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This one is simple. The neutron star is torn apart and then falls into the black hole and disappears, while the mass of the black hole increases.
Although neutron stars have a very strong gravitational pull and a very high density, they are still not as good as black holes. When the two meet, as the distance decreases, the black hole's gravitational pull on the neutron star increases, and the neutron star gradually lengthens, like an elongated rugby. The neutron star then continues to approach the black hole, being stretched longer and longer by the tidal force of the black hole until it shatters into a long string of neutron matter, which falls into the black hole's event horizon one by one.
As a black hole absorbs the mass of a neutron star, its mass will also increase, which is reflected in the expansion of the black hole's horizon.
That's it.
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Black holes are denser than neutron stars, so don't think of invincibility so narrowly. Unless the heart is touching, absorption is unlikely. Quasars are just a discovery.
Can you beat the rules when playing chess, thousands of years ago humans believed that the earth was the center of the universe. Newton's laws of motion were real hundreds of years ago. When de Broglie came up with the concept of a wave of matter.
Albert Einstein gasped too. The quasars observed so far can only be described as the most mysterious phenomenon so far. Because his existence is once again like the theory of relativity, quantum theory has hit Newton's laws hard, shaking the current theory.
Nowadays, there is no way to explain his superluminal speed (I personally think that its compressive dimension is different from ours, he moves normally in another dimension, but the projection in our dimension breaks the existing laws. I would like to discuss it with all scholars).
So it's hard to say what else will be discovered in the near future. Science is like a whirlpool. The deeper you dre, the more mysterious it becomes. That's right. About the so-called mutual restraint. Does it have anything to do with the evolution of the universe? I haven't thought about this for a while.
Reference**.
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Neutron stars will be swallowed by black holes when they encounter them.
Gamma burst can occur when two systems of giant compact objects (such as neutron stars and black holes) merge.
The process of neutron star being swallowed by a black hole is not instantaneous: when approaching a black hole, the neutron star is first "torn apart" into tiny pieces, and then gradually sucked into the "mouth" by the black hole, during which a brief but intense gamma-ray burst occurs.
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Neutron stars and black holes are both objects of great mass and gravitational pull.
But when they meet:
At a distance of 20 billion kilometers, the neutron star surface metamorphosis is unstable, and the magnetic field fluctuates significantly. At 10 billion kilometers, the extra-neutron material flies out and circles the black hole, after which the neutron star moves towards the black hole. At 5 billion kilometers, they will have a strong magnetic collision and release a large number of electrons and light, after which the energy of the neutron star will be slowly consumed and then swallowed by the black hole.
The same is true when a white dwarf meets a black hole, if a white dwarf meets a neutron star, the neutron star will constantly transfer its internal energy to the white dwarf, and when the white dwarf cannot bear too much energy, it will **. .
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And then the gravitational force is of course the size of a black hole, and the gravitational force of a neutron star is large, but it is a drop in the bucket compared to a black hole.
If it does, the neutron star will be torn apart and swallowed up inside the black hole, which can swallow up too many things at once and produce gamma rays.
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Black holes will swallow neutron stars. But because neutron stars have too much energy, black holes will also **.
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Summary. Black holes dare to devour neutron stars.
Black holes dare to devour neutron stars.
And black holes don't think, there is nothing that dares to say it.
Neutron stars are already very small, a neutron star greater than the mass of the Sun has a radius of only about 10 kilometers, so its surface gravity is extremely large, the escape speed reaches half the speed of light, and the lack of attack is about 150,000 kilometers per second. But the neutron star is relative to the black hole, and the brother said, and the answer is trivial. Celestial matter before the formation of a black hole has collapsed within its Schwarzschild radius, so the gravitational pull has become very strong, and in its Schwarzschild radius the gravitational force has become infinite, and even the speed of light cannot escape, that is, the escape speed exceeds the speed of light.
So black holes dare to devour neutron stars.
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Summary. 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.
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.
Dear, for you to expand the query: neutron stars are very dense celestial bodies, 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 that can also affect black holes, making it more difficult for them to approach and engulf mesolites. Therefore, when neutron stars and black holes come closer, the force fields between them cancel each other out, making it impossible for the black hole to easily swallow neutron stars.
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Kiss! Hello, happy to answer your <>
Dear, black holes dare not swallow neutron starsReason: When neutron stars and black holes are close enough, the gravitational waves generated by their motion will be very strong, which will make them 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.
The black hole swallows the old god and can't devour the neutron star, and when the two strong meet, both lose, and they can't bear it. The powerful rays and energy of the Waiter Neutron Star can cause the black hole to collapse. Hope mine can help you <>
If you have any other questions, you can ask me again<>
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Summary. Hello dear, according to astronomers, neutron stars actually evolved from stars. At the end of their evolution, a star has a supernova due to the collapse of gravity, and then it is possible that it will become a neutron star.
Neutron stars are very dense, but they cannot evolve into black holes because their mass is not yet at the level of black holes. As a result, this celestial body between a white dwarf star and a black hole has become a unique existence in the universe.
Hello dear, according to astronomers, neutron stars actually evolved from stars. At the end of their evolution, a star has a supernova due to the collapse of gravity, and it is possible that it will become a neutron star. The density of neutron stars is very large, but it cannot evolve into a black hole because its mass is not yet at the level of a black hole.
As a result, this celestial body between a white dwarf and a black hole has become a unique existence in the universe.
The black hole can't swallow the neutron star, and when the two strong meet, both lose, and they can't bear it. The powerful rays and energy of neutron stars can cause black holes to collapse.
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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.
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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.
I'm not sure I understand your question, but you seem to be talking about the overtitle of a neutron star becoming a black hole, specifically an accretion neutron star becoming a black hole or a celestial nucleus. My personal phenomenological understanding is that as the mass of the neutron star increases, until a certain point, the degenerate pressure on the outside of the neutron star cannot resist gravity, causing it to collapse inward. This contraction will cause the degenerate pressure to resist gravity even more, causing the collapse to become more and more severe, and eventually become a black hole. >>>More
Neutron stars, white dwarfs, and black holes are all products of the decay of stars, and they are all compact objects. >>>More
When a star in the universe dies, its remnants are more massive than the mass of the sun (this phenomenon is also known as the Chandrasekhar limit), and the electrons are forced to merge into the nucleus, and then the electrons and protons combine to form a substance called neutrons, and neutron stars are born. Neutron stars are not entirely made up of neutrons. >>>More
When a star ages, its thermonuclear reaction has exhausted the fuel (hydrogen) of the center, and there is not much energy produced by the center. In this way, it no longer has enough strength to carry the enormous weight of the shell. So under the weight of the shell, the core begins to collapse until it finally forms a small, dense star that regains its ability to balance with the pressure. >>>More
A neutron star is close to the Earth, and it will not be absorbed by the Earth. A medium star is a supernova that a star has evolved over a long period of time and finally becomes a supernova, a product of supernova produced after passing through **. Although the neutron star has become smaller in size after supernovae**, its density has increased. >>>More