What would happen when a person entered a supermassive black hole?

If you approach the event horizon of a stellar mass of a black hole.

Your body will be affected by tidal forces.

Pull away, turn into a high-energy plasma, and die before you reach the event horizon. The black hole itself has zero volume and is a singularity. of black holes"surface"Known as the event horizon, it is not made of matter, it is a location.

When you approach a black hole, if you haven't reached the event horizon, the gravitational field.

is strong, but if your ship pushes hard, you can escape.

<>But when you cross the event horizon, no matter how powerful your ship is, you can't leave the black hole, because the space within the event horizon, no matter which direction you go, is close to the black hole. If the mass of a black hole is very small, its gravitational gradient is very large, which means that the gravitational force changes so fast that you are torn apart by tidal forces before you reach the event dome. If it's a massive black hole with a small gravitational gradient, you can go straight through the event dome, but you'll never be able to go back.

Black holes are one of the most mysterious objects in the universe and are full of unknown mysteries for scientists; For the general public, it has always been shrouded in mystery. Ever since scientists proved its existence, humans have been curious and eager to explore it. Some even ask if a person falls into a black hole, will he be torn to pieces immediately; Or in an instant it will turn to ashes and disappear without a trace; Or will they travel to another dimension unscathed?

In fact, no one is quite sure. According to the black hole theory, we know that a black hole is an infinitely small body with infinite density. Its magnetic field is so strong that no matter, no radiation, or even extremely fast light can escape from it.

And, the closer you get to the edge of the black hole, the more you can't escape. It is called"Monsters of the universe", because it has the power to devour everything. So, what happens to an object that falls into such an incredible black hole?

One of the most imaginative gravitational effects of black holes is known as spaghetti.

This means that if we get too close to the black hole, we will be pulled like spaghetti. This happens because the gravitational pull of the black hole has a gradient on the body. In this way, we can imagine a person flying into a black hole under his feet.

Because the foot is closer to the black hole, the gravitational pull is stronger than the head, and as he gets closer to the black hole, the body is stretched longer and longer.

The body may be injured to a certain extent, and there will be many problems, and the impact will be more serious, and it will also be infected or die directly, and the body will also be pulled by the tidal force.

People can be torn apart, they can be crushed, because the attraction of black holes is particularly strong, and anything that enters can be shattered, and it is very weird inside.

It may be torn to pieces, and in an instant, it will be reduced to ashes, disappear without a trace, travel to another dimension, and be pulled into noodles by the invisible impact.

It will be torn apart, and the black hole can devour everything, and if it can enter, it will be torn apart immediately, and there is no way to exist, which will directly lead to death.

It will affect people's lives, and the black hole will produce suction to enter the black hole, and the person will die in the black hole and completely disappear into dust.

You won't feel anything out of the ordinary ...... at allBecause the density of supermassive black holes is too small......

If things are not villages, how can we talk about human beings. Writer Yang Daxia Yang Ke narrated.

To break through the constraints is to accelerate, as long as the speed is fast enough, you can break through the distortion of space and time of the massive celestial body, and get free, as for how fast to be free, this can be achieved through formulas, it is these formulas that make people discover that if the density of the celestial body is large enough, then it needs to be faster than the speed of light to break away from the celestial body, from which astronomers and physicists deduce the existence of black holes.

The escape speed required to escape from the planet. From left to right, Mercury, Venus, Earth, Mars, Jupiter, Saturn, Uranus, Neptune. Since Pluto is no longer a planet of fortune, it is not on the gif, alas, even in the field of science, the title is important.

So, what exactly is going on between a black hole and gravitational waves, and why a black hole emits gravitational waves when it collides and sends them into orbit is a question that no one has ever asked. Since Einstein's general theory of relativity replaced Newton's law of gravitation with the distorted mass of space-time, this leads to a corollary, <>

That is, when the mass of the object's motion changes, then the curvature of space-time will constantly change, and when the space-time that was once curved behind the object's motion becomes straightened again, and the space-time that was once flat in front of the object becomes curved; This curvature of space-time is not confined to local areas, but spreads outward like ripples. These are known as gravitational waves. Gravitational waves are ripples in space-time and are caused by the movement of massive objects through space-time.

Therefore, black holes and gravitational waves are not contradictory, <>

When a black hole is set to move, it may disturb the surrounding space and time, considering that black holes are usually very massive, so their intertemporal and spatial interference is stronger, and the nature of gravitational waves is stronger, but why do the gravitational waves we detect usually arise from the merger of black holes or neutron stars? Because when they merge, they usually rotate around each other extremely quickly, which creates extremely powerful gravitational waves that can travel great distances to reach the Earth. When gravitational waves pass through a distant observer, the observer notices that space-time is distorted.

The distance between two free objects fluctuates rhythmically at the same frequency as gravitational waves.

However, in this process, the two free objects are not actually subjected to a force, and the absolute position of the coordinates does not really change, but their relative distances do, because the space-time coordinates themselves are also changing. The intensity of the gravitational wave at the observer is inversely proportional to its distance from the source. According to **, a spiraling approaching neutron binary star system will emit powerful gravitational waves due to its large mass and high acceleration.

But due to the large scale of astronomical distances, the impact of even the most violent gravitational waves, when they reach the Earth, has become extremely low, and the ripple effect is on the order of less than 10 21 meters, much like a distant wave, after a long enough distance, into a wavelet.

It is mainly because of the gravitational pull and the change in the situation in terms of nuclear fusion of matter, that it is absorbed by black holes.

Because black holes can distort space-time, and they also produce some gravitational waves. That's what happens.

First of all, it is because of the gravitational attraction and the change in the nuclear fusion of matter, so it is absorbed by the black hole.

The collision of two supermassive black holes at the speed of light should not happen. First, black holes do not collide with each other. The black holes are only slowly merging, and the supermassive black holes are located in the central region of the galaxy.

In order for two supermassive black holes to merge, the galaxies must merge before the black holes merge. Just like a merger between stars, the two stars do not meet directly, but come closer together, forming a binary star system that leads to mass transfer. There are no direct collisions above the stellar energy level, and mass transfer occurs through merger.

The same applies to black holes, so if two supermassive black holes collide at the speed of light, the second case is also incorrect. There is no black hole in the universe that moves at the speed of light, and a black hole moves at the speed of light, so is it still a black hole? Galaxy mergers have been widely observed, and such systems may have formed after mergers billions of years ago.

According to the study, in this case, the two merged galaxies would each have a superheavy black hole. Scientists already know that two massive black holes emit gravitational waves when they get close, and researchers believe the two black holes will eventually collide.

Researchers at the University of Washington, John A. Ruan et al. found that although we cannot determine exactly how much mass these black holes have, according to the latest observations, the two black holes will form a large black hole in hundreds of thousands of years of collision and fusion, and the time is controlled for hundreds of thousands of years, which has been a cutting-edge research topic in the field of black hole merger. If the black hole problem is solved, we will be one step closer to understanding the ultimate mystery of the universe.

If two protons collide at the speed of light, thousands of protons will be thrown. Similarly, if a black hole collides at the speed of light, thousands of black holes will be created and scattered. Eventually, these high-energy, high-velocity black holes will form galaxies.

Those thousands of galaxies make up a new universe. Two super-black holes have a mass of 5 billion times that of sunlight, and can make the mass of the collision space tens of thousands of times more than that of a black hole, forming thousands of galaxies, each with billions of new universes, perhaps, our galaxy and the two supermassive black holes in our universe, were piled up 13.7 billion years ago.

When two supermassive black holes collide, there will be a collision between them, and then **, etc., or the black hole will continue to change and cause the big match to accumulate damage.

One black hole will be swallowed up by another, and the two will merge into a larger black hole, and the gravitational pull of this black hole will bury the bigger bend, sucking everything else around it into it.

A black hole with a super mass or a large reed. Devouring everything in the universe at all times. When two black holes with strong gravitational pull collide, then a big ** will occur.

Because although light does not have a mass at rest (only theoretically, in fact, there should be, but infinitely close to and without, we cannot measure this mass yet), but it has a moving mass. There are two explanations for light being affected by gravity, the classical explanation and the general relativity explanation. What you say about gravity is related to mass is the classical explanation.

The theory of relativity explains that gravity causes space-time to bend, causing light to change its path.

Photons do not have a resting mass, and the deflection of photons caused by the gravitational pull of the so-called black hole has been clearly described in Einstein's general theory of relativity as the distortion of space-time caused by mass, and the photons themselves still propagate according to the shortest distance in space. Photons must have mass, are extremely tiny spheres, and when their density is extremely high, like a laser, it destroys everything. Black holes are celestial bodies from which even light cannot escape, so of course black holes attract light.

The essence of the problem is that the black hole bends space so much that the space within the Schwarzschild radius shrinks into a singularity, and the light enters the singularity after crossing the Schwarzschild radius, which is equivalent to the light being attracted into the singularity by the black hole.

If you look closely at the relationship between gravity and energy, you don't know if you find that the direction of energy movement is against the direction of gravity. For example, the heat on the earth is going upward. Since the black hole is a shrinking body in the universe, then the energy must be moving outward in the direction of the black hole's contraction.

Light waves are energy, so black holes don't absorb light waves. They are completely different directions of movement.

Personally, I think but don't necessarily tell you that light spreads through dark matter, matter cannot transmit light, matter can only reflect light. Gravity is related to the depth and breadth of consciousness. If the amount of information contained in a photon is high and the value of the information is high, it will certainly be very attractive.

Therefore, consciousness guides and determines the gravitational pull of all things in the universe. This is a strong proof and concrete guarantee for us to strengthen the learning of natural language systems and enhance the decisiveness and effectiveness of consciousness.

The main reason is that the gravitational pull of the black hole is so great that the light is distorted, which makes people feel this way, but it is not actually the so-called swallowing.

This is because when light passes through a black hole, there is no reflection of light, and when you can't see the light, you will naturally think that it is swallowed by the black hole.

Because the black hole is too big and too long to shine through, not to swallow it, but to light energy that can't reach the end, like a night flashlight, it can't shine far.

The main reason is that light has a strong energy, and this matter can interact with black holes.

It is common for light to be absorbed in the process of propagation!

Supermassive black holes are formed by the continuous accumulation and compression of matter in the universe. Because the gravitational pull of a black hole is very large, it will continue to absorb external matter to strengthen itself, so it will become so huge.

Supermassive black holes can be formed because they absorb other stars in space for a long time, and the larger the black hole, the stronger its attraction, so it will become larger and larger.

<> depends on how the singularity is defined, such as a black hole. Singularities and black holes are both nouns (names) used by cosmologists to generalize and define a phenomenon in the universe. Singularities share common features with black holes:

It is internally agnostic, and all laws fail inside a singularity or a black hole. There is no time or space inside singularities and black holes. Both singularities and black holes have unknowably strong cohesion (suction), and all matter or energy is highly compressed and condensed.

If there is one of the most authoritative cosmologists who defines the singularity as the same concept as a black hole, that is, the singularity = black hole. This issue is no longer a problem. No one knows what is in a black hole, gravitational force and Einstein's theory of relativity, whether it is applicable, these basic principles, in a black hole, whether the size of gravity is not the same curvature is not the same, it is possible to produce another space, everyone knows that the atom collapses in the black hole, whether the neutron electron will collapse again, if it collapses, it will become something, if it becomes another space, another kind of human beings will be possible.

The origin of the universe should be, zero gap error. After the crevices are compressed, a large amount of material is continuously produced. These substances form a group of substances.

Due to the relatively low temperature. itself is extending indefinitely. Over time, the temperature rises.

So that the material group produces a collective ** to form a space. The space is clear and clear, but the non-substance contained in it is dissolved. At the same time, the material at the edge is pushed to the periphery, and the peripheral material begins to rotate the space, so the buoyancy in the space is generated.

It is only a remnant in space, forming an organizational structure of the cycle of life and death of light and dark matter. It's like a piece of ice that is produced by temperature and melts into water. Formed space.

It's not created by black holes. Black holes are just the end of supermassive stars. The accumulation of matter formed, the vortex of matter produced.

There is a strong magnetic field. It is also just a tiny speck of space. It doesn't have that much power to form the universe.