A loop shown in the figure is immersed in the varying magnetic field `B=B_0t`, directed into the page. If the total resistance of the loop is `R`, then the direction and magnitude of induced current in the inner circle is

A wire is bent in the form of a square of side .a. in a varying magnetic field vecB ='alpha'B_0 t hat k . If the resistance per unit length is lamda , then find the following. (i) The direction of induced current (ii) The current in the loop (iii) Potential difference between P and Q

A wire is bent in the form of a square of side a in a varying magnetic field vec(B)= prop B_(0) t hat(k) . If the resistance per unit length is lamda , then find the following (i) The direction of induced current (ii) The current in the loop (iii) Potential difference between P and Q

A wire is bent in the form of a square of side la in a varying magnetic field B= prop B_(0)t hatk . If the resistance per unit length is lambda . then find the following: (i) The direction of induced current (ii) The current in the loop (iii) Potential difference between P and Q

Figure shows planar loops of different shapes moving out of or into a region of a magnetic field which is directed normal to the plane of the loop away from the reader. Determine the direction of induced current in each loop using Lenz's law.

Current in a long current carrying wire is I=2t A conducting loop is placed to the right of this wire. Find a. magnetic flux phi_B passing through the loop. b. induced emf|e| prodced in the loop. c. if total resistance of the loop is R , then find induced current I_("in") in the loop.

A constant current I flows through a long straight wire as shown in figure. A square loop starts moving towards righ with as constant speed v . a Find induced emf produced i the loop as a function x b. If total resistance of the loop is R , then find induced current in the loop,

A closed loop with the geometry shown in Fig. 3.9 is placed in a uniform magnetic field direction into the plane of the paper. If the magnetic field decreases with time, determine the direction of the induced emf in this loop.

The magnetic field B shown in is directed into the plane of the paper. ACDA is a semicircular conducting loop of radius r with the centre at O. The loop is now made ot rotate clockwise with a constant angular velocity omega about on axis passing through O and perpendicular to the plane of the paper. The resistance of the loop is R. Obtain an expression for the magnitude of the induced current in the loop. Plot a graph between the induced current i and omegat , for two periods of rotation.

A triangular loop as shown in the figure is started to being pulled out at t=0 form a uniform magnetic field with a constant velocity v. Total resistancee of the loop is constant and equal to R. Then the variation of power produced in the loop with time will be :

An equilateral triangular loop ADC having some resistance is pulled with a constant velocity v out of a uniform magnetic field directed in to the paper. At time t = 0 , side DC of the loop at is at edge of the magnetic field. The induced current (i) versus time (t) graph will be as