A body of mass 5 kg moving on a horizontal surface with a velocity of `10 ms^(-1)` comes to rest in 2s. The force required to make this body move with a velocity of `10 ms^(-1)` on the same surface is

A body of mass 2kg moving on a horizontal surface with an initial velocity of 4 ms^(-1) comes to rest after 2 second. If one wants to keep this body moving on the same surface with a velocity of 4 ms^(-1) the force required is

A body of mass 10 kg is moving on a horizonal surface be applying a force of 10 N in the forward direction. The body moves with a constant velocity of 0.2ms^(-1) . Work done by the force of friction in the first 10 seconds is

An object of mass 1 kg moving on a horizontal surface with initial velocity 8 m/s comes to rest after 10 s. If one wants to keep the object moving on the same surface with velocity 8 m/s the force required is

An object of mass 2kg is sliding with a constant velocity of 4ms^(-1) on a frictionless horizontal table. The force required to keep the object moving with the same velocity is

A block moving on a horizontal surface with velocity 20 ms^(-1) comes to rest because of surface friction over a distance of 40 m. Taking g = 10 ms^(-2) , the coefficient of dynamic friction is :

A body of mass 10 kg moves on rough horizontal surface with initial velocity 10m/s and travels 500m before coming to rest. The coefficient of friction is

A ball of mass 0.5 kg is moving with a velocity of 2 ms^(-1) . It if subjected to a force of x Newton for 2s. Because of this force, the ball moves with a velocity of 3ms^(-1) . The value of x is :

A body of mass 10 kg initially at rest acquires velocity 10 ms^(-1) . What is the work done ?

A body of mass 1 kg is rotated in a horizontal circle of radius 1 m and moves with velocity 2 ms^(-1) The work done in 10 revolutions is

A 4 kg mass is resting on a horizontal surface. For this surface mu_s = 0.6 & mu_(k) = 0.2 . Force required to move the body with 5ms^(-2) acceleration is (g = 10ms^(-2) )