Where does something go when something enters a black hole?
From the usual "rubber plate" analogy, the way in which a giant gravitational body distorts the plane of space in a constant time structure is very similar to the way a heavy object presses down on a trampoline.
The mass of the black "hole" is so dense that it can stretch the "trampoline" infinitely down, "tearing" a "hole" on the structural surface. Stretching tends to infinity at the event horizon, while matter exists in some way within the horizon, a point that, from the outside, is called "the past."
(My physics professor once told me, "There is no infinity in nature.") If so, then the "ERR" of the computer is not really happening. But this is the best theory to date. )
Particles that enter a black hole never reach the event horizon because their distance is infinite. At the scale of reality, the measurable distances that reach the event horizon inward are mathematically infinite. The space-time structure of a black hole is infinitely distorted. Even if it falls inward at the speed of light, the structure of space-time is stretched infinitely. Even if you want to reach the event horizon, you need to go through an infinite distance in the mathematical sense, let alone reach the inside of the event horizon. Suppose you can go faster than light at faster than light speeds, and you still can't reach the event horizon, let alone cross it.
So to answer this question first, any object that falls into a black hole will remain in a state of falling all the way down. Space is infinitely stretched (by transcending the higher hyperdimensional dimensions of the 3D we are familiar with, "down" or "outward"), and only the event horizon is reached through an infinite distance, that is, the event horizon that is always infinitely distant.
(Mathematically, matter itself is stretched "farther" and then exists "outside the structure of space-time.") )
This is a very important question, but most physicists don't try to answer it. Understanding the structure of black holes can help us understand the answers that can answer your questions.
Gravity also comes with the properties of time expansion. This means that gravity affects the flow of time near massive objects. Even on Earth, this is obvious. Time flows more slowly near the surface than in space. Therefore, there are many problems in synchronizing the clock on the satellite with the clock on the ground. This is also the reason why all the communication satellites failed in the first place. Later, they had to design compensators for clocks on satellites that would allow them to communicate with the ground.
Due to extreme gravity, black holes exhibit extreme cases of time expansion. (There are many concepts that need to be sorted out in the mind and understood together.) )
The speed of light is the largest speed limit in the universe. Because the speed of light is finite, we are actually experiencing the universe of the past. For example, sunlight takes 8 minutes to reach Earth. So, the sun we see is not the current sun, but the sun 8 minutes ago. So, if the sun suddenly disappears, it will take 8 minutes for us to know that the sun is gone. Similarly, it takes 4 years for the light from the nearest star to reach Earth. So we're not seeing the real star, it was four years ago. Further, we are actually going back in time.
Now, fix this idea in your head.
Gravity affects space. It can bend, stretch, and compress spaces. A black hole can use its extreme gravity to bend space to its limits. When we look at the properties of black holes based on the research of famous scientists, they clearly show that the environment inside black holes is indescribable because the known laws of physics have been broken. Where do you think this will happen? This is the same as the environment of the Big Bang.
We also need to look at scientific research that points to black holes. The most important of these is Einstein's system of field equations. But they also have some characteristics. The Schwarzschild gauge is solved from the field equations , and its complete geometry consists of a black hole , a white hole , and two universes connected to its event horizon through wormholes. Schwarzschild wormholes are precise solutions to Einstein's field equations, and white holes are the opposites of black holes, which pull matter inward through gravity, and white holes throw matter outward. According to the Schwarzschild gauge, all the material that falls into the black hole is thrown by the white hole after passing through the wormhole.
Now the answer to your question is, "After the matter is sucked into the black hole, it travels through the wormhole to the white hole, and then it is thrown out." ”
But don't stop here, we need to check if this is correct and if we have any evidence of the existence of white holes.
Now let's summarize the points we have:
The farther we look, the more we can go back in time.
Black holes compress space to the extreme. For example, black holes compress large spaces into small spaces with their enormous gravitational pull.
The laws of physics are broken in black holes.
Before the Big Bang, the laws of physics didn't exist.
Now let's look at the big picture and try to understand how the whole thing works.
From perspectives 1 and 2, it can be seen that when matter falls into a black hole, it is actually thrown back into the past due to extreme time expansion. That is, all the material that falls into the black hole will only reach the point in time before the Big Bang.
This also explains the source of the Big Bang matter (or energy). The law of conservation of energy states that energy neither arises nor disappears out of thin air. But that doesn't explain the energy loss in black holes and the energy generated in the Big Bang. But the two are linked. Millions of black holes that existed in the past, black holes that exist today, and black holes that will exist in the future, all fuel the only white hole at the beginning of time, the Big Bang as we know it.
BY: quora
FY: Hairpin flower sweet bean
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