A uniformly charged conducting sphere is having radius 1 m and surface charge density `20" Cm"^(-2)`. The total flux leaving the Gaussian surface enclosing the sphere is

A uniformaly charged conducting sphere of diameter 2.4 m has a surface charge density of 80.0muCm^(-2) . What is the total electric flux leaving the surface of the sphere ?

A uniformly charged conducting sphere of 4.4 m diameter has a surface change density of 60muCm^(-2) . The charge on the sphere is

(a) Using Gauss's law, derive an expression for the electric field intensity at any point outside a uniformly charged thin spherical shell of radius R and charge density sigma C//m^(2) . Draw the field lines when the charge density of the sphere is (i) positive, (ii) negative. (b) A uniformly charged conducting sphere of 2.5 m in diameter has a surface charge density of 100 mu C//m^(2) . Calculate the (i) charge on the sphere (ii) total electric flux passing through the sphere.

A uniformly charged conducting sphere of 2.4 m diameter has a surface charge density of 180.0 muC//M^(2) (ii) Find the charge on the sphere. (ii) what is the total flux leaving the surface of the sphere ?

A uniformly charged conducting sphere of 2.4m diameter has a surface density of 80.0 mu C//m^(2) . (a) Find the charge on the sphere (b) What is the total electric flux leaving the surface of the sphere ?

Two conducting spheres of radii r_(1) and r_(2) are charged to the same surface charge density . The ratio of electric field near their surface is

Find out electric field intensity due to uniformly charged solid non-conducting sphere of volume charge density rho and radius R at following points : (i) At a distance r from surface of sphere (inside) (ii) At a distance r from the surface of sphere (outside)

Two charged spheres of radii R_(1) and R_(2) having equal surface charge density. The ratio of their potential is