A solid non conducting sphere of radius R and uniform volume density `rho` has centre at origin. Find out electric field intensity in vector form at following positions :
(i) (R, 0, 0) (ii) (0, 0, R/2) (iii) (R, R, R)

A solid non conducting sphere of radius R and uniform volume charge density rho has its centre at origin. Find out electric field intensity in vector form at following positions : (i) (R//2, 0, 0)" " (ii) (R/sqrt(2), R/sqrt(2), 0)" " (iii) (R, R, 0)

A solid non conducting sphere of radius R and uniform volume charge density rho has its centre at origin. Find out electric field intensity in vector form at following positions : (i) (R//2, 0, 0)" " (ii) (R/sqrt(2), R/sqrt(2), 0)" " (iii) (R, R, 0)

A Uniformly charged solid non-conducting sphere of uniform volume charge density rho and radius R is having a concentric spherical cavity of radius r. Find out electric field intensity at following points, as shown in the figure : (i) Point A (ii) Point B (iii) Point C (iv) Centre of the sphere

A Uniformly charged solid non-conducting sphere of uniform volume charge density rho and radius R is having a concentric spherical cavity of radius r. Find out electric field intensity at following points, as shown in the figure : (i) Point A (ii) Point B (iii) Point C (iv) Centre of the sphere

A non conducting solid sphere of radius R is uniformly charged. The magnitude of electric field intensity due to the sphre at a distance r from its centre

A non-conducting solid sphere of radius R is uniformly charged. The magnitude of the electric field due to the sphere at a distance r form its centre

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

There is a solid non-conducting sphere of radius R. Sphere is uniformly charged over the volume. Electric field due to this where in observed.