Two infinite, parallel, nonconducting sheets carry equal positive charges density `sigma`. One is placed in the yz plane and the other at distance `x = a`. Take potential `V = 0` at `x = 0`. Then.

Two infinite parallel,non- conducting sheets carry equal positive charge density sigma ,One is placed in the yz plane other at distance x=a Take potential V=0 at x=0 then

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

Two infinite plane parallel sheets, separated by a distance d have equal and opposite uniform charge densities sigma . Electric field at a point between the sheets is

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

An infinite non-conducting plane with uniform charge density sigma is kept parallel to yz plane and at a distance 'd' from a dipole vecp which itself is located at the origin. An equipotential surface for this system is spherical, centred at origin, having radius R(ltd) . Given that R=(p/(npisigma))^(1//3) , find the integer n

In front of a uniformly charged infinite non-conducting sheet of surface charge density sigma , a point charge q_(0) is shifted slowly from a distance a to b (b gt a) . If work done by external agent is W, then find out relation between the given parameters.

Two infinite sheets of unifrom charge density +sigma and -sigma are parallel to each other as shown in the figure. Electric field at the

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

Two infinitely large charged planes having uniform suface charge density +sigma and -sigma are placed along x-y plane and yz plane respectively as shown in the figure. Then the nature of electric lines of forces in x-z plane is given by:

A nonconducting disk of radius a and uniform positive surface charge density sigma is placed on the ground, with its axis vertical. A particle of mass m and positive charge q is dropped, along the axis of the disk, from a height H with zero initial velocity. The particle has q//m = 4 epsilon_(0) g// sigma . (i) Find the value of H if the particle just reaches the disk. (ii) Sketch the potential energy of the particle as a function of its height and find its equilibrium position.