Our knowledge of black holes is expanding.
Our understanding of black holes is continually expanding. Due to new observation models and fundamental mathematical and computational tools, such as quantum computers and AI, we can develop new models of the most fascinating phenomena in the universe. In the past, we thought that black holes were only destroyers. When information fell into a black hole. That means the information is gone forever. But today we think differently. The key element in quantum mechanics is that information cannot just vanish. Information can only change its form. A black hole rolls information into it. In the yarn ball model, a black hole rolls information into its event horizon like the strings or wires. Those wires store information that the black hole releases as wave movement.
When we look at the black hole’s event horizon, we would see that thing waving. When those waves move up and down, they send waves to space. When the wave pushes the quantum field around the event horizon and falls back, it leaves a small quantum vacuum between the event horizon. And the quantum field around it. That pulls energy or information out from the black hole. When a black hole's event horizon separates from the whirl around it, it allows it to send a wave burst. The black hole is an interaction. If the outside whirl that includes quantum fields and material is removed, the black hole will be destroyed.
The black hole’s evaporation causes a similar effect to what ice makes when we transport it into the room. When a black hole evaporates, energy field. That comes from outside, try to fill that space. So what if black hole’s evaporation ends? What if a black hole sometimes reaches energy stability with space around it? That can cause a situation where energy or a quantum field don’tt move to the black hole. Or out of it. That thing can turn a black hole completely invisible. And that causes a wild theory that maybe dark matter could be black holes that almost reach energy stability with their environment.
Black holes are like gravitational solitons. They are packed gravitational wave packages. Like impacting, identical laser beams or identical acoustic waves can form solitons. Gravitational waves that impact with each other can form a gravitational soliton.
Today, we think that the black hole evaporates. In that process black hole releases information that is stored in the form of Hawking radiation. Or, in the form of gravitational waves. So can the black hole have hair? Maybe a black hole has so-called soft hair, or maybe it’s partially bald. The black hole’s hair means strings that transport information out from that structure. The black hole is not completely smooth. There are small hills and valleys in its structure. If a black hole were to be completely smooth, that means that it could not touch the fields around it. Those small hills and valleys would play an important role in black hole interactions.
Those small hills and valleys form when a black hole forms. And supernova energy presses those particles into one entirety. Called a singularity. Electrons that orbit atoms will be smashed against the atom's nucleus. And they leave at the shell of that thing as the quantum-sized hills and valleys. There are also models where there are no singularities. Singularities can explain some black holes. Things like the Kugelblitz theory suggest. Black holes can form from the energy fields or wave movement. In that case, something starts to transport energy out from a certain point. And then energy or wave movement that comes from around tries to fill that point. This thing could prove superstring theory.
That means black holes are like gravitational solitons. When gravity fields start to travel against each other. That effect locks wave movement in the gravitational wave soliton. Can that soliton be stable? That depends on the energy that whirls around it. If that gravitational soliton can form a whirl that is large enough that it cannot let energy or wave movement travel out from that soliton, that makes it stable. Maybe not all black holes are similar. Some of them might have a singularity. And some of them might not have that thing. Black holes are not destroyers.
They store information in them. In new models, there can even be universes inside black holes. And in wildest models, our universe exists in a black hole. In this model, we cannot see the black hole’s event horizon because it's too far away. In some models, there is also a shockwave inside the event horizon that covers the event horizon itself. And when information travels through that event horizon, it stretches those waves. And anyway, the black hole is surrounded by a material disk. That covers things that are outside that thing.
There is a possibility that our universe formed when a black hole from the previous universe detonated. Those new models are tools that can open the biggest mystery in the universe. Black holes can offer a solution for information paradoxes. And answer how the universe formed.
https://en.wikipedia.org/wiki/Soliton
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