There are two nonconducting spheres having uniform volume charge densities `rho` and `- rho` . Both spheres have equal radius `R`. The spheres are now laid down such that they overlap as shown in Fig.2.125. Take `vec(d) = O_(1) vec(O_(2))`.

The electric field `vec(E)` in the overlapped region is

There are two nonconducting spheres having uniform volume charge densities rho and - rho . Both spheres have equal radius R . The spheres are now laid down such that they overlap as shown in Fig.2.125. Take vec(d) = O_(1) vec(O_(2)) . The potential difference Delta V between the centres of the two spheres for d = R is

There are two nonconducting spheres having uniform volume charge densities rho and - rho . Both spheres have equal radius R . The spheres are now laid down such that they overlap as shown in Fig.2.125. Take vec(d) = O_(1) vec(O_(2)) . The potential difference Delta V between the centres of the two spheres for d = R is

Two non-conducting spheres of radii R_(1) and R_(2) and carrying uniform volume charge densities +rho and - rho respectively are placed such that they partially overlapping region.

Two non-conducting spheres of radii R_1 and R_2 and carrying uniform volume charge densities +rho and -rho , respectively, are placed such that they partially overlap, as shown in the figure. At all points in the overlapping region

Two non-conducting spheres of radii R_1 and R_2 and carrying uniform volume charge densities +rho and -rho , respectively, are placed such that they partially overlap, as shown in the figure. At all points in the overlapping region

A sphere of charge of radius R has uniform volume charge density. The electric field due to the sphere of charge at a point

A solid sphere having uniform charge density rho and radius R is shown in figure. A spherical cavity ofradius (R)/(2) is made in it. What is the potential at point O?

A solid sphere having uniform charge density rho and radius R is shown in figure. A spherical cavity ofradius (R)/(2) is made in it. What is the potential at point O?

There is a hemisphere of radius R having a uniform volume charge density rho . Find the electric potential and field at the centre

The electric potential due to uniformly charged sphere of radius R ,having volume charge density rho having a spherical cavity of radius R/2 as shown as in figure at point p is