Black holes can form only when supernovas are forming falling WARP-bubble.

Forming of a black hole. 

When a supernova explodes it forms a bubble. The shockwave of the supernova has so high energy level and density are so high, that this shockwave can push gravitational waves away inside it. The fall of the bubble is the reason why black holes are forming. 

And the thing that makes a gravitational effect around a black hole could be the gravitational tornado that pulls wave movement and material out from the event horizon. When that gravitational or quantum tornado pulls the material to the poles of the singularity it causes electromagnetic low pressure. Then the outside field tries to fill that effect and takes all other particles with it. 

The birth of black holes is an extreme situation. The supernova explosion pushes all other quantum fields away from the point where the star that ran out of fuel was. The black hole forms the WARP bubble. The shockwave that traveled across the universe has such a high density and energy level that it can interact with gravitational waves.

The power of a supernova explosion is so high that it also pushes gravitational fields away from the point where that explosion happens. When we think like that, we must realize that the falling material and wave movement are forming the black hole. The black hole forms when the singularity turns all radiation that touches it into a quantum tornado. That quantum tornado unites all electromagnetic fields, including gravitation.

And that quantum tornado pushes electromagnetic fields out from the black hole through its poles. If that model is true, all black holes have wormholes connected to them. And the drop in black hole mass can be explained. That quantum tornado that we can call a "gravitational tornado" takes material from the black hole.

But this model requires that those electromagnetic fields be pushed away. And we can say that gravitation is one version of EM radiation.

The new observations also show that the cocoons of supernovae also form gravitational waves, or maybe those cocoons do not form gravitational waves. Maybe they just push them or give them more energy. The fact that those jets can interact with gravitation is what causes the model to suggest that maybe the supernova can also whip the gravitational field away.

When that WARP bubble, or bubble of nothingness, falls, the energy impacts the middle of that bubble. That pushes the material and energy in that bubble into a form called a singularity. Falling energy forms material. Where all quantum fields are in their entirety. When that bubble falls, it pumps energy into that singularity.

This thing makes the sign spin at a very high speed. The spin of a singularity makes gravitational tornadoes on its poles. Those gravitational tornadoes are pushing material away from the black hole. And the gravitational waves are forming in the waves of that tornado. We can see that a gravitational tornado is in the jet of a black hole.

But when we think that energy travels to lower energy levels, we can ask which way gravitation travels in the system of two black holes.

Gravitation is one version of energy and wave movement. If we think that the gravitational effect is like quantum entanglement between two particles. We can say that energy travels from the higher-energy particle in that system to the lower-energy particle. That thing is called the system's attempt to reach energy balance. The length of that quantum entanglement is the radius of the gravitational effect.

If that thing that energy travels in lower energy particle happens in quantum entanglement. The lower energy particle pulls the higher energy particle into it because quantum entanglement turns shorter when it releases its energy. The ability to maintain quantum entanglement determines the gravitational radius between higher and lower energy gravitons.

When a lower-energy particle transfers energy into it, it decreases energy in quantum entanglements. That will pull higher-energy particles toward the lower-energy particles. And gravitation is one version of energy. So we should say that gravitation travels from more massive to less massive participants in the system. That means the gravitational interaction is opposite to all other forces. When gravitation travels to a less massive object, that thing makes the larger object send energy to the less massive object.

When energy transfers to a lower-energy object, that means the quantum entanglement loses part of its energy. That means that the quantum energy pulls the objects closer to each other. In the case of quantum gravitation, other radiation types cover the gravitational quantum entanglement. The graviton is such a small particle that researchers cannot see it. The gravitational waves are the reason for the large number of gravitons. Gravitation is the force that affects entireties. The gravitons send so short-wave radiation that only a large number of them can form a visible long-range effect that pulls objects together.