Find the dimensions of
a. electric dipole moment p and
b. magnetic dipole moment M.
The defining equations are `p=q.d and M=IA,`
whre d is distance, A is area, q is charge and I is current.

Write the equation of dipole moment of magnet in the form of electric current.

An electric dipole is kept on the axis of a uniformly charged ring at distance from the centre of the ring. The direction of the dipole moment is along the axis. The dipole moment is p , charge of the ring is Q & radius of the ring is R . The force on the dipole is

The intensity of magnetization of a magnet of magnetic dipole moment 1.2 "Am"^(2) and dimension 0.15 m xx 0.02 m xx 0.01m is…..... A/m.

For a short magnet with magnetic dipole moment overset(to)(m) , its magnetic field at distance d from its centre on its equator is ......

The work in rotating electric dipole of dipole moment p in an electric field E through an angle theta from the direction of electric field, is:

The magnetic field due to short bar magnet of magnetic dipole moment M and length 2l, on the axis at a distance z (where z >> I) from the centre of the magnet is given by formula ....

A short electric dipole is situated at the origin of coordinate axis with its axis along x-axis and equator along y-axis. It is found that the magnitudes of the electric intensity and electric potential due to the dipole are equal at a point distance r=sqrt(5) m from origin. Find the position vector of the point in first quadrant.

A charge +Q is fixed at the origin of the co-ordinate system while a small electric dipole of dipolement vecp pointing away from the charge along the x-axis is set free from a point far away from the origin. (a) Calculate the K.E. of the dipole when it reaches to a point (d, 0). (b) Calculate the force on the charge +Q at this moment.

An electric dipole of moment p is placed normal to the lines of force of electric field E, then the work done in deflecting it through an angle of 180 degree is

An electric dipole of moment p is placed parallel to the lines of force of electric field E, then the work done in deflecting it through an angle of 180 degree is