Induced charge q can neverbe greater than inducing charge Q. Why ?

Induced charge q can never be greater than inducing charge Q. Why ?

In the simple L-R circuit, can the emf induced across the inductor ever be greater than the emf of the battery used to produce the current?

A point charge + q is fixed at same height as centre of an uncharged sphere placed on a smooth horizontal surface as shown in figure. Neglect the induced charges on horizontal surface. Then conducting sphere is released from rest. Then the conducting sphere

If only one charge is availabel, can it be used to obtain a charge many times greater than itself in magnitude?

Show in the figure are two point charge + Q and - Q inside the cavity of the Spherical .shell the changes are kept near the surface of the cavity on opposite sides of the centre of the shell if sigma_1 is the surface charge on the inner surface and Q_1 net charge on it and sigma_2 the surface charge on the outer surface and Q_2 net charge on it then :

A dielectric slab is inserted between the plates of a capacitor. The charge on the capacitor is Q and the magnitude of the induced charge on each surface of the dielectric is Q' .

As shown in the figure, à magnet is moved with a fast speed towards a coil at rest. Due to this induced emf, induced current and induced charge in the coll is E, I and Q respectively. If the speed of the magnet is doubled, the incorrect statement is

A charge q kept in front of a neutral metallic sphere. Find the electric field at the centre of sphere due to the induced charges on the surface of the sphere shown. Strategy : The net electric field inside the conductor is zero. This is produced by induced charges and the external charge.

A charge q kept in front of a neutral metallic sphere. Find the electric field at the centre of sphere due to the induced charges on the surface of the sphere shown. Strategy : The net electric field inside the conductor is zero. Thsi is produced by induced charges and the external charge.

A charge q is placed at the centre of the line joining two equal charges Q. The system of the three charges will be in equilibrium if q is equal to: