A conducting rod of mass `50 gm` and length `10 cm` can slide without friction on two long, horizontal rails. A uniform magnetic field of magnitude `5 mT` exists in the region as shown. A source `S` is used to maintain a constant current `2 A` through the rod. If motion of the rod starts from the rest, its speed after `10 s` from the start of the motion will be

A conducting rod of mass 200 gm and length 10 cm can slide without friction on two long, horizontal rails. A uniform magnetic field of magnitude 5 m T exists in the region as shown. A source S is used to maintain a constant current 2 A through the rod. If motion of the rod starts from the rest, find its speed (in cm/s) after 10 s from the start of the motion

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 20 cm long conducting rod is set into pure translation with a uniform velocity of 10cm s ^(-1) perpendicuarl to its length. A uniform magnetic field jof magnitude 0.10 T exissts in a direction perpendicuarl to the plane of motion.

A conducting rod of 1m length rotating with a frequency of 50 rev/sec. about its one of end inside the uniform magnetic field of 6.28 mT. The valu of induced emf between end of rod is :-

An iron rod of mass 50 g and length 50 cm is suspended by master wires as shown in the figure. Calculate the magnitude and direction of magnetic field to be set in the region such that the tension is the wires is zero. The current in the rod is 4 A.

Two long parallel horizontal rails a, a distance d aprt and each having a risistance lambda per unit length are joing at one end by a resistance R. A perfectly conduction rod MN of mass m is free to slide along the rails without friction (see figure). There is a uniform magnetic field of induction B normal to the plane of the paper and directed into the paper. A variable force F is applied to the rod MN such that, as the rod moves a constant current flows through R. (i) Find the velocity of the rod and the applied force F as function of the distance x of the rod from R. (ii) What fraction of the work done per second by F is converted into heat?