Traveling into Black Hole

According to Jafferis, sending someone through Black Hole is not a problem, at least legally. Statistics based on the species of wormholes studied so far suggest that their use will be slower than just moving into space, says Jafferis. In addition, he said that very little is known about quantum gravity - the union of quantum physics and the ancient ideas of gravity - those unseen laws can completely block the flow of hyperspace. While the idea of ​​moving interstellar space through black holes is possible, getting to the testing can be a challenge.

Physicist Stephen Hawking points out that since no one has ever seen a time traveler today (at least it has been reported), the passage of time seems impossible in our universe. This suggests that black holes are less commonly used as wormhole generators. But now physicists have developed computer simulations to show that certain types of black holes - large, black holes in them - can act as hyperspace sites. So scientists are turning to computer simulations to see what will happen if we reach a single black hole, and now, for the first time, a team of scientists from the University of Massachusetts Dartmouth and Georgia Gwinnett College has done just that. . For example, if you were to walk in a black hole first, the force of gravity would be so strong that you would turn into spaghetti and expand until it became a stream of atoms facing the center.

This is one of the main reasons why stars fall into black holes: as the star grows, the pressure in the center increases, making the gravitational force stronger, increasing the pressure even more. This is problematic because the difference in gravity between the neighboring points creates the force of the ocean. Understanding this requires a shift in Einstein's theory of relativity as it is applied to gravity. Scientists agree that if you get too far into the black hole, the gravitational pull will eventually be strong enough to kill everything in its path.

For people to send Voyagers in the next few years, we must use a strong magnetic field caused by black holes or send Voyagers into space at about light speed (about 1 billion kilometers per hour). If so, then even if we can go on time, we will never change events to create a different future. While it might be fun to go back and see the dinosaurs or meet Albert Einstein and show him the authenticity of time travel, it might be best not to touch the past. But no matter where you go (or not) in space, you must always go to your future.

This idea is very interesting because if you can keep track of time, no matter how you travel, unity will always be your future if you are inside the event venue. But the element of the ring can behave differently; the part that made you worthless does not have to be your future because of the strange ways the unity of the ring twists and twists place and time. This means that unity if rounded fast enough, can be a ring rather than a point.

It can be a time-bound region, another place, or a remote place. But in Schwarzschild, at least we can talk about the place between the horizon and the singularity, and what visitors experience as they pass through that area. After all, you will still be dumb as you approach the singularity of the middle, but at least you have the opportunity to look inside the event horizon.

With a black hole weighing our Sun (the weight of the sun), the event horizon will have a radius of fewer than 2 miles. This is the distance from unity, where the gravitational force is so strong that nothing, not even light itself, can escape the trap of black holes. It still has a strong gravitational pull, but it will only stretch for a limited amount and may NOT kill you in the process, which means you can survive when you walk through a black hole.

And because it is so heavy, it can fully extend local time, and moving to its center means that time almost depends on you. And a heavy object or a large pile, most of the time it will stretch. The value of all the energy-moment-stress tensors, so the gravitational pull of space-time is no different.

It turns out that the mass of the most common elements does not come from the empty mass of constructive particles, but from the binding forces that hold and cling to each other. It refers to the strange quantum connections that can exist between two objects, so that whatever is done to one touches the other immediately, no matter how far apart they are.

However, no one has ever discovered how quantum mechanics can work with gravity to comprehend what unity can look like. Perhaps, as the University of California, Riverside (UCR) suggests, quantum gravity theory will help us solve this problem in the end, but not now. A new paper by University of Utah physicist Lior Burko on previous work raises the question of whether black holes cannot destroy everything, and the power of the hyperspace movement remains.

According to a study published in the Journal Physical Review, if the black hole is large enough, astronauts will fly smoothly through it. When the body shrinks below a certain level, it twists the space of time in such a way that even light can escape it.

Einstein's calculations suggest that if the bridge in space were stable enough, it would cover two points at a time. Einstein suggested using the Einstein-Rosen bridge (a type of wormhole) to make it easier to navigate the past. It is now called the Einstein-Rosen Bridge. It seems to open the way to take shortcuts into space and time, into a black hole in one part of the universe, and leave another, perhaps thousands of light-years away, but not millions of light-years.

Building on the work done by physicist Amos Ory two decades earlier, and armed with his powerful arithmetic skills, Mallari built a computer model capable of showing most of the basic physical effects of a spacecraft and any large object that falls into a rotating black hole like Sagittarius A *. In 2016 Ph.D. Student Caroline Mallary, inspired by Christopher Nolan's Interstellar, plans to see if Cooper (Matthew McConaughey's character) can survive when he falls into the depths of Gargantua, a fictional, massive, and fast-changing object weighing 100 million times the mass of our sun.