Monday, 13 February 2017

Black hole gravitational pull

Does a black hole have a very strong gravitational pull? What is the gravity of black holes? Are black holes really holes? Black holes may solve some of the mysteries of the universe. Yet we know that black holes exist.


We know how they are born, where they occur, and why they exist in different sizes.

The ESCAPE VELOCITY is greater than SPEED OF LIGHT. Do all black holes have the same gravitational pull yes or no, and if not, is it possible that if space and time bends on itself and connects two black holes that the one with the strongest pull will continue as a black hole and the weakest will turn into a white hole considering the amount of matter that is being pulled out by the stronger black hole ? In actuality nothing is known about the insides of a black hole. But in theory, at the center of a black hole is a region of infinite density and very strong gravitational pull that it breaks down. The gravity of the black hole is completely confined to the surface tension feature of the singularity.


A black hole does not have a gravitational pull. The singularity displacement rips phase space causing an accretion disk pushing things in. Is the gravitational pull of a black hole.

A Black Hole is an object for which nothing can get a high enough escape velocity to get away from it. Think of a cannonball being fired straight up in the air. As it goes up it will be slowed down by gravity and come crashing back down. If the speed is high enough however it will keep going until it escapes the gravitational pull.


Suction is caused by pulling something into a vacuum, which the massive black hole definitely is not. Instea objects fall into them just as they fall toward anything that exerts gravity , like the. If its mass collapses into an infinitely small point, a black hole is born. Packing all of that bulk—many times the mass of our own sun—into such a tiny point gives black holes their powerful.


So much so that when they are compressed in the same way, they are still very large. So around one light year diameter black holes have gravity just like the surface of earth at the event horizon. The entire milky way compressed into a black hole would have radius 0. Just remember that a black hole is any amount of matter squeezed into a very, very dense package. But, the gravitational pull of a black hole , or anything else for that matter, depends only on mass and distance, not how large or small the object is. Earth would then be a black hole ! This means the entire energy of the photon is used to escape the gravitational pull of the black hole.


If the photon comes from the annihilation of a particle of mass m near the horizon, then it means the entire mass of the particle is used to make the photon escape from the black hole. The gravitational “pull”, or ‘force’, of the black hole on an object will scale with the distance from the singularity, just as with any other massive object. More accurately, you could say that spacetime is less distorted further from the singularity.

If a small black hole passes between us and a distant star, the light from the star would be gravitationally deflected by the black hole , causing the star to appear momentarily brighter. The core succumbs to its own gravitational pull and collapses into itself, in extreme cases forming a black hole. Theoretically, if you shrank any mass down into a certain amount of space, it could.


The force of gravity is so high in Black Holes that it leads to gravitational time dilation. This is a phenomenon where time slows down because of gravitational pull. Interesting fact is that time dilation can also occur when velocity increases. This is known as velocity time dilation and is generally experienced by astronauts.


As a result, they have an extremely strong gravitational pull. This is because a black hole is the product of mass being squeezed together so densely, and so tightly, that it creates a gravitational pull that is so strong, that not even light can escape its. If you stand beside a massive object (planet, star, black hole or anything else with mass) you will feel a gravitational pull , and unless you do something about it you will start to accelerate towards the object.


The black hole has greater pull. But it has the same mass, so how does its gravitational field strength increase? With vision that spans the ultraviolet through visible and into the near infrare Hubble investigates everything from black holes to planets around other.

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