The greater the mass of the planet, the greater will be the escape velocity.
the greater the mass, the greater will be the inertia produced in the body when the force is applied on it.
The factors affecting kinetic energy are mass and velocity.
Anything within the Schwarzschild radius can't escape from the black hole, even at the speed of light.Anything within the Schwarzschild radius can't escape from the black hole, even at the speed of light.Anything within the Schwarzschild radius can't escape from the black hole, even at the speed of light.Anything within the Schwarzschild radius can't escape from the black hole, even at the speed of light.
Gravity is not a 'wave', it is a field of curvature of space-time caused by objects with mass. A black hole contains the mass of a star, compressed to the space of a single atom (a singularity), the compression of so much mass into such a small space, is why the black hole has such a powerful gravitational pull.
Mass= mass of electron Speed= Almost equal to that of light
The Schwarzschild radius is a concept related to black holes. Given a body it is the radius such that, if all the mass of the body were squeezed (uniformly) within that sphere, then the escape velocity at the surface of the velocity would be equal to the speed of light.
What energy is related to the mass and speed of an object
No, a body's inertia is related to its mass and movement. Weight is related to a body's mass in a gravity field without movement.
The earth's escape velocity, which is the speed necessary to overcome gravity and achieve either orbit or escape, is about 25,000 miles per hour (or about 7 miles per second). From a physics standpoint, it's the speed at which a rocket's kinetic energy plus its gravitational potential energy is zero. Every celestial body has a different escape velocity, depending upon its mass.
How the acceleration of a body related to its mass and the resultant force acting on it?
Inertia is matter's unwillingness to slow down, speed up, or change direction in any way. It is also related to the matter's momentum. Momentum is caused by the body's velocity as well as the body's direction. If the velocity of the matter is increasing, or the body changes its direction, it can be said that the body of mass is experiencing inertia. When the body is accelerating (changing in velocity), the momentum of the matter is also changing (F=ma), thus mass and acceleration is related by momentum through inertia.
Very, very basically, momentum is a combination of speed and mass of the object.
According to Einstein's famous equation, it is related to mass and the speed of light (in vacuum).
The mass of a body increases as its speed increases. A body that has any masswhen it's not traveling at the speed of light would have infinite mass when it istraveling at that speed. So its kinetic energy would be infinite, and anything it hit ...whether a bird, a plane, the Earth, or a star ... would be totally blasted to smithereensthat were too small to detect.Fortunately, a body that has any mass when it's not traveling at the speed oflight can never travel at that speed.
The only thing that travels at the speed of light, is light. Light is also said to have no mass, therefore the only way for something to travel at the speed of light is for it to have no mass.
Not at all. It would take an infinitely large mass to produce an infinite escape velocity, and no such infinite mass exists. Furthermore, the escape velocity for any object is the same no matter what is trying to escape, so light does not have its own escape velocity. This question presumably concerns black holes. Light does not escape from black holes because the escape velocity is greater than the speed of light. The speed of light is not infinite, it is 300,000 kilometers per second.
Kinetic energy is the energy of movement. It is related to an object's mass, and to its speed.