Will a black hole in the universe swallow neutron stars with a density of up to 100 million tons per

Black holes swallow neutron stars, because neutron stars also have limits, and the gravitational pull of black holes is very strong, which can cause neutron stars to collapse, but it is more time-consuming to swallow neutron stars.

Yes. Because the gravitational pull of a black hole is so strong that it can swallow any matter, it will swallow neutron stars with densities of up to 100 million tons per cubic centimeter.

No, because although the neutron star is not very large, its density is very high.

If a black hole swallows a neutron star, it has the potential to cause the black hole to collapse and disappear into the universe.

Neutron stars are formed at the end of the star**, and the neutron star has most of the angular momentum of the parent star, and because there is no black hole with a large mass and no deep hole in space-time, the neutron star can maintain an extremely high rotation speed and rampage through space. The horror of a black hole lies in its amazing gravitational attraction that swallows everything, and the neutron star can move quickly when it has the vast majority of the mass of the black hole, which causes the destructive power of the neutron star itself to far exceed that of the black hole.

If the black hole swallows up the neutron star, the black hole cannot control the energy of the neutron star, and the neutron star will be in the black hole**, causing the black hole to collapse and disappear into the universe.

Formation of neutron stars.

When a larger star becomes a supernova**, the tremendous pressure during the internal collapse will completely change its structure, and the electrons and protons that originally existed in the nucleus appear, and the electrons and protons interact to form neutrons, and when these neutrons continue to gather together, they will become neutron stars.

However, the neutron star does not exist in the universe forever, with the rotation of the neutron star, its energy is also quickly consumed, and soon, the neutron star will burn up all its energy and become a black dwarf, and the star is really at the end of its life.

Because in this way, the black hole will collapse and disappear. Disappear into the universe.

There are at least two ways to describe how big an object is. We can say how much mass it has, or how much space it occupies. Let us discuss the mass of black holes first.

Theoretically, there is no limit to the mass of a black hole. Masses of any size, if compressed to a sufficiently high density, have the theoretical potential to form a black hole. We think that most of the actual black holes that exist are created after the death of massive stars, so we think that those black holes are as heavy as those massive stars.

A stellar black hole typically has a mass almost ten times that of the Sun, or 10 (30) kilograms. Astronomers also believe that many galaxies have massive black holes at their centers. They have a mass of about a million times that of the Sun, or 10 (36) kilograms.

The greater the mass of a black hole, the more space it occupies. In fact, the Schwarzschild radius (i.e., the radius of the event horizon) is directly proportional to the mass: if a black hole is ten times as heavy as another, its radius is also ten times that of that one.

The radius of a black hole with a mass like the Sun is three kilometers. A typical black hole is ten times more massive than the Sun, and their radius is thirty kilometers. And the black holes in the center of galaxies are a million times more massive than the Sun, and their radius will be three million kilometers.

Three million kilometers may sound like a long distance, but it's not that long by the standards of astronomy. For example, the Sun has a radius of about 700,000 kilometers, while those supermassive black holes have a radius of about four times that of the Sun.

How big can a black hole be?

Black holes do not have the maximum limit. However, the largest black hole in our imagination is located in the center of many galaxies, with a mass of about one million suns. Its radius is about the size of our solar system.

How small can a black hole be?

According to general relativity (which predicts and explains most of the properties of black holes), there is no small limit to the size of black holes. But, however, the whole set of theories about how gravity works must include quantum mechanics. This theory is still being worked out.

Some recent research on this theory gives us some hints about how small a black hole can be. Its radius cannot be less than 10-33cm 10-38cmWith such a small size, even the smoothest space will break into "mouse trap" tunnels, loops and other mesh structures!

At least, that's what our current research shows.

Black holes are actually capable of swallowing neutron stars, and in fact, black holes may be one of the results of neutron star evolution. Neutron stars are very dense celestial bodies that are formed from the debris left behind behind by the star**. Its mass is usually several times greater than that of the sun, but its volume is only about a few tens of kilometers.

Black holes are celestial bodies formed by extremely dense matter, and their gravitational pull is so strong that even the celery rocks can't escape light. When the mass of a neutron star exceeds a certain threshold, it may collapse into a black hole. In this process, the material of the neutron star will be swallowed by the black hole.

Thus, a black hole can swallow neutron stars, not just neutron stars, it can also swallow other matter, including dust, gas, and other stars. The engulfing power of a black hole depends on its mass and the availability of surrounding matter.

Summary. As far as I know, the reason why black holes dare not swallow neutron stars is that they will form accretion disks.

As far as I know, the reason why black holes dare not swallow neutron stars is that they will form accretion disks.

But if it is a neutron star, because of its small radius and large gravitational force, it must be very close to the black hole before it is swallowed, and when the neutron star and the black hole are close enough, the gravitational waves generated by their motion will be very strong, which will cause them to lose energy quickly, so that the entire neutron star may quickly fall into the black hole. Therefore, the engulfment of neutron stars by black holes is definitely an extremely difficult event to encounter. Neutron stars, also known as pulsars, are one of the few endpoints that a star may become at the end of its evolution, after a supernova through a gravitational collapse.

If a star that does not have mass enough to form a black hole collapses at the end of its life, it forms a star between a star and a black hole.

Hello dear. Black holes do not dare to devour neutron stars because the presence of neutron stars prevents black holes from getting close enough to ingest their matter. A neutron star is a very dense celestial body composed of extremely compressed neutrons with a very strong gravitational field.

When a black hole tries to get close to a neutron star, the neutron star's gravitational field will begin to constrain and cancel out the black hole's gravitational field, which will cause the black hole to not get close enough to engulf the neutron star. In addition, neutron stars emit very intense radiation, which can also affect black holes, making it more difficult for black holes to approach and engulf neutron stars. Therefore, when a neutron star and a black hole come closer, the force fields between them cancel each other out, allowing the black hole to easily swallow the neutron star.