Figure shows loop of 200 turns and side a=3m and resistance of one coil `R=1000 Omega`. The work done in pulling the loop out of the field, slowly and uniformly in 1.0 s is

Figure shows a square loop 100 turns as area of 2.5 xx 10^(-3) m^(2) and a resistance of 100 Omega . The magnetic field has a magnitude B = 0.40 T . The work done in pulling the loop out of the field slowly and uniformly in 1.0 "s is n" xx 10^(-6) then n is

A conducting square loop of side 10 cm is placed in a region of uniform magnetic field 0.5 T as shown in the figure. Calculate the work done in slowly moving the loop out of the field in 2 seconds with a speed of 0.05 m s^(-1) . The resistance of loop is 10 Omega .

A closed circular loop of 200 turns of mean diameter 50 cm & having a total resistance of 10 Omega is placed with its plane at right angle to a magnetic field of strength 10^(-2) Tesla.Calculate the quantity of electric charge passed through it when the coil is turned through 180^(@) about an axis in its plane.

A square loop of side 20 cm and resistance 1 Omega is moved towards right with a constant speed v_0 . The right arm of the loop is in a uniform magnetic field of 5 T. The field is perpendicular to the plane of the loop and is going into it. The loop is connected to a network of resistors each of value 4 Omega. What should be the value of v_0 so that a steady current of 2 mA flows in the loop ?

A square loop of side a and resistance R is moved in the region of uniform magnetic field B(loop remaining completely insidefield), with a velocity v through a distance x. The work done is:

A uniform circular loop of radius a and resistance R palced perpendicular to a uniform magnetic field B . One half of the loop is rotated about the diameter with angular velocity omega as shown in Fig. Then, the current in the loop is

A square loop of side a and resistance B is moved in the region of uniform magnetic field B (loop remaining completely inside field), with a velocity v through a distance x. The work done is