Can the gravitational pull of a black hole tear atoms apart? Why?

You don't actually need a black hole to shred an atom. The gravitational pull of a neutron star has shattered atoms. The later stages of a star are actually a competition between its own gravity and the degradation of matter.

Ordinary stars use nuclear fusion to balance their gravitational pull. After burning helium and hydrogen, some massive stars rely on the electro-poly exclusion principle to resist their own gravitational pull. These are white dwarfs.

For a star with a larger mass, the electron degradation force is too weak to resist, and the neutron can balance the gravitational force, which is a neutron star, and there are no atoms in the ordinary sense here.

<> if the gravitational pull is strong enough to crush a neutron star, there is nothing left to fight it, forming a black hole. Another theoretical object between a neutron star and a black hole is a quark star, which relies on the compressive force of a quark to resist gravity and keep it from collapsing. But quarks have not yet been discovered.

The behavior of a black hole devouring an object is actually the most common astrophysical process of a black hole, which is accretion. It is the process by which the gravitational pull of a dense object captures the material around it, and even a black hole as small as 1 millimeter in diameter has enough accretion to destroy the entire Earth. If such a black hole appears on Earth, the objects near the black hole will be instantly torn apart by its strong gravitational pull, disintegrated into atoms, and eventually absorbed by the black hole, and finally merged into a black hole the size of a bean.

Of course, the nuclear force of the nucleus cannot withstand the gravitational pull of a black hole. The problem is that there will never be a tear without an opponent to tear the black hole. This means that the nucleus can be held and will never be torn apart.

In fact, even neutron stars can be swallowed by black holes, not to mention small atoms, which do not need to be eaten individually. However, before the star is swallowed whole, the black hole's gaseous and liquid outer layers are stripped away. This peeling process is observed, which can also be said to be tearing.

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Personally, I think that the gravitational pull of a black hole can tear atoms apart, because the gravitational pull of a black hole is determined by its own mass, although the black bean is small in size, but the mass is very large, nothing can escape the black hole colleagues and then enter the black hole after the strong pressure and gravity to tear any atom apart is no problem.

The gravitational pull of a black hole can tear atoms apart, because the gravitational pull of a black hole is very strong, and the destructive force of this gravitational force is also very strong, so it will definitely tear atoms apart.

Yes, the attraction of a black hole is so great that a neutron star can already tear atoms apart.

OK; Black holes have a strong gravitational pull and are so destructive that they can completely tear leaves apart.

A black hole can shatter atoms, and even the electrons in the nucleus, the nucleus, the neutrons in the protons, and the quarks in the protons are all crushed into pieces, forming a singularity with almost infinite mass, and his gravitational pull can suck in matter, disappear, and convert into energy, you are right about a black hole, compress an atom, and if you don't kill it, you won't be able to take your turn? Obviously, the gravitational pull of a black hole can easily crush atoms.

<> in the last moments of life, the stars in the universe are essentially pulled by their own gravity, causing them to contract and collapse. The gravitational pull is so strong that it can crush an atom (we know that an atom is made up of a nucleus, around which electrons orbit, and there is a very large space between the electrons and the nucleus that can be compressed). And when the nucleus is crushed, you are left with only the neutrons that make up the nucleus.

At this point, the star becomes a neutron star, which is very dense and weighs as much as a matchhead on Earth. A black hole is formed when a star collapses and its gravitational pull crushes neutrons into nothingness.

The black hole can further compress the atoms, it also depends on the gravitational force of the area where the black hole is located, if you feel that the gravitational pull of this new black hole is greater, the old black hole should be smaller, if it is just for the effect of further experiments, we can do and I don't know right to say that the black hole level of the body, even if the neutron star has been torn apart atoms - electrons outside the nucleus forcibly expelled to the protons inside the nucleus, turning the protons into neutrons. As neutrons increase in the nucleus, the nuclear structure becomes loose and the neutrons begin to separate from the nucleus and become free neutrons. The density reaches 10 to 11 kilograms per cubic centimeter.

Between a black hole and a neutron star, there may be another object known as a quark star.

Because unlike the singularity of the big **, which is a mathematical point of being, the black hole and the big ** should still be different things, because they are not**. The singularity of a black hole is supposed to be physically present, so its strong gravitational pull does tear apart the matter that falls into it. As for black holes like Kerr, it has been said that if you accidentally fall into a black hole, you don't have to die.

Perhaps you can survive with the energy layer between its static and event horizons, as this energy layer is connected to the white hole. In this sense, black holes don't tear apart anything.

OK; Because the gravitational pull of a black hole can easily crush atoms, causing them to contract and collapse, when the nucleus is crushed, only the neutrons in the nucleus remain, and its density is very large, but the core it will form a black hole, and black beans can further compress the atoms.

Yes, you can. The gravitational pull of a black hole is very strong. And the crushing capacity should not be underestimated. It is possible to shatter a star, and it can also compress atoms further. Even the quarks inside the proton are crushed to pieces. Let the ash go up in smoke.

It shouldn't be a matter of "compression", there is an indescribable amount of energy in a black hole with extremely high pressure and temperature, and all the particles we know are afraid of being torn apart.

Black holes are capable of compressing atoms further because the gravitational pull of a black hole can easily crush atoms.

Atoms are the basis of the structure of an object, and breaking and crushing them is not something that a rotating body can afford.

If a large number of nuclear bombs were dropped into a black hole, would the black hole be destroyed? No. Black holes are like an incurable addict.

On the one hand, black holes must constantly absorb energy to survive; On the other hand, the density of the black hole will continue to increase as energy is ingested, so the quanta inside have higher and higher energy. In short, as a dissipative structure, black holes are the most energy-dense objects in the universe. Black holes must constantly absorb energy to maintain a state of decreasing entropy.

Therefore, for black holes, a nuclear bomb is food for replenishment, not a destructive bomb.

There are two main ways in which black holes are created. One is that massive stars, after consuming fusion nuclear fuel, collapse under gravity, compressing all matter into a single "singularity". The density of the singularity is considered to be infinite, and the curvature of space-time around it is very large, so that light cannot escape in a certain time interval.

A black hole is formed.

Another type of black hole was formed at the dawn of the universe. Because when the universe was first born, the energy density in space was very high, so with a small disturbance, black holes could form. This type of black hole is called a primordial black hole.

Its mass can be large or small. The mass that was too small was evaporated by Hawking radiation.

From the point of view of the birth of a black hole, a large density of mass is required. Attacking him with a nuclear ** will only make him bigger. From the current knowledge of physics, there is only one way to eliminate a black hole, and that is to "wait".

Wait until Hawking's radiation evaporates him. But this time it will be long. In the universe, these quantities, defined by Planck's constant h, usually exist in two different ways.

One is the discrete state, which constitutes the physical background (space) and energy of the universe; The second is the closed state, which forms the mass of physical objects (matter) and the universe. The initial formation of matter was due to the rapid expansion of the universe. When the expansion rate of the universe is greater than its internal propagation speed, it leads to an imbalance in the universe, resulting in a closed system of discrete quantum high energies, i.e., various elementary particles.

No, black holes are the most energy-dense objects in the entire universe.

Can a black hole have such a gravitational pull that it can tear atoms apart?

Yes, because of this happening, so far we have not been able to detect black holes completely.

The gravitational pull of a black hole can tear atoms apart, and the gravitational pull of a black hole is so strong that any matter around the black hole will be torn apart.

Can be shredded. Because the gravitational pull of a black hole is very huge. I think theoretically, this gravitational pull can tear atoms apart.

A black hole refers to a singularity with an infinite central density, infinite curvature of space-time, infinitely small volume, and infinite heat, and a part of the surrounding celestial region that is empty, and is invisible within this celestial region. According to Albert Einstein's theory of relativity, when a dead star collapses, it gathers at one point, where it becomes a black hole that devours all the light and matter adjacent to the universe.

Yes, because the gravitational pull of a black hole is endless, and anything that comes close to a black hole can be swallowed, such as atoms, the earth, and the planet.

No. Because the atom is the smallest unit of matter, and the atomic structure is very stable, it cannot be torn apart.

The gravitational pull of black holes is said to be high. Can the gravitational pull of a black hole tear apart atoms? A black hole refers to a singularity with an infinite central density, an infinitely high curvature of space-time, an infinitely small volume, and an infinite amount of heat, as well as a part of the surrounding empty sky region that is invisible.

According to Albert Einstein's theory of relativity, when a dead star collapses, it gathers at a point where it turns into a black hole that devours all the light and matter adjacent to the universe.

So, can the gravitational pull of a black hole tear atoms apart? Let's start with the conclusion. From my personal point of view, black holes can tear atoms apart.

Here are the detailed instructions. You don't really need a black hole to tear atoms apart. The gravitational pull of a neutron star shatters atoms.

The later stages of the star are actually a competition between their own gravity and the degradation of matter. Ordinary stars use nuclear fusion to balance their gravitational pull. After burning helium and hydrogen, some massive stars rely on the principle of electron multi-repulsion to resist their own gravitational pull.

These are white dwarfs. For stars with greater mass, the electron degradation force is too weak to resist. Neutrons can balance gravity.

This is a neutron star. There are no atoms in the general sense. What is the gravitational pull of a black hole.

The formation process of black holes is similar to that of neutron stars. A star is preparing to perish. The nucleus of the atom rapidly contracts and collapses under the action of its own gravity, resulting in a strong **.

As soon as all the matter in the core becomes neutrons, the contraction process immediately stops and compresses into a dense star.

At the same time, interior space and time are compressed. However, in the case of a black hole, the mass at the center of the star is very large, and the contraction process is infinite, so the repulsion between the neutrons cannot be stopped. The neutrons themselves are squeezed by gravity and attracted into powder, leaving behind an unimaginably dense substance.

Due to the gravitational force caused by the high quality, objects that are close to it are inhaled. If gravity is strong enough to smash neutron stars, then nothing can compete with it, forming black holes. Another theoretical object between neutron stars and black holes is quark stars, which rely on the compressive force of quarks to defy gravity and prevent them from collapsing.

But the Quakers have not yet been discovered. The behavior of black holes engulfing objects is actually the most common astrophysical process of black holes, namely accretion. It is a process in which the gravity of a dense object captures the surrounding matter.

Even a black hole with a diameter of only 1 millimeter is accretion enough to destroy the entire Earth. If such a black hole appeared on Earth, the objects near the black hole would be instantly torn apart by its strong gravitational pull, disintegrated into atoms, and finally absorbed by the black hole, and finally merged into a black hole the size of a bean.

Black holes can produce not only new matter, but also new life, new energy, and new worlds. The gravitational pull within the black hole's event horizon is indeed so great that light cannot escape. But what you call tearing is actually caused by tidal forces.

The tidal force is not a real force but the action of gravity. We know that the magnitude of gravity is inversely proportional to the square of the distance. Therefore, when any matter falls into a black hole, the magnitude of the gravitational force acting on each part of the matter is different.

For example, an astronaut heads toward the singularity because the head and feet have a concept of length, and the gravity acting on the head and feet is of different magnitude, which is equivalent to your body being pulled towards the ends. Because the gravitational pull of a black hole is so strong, this effect is amplified, and this tidal force can tear apart any matter. However, the tidal forces within the event horizon are related to the mass of the black hole.

When the mass of a black hole is larger, the diameter of the black hole event horizon is also larger. The matter that has just fallen into the event horizon is equivalent to a point, and the tidal force at this time is very small.

A massive black hole can allow even a living person to safely enter the horizon. Of course, the closer to the singularity, the greater the tidal force, and the matter that reached the singularity should theoretically erase all information, including the state of the nucleus. We usually call the hypergravitational regions of the universe black holes, if generalized.

We can also call them black holes. We breathe, eat, and absorb the sun's energy, which has the same relationship as a black hole. So you can imagine.

After entering a black hole, things may remain the same, or become unrecognizable.

If there is only matter in a black hole with ordinary gravity, then only matter is absorbed. Since it is a single component 1, there will not be much physical and chemical reaction. But if the black hole is supermassive.

Even if it enters the substance, it will produce a violent reaction similar to the nuclear **. Thus, a new substance is formed. It's like the legendary big ** in our universe.

In other words, there may be one or more universe-like worlds within a black hole. The world has also given rise to intelligent beings like humans.