An elastic dipole is formed by two equal and opposite charge with separation d. The charges have same mass m. It is Kept in a uniform electric field E. If it is slightly rotated from its equilibrium frequency `omega` is
An electric dipole is formed by two equal and opposite charges q with separation d. The charges have same mass m. It is kept in a uniform electric field E. If it is slightly rotated from its equilibrium orientation, then its angular frequency omega is:
An electron having charge 'e' and mass 'm' is moving a uniform electric field E . Its acceleration will be
An electric dipole has the magnitude of its charge as q and its dipole moment is p . It is placed in a uniform electric field E . If its dipole moment is along the direction of the field, the force on it and its potential energy are respectively
An electric dipole consists of two equal and opposite charges placed 2 cm apart. When the dipole is placed in a uniform electric field of strength 10^(5)NC^(-1) , it experiences a maximum torque of 0.2xx10^(-3)Nm . Find the magnitude of each charge
An electric dipole (AB) consisting of two particles of equal and opposite charge and same mass is released in an electric field. In the figure field lines are without considering effect of field of dipole. The centre of mass of the dipole
An electric dipole (AB) consisting of two particles of equal and opposite charge and same mass is released in an electric field. In the figure field lines are without considering effect of field of dipole. Angular acceleration of the dipole, immediately after it is released
How does the energy of dipole change when it is rotated from unstable equilibrium to stable equilibrium in a uniform electric field.
A dipole is formed by two point charge -q and +q, each of mass m, and both the point charge are connected by a rod of length l and mass m. This dipole is placed in uniform electric field vec(E) If the dipole is disturbed by a small angle theta from stable equilibrium position, prove that its motion will be almost SHM. also find its time period.
