What do you mean? "Gravitational pull" and "gravity" is the same thing.
The strength of a black hole's gravity depends on the black hole's mass and how far your reference point is from the center of mass.
black holes are believed to have the strongest gravitational pull. that and beaches at spring break.
If gravitational force is strong enough, light itself is affected by the gravity. The gravitational force of a black hole is so intense that light cannot escape from it. No light, nothing to see. It appears as a "black hole".
No; a black hole has a gravitational force that's so strong that even light cannot escape it.
Yes, there's gravity in a black hole.. gravitational force is exerted wherever there is mass.
No. While the gravity of Jupiter is much stronger than Earth's it is nowhere near as strong as that of a black hole.
No. A black dwarf is dense and has the mass of an entire star, so the gravitational pull would still be quite strong.
Black holes have the strongest gravity of any object.
A black hole doesn't literally suck. A black hole pulls things closer to it. And it does this the same way that we stay on the earth--- gravity. A singularity, a point with mass but no height, width or length is at the center of every black hole. This singularity is what has the gravitational strength to pull everything, even light, towards it. It does it all with an unfathomably strong gravitational pull.
Yes. A typical black hole has a mass similar to that of a large star and so would have the same same gravitational effects on objects in the general vicinity. At close range the gravity becomes extremely strong.
No. You know that the stronger the gravity of a body is, the faster you have to move in order to escape from it. The gravitational field of a black hole is so strong that light can't escape from it. And as you know, light moves at the speed of light.
The whole point of a black hole is that its gravity is so strong that nothing - not even a ray - can escape from its gravitational pull. However, it is theorised that Hawking radiation does escape from the event horizon. Not yet proven (May 2013).