Plasma around a black hole sends powerful radiation. That radiation causes effects, and the black hole also pushes objects from around it. It’s not only gravitation. That pulls objects to the black hole. Also, things like electrons and protons that impact objects have an effect on objects. When gravity alone pulls objects, it is not the same. As the gravitation. And electromagnetic interactions together pull objects like electrons.
Maybe electromagnetic interaction itself cannot slow a black hole. But the electromagnetic interaction can slow plasma whirl. Around a black hole. Or the electromagnetic interaction can pull plasma away from the black hole. That decreases the energy that travels in that object. When a small object like an electron falls into a black hole. It’s possible. That just before it hits the event horizon. The electron transmits energy.
Out of the black hole. The top point of the electron is on a lower energy level. Than the bottom of it. That causes a situation. Where energy travels to the top of the electron. That forms a small high-energy object at its axle. And that pushes the electron forward. Normally, those things mean almost nothing. But in a black hole’s extremely dense conditions, even a small thing. Means very much.
The interaction between magnetic fields and black holes is one of the least researched phenomena in the universe. The interaction means that the magnetic field can slow down. The rotation of a black hole. The rotation of a black hole slows when the magnetic field accelerates or slows. Plasma whirls around the black hole. When that whirl accelerates. It converts kinetic energy into it. When the speed of that whirl slows, it releases its kinetic energy.
"A still image from a computer simulation of a black hole’s formation and evolution. Credit: Ore Gottleib/Simons Foundation" (ScitechDaily, Scientists Finally Explain Mysterious “Impossible” Merger of Two Massive Black Holes)
When plasma starts to whirl near a black hole’s event horizon, its energy level rises. And that means they bring more energy to the black hole. The mass of those particles is far higher than outside the whirl. And when the magnetic field pulls those particles backward. That effect also affects the black hole’s gravitational field. It slows the black hole’s rotation speed.
A black hole takes its energy from the whirl. Around it. The black hole binds energy from that whirl. Into it. And transforms it into kinetic energy. When the speed of the whirl slows, it transfers less energy to the black hole. The black hole is massive. But it's still in interaction with its environment. The heavy mass can also slow down. The speed of the black hole.
"These 3D renderings of a direct-horizon collapsar with an initially weak magnetic field illustrate the system’s evolution. Early in the collapse, accretion disk winds unbind much of the stellar envelope, reducing the mass available for accretion onto the black hole. Eventually, a one-sided jet emerges from the region just outside the black hole, spinning down the black hole and expelling the remaining stellar material. Credit: Ore Gottleib/Simons Foundation" (ScitechDaily, Scientists Finally Explain Mysterious “Impossible” Merger of Two Massive Black Holes)
“Inferred orbits of 6 stars around the supermassive black hole Sagittarius A* at the Milky Way's center”. (Wikipedia, Sagittarius A* cluster)
When a black hole slows, it must realease its energy. And in that moment, it sends gamma or gravitational waves. Many times. Black holes are mentioned as the extreme gravitational objects. In those cases, the interactions are simplified. Black hole’s halo. And its relativistic jets are the highest-energy phenomena. In the universe. That plasma-halo. Also transmits energy out from the black hole. This means that. The black holes are, anyway. A little bit like other stars.
In modern research, black holes are not as devastating as researchers believed. Research about the Sagittarius A*, (Sgr* A) the supermassive black hole in the center of the milky way gives an information that there are also objects in stable trajectories around the Sgr*A. Many of those objects are very hot stars. That means those stars can probably push material from around them. That causes the effect. That's the matter. That which falls into the black hole cannot affect the star. When an object falls. To a black hole, gravity pulls fields that make objects travel with it. But also things. Like gas and other particles push those objects into the black hole.
The plasma whirls around the black hole, acting like a generator. That forms an extremely powerful magnetic field. And when a black hole pushes and pulls matter. All its wave interactions and plasma interactions affect objects around it. Things like gamma-ray and X-ray radiation are high-energy short-wave radiation that tunnels through the plasma. Also, things like neutrinos can tunnel through those fields and other objects.
https://www.aanda.org/articles/aa/abs/2024/10/aa50571-24/aa50571-24.html
https://scitechdaily.com/scientists-finally-explain-mysterious-impossible-merger-of-two-massive-black-holes/
https://en.wikipedia.org/wiki/Sagittarius_A*
https://en.wikipedia.org/wiki/Sagittarius_A*_cluster
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