An infinitely long line charge having a uniform charge per unit length `lambda` lies a distance `d` from center of imaginary sphere of radius `R`.Then

An infinitely long line charge having a uniform charge per unit length lambda lies at a distance d from a point O as shown in figure. Determine the total electric flux through through the surface of a sphere of radius R centered at O resulting from this line charge. Consider both cases where Rltd and Rgtd .

An infinitely long line charge having a uniform charge per unit length lambda lies at a distance d from a point O as shown in figure. Determine the total electric flux through through the surface of a sphere of radius R centered at O resulting from this line charge. Consider both cases where Rltd and Rgtd .

A uniformly charged and infinitely long line having a linear charge density 'lambda' is placed at a normal distance y from a point O . Consider a sphere of radius R with O as centre and Rgty . Electric flux through the surface of the sphere is

A uniformly charged and infinitely long line having a linear charge density 'lambda' is placed at a normal distance y from a point O . Consider a sphere of radius R with O as centre and Rgty . Electric flux through the surface of the sphere is

Find the electric field due to an infinitely long cylindrical charge distribution of radius R and having linear charge density lambda at a distance half of the radius from its axis.

Two infinitely long thin straight wires having uniform linear charge densities lambda and 2lambda are arranged parallel to each other at a distance r apart.The intensity of the electric field at a point midway between them is

Consider an infinite line charge having uniform linear charge density and passing through the axis of a cylinder is removed.

A solid conducting sphere of radius r is having a charge of Q and point charge q is a distance d from the centre of sphere as shown. The electric potential at the centre of the solid sphere is :

Two infinitely long parallel wires having linear charge densities lambda_(1) and lambda_(2) respectively are placed at a distance of R metres. The force per unit length on either wire will be (k= 1/(4piepsilon_(0)))

If the potential at the centre of a uniformly charged hollow sphere of radius R is V, then electric field at a distance r from the centre of sphere will be (rgtR) .