A conducting wire of length 30 cm revolves 1000 times per minute about one of its ends and perpendicular to the direction of a magnetic field of 0.5 T. Determine the emf induced across the ends of the wire.

A conducting loop in the form of a circle is placed in a uniform magnetic field with its plane perpendicular to the direction of the field. An emf will be induced in the loop if

A straight conductor of length 50 cm is moving with a velocity 5 m. s^(-1) in a magnetic field of strength 2T in a direction perpendicular to the field. What is the emf (in V) induced between the two ends of the conductor?

A conducting wire is bent in the form of an angle theta . The wire moves with velocity v along the bisector of angleA'OB' as shown in figure. Find the emf induced between the two ends of the wire if a magnetic field is acting perpendicular to the plane of the paper and directed into it.

A metal rod of length 1 m is rotated about one of its ends in a plane at right angles to a uniform magnetic field of 2.5xx10^(-3)(Wb)/m^2 . If itmakes 30rps, calculate the induced emf between its ends.

A rod of length l is moved horizontally with a uniform velocity v in a direction perpendicular to its length through a region in which a uniform magnetic field is acting vertically downward. Derive an expression for the emf induced across the ends of the rod.

The induced emf between the two ends of a straight conductor moving perpendicular to its axis in a uniform magnetic field is

A straight conductor of length 10 cm is rotating in a vertical plane with one of its ends fixed. The angular velocity is 10 rad . s^(-1) . What is the value of emf (in muV ) induced between the two ends of the conductor if the horizontal component of earth's magnetic field at the place is 10^(-4)T ?

A conducting rod of length L with one end pivoted is rotated with a uniform angular speed omega in a vertical plane, normal to a uniform magnetic field B. Deduce an expression for the emf induced in this rod.

A conducting wire of length l is rotating with angular velocity w in a magnetic field B perpendicular to it. Prove that the induced e.m.f. at the two ends of the conducting wire is e = 1/2 Bwl^2 .