A conducting rod is moved with a constant velocity v in a magnetic field. A potential difference appears across the two ends

A rod AB moves with a uniform velocity v in a uniform magnetic field as shown in figure

A circular loop of radius r moves with a constant velocity v in a region with uniform magnetic field B . Calculate the potential difference between two points (A, B) , (C, D) , and (E, F) located on the loop.

If an electron is moving with velocity v produces a magnetic field vecB , then

A conducing rod of length l is falling with a velocity v perpendicular to a unifrorm horizontal magnetic field B . The potential difference between its two ends will be

A conducting rod of resistance r moves uniformly with a constant speed v in a uniform magnetic field. If the rod keeps moving uniformly, then the amount of force required is

A small conducting rod of length l, moves with a uniform velocity v in a uniform magnetic field B as shown in fig __ A. Then the end X of the rod become positively charged B. The end Y of the rod become positively charged C. The entire rod is unevenly charged D. The rod become hot due to joule heating

A long conducting wire AH is moved over a conducting triangular wire CDE with a constant velocity v in a uniform magnetic field vec(B) directed into the plane of the paper. Resistance per unit length of each wire is rho . Then

A metallic conductor of irregular cross-section is as shown in the figure. A constant potential difference is applied across the ends (1) and (2). Then :

A small conducting rod of length l, moves with a uniform velocity v in a uniform magnetic field B as shown in fig __

In the figure shown a T-shaped conductor moves with constant angular velocity omega in a plane perpendicular to uniform magnetic field B. The potential difference V_A-V_B is