Skip to main content

What makes neutrinos so interesting?


Neutrino is a so-called ghost particle. There is only a small interaction between neutrino and other particles and that's why neutrino can travel through the planets. In the nucleus of stars, particle-wave duality forms the neutrinos. And that thing makes them very interesting. If some researchers can create synthetic neutrinos and make them interact. 

The thing that makes the neutrinos interesting is that they are forming at an extremely high energy level. Sometimes is introduced that some neutrinos were tachyons that are fallen from their energy level. So when we are thinking that the fourth dimension is the certain energy level or the point of energy levels where the particle is disappearing. 

That thing means, that the nuclei of the stars are closer to the fourth dimension than other places in the universe. So there might be particles that are not existing in the other places in the universe. The reason for this theory is that hot stars are forming more neutrinos than cold stars. 

So neutrinos are forming between particles that are connected in nuclear fusion. The flashing quantum fields are forming those ghost particles. And in that place of billions of degrees celsius, the energy load keeps those particles stable. In hot stars, those flashes happen more often than in cold stars. 

That allows us to use them in quantum computers and quantum sensors. The thing that makes neutrino tunnel itself through the planets is one of the biggest things in the world. Sometimes is introduced that the neutrino has so strong quantum field or some kind of bipolar quantum field that pushes the atoms or their quantum fields away from its path. 

Could neutrino be the missing particle between photon and Higgs boson? The idea is that when the hypothetical tachyon falls from the fourth dimension to the third dimension it transforms into a photon. And then to Higgs boson or neutrino. We cannot see the tachyon itself. But we can see the photon. 


So if the chain of the energy loose reaction of a tachyon is like this: 

Tachyon>>Doppler field>>Photon>>?>>Higgs boson>>?. In the point of the question mark is the neutrino. The question is what would be the position of neutrino in this series? 

Ions can theoretically make the same thing. But then the opposite polar field will impact and slows them. Ions are acting a little bit like the neutrino. They can also tunnel themselves through the material. And when they will stop those things remove their energy from the material. If somebody can make the same thing to neutrino that will open a new page in the field of electromagnetic power systems, quantum computing, and weapon research. 

If we want to weaponize neutrinos, that thing requires that the system creates synthetic neutrinos. And then it must shoot them to target. A neutrino can travel through the strongest bunkers and if the system can stop them in the right place neutrinos send their energy as the wave movement. 

Synthetic neutrinos are heavier than photons. If the rocket engine can use neutrinos as the propellant they can give more punch than photons. So neutrino rocket can be one of the interstellar rocket concepts that can send to other solar systems in the distant future. 

The neutrino is hoped also to give answers for existing of the hypothetical particles like tachyon and graviton. The existence of a tachyon is impossible to see because its energy level is too high that it can interact. So tachyons are in the fourth dimension. But sometimes that hypothetical tachyon loses its energy and falls to the third dimension. During that process, it transforms into the photon and then to the Higgs boson or neutrino. 


https://www.cnet.com/science/space/features/what-is-a-neutrino-the-missing-key-to-modern-physics-could-be-a-ghost-particle/


See also:

Fourth dimension

Graviton

Higgs boson

Neutrino

Tachyon


https://artificialintelligenceandindividuals.blogspot.com/

Comments

Popular posts from this blog

The hydrogen-burning supernovas are interesting models.

"Researchers discovered a significant magnesium anomaly in a meteorite’s dust particle, challenging current astrophysical models and suggesting new insights into hydrogen-burning supernovas. (Artist’s concept.)Credit: SciTechDaily.com" (ScitechDaily, Rare Dust Particle From Ancient Extraterrestrial Meteorite Challenges Astrophysical Models) If the star is too heavy when its fusion reaction starts, it can detonate just at that moment, when its fusion starts. If the collapsing nebula is heavy enough, it can form a black hole straight from the nebula. But if the nebula's gravity is too heavy to  form  the blue giant or too  small  it can collapse  straight  into a black hole . If  the forming star is a little bit larger than the blue supergiants. It can explode immediately when the fusion starts.    The theory of hydrogen-burning supernovas consists  model  of the giant stars that explode immediately after their fusion starts. When the...

The ancient galaxy mirrors the Milky Way.

"This image shows the galaxy REBELS-25 as seen by the Atacama Large Millimeter/submillimeter Array (ALMA), overlaid on an infrared image of other stars and galaxies. The infrared image was taken by ESO’s Visible and Infrared Survey Telescope for Astronomy (VISTA). In a recent study, researchers found evidence that REBELS-25 is a strongly rotating disc galaxy existing only 700 million years after the Big Bang. This makes it the most distant and earliest known Milky Way-like galaxy found to date. Credit: ALMA (ESO/NAOJ/NRAO)/L. Rowland et al./ESO/J. Dunlop et al. Ack.: CASU, CALET" (ScitechDaily, Astronomers Baffled by Ancient Galaxy That Mirrors Modern Milky Way) Researchers found the youngest Milky Way-type galaxy. The distance to the galaxy is enormous. And the light that comes from that galaxy named REBELS-25 comes from the Universe that is only 700 million years old. The distance to that galaxy is enormous about 236 billion light years. And that means it's a very dista...

Transcendence, or the ability to transcendent thinking may grow in teen's brains.

   "New research has discovered that transcendent thinking, which involves analyzing the broader implications of situations, can foster brain growth in adolescents. This form of thinking enhances brain network coordination, impacting developmental milestones and future life satisfaction. The study emphasizes the need for education that encourages deep, reflective thought, underscoring the critical role of adolescents in their own brain development". (ScitechDaily, Scientists Discover That “Transcendent” Thinking May Grow Teens’ Brains) "Scientists at  USC Rossier School of Education’s Center for Affective Neuroscience, Development, Learning and Education (CANDLE) have discovered that adolescents who grapple with the bigger meaning of social situations experience greater brain growth, which predicts stronger identity development and life satisfaction years later". (ScitechDaily, Scientists Discover That “Transcendent” Thinking May Grow Teens’ Brains) The transcendenc...