A bar magnet having a magnetic moment of `1.0 xx 10^4 J T^(-1)` is free to rotate in a horizontal plane. A horizontal magnetic field `B = 4 xx 10^(-5) T` exists in the space. Find the work done in rotating the magnet slowly from a direction parallel to the field to a direction `60^@` from the field.

A bar magnet having a magnetic moment of 2xx10^(4) JT^(-1) is free to rotate in a horizontal plane. A horizontal magnetic field B=6xx10^(-4)T exists in the space. The work done in taking the magnet slowly from a direction parallel to the field to a direction 60^(@) from the field is

A magnet having magnetic moment of 2.0 xx 10^(4) (J)/(T) is free to rotate in a horizontal plane where magnetic field is 6 xx 10^(-5) T . Find the work done to rotate the magnet slowly from a direction parallel to field to a direction 60^(@) from the field .

A bar magnet with magnetic moment 2.5xx10^(3)JT^(-2) is rotating in horizontal plane in the space containing magnetic induction B=4xx10^(5)T . The work done in rotating the magnet slowly from a direction parallel to the field to a direction 45^(@) from the field, is (in joule).

A uniform magnetic field of 0.20 xx 10^(-3) T exists in the space. Find the the change in the magnetic scalar potential as one moves through 50cm along the field.

The horizontal component of the earth's magnetic field is 3.6 xx 10^(-5) T where the dip is 60^@ . Find the magnitude of the earth's magnetic field.

For given arrangement ( in horizontal plane ) the possible direction of magnetic field :

The work done in rotating a magent of the magnetic moment 2Am^(2) in a magnetic field of induction 5 xx 10^(-3)T from the direction along the magnetic field to the direction opposite to the field , is

A bar magnet of magnetic moment 1.5JT^-1 lies aligned with the direction of a uniform magnetic field of 0.22T . (a) What is the amount of work done to turn the magnet so as to align its mangetic moment (i) normal to the field direction, (ii) opposite to the field direction? (b) What is the torque on the magnet in cases (i) and (ii)?

A 10 g bullet having a charge of 4.00 muC is fired at a speed of 270 ms^(-1) in a horizontal direction. A vertical magnetic field of 500 muT exists in the space. Find the deflection of the bullet due to the magnetic field as it travels through 100m. make appropriate approximations.

A short bar magnet has a magnetic moment of 0.39 J "T"^(-1) . The magnitude and direction of the magnetic field produced by the magnet at a distance of 20 cm from the centre of the magnet on the equatorial line of the magnet is