If a star is large enough, it can collapse on its own to form a black hole. But if the star is very big, but not big enough to become a black hole, it will tend to explode into a supernova, eventually turning into a neutron star.
A black hole is not much different from any other mass in the universe.
A black hole is not much different from any other mass in the universe.
Dark neutron stars are A mysterious and dark object has appeared at the edge of our solar system. Looks like the remains of a dying star. It’s not a black hole, but it behaves like a black hole.
A black hole is not much different from any other mass in the universe. Except it’s a dense matter entity. All the matter it contains is compressed into a point called a singularity, so small and dense that our understanding of the time and space it contains is disrupted.
This singularity is why black holes have such great gravity. to neutron stars. They form when a massive star collapses at the end of its life. Normally, these stars are 1.5 times more massive than our Sun but only about 20 km wide.
however these a dark neutron star is too massive to be an ordinary neutron starBut too small to be a standard black hole. At present, we do not have much information about these entities.
Dark neutron stars are too massive to be ordinary neutron stars
The dark neutron star is too massive to be an ordinary neutron star.
Imagine that the best scientists on the planet have developed a way to scan the surroundings of our planet very quickly. And now you will take a closer look at these fascinating entities. You will know exactly where a dark neutron star is.
You will then risk finding yourself in the center, what will happen? This mission will require special protective equipment. And this device will have to protect you from one of the strongest gravities in the universe. This dark neutron star will pull you towards it with a gravitational pull about two billion times stronger than the gravity you are used to on Earth.
The problem is the type high strength gravity protection device you need has not appeared at this time. Without it, your mission would be like suicide. As you get closer to a dark neutron star, different parts of your body will experience different gravity. If you rush directly at this monstrous entity, your upper body will be much more stretched than your legs. As you approach its center, your body stretches out like spaghetti noodles.
Externally, a dark neutron star looks like any other type of star.
From the outside, a dark neutron star looks like any other type of star.
What if NASA’s top scientists could provide you with a suit against the extreme pressures, heat, and radioactive materials inside a dark neutron star? Your task will become easier. You will pass through the layers of an object of astonishing mass.
Externally, a dark neutron star looks like any other type of star. Ordinary neutron stars will have extremely high temperatures, usually around a million degrees Celsius. What about a dark neutron star? You’ll probably have to figure it out on your own, as astronomers still don’t have any information, but there’s probably a very high temperature too.
First, you will pass through a layer of hydrogen and helium gas. Then you will move on to the next layer of the star. Scientists say This second layer may consist of iron and silicon. To continue your quest, you must somehow break through this solid, fiery surface.
Things will start to get dangerously dense. At the center of the Dark Neutron Star, you will notice unique matter, perhaps one of the strangest in the universe. Inside a neutron star, the clusters of nuclei are so dense that they produce the hardest material known.
You will now be so deep that the strong pressure around you will be about three times the density of the nucleus of an atom. Protons and electrons will combine to form neutrons. As these newly formed neutrons begin to overlap more and more, you will continue to move further and further apart. Eventually, you will come across neutron and proton components compressed by quarks. When you finally approach the core of the dark neutron star, you will be close to reaching the maximum degree of eccentricity.
If a star is big enough, it can collapse on its own to form a black hole.
If a star is massive enough, it can collapse on its own to form a black hole.
Of all the weak quarks around you, some are so strange that even scientists call them. “strange quark”. These quarks are heavier than other quarks and get their name from their property known as strangeness. All of this means that strange quarks are less likely to be destroyed by the dark neutron star’s electromagnetism.
Inside this nucleus, the strange quarks will form a dense mixture called simply . foreign matter. Foreign bodies are contagious. This means that when it comes into contact with ordinary matter, like you, it will produce more foreign matter.
So as soon as you touch it, it will immediately disintegrate your protective suit and soon your whole body.
If a star is massive enough, it can collapse on its own to form a black hole. But if a star is still very big, but not big enough to become a black hole, it will tend to explode into a supernova, eventually turning into a neutron star.
What has long puzzled scientists is that the smallest black holes have at least 5 times the mass of the Sun, while neutron stars have at most 1.5 times the mass of the Sun. And the space between these borders is called “mass distance” – a mysterious range between the masses of a black hole and a neutron star – “dark neutron star”.
Article source: PNVN
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If a star is just big enough, it can collapse on its own to form a black hole. But if that star is huge, but not big enough to become a black hole, it will explode…
