A solid cube of side `2a` and mass `M`, sliding on a smooth surface with velocity `v_(0)` , collides inelastically with the raised edge of the table:

A solid cylinder of mass m rolls on a rough surface with velocity v_(0) . It collides elastically with a cubical block of same mass at rest. The centre of mass of both the bodies are at same height. Coefficient of friction between horizontal surface and cylinder as well as horizontal surface and cube is mu . No frictional exists between cylinder and cube. The cylinder collides the, cube at t = 0 , then. Velocity of cylinder with which it will collide with cube again is:

A solid cylinder of mass m rolls on a rough surface with velocity v_(0) . It collides elastically with a cubical block of same mass at rest. The centre of mass of both the bodies are at same height. Coefficient of friction between horizontal surface and cylinder as well as horizontal surface and cube is mu . No frictional exists between cylinder and cube. The cylinder collides the, cube at t = 0 , then. Maximum separation between cylinder before it collide the cube again is:

A solid cylinder of mass m rolls on a rough surface with velocity v_(0) . It collides elastically with a cubical block of same mass at rest. The centre of mass of both the bodies are at same height. Coefficient of friction between horizontal surface and cylinder as well as horizontal surface and cube is mu . No frictional exists between cylinder and cube. The cylinder collides the, cube at t = 0 , then. Velocity of cube when the cylinder starts pure rolling:

A solid cylinder of mass m rolls on a rough surface with velocity v_(0) . It collides elastically with a cubical block of same mass at rest. The centre of mass of both the bodies are at same height. Coefficient of friction between horizontal surface and cylinder as well as horizontal surface and cube is mu . No frictional exists between cylinder and cube. The cylinder collides the, cube at t = 0 , then. Regarding frictional force acting on cylinder we can say that:

A solid cylinder of mass m rolls on a rough surface with velocity v_(0) . It collides elastically with a cubical block of same mass at rest. The centre of mass of both the bodies are at same height. Coefficient of friction between horizontal surface and cylinder as well as horizontal surface and cube is mu . No frictional exists between cylinder and cube. The cylinder collides the, cube at t = 0 , then. Time after which the cylinder starts pure rolling again:

A solid cylinder of mass m rolls on a rough surface with velocity v_(0) . It collides elastically with a cubical block of same mass at rest. The centre of mass of both the bodies are at same height. Coefficient of friction between horizontal surface and cylinder as well as horizontal surface and cube is mu . No frictional exists between cylinder and cube. The cylinder collides the, cube at t = 0 , then. Percentage of energy of cylinder lost due to collision is:

A uniform rod of mass M and length l is placed on a smooth- horizontal surface with its one end pivoted to the surface. A small ball of mass m moving along the surface with a velocity v_(0) , perpendicular to the rod, collides elastically with the free end of the rod. Find: a. the angular velocity of the rod after collision. b. the impulse applied by the pivot on the rod during collision. (Take M//m = 2 )

A body of mass m/2 moving with velocity v_0 collides elastically with another mass of m/3 . Find % change in KE of first body

A solid cube of wood of side 2a and mass M is resting on a horizontal surface as shown in the figure. The cube is free to rotate about the fixed axis AB. A bullet of mass m (ltltM) and speed v is shot horizontally at the face opposite to ABCD at a height 'h' above the surface to impart the cube an angular speed omega_(c) so that the cube just topples over. Then omega_(c) is (note : the moment of inertia of the cube about an axis perpendicular to the face and passing through the center of mass is 2Ma^(3)//3 )