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 non-conducting disk of radius R is rotating about its own axis with constant angular velocity omega in a perpendicular uniform magnetic field B as shown in figure. The emf induced between centre and rim of disk is

A rod of length 10 cm made up of conducting and non-conducting material (shaded part is non-conducting). The rod is rotated with constant angular velocity 10 rad//s about point O , in constant magnetic field of 2 T as shown in the figure. The induced emf between the point A and B of rod will be:

A conducting rod of length 2l is rotating with constant angular speed w about its perpendicular bisector. A uniform magnetic field B exists parallel to the axis of rotation. The e.m.f. induced between two ends of the rod is

A conducting wheel in which there are four rods of length l is rotating with angular velocity omega in a uniform magnetic field B . The induced potential difference between its centre and rim will be __

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?

When a 'j' shaped conducting rod is rotating in its own plane with constant angular velocity omega about one of its ends P in a uniform magnetic field rarr B ( directed normally into the plane of paper ) the magnitude of emf induced across it will be