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

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 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 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

The current generator i_g , shown in , sends a constant current I through the circuit. The wire ab has a length l and mass m and can slide on the smooth, horizontal rails connected to l_g . The entire system lies in a vertical magnetic field B. Find velocity of the wire as a function of time.

The current generator i_g , shown in , sends a constant current I through the circuit. The wire ab has a length l and mass m and can slide on the smooth, horizontal rails connected to l_g . The entire system lies in a vertical magnetic field B. Find velocity of the wire as a function of time.

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