Researching the GRB (Gamma-Ray Bursts) is not very easy. The GRB is the effect that has the highest energy level in the universe. Nobody knows what form those most high-energy radiation impulses. Sometimes claimed, that impacting black holes are forming those things.
Confirmation of those things requires that researchers can compile gravitational waves with GRBs. In some very popular theories, a fast-collapsing black hole sends the GRBs. The fact is that there might be multiple reasons for gamma-ray bursts.
There are three types of gamma-ray bursts
1) Short gamma-ray bursts
2) Long gamma-ray bursts
3) Ultra-long gamma-ray bursts.
And there is a possibility that those GRB types have different origins. And there is also the possibility that different effects can form similar-looking radiation effects.
Gamma rays are the most high-energy radiation in the universe. That makes it very hard to detect. And the problem for researchers in GRBs:s is that they are unique. They are not repeating. So when the sensor catches that radiation burst it's over. The new research claims that GRB forms in very hot young stars.
Maybe the reason for that is the beginning of nuclear reactions. But there is a possibility that things like black hole gamma- or X-ray beams hit just born a blue giant. And that thing can form those very powerful radiation bursts.
When we are thinking about this model, we must realize one thing. The young super-hot stars or blue giants are involving mainly hydrogen. When a gamma-ray beam hits that star it rises the radiation level of that star.
There is the possibility that in a short moment, the hot young star gets an electron core when the radiation beam from the star's nucleus pushes electrons to the same side as protons. At that moment star has multiple electron cores that are forming an onion-looking structure. That remains only a short moment.
That forms the energy impact away from the star. And that energy impact forms the warp bubble.
The rising radiation level could push other quantum fields away and form the short-term WARP bubble around that star. So in a short moment. Particles that leave from that star travel faster than they should. And when that warp bubble collapses the particle sends radiation when its speed decreases.
In some other theories things, like crossing gamma-ray beams from black holes can form GRBs. The GRB is a fascinating mystery. In less than a second something sends an extremely high-energy radiation beam to the universe.
Image 2)
The Fermi bubbles at the center of the Milky Way are confirmed to be impact radiation.
When radiation beams leave from Sagit A they are also taking particles and ions with them. They are also forming extremely high-energy plasma that expands like all other gas. That high-energy material forms two impact areas. And in those impact waves is forming gamma- or X-rays. Image 3 shows the impact areas that are forming the Fermi bubbles.
When particles leave from black holes' transition areas, they form wind where particles travel 1000 kilometers per second. "These winds travel outwards and interact with surrounding “halo gas,” causing a “reverse shock” that creates a characteristic temperature peak. The Fermi bubbles correspond to the volume on the inside of this reverse shock front". ScitechDaily.com/“Reverse Shock” – Mysterious Gamma-Ray Emitting Bubbles Around the Center of Our Galaxy Explained)
Image 3:
There are two radiation bubbles at both poles of Sagit A the supermassive black hole in the center of our galaxy. Those gamma-ray bubbles look a little bit like acetylene flames. The thing that forms those bubbles is impact radiation. The structure that forms around the radiation beam looks a little bit like a candle.
Sagittarius A is a supermassive black hole that sends radiation beams to space from both of its poles. That radiation is powerful X-and gamma-rays. When those radiation beams hit atoms and ions it pumps energy to them. And then those particles are sending that extra radiation away from them. That effect forms two fermi bubbles on both poles of that black hole.
In those bubbles, part of the radiation left from atoms travels backward. And impacts with radiation that comes from the radiation beams of Sagit A. In that case, the radiation forms a standing wave movement where the power of radiation increases.
https://scitechdaily.com/not-black-holes-astronomers-may-need-to-rethink-how-gamma-ray-bursts-are-formed/
https://en.wikipedia.org/wiki/Gamma-ray_burst
https://scitechdaily.com/reverse-shock-mysterious-gamma-ray-emitting-bubbles-around-the-center-of-our-galaxy-explained/
https://shorttextsofoldscholars.blogspot.com/
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