If a distance of 40 cm at an axial position of a dipole, the ''magnetic potential'' (analogous to electric potential) is `2.4xx10^(-5)"J A m"^(-1)` then the magnetic moment of the dipole is

The magnetic potential at a point at a distance of 10 cm from mid point of magnetic dipole on a line making an angle of 60^(@) with axis is 1.5 xx 10^(-7) Wb//m .The magnetic moment of the dipole is

A magnetic dipole of lrngth 10 cm has pole strength of 20 Am apart . Find the magnetic moment of the dipole

The magnetic scalar potential due to a magnetic dipole at a point on its axis situated at a distance of 20cm from its centre is found to be 1.2 xx 10^(-5) T m . Find the magnetic moment of the dipole.

The magnetic scalar potential due to a magnetic dipole at a point on its axis situated at a distance of 20cm from its centre is found to be 1.2 xx 10^(-5) T m . Find the magnetic moment of the dipole.

The magnetic scalar potential due to a magnetic dipole at a point on its axis situated at a distance of 20cm from its centre is found to be 1.2 xx 10^(-5) T m . Find the magnetic moment of the dipole.

The electric potential at an axial point of an electric dipole depends upon the distance r(>>a) of the point from the centre of the dipole as

Derive an expression for the electric potential at a point along the axial line of an electric dipole.

Two point-charges +2e and -2 e are situated at a distance of 2.4 Å from each other and constitude an electric dipole. This dipole is placed in a uniform electric field of 4.0 xx 10^(5) "Vm"^(-1) . Calculate (i) electric dipole moment, (ii) potential energy of the dipole in equilibrium position, (iii) work done in rotating the dipole through 180^(@) from the equilibrium position.

Two point-charges +2e and -2 e are situated at a distance of 2.4 Å from each other and constitude an electric dipole. This dipole is placed in a uniform electric field of 4.0 xx 10^(5) "Vm"^(-1) . Calculate (i) electric dipole moment, (ii) potential energy of the dipole in equilibrium position, (iii) work done in rotating the dipole through 180^(@) from the equilibrium position.