A spherical planet far out in space has a mass `M_0` and diameter `D_0`. A particle of mass m falling freely near the surface of this planet will experience an acceleration due to gravity which is equal to

A spherical planet far out in space has a mass M_(0) and diameter D_(0) . A particle of mass m falling freely near the surface of this planet will experience an accelertion due to gravity which is equal to

A spherical planet far out in space has a mass M_(0) and diameter D_(0) . A particle of mass m falling freely near the surface of this planet will experience an accelertion due to gravity which is equal to

A spherical planet far out in space has a mass M_(0) and diameter D_(0) . A particle of mass m falling freely near the surface of this planet will experience an accelertion due to gravity which is equal to

The mass and diameter of a planet have twice the value of the corresponding parameters of earth. Acceleration due to gravity on the surface of the planet is

The mass of a planet is (1//10)^("th") that of earth and its diameter is half that of earth the acceleration due to gravity is

A uniform spherical planet · (Radius R) has acceleration due to gravity at its surface as g. Points P and Q located inside and outside the planet respectively have acceleration due to gravity g/4 . Maximum possible separation 4 between P and Q is,

Two particles of equal mass m and charge q are placed at a distance of 16 cm. they do not experience any force. The value of q/m is

A simple pendulum of length 'L' has mass 'M' and it oscillates freely with amplitude energy is (g = acceleration due to gravity)

Consider a spherical planet which is rotating about its axis such that the speed of a point on its equator is 'v' and the effective acceleration due to gravity on the equator is 1/3 of its value at the poles. What is the escape velocity for the particle at the pole of this planet?

The energy required to move a body of mass 10 kg from the ground to 5 m is 490 J. Find the acceleration due to gravity on the body.