A particle of mass m=0.1 kg is released from.rest from a point A of a wedge of mass M=2.4kg . The wedge is free to slide on a frictionless horizontal plane. The particle slides down the smooth face A B of the wedge. When the velocity of the wedge is 0.2 m / s , the velocity (in m / s ) of the particle relative to the wedge is '(##CEN_KSR_PHY_JEE_C08_E01_013_Q08##)'

A block of mass m is placed at rest on a smooth wedge of mass M placed at rest on a smooth horizontal surface. As the system is released

A particle of mass m strikes normally to a stationary wedge of mass 5m kept on the smooth horizontal surface as shown.If the particle sticks to the wedge then loss in kinetic energy of the system during collision is?

A wedge of mass M rests with one face in contact with horizontal , smooth surface . A particle of mass m is placed on the smooth face on it , inclined at an angle alpha to the horizontal and released . Find the velocity of the wedge and that of the particle relative to the wedge when the particle has slipped a distance x down the face of the wedge . Also calculate the acceleration of the wedge and that of the particle relative to the wedge and the smooth surface . [Hint : Apply principal of conservation of momentum along the horizontal and energy conservation principle . See Example 8 )

A particle of mass m is placed at rest on the top of a smooth wedge of mass M, which in turn is placed at rest on a smooth horizontal surface as shown in figure. Then the distance moved by the wedge as the particle reaches the foot of the wedge is :

A block of mass 2kg slides down the face of a smooth 45^@ wedge of mass 9 kg as shown in the figure. The wedge is placed on a frictionless horizontal surface. Determine the acceleration of the wedge.

A small block of mass m_(1) is released from rest at the top of a curve-shaped, frictionless wedge of mass m_(2) which sits on a frictionless horizontal surface as shown. When the block leaves the wedge its velocity is measured to be 4.00 m/s to the right as shown in the figure. if the mass of the block is doubled to becomes 2m_(1) , what can be said about the speed with which it leaves the wedge ?