"The Majorana Demonstrator, a six-year experiment conducted by researchers from Indiana University and international collaborators, sought to answer significant questions about fundamental physics laws, particularly regarding neutrinos. The study aimed to observe whether neutrinos could be their own antiparticles and the occurrence of neutrinoless double-beta decay, which, although not conclusively observed, provided valuable insights into neutrino decay timescales, dark matter, quantum mechanics, and demonstrated that the research techniques used can be scaled up for future work in understanding the universe’s composition". (ScitechDaily.com/Hunting the Ghosts of the Universe: Unraveling the Neutrino Enigma)
There is the possibility that all elementary particles are the same particle with different energy levels.
There is the possibility that all elementary particles are the same particle with different energy levels. And that thing makes neutrinos very interesting. If the energy level determines the shape of the elementary particle. That thing could make a revolution in quantum communication.
In this model, the energy level determines the particle quark or gluon. And there is a possibility that the stressing electrons with powerful radiation that radiation or energy can turn electrons into any other elementary particle. And decreasing energy level causes the situation.
That gluon would turn to W or Z boson. Maybe the origin of W or Z boson determines is boson W or Z. If the origin of the W boson is in the proton, that produces the W boson. And neutron would create a Z boson. Or the opposite thinking neutron could make W and proton make the Z boson. Finally, the chain that begins from the Higgs boson could turn into a gluon and later into an electron means that all elementary particles can turn into another one.
And maybe neutrinos can answer that problem.
Neutrino is famous because it can travel through planets without touching anything. That means neutrino has a very good tunneling capacity. The tunneling effect of neutrino makes it very hard to detect.
And sometimes researchers call that particle a "grey photon". Sometimes is flashed a possibility that neutrinos can use in quantum computers as qubits. Another possible place where the neutrino can use is quantum radars.
In quantum radars, superpositioned quantum entanglement makes it possible for that system can scan layers even through walls. And Quantum radar can read data that travels in the computer's microchips. The quantum-entanglement-based antennas are suitable for military and civil purposes.
And they could scan our nervous system and take extremely sharp images of internal organs without surgical operations. Quantum entanglement can also make it possible to use that thing as a scalpel that can destroy tumors. But that kind of system requires the particles that it can superposition.
Neutrinos could be suitable for those missions. But it's hard to create synthetic neutrinos. In some visions, the aliens use neutrinos in long-range communication. That vision is very hard to prove.
The reason is that: if researchers want to find out do some neutrinos carry quantum information stored in their purpose they must capture the neutrinos. In that process where neutrino hits the water. That impact destroys the information that neutrino carries.
But theoretically, neutrinos could be extremely good communication tools. They can travel through walls. And that makes them good tools for long-range quantum communication. The problem is how to capture neutrino without destroying the information that it carries.
In some models, the neutrinos are very close to hypothetical WIMPs (Weakly Interacting massive particles". Those wimps were introduced as dark matter particles. The thing that could explain the neutrino's outstanding tunneling ability is that neutrinos are some features that keep them at a higher energy level than their environment. But that feature conducts energy into neutrinos.
The energy level of neutrinos is extremely stable. And that means neutrino itself will not send radiation. Or it sends monotonic radiation there are no changes in its energy level. That thing makes the particle hard to detect. And in some scenarios, the neutrino could be the particle. That connected with a quantum-size black hole. In that case, the quantum-size black hole would explain why neutrino is hard to detect.
In some more conventional theories, the neutrino is the particle. That connected with extremely dense quark or gluon. The "quantum neutron star" means the elementary particle. That pushed in extremely high density. That means the high-energy radiation can turn a quark in the atom's nucleus into a quantum-size object that acts in the same way as a neutron star, but that structure would be much smaller than a neutron star.
So could the neutrino be the high-energy version of some other elementary particle? Those kinds of visions can turn the neutrino even more interesting than nobody expected.
https://scitechdaily.com/hunting-the-ghosts-of-the-universe-unraveling-the-neutrino-enigma/
Comments
Post a Comment