If a coil carrying current is placed in a uniform magnetic field, then

A coil of diameter 0.2 cm is formed by a 6.28 m long wire and a current of 1 amp is passed in it. The magnetic induction at its centre will be

A long wire carrying a steady current is bent into a circular loop of one turn. The magnetic field at the centre of the loop is B. It is then bent into a circular coil of n turns. The magnetic field at the centre of this coil of n turns will be

A long straight wire of radius a carries a steady current I. The current is uniformly distributed over its cross-section. The ratio of the magnetic fields B and B’, at radial distances a/2 and 2a respectively from the axis of the wire is:

Compute the magnetic field of a long straight wire that has a circular loop with a radius of 0.05 m. 2 amp is the reading of the current flowing through this closed loop.

A wire of length L carrying current I is bent into a circle of one turn. The field at the centre of the coil is B1. A similar wire of length L carrying current I is bent into a square of one turn. The field at its centre is B2. Then

Two long straight parallel wires carry currents I1 and I2, respectively, in the same direction (as shown). The distance between the wires is R. The magnetic field at the centre of the two wires will

A large metal sheet carries an electric current along its surface. Current per unit length is λ. Magnetic field near the metal sheet is

Charged particle ‘q’ moving through a magnetic field with velocity V will have zero magnetic force when the angle is