The figure shows a loop of wire carrying a current i as shown. There exists a uniform magnetic field along x-axis given by `vec(B) = B_(0) hat(i)`. If the length of each side is a, then

A circular loop of wire is carring a current i (as shown in the figure). On applying a uniform magnetic field inward perpendicular to the plane of the loop, the loop

A square loop of side a carris a current I . The magnetic field at the centre of the loop is

the force on current carrying wire placed in uniform magnetic field B as shown in figure is

A rectangular loop of dimensions (axxb) carries a current i. A uniform magnetic field vec(B)=B_(0) hat(i) exists in space. Then :

A wire loop carrying current I is placed in the x-y plane as shown in the figure. If an external uniform magnetic field vec(B)=B hat(i) is switched on, then the torque acting on the loop is

A wires PQRS carrying a current I runs along three edges of a cube of side l as shown in figure. There exists a uniform magnetic field of magnitude B along one of the sides of cube. The magnitude of the force acting on the wire is

A loop PQR carries a current i = 2A as shown in the figure. A uniform magnetic field B = 2T exists in space parallel to the plane of the loop . The magnetic torque on the loop is

In figure is shown a circular loop carrying current I. Show the direction of the magnetic field with the help of lines of force.

A circular flexible loop of wire of radius r carrying a current I is placed in a uniform magnetic field B . If B is doubled, then tension in the loop