"Researchers have unveiled that the mysterious ‘little red dots’ captured by NASA’s Webb Telescope are likely young black holes, potentially reshaping our understanding of early cosmic phenomena and challenging existing cosmological theories. (Artist’s concept.) Credit: SciTechDaily.com" (ScitechDaily, Webb’s Stunning Discovery: Could These Mysterious “Little Red Dots” Be the Universe’s Earliest Black Holes?)
Little red dots in the JWST images can be the first black holes. In the history of the universe. The black holes seem red because their gravity field stretches light. When a black hole pulls particles and radiation inside it that thing forms the effect called synchrotron radiation. Normally synchrotron radiation forms when a particle travels in an electromagnetic field in a circular trajectory.
When a particle travels in the electromagnetic field it collects energy in it. The curving movement causes a situation in which there is an asymmetry in energy levels at the sides of the particle. And the particle sends radiation that it packs to the outer edge of the curve.
But there is another thing that can form similar radiation as synchrotron radiation. When two quantum fields are moving at different speeds they form whirls between them. Those whirls can be behind the primordial black holes. But those whirls can collect energy to the quantum dots. That means that the quantum friction between two fields that travel with different speeds or different directions can form similar synchrotron radiation as particles that travel in synchrotron.
The radiation from the nearby black hole buffers astronomers. A nearby black hole sends mysterious X-ray bursts that might originate in the magnetic field. That means the black hole sends so-called synchrotron radiation on Earth sychrotron radiation forms in the electromagnetic field interaction in synchrotrons. That means the radiation is forming in field interaction.
That thing gives interesting possibilities for things like gravitational radiation or gravity fields. When we think about the energy field interaction that forms the synchrotron radiation, that effect should be possible in the other energy fields.
So gamma rays and other kinds of things can form similar radiation as synchrotron radiation. And that brings one of the most interesting things to the front of our eyes. If gravitational waves form outside the event horizon that means the origin of the gravitational waves can be similar to synchrotron radiation.
That means whirling fields that move with different speed forms that radiation. And because gravitation has waveform interaction that means gravity can also form in similar reactions as X- and gamma rays. But interacting fields are different. Their wavelength and energy levels are different if we think that the "friction" between fields forms the gravitational waves.
But when we think of cases where black holes pull stars inside them. Those superenergy reactions form neutrinos. Neutrinos are elementary particles that have a very weak interaction. Neutrinos can travel through even planets without interacting with other particles. That means. Maybe neutrino can push other particles and fields away from its route. And that can mean that neutrino could have so fast spin, that it just drills itself through other particles. But that is only speculation.
It's possible that if time is some kind of wave movement the black holes that stretch space and time can form a synchrotron radiation-like phenomenon. Proving that. Could be the greatest in the history of physics.
When a neutrino takes an energy load in it it releases that energy if the energy level around it turns lower. So, the neutrino sends neutrino radiation just like the neutron sends neutron radiation.
When it takes an extra energy dose. Neutron radiation forms when the neutron takes an energy dose and then releases that energy. In the same way, quarks, neutrinos, gluons, and other particles should send radiation whose wavelength is the same as their size.
All parts of the material behave in the same way. When they get energy stress they store energy, until the energy level in the particle turns higher than their environment. That means. Also, things like superstrings can send energy waves through the universe. Sometimes dark energy is described as energy waves that originate in the gluons. Gluons can send radiation just like neutrinos and neutrons.
If dark energy is real and its source is in gluons that means that the strong nuclear force is the same as dark energy. And it's possible. That free gluons make the dark matter. That is one hypothesis about the mysterious energy and gravitation. The source of the dark energy can also be in the superstrings. Superstrings can also act like particles and they can store and release energy as particles. That is one of the things that can be a source of dark energy.
https://scitechdaily.com/mysterious-pulsing-x-rays-from-a-nearby-black-hole-baffle-astronomers/
https://scitechdaily.com/revolutionary-telescope-captures-sharpest-view-ever-of-a-supermassive-black-hole-in-action/
https://scitechdaily.com/this-is-what-it-looks-like-when-a-black-hole-snacks-on-an-unlucky-star/
https://scitechdaily.com/webbs-stunning-discovery-could-these-mysterious-little-red-dots-be-the-universes-earliest-black-holes/
https://en.wikipedia.org/wiki/Neutrino
https://en.wikipedia.org/wiki/Synchrotron_radiation
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