Maybe the intermediate-mass black hole was only a cluster of stellar-mass black holes.
The intermediate-mass black hole in Omega Centauri is only the stellar-mass black hole cluster. That thing means that the intermediate-mass black hole waits for its finder. The intermediate-mass black holes might be far rarer than nobody imagines.
When the black hole collides with another black hole it raises its mass. That means the intermediate-mass black hole can be the intermediate stage for the black hole.
If an intermediate-mass black hole exists its event horizon area versus volume is far smaller than in a stellar-mass black hole. That means intermediate-mass black hole vaporization is slower than stellar-mass black hole. That thing causes a situation in the intermediate-mass black hole that raises its mass faster than the stellar-mass black hole.
The intermediate-mass black hole can also pull far more material inside it than a stellar-mass black hole. The stellar-mass back holes can form intermediate-mass black holes when they collide. Or that thing can form when some very massive stars collide.
But the fact is that: the intermediate-mass black hole can require very special conditions like cases where the massive- or top-mass stellar black hole arrives in the solar system and pulls the star and its planets inside it very fast.
But the thing is that our knowledge about black holes rises all the time. In some models, the back hole follows the structure of the Mandelbrot fractal set. That means its gravity and other energy fields stretch around its spin axle. That thing creates a nose for the black hole. And that nose can explain the black hole relativistic jet.
Mandelbrot fractal and black holes.
The Mandelbrot fractal or Mandelbrot set offers the possibility to simulate structures and material and energy flows in the black hole. When we think about things like black holes and their models as the whirls that they pull inside their event horizons we sometimes forget that black holes are far more than some acceleration disks and event horizons. Their effect on their environment is far larger than people normally think.
If the Mandelbrot fractal can be used to model the black hole interactions.
That can explain some parts of the dark matter and dark energy. As you see the black hole would be the main whirl and it forms multiple sub-whirls around the event horizon and relativistic jets.
Maybe the friction between those whirls and the main structure makes it possible for those whirls.
Those whirls can transport energy out from the black hole.
Whirls around back holes and their relativistic jets can form so-called parasite black holes around them.
If there is a whirl in the gravity field. That can form a hole in the event horizon.
Maybe Hawking radiation exists but for escaping from the black hole that radiation requires an extremely high energy level. So when hypothetical Hawking radiation comes out from the black hole. It impacts the event horizon and stretches into another radiation type like gravitational waves.
And maybe those strange whirls can explain things like dark energy. Maybe those whirls just change the wavelength of some other wave movements or radiation types and transform things like gravity waves into some other wave movement.
It explains why we cannot detect Hawking radiation.
That thing can be the thing that helps to form the black hole and its interaction with its environment.
Spiral galaxies are the material disks around supermassive black holes. That tells how large the area of the interaction between black holes and their environment is.
https://www.livescience.com/space/missing-link-black-hole-found-not-so-fast-new-study-says
https://en.wikipedia.org/wiki/Fractal
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