A uniform disc shaped pulley is free to rotate about a horizontal axis passing through the centre of the pulley. A light thread is tightly wrapped over it and supports a mass m at one of its end. A small particle of mass `m_(0) = 2m` is stuck at the lowest point of the disc and the system is released from rest. Will the particle of mass `m_(0)` climb to the top of the pulley?

A uniform disc of radius R and mass M is free to rotate about a fixed horizontal axis perpendicular to its plane and passing through its centre. A string is wrapped over its rim and a block of mass m is attached to the free end of the string. The block is released from rest. If string does not slip on the rim then find the acceleration of the block. Neglect the mass of the string.

A uniform disc of mass M and radius R is rotating about a horizontal axis passing through its centre with angular velocity omega . A piece of mass m breaks from the disc and flies off vertically upwards. The angular speed of the disc will be

A metallic pulley is in the shape of a disc of radius a. It can rotate freely about a horizontal axis passing through its centre. The moment of inertia of the pulley about this axis is I. A light string is tightly wrapped around the pulley with its one end connected to a block of mass M. The centre of the pulley and its circumference are connected to a resistance R as shown. The contact of resistance at the circumference does not cause any friction. A uniform magnetic field B is switched on which is parallel to the axis of rotation of the pulley (see Figure). The mass M is allowed to fall. Assume that resistivity of the material of the pulley is negligible. (a) Find the acceleration of the block of mass M at the instant its velocity becomes v_(0) . (b) Assuming that the block can fall through a large distance, calculate the terminal speed (v_(T)) that it will acquire. (c) Find the rate of change of kinetic energy of the pulley at the instant speed of the falling block is (v_(T))/(2) .

A uniform disc of mass m and radius R rotates about a fixed vertical axis passing through its centre with angular velocity omega . A particle of same angular velocity mass m and moving horizontally with velocity 2omegaR towards centre of the disc collides and sticks to its rim. The impulse on the particle due to the disc is

A frictionless pulley has the shape of a uniform solid disc of mass M and radius R . A stone of mass m is attached to a light wire that is wrapped around the rim of the pulley and a system is released from rest. If a stone falls by a distance h , what is the angular speed of pulley at that moment?

A disc of mass m and radius r is free to rotate about its centre as shown in the figure. A string is wrapped over its rim and a block of mass m is attached to the free end of the string. The system is released from rest. The speed of the block as it descends through a height h, is :-

A uniform disc of mass m and radius R rotates about a fixed vertical axis passing through its centre with angular velocity omega . A particle of same mass m and having velocity of 2omegaR towards centre of the disc collides with the disc moving horizontally and sticks to its rim. Then