A charge Q is placed at the centre of an inaginary hemispherical surface. Using symmetry arguments and the Gauss's law, find the flux of the electric field due to this charge through the surface of the hemisphere (figure ).

The Gaussian surface for calculating the electric field due to a charge distribution is ....

A point charge Q is placed at the centre of a spherical conducting shell. A total charge of -q is placed on the shell. The magnitude of the electric field at point P_1 at a distance R_1 from the centre is X. The magnitude of the electric field due to induced charges at point P_2 a distance R_2 from the centre is Y. The values of X and Y are respectively.

A spherical conducting shell of inner radius r_(1) and outer radius r_(2) has a charge Q. (a) A charge q is placed at the centre of the shell. What is the surface charge density on the inner and outer surfaces of the shell? (b) Is the electric field inside a cavity (with no charge) zero, even if the shell is not spherical, but has any irregular shape? Explain.

A charge q is placed at the point P as shown in figure on the axis of the ring of elemental thickness 't' and radius R then flux through the ring is :-

A point charge q is placed at the centre of a cube of side length L . The electric flux emerging from the cube is……

Obtain Gauss's law from the flux associated with a sphere of radius r and charge 'q' at centre.

A hollow metal sphere of radius R is uniformly charged. The electric field due to the sphere at a distance r from the centre

Calculate the electric field at origin due to infinite number of charges as shown in figure below.

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

A cube of side b has a charge q at each of its vertices. Determine the potential and electric field due to this charge array at the centre of the cube.