An infinitely long line charge is bent in U shape as shown in figure. The semicircular part has radius R and linear charge density is `lamda C//m`. Using the results obtained in last two problems, calculate the electric field intensity at centre of the circle (point O)

Find the electric field at the centre of a uniformly charged semicircular ring of radius R. Linear charge density is lamda

A long wire with a uniform charge density lambda is bent in two configurations shown in fig. Determine the electric field intensity at point O.

A circular ring of radius R and uniform linear charge density +lamdaC//m are kept in x - y plane with its centre at the origin. The electric field at a point (0,0,R/sqrt(2)) is

Figure shows a long wire having uniform charge density lambda as shown in figure. Calculate electric field intensity at point P.

A very long charged wire (lying in the xy plane ) which is having a linear charge density lambda is having one of its end at a point P as shown in figure . What is electric field intensity at point Q :

Two infinite, non-conducting sheets of charge are parallel to each other, as shown in figure. The sheet on the left has a uniform surface charge density sigma , and the one on the right has a uniform charge density -sigma . Calculate the electric field at points (a) to the left of, (b) in between, and (c) to the right of the two sheets.

An infinitely long time charge has linear charge density lamdaC//m the line charge is along the line x=0,z=2m find the electric field at point (1,1,1) m.

Two semicircular rings lying in same plane, of uniform linear charge density lambda have radius r and 2r. They are joined using two straight uniformly charged wires of linear charge density lambda and length r as shown in figure. The magnitude of electric field at common centre of semi circular rings is -

A sphere of radius R has a charge density sigma . The electric intensity at a point at a distance r from its centre is