Higgs boson send radiation whose wavelength is the same as their size. The lifetime of those particles is very short and that radiation can be covered by radiation that other particles send. 


The neutrino fog can be used to create a neutrino laser. That system is extremely hard to create. 


Because neutrinos are hard to trap. However, if researchers can make the neutrino fog. And trap neutrinos in the tube. They can create synthetic neutrino beams that can be the most revolutionary thing in history. But near black holes, neutrinos orbit the event horizon. And there the material disk and radiation can interact with those neutrinos. And they can send that radiation. 

The thing is that neutrinos themselves and neutrino radiation can cover the interaction between still hypothetical weakly interacting massive particles, WIMP, and its environment. The only known interaction between WIMP and other particles is gravity. That forms an idea that maybe the WIMP is the stable quasiparticle. That means WIMP can be the hole or low energy point in the quantum field. 

WIMP could have other types of interactions but those interactions are so weak, that we cannot see those interactions. In some models, the WIMP is so fast fast-spinning object. That it creates a quantum bubble around it. The WIMP can be a string-shaped structure. The fast spin makes the electromagnetic vacuum around the spin axle. And that stretches the WIMP into the wire-shaped thing. That means the WIMP can send energy waves whose wavelength is so short and the altitude or power is so low that we cannot see them. 

The thing is that we cannot see static energy fields. We can only see the changes in the field. That means if the wave movement's wavelength is very small that means the object sends energy impulses very often, and we cannot see that energy impulse. When we think about the decay or destruction of the Higgs boson the Higgs boson sends its energy as all other particles. It sends a series of energy impulses. But it sends them in a so short time, that obeservers see them as one energy impulse. 


https://bigthink.com/hard-science/signs-of-neutrino-fog-emerge-complicating-the-search-for-dark-matter/


https://en.wikipedia.org/wiki/Neutrino


https://en.wikipedia.org/wiki/Weakly_interacting_massive_particle

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