Right.livethere said:It is my understanding of black holes that nothing can escape them because their escape velocity is higher than the speed of light. The place at which the escape velocity becomes higher than the speed of light is known as the event horizon.
Huh? I have no idea what you mean but nothing can escape from inside the EH of a BH.My question is what happens if there is a normal force in the black hole that combats the gravitational potential force? Could something not escape then?
livethere said:It is my understanding of black holes that nothing can escape them because their escape velocity is higher than the speed of light.
livethere said:My question is what happens if there is a normal force in the black hole that combats the gravitational potential force?
Escape velocity is the minimum speed needed for an object to escape the gravitational pull of a massive body, such as a planet or star. It is determined by the mass and radius of the body and is calculated using the equation v = √(2GM/r), where v is the escape velocity, G is the gravitational constant, M is the mass of the body, and r is the distance from the center of the body.
No, once an object crosses the event horizon of a black hole, it is impossible for it to escape. The escape velocity at the event horizon is greater than the speed of light, making it impossible for anything to escape, including light itself.
Escape velocity is the minimum speed needed to escape the gravitational pull of a body, whereas orbital velocity is the speed needed for an object to maintain a stable orbit around a body. Orbital velocity is dependent on the mass of the body and the distance from the center, while escape velocity is only dependent on the mass and radius of the body.
Yes, a rocket can reach escape velocity by achieving a high enough speed. However, this requires a significant amount of fuel and energy, and it is more efficient to use a gravitational slingshot maneuver around a planet or other celestial body to increase the speed and conserve fuel.
No, the escape velocity for an object is dependent on the mass and radius of the body it is trying to escape from. A smaller and less massive body, such as a moon, will have a lower escape velocity compared to a larger and more massive body, like a planet.