The moment of inertia of a body moving with angular velocity `omega` decreases from `l` to `(l)/(3)` without any external torque. Calculate the new angular velocity of the body.

A flywheel having moment of inertia 20kgm^(2) rotates about its axis with an angular velocity of 100rads^(-1) . If the moment of inertia of the flywheel is reduced to 10kgm^(2) without applying external torque, calculate the new angular velocity of the Flywheel.

What is the torque acting on a body moving with constant angular velocity ?

If the resultant external torque acting on a body is zero, then angular momentum of the body

The moment of inertia of a rigid body in terms of its angular momentum L and kinetic energy K is

Two points of a rigid body are moving as shown. The angular velocity of the body is : .

The moment of an inertia about an axis of a body which is rotating with angular velocity "1rad s"^(-1) is numerically equal to

The moment of inertia (I) and the angular momentum (L) are related by the expression

If no external torque acts on a body, will its angular velocity remain conserved ?

An ice skater having moment of inertia l rotating with angular speed omega suddenly opens her arms, which reduces her angular velocity to (omega)/(4) . Calculate the change in moment of inertia of the dancer.