Electric potential due to a dipole at a position `vec r` from its centre is: where `(K = 1/(4pi epsilon_0)`

In the previous question assume that the electrostatic potential is zero at an infinite distance from the spherical shell. The electrostatic potential at a distance R (a lt R lt b) from the centre of the shell is where (K=1/(4pi epsilon_(0)))

A short electric dipole has dipole moment of 4xx10^(-9)Cm . Determine the electric potential due to the dipole at a point distant 0.3 m from the centre of the dipole situated on (a) the axial line (b) on equatorial line and (c) on a line making an angle of 60^(@) wth the dipole axis.

The electrostatic potential due to an electric dipole at a distance 'r' varies as

The electric potential due to an extermely short dipole at a distance r form it is proporitonal to

A short electric dipole has dipole moment of 16 x 10^-9 C m. The electric potential due to dipole at a point at a distance of 0.6m from centre of dipole situated on aline making an angle of 60 degrees with dipole axis:

The electric field due to an electric dipole at a distance r from its centre in axial position is E . If the dipole is rotated through an angle of 90^(@) about its perpendicular axis, the electric field at the same point will be

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.