A uniform cube of mass m and edge a moves on a horizontal surface along the positive x-axis, with initial velocity `v_(0)`. Then

A uniform rod of mass m and length L is at rest on a smooth horizontal surface. A ball of mass m, moving with velocity v_0 , hits the rod perpendicularly at its one end and sticks to it. The angular velocity of rod after collision is

In each situation of Table-1, a uniform disc of mass m and radius R rolls on a rough fixed horizontal surface as shown. At, t=0 (initially) the angular velocity of disc is omega_(0) and velocity of centre of mass of disc is v_(0) (in horizontal direction). The relation between v_(0) and omega_(0) for each situation and also initial sense of rotation is given in Table-1 . Then match the statements in Table-1 with the corresponding results in Table-2.

A uniform disc of mass m and radius R is released gentiy on a horizontal rough surface. Such that centre of the disc has velocity V_(0) towards right and angular velocity omega_(0) (anticlockwise) as shown. Disc will certainly come back to its intial position if

In the adjacent figure, a uniform cube of mass m and edge l=2m is lying at rest an a rough horizontal surface. A small ball of mass m hits the cbe at its top edge with horizontal speed v_(0) and sticks to it. Friction is so large that the cube can rotate about the edge 'O' without sliding. Calculate the minimum value of v_(0) ( in m/s) so that the cube will topple. Ignore any loss of energy due to friction at the edge O and take sqrt(2)-1=0.4 .

A uniform circular disc of radius r is placed on a rough horizontal surface and given a linear velocity v_(0) and angular velocity omega_(0) as shown. The disc comes to rest after moving some distance to the right. It follows that

There is a uniform electric field of strength 10^(3)V//m along y -axis. A body of mass 1g and charge 10^(-6)C is projected into the field from origin along the positive x -axis with a velocity 10 m//s . Its speed in m//s after 10 s is (Neglect gravitation)

A cylinder is rolling towards a cube of same mass on rough horizontal surface ( coefficient of friction = mu ) with velocity v_(0) as shown in figure. Assume elastic collision and friction is negligible between cube and cylinder. Then after collision

A block of mass m moves on a horizontal rough surface with initial velocity v . The height of the centre of mass of the block is h from the surface. Consider a point A on the surface.

A small smooth disc of mass m and radius moving with an initial velocity 'v' along the positive x- axis collided with a big disc of mass 2m and radius 2r which was initially at rest with its centre at origin as shown in figure. If the coefficient of restitution is 0 then velocity of larger disc after collision is

A uniform circular disc placed on a horizontal rough surface has initially a velocity v_(0) and an angular velocity omega_(0) as shown in the figure. The disc comes to rest after moving some distance in the direction of motion. Then v_(0)//r omega_(0) is :