Figure shows some of the equipotential surfaces of the magnetic scalar potential. Find the magnetic field `B` at a point in the region.

A bar magnet of length 1cm and cross-sectonal area 1.0 cm^2 produces a magnetic field of 1.5 xx 10^(-4) T at a point in end-on position at a distance 15cm away from the centre. (a) Find the magnetic moment M of the magnet. (b) Find the magnetization I of the magnet. (c) Find the magnetic field B at the centre of the magnet.

Figure shows a current loop having two circular arcs joined by two radial lines. Find the magnetic field B at the centre O.

Figure shows a square loop of edge a made of a uniform wire. A current i enters the loop at the point A and leaves it at the point C. Find the magnetic field at the point P which is on the perpendicular bisector of AB at a distance a/4 from it.

Two charges 2muC and -2muC are placed at points A and B 6cm apart. a. Identify an equipotential surface of the given system. (b) What is the direction of the electric field at every point on this surface?

Two charges 2 µC and –2 µC are placed at points A and B 6 cm apart. (a) Identify an equipotential surface of the system. (b) What is the direction of the electric field at every point on this surface?

Figure shows a cross section of a large metal. Sheet carrying an electric current along its surface. The current in a strip of width dl is Kdl where K is a constant. Find the magnetic field at a point P at a distance x from the metal sheet.

A bar magnet has a pole strengh of 3.6 A m and magnetic length 8cm . Find the magnetic field at (a) a point on the axis at a distance of 6cm from the centre towards the north pole and (b) a point on the perpendiuclar bisector at the same distance.

What is the magnetic field at the center of the loop shown in figure ?

Let r be the distance of a point on the axis of a bar magnet from its center. The magnetic field at such a point is proportional to