Shows a copper rod moving with velocity `v` parallel to a long straight wire carrying current `= 100 A`. Calculate the induced emf in the rod, where `v = 5 m S^(-1)`, `a = 1 cm` , `b = 100cm`.

A uniform metal rod is moving with a uniform velocity v parallel to a long straight wire carrying a current I. The rod is perpendicular to the wire with its ends at distance r_(1) and r_(2) (with r_(2) gt r_(1) ) form it. The E.M.F. induced in the rod at that instant is

An electron is moving with the velocity of 10^(7)m/s , parallel to a straight wire, carrying a current of 10 A. What is the force acting on the electron, if the electron is at a distance of 4 cm from the wire ?

A copper rod of length 0.19m is moving with uniform velocity 10ms^(-1) parallel to a long straight wire carrying a current of 5.0A . The rod is perpendicular to the wire with its ends at distances 0.01 and 0.2m from it. Calculate the emf induced in the rod.

If a long straight wire carries a current of 40 A, then the magnitude of the field B at a point 15 cm away from the wire is

A copper rod moves with a constant angular velocity omega about a long straight wire carrying a current I. If the ends of the rod from the wire are at distances a and b, then the e.m.f induced in the rod is

A cionducing rod moves with constant velocity v perpendicular to the straight wire carrying a current I as shown compute that the emf generated between the ends of the rod

A copper rod of length L is moving at a uniform speed v parallel to along straight wire carrying a current of I as shown in figure-5.25. The rod is perpendicular to the wire with its ends at distance a and b from if . Calculate the motional EMF induced in the rod.

In the figure shown AB is a plastic rod moving with a constant velocity v , W is an infinite long wire carrying current I . The end of the rod which is at higher potential is

Shows an irregular shaped wire AB moving with velocity v . Find the emf induced in the wire.