Find force acting between two shells of radius `R_(1)` and `R_(2)` which have uniformly distributed charges `Q_(1)` and `Q_(2)` respectively and distance between their centres is r.

Two concentric spherical shells of radius R_(1) and R_(2) (R_(2) gt R_(1)) are having uniformly distributed charges Q_(1) and Q_(2) respectively. Find out total energy of the system.

Figure shows two concentric conducting shells of radii r_(1) and r_(2) carrying uniformly distributed charges q_(1) and q_(2) , respectively. Find an expression for the potential of each shell. .

The insulated spheres of radii R_(1) and R_(2) having charges Q_(1) and Q_(2) respectively are connected to each other. There is

The insulated spheres of radii R_(1) and R_(2) having charges Q_(1) and Q_(2) respectively are connected to each other. There is

You are given two concentric charged conducting spheres of radii R_(1) and R_(2) such that R_(1) gt R_(2) , having charges Q_(1) and Q_(2) respectively and uniformly distributed over its surface. Calculate E and V at three points A, B , C whose distances from the centre are r_(A), r_(B) and r_(c) respectively as shown in figure.

Two concentric uniformly charge spherical shells of radius R_(1) and R_(2) (R_(2) gt R_(1)) have total charges Q_(1) and Q_(2) respectively. Derive an expression of electric field as a function of r for following positions. (i) r lt R_(1) (ii) R_(1) le r lt R_(2) (iii) r ge R_(2)

Three concentric spherical shells A, B and C having uniformly distributed total charges +Q, -2Q and +Q respectively are placed as shown. The potential at the centre will be -

Two non-conduction hollow uniformly charged spheres of radil R_(1) and R_(2) with charge Q_(1) and Q_(2) respectively are places at a distance r. Find out total energy of the system.

Two concentric, thin metallic spheres of radii R_(1) and R_(2) (R_(1) gt R_(2)) charges Q_(1) and Q_(2) respectively Then the potential at radius r between R_(1) and R_(2) will be (k = 1//4pi in)

There is a solid sphere of radius R having uniformly distributed charge throughout it. What is the relation between electric field E and distance r from the centre (r is less than R) ?