A conductor of length `l` and mass `m` can slide without any friction along the two vertical conductors connected at the top through a capacitor. A uniform magnetic field `B` is set up `_|_` to the plane of paper. The acceleration of the conductor

A conducting wire xy of lentgh l and mass m is sliding without friction on vertical conduction rails ab and cd as shown in figure. A uniform magnetic field B exists perpendicular to the plane of the rails, x moves with a constant velocity of

A conducting wire xy of lentgh l and mass m is sliding without friction on vertical conduction rails ab and cd as shown in figure. A uniform magnetic field B exists perpendicular to the plane of the rails, x moves with a constant velocity of

A conductor of length I and mass m can slide without friction, but with an ideal electrical contact, along two vertical conductors AB and CD connected through a capacitor (Fig. 30.2). Perpendicular to the plane of the figure a uniform magnetic held of induction B is set up. Find the voltage across the capacilor plates as a function of h.

A conducting wire of length l and mass m can slide without friction on two parallel rails and is connected to capacitance C . Whole system lies in a magnetic field B and a constant force F is applied to the rod. Then

A conducting wire of length l and mass m can slide without friction on two parallel rails and is connected to capacitance C . The whole system lies in amagnetic field B and a constant force F is applied to the rod . Then

Two metal bars are fixed vertically and are connected on the top by a capacitor C . A sliding conductor of length land mass m slides with its ends in contact with the bars. The arrangement is placed in a uniform horizontal magnetic field directed normal to the plane of the figure. The conductor is released from rest. Find the displacement x(t) of the conductor as a function of time t.

A wire cd of length l and mass m is sliding without friction on conducting rails ax and by as shown. The verticle rails are connected to each other with a resistance R between a and b . A uniform magnetic field B is applied perpendicular to the plane abcd such that cd moves with a constant velocity of

A loop is formed by two parallel conductors connected by a solenoid with inductance L=2H and a conducting rod of mass m=80g, which can freely (without fricition) slide over the conductors. The conductors are located in a horizontal plane in a uniform vertical magnetic field with induction B=4T. The distance between the conductors is equal to l=4cm. At the moment t=0 the rod is imparted an initial velocity v_(0)=2 cm//s directed to the right. Find the amplitude (in cm) for the oscillations of conducting rod, if the electric resistance of the loop is negligible.

Two parallel long straight conductors lie on a smooth plane surface. Two other parallel conductors rest on them at right angle so as to form a square of side a. A uniform magnetic field B exists at right angle to the plane containing the conductors. Now, conductors starts moving outward witha constant velocity v_0 at t=0 . Then, induced current in the loop at any time is (lamda is resistance per unit length of the conductors)

A copper wire ab of length l , resistance r and mass m starts sliding at t=0 down a smooth, vertical, thick pair of connected condcuting rails as shown in figure.A uniform magnetic field B exists in the space in a direction perpendicular to the plane of the rails which options are correct.