A large sheet carries uniform surface charge density `sigma` . A rod of length 2l has a linear charge density `lambda` on one half and `-lambda` on the second half. The rod is hinged at the midpoint O and makes an angle `theta` with the normal to the sheet. The torque experience by the rod is

A half ring of radius r has a linear charge density lambda .The potential at the centre of the half ring is

A long thin flat sheet has a uniform surface charge density sigma . The magnitude of the electric field at a distance .r. from it is given by

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))

A uniform rod AB of mass m and length l is hinged at its mid point C. The left half (AC) of the rod has linear charge density -lamda and the right half (CB) has + lamda where lamda is constant. A large non conducting sheet of uniform surface charge density sigma is also present near the rod. Initially the rod is kept perpendicular to the sheet. The end A of the rod is initialy at a distance d. Now the rod is rotated by a small angle in the plane of the paper and released. Prove that the rod will perform SHM and find its time period.

What is the electric field intensity at any point on the axis of a charged rod of length 'L' and linear charge density lambda ? The point is separated from the nearer end by a.

You are given a rod of length L. The linear mass density is lambda such that lambda=a+bx . Here a and b are constants and the mass of the rod increases as x decreases. Find the mass of the rod

An insulting thin rod of length l has a linear charge density rho(x)=rho_(0)(x)/(l) on it. The rod is rotated about an axis passing through the origin (x=0) and perpendicular to the rod. If the rod makes n rotations per second, then the time averaged magnetic moment of the rod is :

In the figure shown there is a large sheet of charge of uniform surface charge density 'sigma' .A charge particle of charge '-q' and mass 'm' is projected from a point A on the sheet with a speed 'u' with the angle of projection such that it lands at maximum distance from A on the sheet. Neglecting gravity, find the time flight

A very long uniformly charged cylinder (radius R) has a surface charge density sigma . A very long uniformaly charged line charge( linear charge density lambda ) is placed along the ctlinder axis. If electric field intensity vector outside the cylinder is zerom then :

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