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Researchers are using nuclear reactors to find the ghost particles called neutrinos.



As you see from the Standard Model above this text there are three types of known neutrinos. electron neutrino, muon neutrino and tau neutrino. Normally when people are talking about ghost particles they mean neutrinos. Neutrino is one of the biggest mysteries in the universe. 

And the thing that makes those particles interesting is that they can travel through the entire planet without any kind of interaction. At this point, I must say that neutrinos are not the only ghost particles. There is some kind of quantum fields bubbles. That acts like some kind of particle. But mostly ghost particles mean neutrinos. 

There is introduced that the neutrinos would have the quantum field that pushes other quantum fields away from it. That kind of quantum field would push other materials out from neutrino. The idea is that because the energy level of a neutrino is so high energy that thing pushes other quantum fields away from the road of that particle. And that thing makes those ghost particles travel through the planets without interaction. 

The reason why neutrino can travel through the planet without touching anything is interesting. If the neutrinos would be easier to detect. They could use in quantum computers as qubits. Or they could use it as quantum yoyo which the superpositioned and entangled particle pairs could use to send a wave movement. 

And that wave movement can detect by using special antennas. Those quantum yoyos or quantum radars are not very easy to make. But they might be the systems of the future. 

Those quantum radars can scan layers from long distances. And they can see microscopic things in the caves. But the problem is how to make that system in practice. The neutrinos would be perfect tools for that kind of detector. But it's hard to make them interact. There are two ways to use neutrinos at the theoretical quantum radars. 

The first is to make the superposition of two neutrinos. And the second one is to stress captured neutrino with radiation. That makes neutrino send similar wave movement with neutrons when they are stressed with radiation. But the wavelength of neutrino radiation is much shorter. And there is also more difficult to capture that radiation by using traditional antennas. 


https://scitechdaily.com/nuclear-reactor-helps-scientists-catch-and-study-ghost-particles/


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


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

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