Surface charge density on a rign of radius a and width d of is `sigma` as sbown in the figure. It rotates with frequency f about its own axis. Assume theat the charge is only on outer surface. The magnetic field inductioni at centre is (Assume that `d lt lt a`)

A plastic disc of radius 'R' has a charge 'q ' uniformly distributed over its surface. If the disc is rotated with a frequency 'f' about its axis, then the magnetic induction at the centre of the disc is given by

The surface mass density of a disc of radius a varies with radial distance as sigma = A + Br where A & B are positive constants then moment of inertia of the disc about an axis passing through its centre and perpendicular to the plane

A thin ring of radius R metre has charge q coulomb uniformly spread on it. The ring rotates about its axis with a constant frequency of f revolution/s. The value of magnetic induction in Wb m^(-2) at the centre of the ring is

A charge Q is placed at the centre of an uncharged, hollow metallic sphere of radius a. (a) Find the surface charge density on the inner surface and on the outer surface. (b) If a charge q is put on the sphere, what would be the surface charge densities on the inner and the outer surface? (c) Find the electric field inside the sphere at a distance x from the centre in the situations (a) and (b).

A thin circular disk of radius R is uniformly charged with density sigma gt 0 per unit area.The disk rotates about its axis with a uniform angular speed omega .The magnetic moment of the disk is :

A nonconducting sphere with a cavity has volume charge density rho . O_1 and O_2 represent the two centres as shown. The electric fields inside the cavity is E_0 . Now, an equal and opposite charge is given uniformly to the sphere on its outer surface. The magnitude of electric field inside the cavity becomes

A charge particle of charge 'q' and mass 'm' enters in a given magnetic field 'B' and perpendicular to the magnetic field as shown in the figure. It enters at an angle of 60^(@) with the boundary surface of magnetic field and comes out at an angle of 30^(@) with the boundary surface of the magnetic field as shown in the figure. Find width 'd' in which magnetic field exist.

The surface charge density of a thin charged disc of radius R is sigma . The value of the electric field at the centre of the disc (sigma)/(2 in_(0)) . With respect to the field at the centre, the electric field along the axis at a distance R from the centre of the disc is

3 charges are placed in a circle of radius d as shown in figure. Find the electric field along x-axis at centre of circle.

3 charges are placed in a circle of radius d as shown in figure. Find the electric field along x-axis at centre of circle.