A square conductind loop, `20.0 cm` on a side placed in the same magnetic field as shown in Fig. 3.195, center of the magnetic field region, where `dB//dt = 0.035 T s^(-1)`.

he direction of induced electric field at points a, b and c:

A square conductind loop, 20.0 cm on a side placed in the same magnetic field as shown in Fig. 3.195, center of the magnetic field region, where dB//dt = 0.035 T s^(-1) . The potential difference between points a and b is

A square conductind loop, 20.0 cm on a side placed in the same magnetic field as shown in Fig. 3.195, center of the magnetic field region, where dB//dt = 0.035 T s^(-1) . The current induced in the loop if its resistance is 2.00 Omega is

A square non - conducting loop , 20 cm , on a side is placed in a magnetic field . The centre of side AB coincides with the centre of magnetic field . The magnetic field is increasing at the rate 2 T /s . The potential difference betweeen B and C is :

A square loop of side 5 cm enters a magnetic field with 1cms^(-1) . The front edge enters the magnetic emf?

A triangular loop is placed in a dot o. magnetic field as shown in figure. Find the direction of induced current in the loop if magnetic field is increasing.

A circular coil of wire consists of exactly 100 turns with a total resistance 0.20 Omega . The area of the coil is 100 cm^(2) . The coil is kept in a uniform magnetic field B as shown in Fig. 3.212. The magnetic field is increased at a constant rate of 2 Ts^(-1) . Find the induced current in the coil in A .

A current of 2*00 A exists in a square loop of edge 10*0 cm . Find the magnetic field B at the centre of the square 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.

A current carrying loop is placed in the non-uniform magnetic field whose variation in space is shown in fig. Direction of magnetic field is into the plane of paper. The magnetic force experienced by the loop is

Figure shows a conducting loop placed in a magnetic field. The flux through the loop changes due to change in magnetic field according to the equation phi=5t-10t^(2) . What is the direction and magnitude of induced current at t=0.25s ?