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

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 p is placed in a uniform external electric field E. Then, the

A dipole of dipole moment vec(P) is placed in uniform electric field vec(E) , then torque acting on it is given by

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 -

A dipole of moment vecp is placed in a uniform electric field vecE . The force on the dipole is vecF and the torque is vec(tau)

An electric dipole of dipole moment vecp is placed in a uniform electric field vecE with its axis inclined to the field. Write an expression for the torquet vec tau experienced by the dipole in vector form. Show diagrammatically how the dipole should be kept in the electric field so that the torque acting on it is : zero

An electric dipole of dipole moment vecp is placed in a uniform electric field vecE with its axis inclined to the field. Write an expression for the torquet vec tau experienced by the dipole in vector form. Show diagrammatically how the dipole should be kept in the electric field so that the torque acting on it is : maximum

An electric dipole of dipole moment vecp is placed in a uniform electric field vecE with its axis inclined to the field. Write an expression for the torque vectau experienced by the dipole in vector form. Show diagrammatically how the dipole should be kept in the electric field so that the torque acting on it is: (i) maximum (ii) zero

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