An infinite sheet of charge has surface charge density `sigma` . The separation between two equipotential surfaces, whose potential differ by V is:

An infinite sheet of charge has a surfaces charge density of 10^-7C/m^2 . The separation between two equipotential surfce whose potentials differ by 5 V is

An infinite nonconducting sheet of charge has a surface charge density of 10^(7) C//m^(2) . The separation between two equipotential surfaces near the whose potential differ by 5V is

An infinite conducting sheet has surface charge density sigma . The distance between two points is r. The potential difference (V_A - V_B) between these point is

Nature of equipotential surface for a point charge is

Electric field intensity at a point due to an infinite sheet of charge having surface charge density sigma is E .If sheet were conducting electric intensity would be

An infinite cylinder of radius r_(o), carrying linear charge density lamda. The equation of the equipotential surface for the cylinder is

A non-conducting semi circular disc (as shown in figure) has a uniform surface charge density sigma . The ratio of electric field to electric potential at the centre of the disc will be

A spherical charged conductor has surface charge density sigma .The intensity of electric field and potential on its surface are E and V .Now radius of sphere is halved keeping the charge density as constant .The new electric field on the surface and potential at the centre of the sphere are

An infinite thin non - conducting sheet has uniform surface charge density sigma . Find the potential difference V_(A)-V_(B) between points A and B as shown in the figure. The line AB makes an angle of 37^(@) with the normal to the sheet. (sin 37^(@)=(3)/(5))

An infinite, uniformly charged sheet with surface charge density sigma cuts through a spherical Gaussian surface of radius R at a distance X from its center, as shown in the figure. The electric flux Phi through the Gaussian surface is .