Two infinite parallel,non- conducting sheets carry equal positive charge density `sigma` ,One is placed on 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

Electric field due to an infinite non-conducting sheet of surface charge density sigma , at a distance r from it is

Electric field due to an infinite non-conducting sheet of surface charge density sigma , at a distance r from it is

Two infinite nonconducting sheets of uniform charge density (+delta) and (-delta) are parallel to each other as shown. Electric field at the

There is an infinite non conducting sheet of charge having uniform charge density sigma . The electric field at a point P at a distance x from the sheet is E_(0) . Point O is the foot of the perpendicular drawn from point P on the sheet. A circular portio of radius r lt lt x centered at O is removed from the sheet. Now the field at point P becomes E_(0)-DeltaE . Find DeltaE .

Two infinite parallel planes have uniform charge densities +-sigma . What is the electric field in the region between the planes

Two infinite non-conducting sheets each with uniform surface charge density sigma are kept in such a way that the angle between them is 30^(@). The electric field in the region I shown between them is

Two infinitely long parallel conducting plates having surface charge densities + sigma and -sigma respectively, are seperated by a small distance. The medium between the plates is vacuum. If epsilon_(0) is the dielectric permittivity of vacumm, then the electric field in the region between the plates 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

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