The kinetic energy of a uniform rod of mass m rotating with constant angular velocit `omega` about one of its end which is fixed as shown in figure is `(momega^(2)l^(2))/(N)` find N

A conducting rod of length l is rotating with constant angular velocity omega about point O in a uniform magnetic field B as shown in the figure . What is the emf induced between ends P and Q ?

A thin uniform copper rod length l and mass m rotates unifomly with an angular velocity omega about a vertical axis passing through one of its ends as shown in the figure. Young's modulus of copper is Y. Breaking stress is sigma_(max) , cross sectional area of rod is A and density of rod is uniform. Based on above information, answer the following questions The maximum angular velocity with which the rod can rotate so that is won't break, is

For an L shaped conducting rod placed in an uniform magnetic field vecB rotating with constant angular velocity omega about an axis passing through one of its ends A and normal to the plane of the conductor induced emf

A rod is rotating with a constant angular velocity omega about point O (its centre) in a magnetic field B as shown. Which of the folloiwng figure correctly shows the distribution of charge inside the rod?

A uniform rod of length l is rotating with constant angular speed omega as shown in figure. Choose the graph which correctly shows the variation of T with x .

A uniform rod of mass m and length l_(0) is rotating with a constant angular speed omega about a vertical axis passing through its point of suspension. Find the moment of inertia of the rod about the axis of rotation if it make an angle theta to the vertical (axis of rotation).

A rod of length l is rotating with an angular speed omega about one of its ends which is at a distance a from an infinitely lonf wire carrying current i . Find the emf induced in the rod at the instant shown in .

A rod of length l is rotating with an angular speed omega about one of its ends which is at a distance a from an infinitely long wire carrying current i . Find the emf induecd in the rod at the instanr shown in .

A rod of length l is rotating with an angular speed omega about one of its ends which is at a distance a from an infinitely long wire carrying current i . Find the emf induced in the rod at the instant shown in .

A uniform rod is hinged at its one end and is allowed to rotate in verticle plANE. Rod is given angular velocity omega in its verticle position as shown in figure. The value of omega for the force exerted by the hinge on rod is zero in this position is