The linear charge density on upper half of semi-circular section of ring is `lambda` and that at lower half is `-lambda`. The direction of electric field at centre O of ring is :

A small element l cut from a circular ring of radius a and lamda charge per unit length. The net electric field at the centre of ring is

The charge per unit length of the four quadrant of the ring is 2 lambda, -2lambda, lambda and -lambda respectively. The electric field at the centre is:

A semi-infinite insulating rod has linear charge density lambda . The electric field atthe pointPshown in figure-1.418 is:

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

The linear charge density on a ring of radius R is lambda=lambda_0 sin (theta) where lambda_0 is a constant and theta is angle of radius vector of any point on the ring with x-axis. The electric potential at centre of ring is

Charges q is uniformly distributed over a thin half ring of radius R . The electric field at the centre of the ring is

The linear charge density on a dielectric ring of radius R vanes with theta as lambda = lambda_0 cos theta//2 , where lambda_0 is constant. Find the potential at the center O of the ring [in volt].

A semicircular wire is uniformly charged with linear charge density dependent on the angle theta from y -direction as lambda=lambda_(0) |sin theta| , where lambda_(0) is a constant. The electric field intensity at the centre of the arc is