An electric dipole of moment p is placed normal to the lines of force of electric intensity E, then the work done in deflecting it through an angle of `80^(@)` is

An electric dipole of moment vecp is placed normal to the lines of force of electric intensity vecE , then the work done in deflecting it through an angle of 180^(@) is

An electric dipole of dipole moment p is placed in a uniform external electric field E. Then, the

An electric dipole of moment p is palced in the positive of stable equilibrium in uniform electric field of intensity E . It is rotated through an angle theta from the initial position. The potential energy of electric dipole in the final position is

An electric dipole of moment vec(P) is lying along a uniform electric field vec(E ) . The work done in rotating the dipole by 90^(@) is:

An electric dipole of dipole moment vec P is lying along uniform electric filed bar E . The work done in rotating the dipole by 37° is

A magnetic dipole is placed at right angles to the direction of lines of force of magnetic induction B. If it is rotated through an angle of 180^(@) then the work done is

An electric dipole is placed at the centre of a sphere. Find the electric flux passing through the sphere.

An electric dipole is placed in a uniform electric field. The net electric force on the dipole

An electric dipole of dipole moment vecP is placed in a uniform electric field vecE such that vecP is perpendicular to vecE . The work done to turn the dipole through an angle of 180^(@) is -