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What is inside black holes?




The fact is that researchers are just finding out that interesting question. We know that we need some new theory that models the curvature of spacetime in the gravitational field where escaping velocity is higher than the speed of light. The Theory of General Relativity is effective only to the point of the event horizon. The limit of the Theory of General Relativity is that it is useful only in gravitational fields where the escaping velocity is lower than the speed of light. That's why researchers are hard to make models of the internal structure of back holes. 

When some particle falls into the black hole it should act as it falls into any other ball-shaped structure. If it follows a straight trajectory. If we would drill a hole through the Moon or Earth and drop some object in it. This object would start to travel back and forth in that hole. And the objects should behave similarly in the black hole. 

That means the particle could start to travel back and forth inside that extremely high gravitational object, where even light cannot escape. The material is in the form called a singularity. In that matter, time and matter are the same things. 

Speed and gravitational field are slowing time. That thing is called time dilation. The reason why time stops or particles stop aging at the speed of light is that. The object rides with the wave motion. The sideways coming wave motion or quantum field pushes the wave motion that is leaving from the object back. So the material turns old when it evaporates. And in the quantum world, vaporation means that material is turning to wave motion. 

The time travels backward behind the event horizon. The reason for that is that when the escaping velocity reaches the speed of light time stops. So logically, when the escaping velocity crosses the speed of light the time should start to move backward.  

So when particle can travel back and forth inside a black hole? That thing requires that the particle falls by using a straight trajectory. But even if the particle is falling into the black hole by using a spiral trajectory. That thing causes an interesting thing. If a black hole acts like all other ball-shaped structures. 

There should be a zero-gravitational bubble in that object. If that zero-gravitational bubble exists the particle would travel through that area at the speed and energy that it got from the travel of the black hole. That particle sends energy or wave motion to the structure around that bubble. And that radiation can rip the black hole into pieces. 

But when we are thinking about the internal structure of the black holes, we might compare that thing with all ball-shaped objects like Earth and Moon. Inside every ball-shaped structure is the point where is no gravitation. So that kind of zero-gravitational point that is found inside Earth and other planets could be inside the black holes. And that point could be the thing that limits the size of the black holes. 

When we are thinking about Hawking's radiation we might think that the source of that Hawking's radiation is in the particles that are dropping into the black hole. So that means Hawking's radiation can be the key to theoretical wormholes. 

A hypothetical wormhole may be the coherent bundle of Hawking's radiation or coherent gravitational waves. There is only a  small moment when the particle, like a quark, is precisely at the point of the event horizon. And during that moment the black hole would load extreme energy load to that particle.

So Hawking's radiation would be the last goodbye of the particle that falls inside the black hole. If that radiation is left from the particle just when it cuts the event horizon that would be the last moment goodbye. Because particle takes that energy from the event horizon it pumps energy out from the black hole. 

But the fact is that there is the possibility that similar radiation will form in the zero gravitational areas in the middle of the black hole. The particle that falls enough will face that zero-gravitational point. And the energy that causes this bubble will start to expand. There is the highest possible mass that a black hole can get. The radiation pressure would start to expand the bubble inside the black hole. 

Also, things like ultimate fast rotation make it possible. That this bubble could break the black hole. When some particle will fall through the wall of that zero-gravitational bubble it sends the radiation. Also if two particles are falling in that area and start to rotate they would send gravitational waves to the massive gravitational zone. And that thing pushes the structure outwards. 

The Event horizon is the point, where we last time see the material. When we are thinking about the white holes that are opponents to black holes and the wormholes that could connect black holes we might think that their sources are in the particles that are falling in black holes.  When a particle falls into a black hole it is at the border of a black hole in a small moment. So the event horizon would travel across that particle and sends the energy waves through the universe. 

Maybe someday we could find those energy channels inside gamma or X-ray radiation that are leaving the black hole. One of the explanations for the hypothetical wormhole could be that is a bundle of coherent gravitational waves. The idea of that theory is that the polarized particles pile up at the poles of the black hole. And there, they could form the quantum entanglement with particles at the border of the black hole. 

When we are thinking about the form of the event horizon, that is the point where escaping velocity reaches the speed of light. But we can say that the event horizon is a certain energy level. That means we could turn any object into a black hole. If we have enough energy. The gravitation along with wave motion would turn the shape of the material and particles into a form that is unknown to us. At the point of the event horizon, the energy level of the particle will rise so high that the particle jumps to the fourth dimension. 


See also: 

Event horizon

Singularity 

Time dilation 

Theory of General Relativity

Theory of Special Relativity

White hole

A wormhole or Einstein-Rose bridge. 


https://miraclesofthequantumworld.blogspot.com/



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