A force shown in the `F-x` graph is applied to a `2kg` block horizontal as shown in figure. The change in kinetic energy is

A block of mass m slides along a floor while a force of magnitude F is applied to it at an angle theta as shown in figure. The coefficient of kinetic friction is mur . Then, the block's acceleration 'a' is given by: (g is acceleration due to gravity)

A block of mass 10 kg is placed on a horizontal surface as shown in the figure and a force F = 100 N is applied on the block as shown, in the figure. The block is at rest with respect to ground. If the contact force between block and ground is 25n (in Newton) then value of n is : (Take g = 10 m//s^(2))

Two block of mass 5 kg and 10 kg respectively are connected by a massless string as shown in the figure. The whole system is kept on a frictionless surface. A force of 50 N is applied horizontally as shown in the figure. The tension T in the string will be

Consider the shown arrangement. The coefficient of friction between the two blocks is 0.5 . There is no friction between the 4 kg block and of 12 N is applied on the 2 kg block as shown in the figure, the acceleration of the 4 kg block would be

If the mass of block is 1 kg and a force of 10 / sqrt3 N is applied horizontally on the block as shown in the figure . The frictional force acting on the block is :

A homogeneous block rests against a vertical wall for which the coefficient of friction is 1//2 . A force 'F' is applied to the block in the direction as shown in figure. Find the maximum magnitude of applied force 'F' such that block remains in rest.

A block of mass 2 kg is free to move along the x -axis. It at rest and from t = 0 onwards it is subjected to a time-dependent force F(t) in the x direction. The force F(t) varies with t as shown in the figure. The kinetic energy of the block after 4.5 seconds is