Hawking was right. Black holes’ event horizons cannot withdraw.
“Computer simulation of the black hole binary system GW150914 prior to merging. Credit: SXS” (Universe Today)
It’s possible that all black holes spin.
Hawking was right about black holes. Their event horizon cannot withdraw. When two black holes collide, their event horizons’ size is as big as both of those black holes before they collide. When black holes collide, they send a gravitational wave. And that wave is an energy impulse that forms when those black holes collide, meaning a small portion of their mass is converted into energy that is released as gravitational waves. But why does the size of those black holes' event horizon not decrease?
The reason for that is in the nature of the spacetime and the universe. The thing that keeps a black hole in its form is the material and energy that forms a whirl around it. As the universe expands, the quantum fields and material pressure against the black hole weaken. That means that. The energy that keeps the black hole in its form turns weaker. When a black hole sends gravitational waves, it sends its event horizon’s “shell” away from it. The idea is that decreasing the energy level of the whirl around the black hole sucks energy out from the event horizon.
In that model, the gravitational wave forms. When the whirl around the black hole jumps out of it. When the energy level in the whirl around the black hole decreases, that whirl jumps out from the black hole. The Schwarzschild radius is the singularity’s distance to the point at which the escaping velocity reaches the speed of light. That distance depends on the mass of the singularity. The Schwarzschild radius doesn’t depend on the whirl that surrounds the black hole. Actually, the Schwarzschild radius depends on the black hole’s mass and energy relation with its environment.
The idea is that when we are in the middle of the quantum system. And we face a global change. That affects all particles. When a black hole loses its mass, the universe or space around it loses its energy in the same relation. That means the relation with the black hole and its environment is the same. We cannot see global changes in the system if we are in it.
All mass in a black hole is in the structure called a singularity, where material, energy, and time are connected together. In this model, gravity waves form in the black hole’s gravity field. In that process, the black hole loses a photon.
The interaction between the black hole and its environment is complicated. Materia is one energy form. It’s like a pack of energy. You can imagine what energy level is stored in a singularity, where an entire star, whose mass is many suns, is pressed into a size that is smaller than an atom. That is a lot of energy packed in a very compact space. Otcoming energy keeps that structure in its form. And without that energy that comes from outside, the energy stored in that structure is released. So, the mass is relative to its environment. When a black hole binds energy from its environment, its own energy level rises. That process happens because a black hole spins. Without that spin, the black hole, or its singularity, cannot bind energy that travels against it.
Above: A Spiral galaxy is a whirl around a supermassive black hole.(Wikipedia)
The singularity must bind more energy than travels into it because its energy level must turn lower than the energy that comes from the environment. The sigularity stores energy. If the energy level that the singularity can release turns higher. Than its environment. That thing starts to evaporate. So the question is not about how much energy is stored in the singularity. The question is about. How much energy can it release? When singularity releases its energy, it must have a higher energy level than the whirl it brings into it. Energy and material continue their spiral-shaped trajectory behind the event horizon. So the whirl around the event horizon continues behind the event horizon, and that spiral structure turns tighter and tighter. Without that whirl, the black hole will detonate.
That spinning movement forms the whirl around it. And we see those whirls. Around supermassive black holes. As a spiral galaxy. This means that it's possible that the only existing black holes are spinning black holes. This spinning movement forms an energy transition in the singularity. Without that spin, the black hole would release energy. And that causes detonation. This means gravity forms when spinning particles bind energy, or quantum fields into them. That energy transports particles to those gravity centers.
The mass is also relative to its environment and the gravitational field. Energy levels in energy fields are relative. To other energy fields, energy levels. Even if a black hole loses its mass, its environment loses its energy. And that means the black hole’s mass compared to its environment is stable.
When we say that black holes oscillate, we mean that black hole sends gravitational waves. That doesn’t mean that the event horizon moves backward. The interaction means that the environment sucks those waves away from the event horizon. That means the point where the event horizon was before the gravity waves stays stable.
The event horizon is the locked energy that surrounds. Something inside that structure. The distance of the event horizon from the core of the black hole is the Schwarzschild radius. Black holes spin, and that spin binds energy from around that thing. A black hole binds energy from its environment. And transforms it into kinetic energy. This process is one of the forms of gravity. The whirl, or the transition disk around the black hole, keeps that structure in its form. The whirl pushes energy to the black hole. Without that, the black hole detonates. When the universe expands, energy in that whirl turns lower. And that allows the black hole to send a gravitational wave.
And then another layer in the event horizon takes the place of the shell that was left out of the event horizon. The idea in that model is that. The structure in the event horizon forms layers, which means the gravitational structure in the event horizon. Looks like an onion. The Schwarzschild radius is the distance to the point where the escape velocity reaches the speed of light from the singularity that exists in the center of the event horizon. Because the Schwarzschild radius is static until the singularity starts to lose its mass, the gravitational wave doesn’t decrease the black hole’s mass. The time that the whirl is separated from the event horizon is so short that this interaction has no time to reach the black hole’s core. But if that whirl is gone and the black hole cannot get energy. This causes the black hole to evaporate. And if a black hole is in a cosmic void, we would see that event as a detonation.
https://www.britannica.com/topic/event-horizon-black-hole
https://as.cornell.edu/news/hawkings-black-hole-theorem-observationally-confirmed
https://www.livescience.com/physics-mathematics/quantum-physics/stephen-hawking-s-black-hole-radiation-paradox-could-finally-be-solved-if-black-holes-aren-t-what-they-seem
https://news.mit.edu/2021/hawkings-black-hole-theorem-confirm-0701
https://www.spacedaily.com/reports/Black_hole_merger_provides_strongest_evidence_yet_for_Hawking_area_law_999.html
https://www.universetoday.com/articles/black-hole-merger-provides-clearest-evidence-yet-that-einstein-hawking-and-kerr-were-right
https://en.wikipedia.org/wiki/Hawking_radiation
https://en.wikipedia.org/wiki/Schwarzschild_radius
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