A bead of mass m and diameter d is sliding back and forth with velocity v on a wire held between two right walls of length L. Assume that th ecollisions with the wall are perfectly elastic and ther is no friction. The average force that the bouncing bead exerts on the one of the walls is :_

A sphere of mass m slides with velocity v on as frictionless surface towards a smooth inclined wall as shown in figure. If the collision with the wall is perfectly elastic find a. the impulse imparted by the wall on the sphere b the impulse imparted by the floor on the sphere.

A parallel beam of particles of mass m moving with velocity v impinges on a wall at an angle theta to its normal. The number of particles per unit volume in the beam is n . If the collision of particles with the wall is elastic, then the pressure exerted by this beam on the wall is

A super-ball of mass m is to bounce elastically back and forth between two rigid walls at a distance d from each other. Neglecting gravity and assuming the velocity of super-ball to be v_(0) horizontally, the average force being exerted by the super-ball on each wall is

A ball of mass 0.5 kg moving with a velocity of 2 m//s strikes a wall normally and bounces back with the same speed . If the time of contact between the ball and the wall is 1 millisecond , the average force exerted by the wall on the ball is

A ball of mass 0.5 kg moving with a velocity of 2 m//s strikes a wall normally and bounces back with the same speed . If the time of contact between the ball and the wall is 1 millisecond , the average force exerted by the wall on the ball is

The Fig. shows a string of equally placed beads of mass m , separated by distance d . The beads are free to slide without friction on a thin wire. A constant force F act on the first bead initially at rest till it makes collision with the second bead. The second bead then collides with the third and so on. Supposed that all collisions are elastic,

A nozzle throws a stream of gas against a wall with a velocity v much larger than the thermal agitation of the molecules. After collision of the molecules with wall the magnitude of their velocity remains same. Also assume that the force exerted on the wall by the molecule is perpendicular to wall. (This is not strictly true for a rough wall.) Find the pressure exerted on the wall. (n = number of molecules per unit volume, m = mass of a gas molecule)

A horizontal frictionless rod is threaded through a bead of mass m . The length of the cart is L and the radius of the bead, r , is very small in comparison with L(r lt lt L) . Initially at ( t = 0 ) the bead is at the right edge of the cart. The can is struck and as a result, it moves with velocity v_(0) towards right. When the bead collides with the cart's walls, the collisions are always completely elastic. The first collision takes place at time ti and the second collision takes place at time t_(2) . Find t_(2)-t_(1)

A small ball is projected at an angle alpha with an initial velocity u between two vertical walls such that in the absence of the wall its range would have been 5d . Given that all the collisions are perfectly elastic and distance between the walls be d/2 , find. (a) maximum height atained by the ball. (b) total number of collisions with the walls before the ball comes back to the ground, and (c) point at which the ball finally falls. The walls are supposed to be very tall.

Two large rigid vertical walls A and B are parallel to each other and separated by 10m . A particle of mass 10g is projected with an initial velocity of 20m//s at 45^@ to the horizontal from point P on the ground, such that AP=5m . The plane of motion of the particle is vertical and perpendicular to the walls. Assuming that all the collisions are perfectly elastic, find the maximum height attained by the particle and the total number of collisions suffered by the particle with the walls before it hits ground. Take g=10m//s^2 .