A thin uniform ring of radius R carrying charge q and mass m rotates about its axis with angular velocity `omega`. Find the ratio of its magnetic moment and angular momentum.

A ring of mass m and radius R is given a charge q. It is then rotated about its axis with angular velocity omega .Find (iii)Magnetic moment of ring.

A thin disc of radius R and mass M has charge q uniformly distributed on it. It rotates with angular velocity omega . The ratio of magnetic moment and angular momentum for the disc is

A ring of mass m and radius R is being rotated about its axis with angular velocity o. If o increases then tension in ring

A ring of mass m and radius R is given a charge q. It is then rotated about its axis with angular velocity omega .Find (i)Current produced due to motion of ring

Solid uniform conductiong sphere of mass 'm' and charge Q , rotates about its axis of symmetry with constant angular velocity 'omega' then the ratio of magnetic moment to the moment of inertia of the sphere is (xQomega)/(6m) then x is :(Neglect induced charges due to centrifugal force)

A long cylinder of radius a carrying a uniform surface charge rotates about its axis with an angular velocity omega . Find the magnetic field energy per unit length of the cylinder if the linear charge density equals lambda and mu = 1 .

A rod is rotating with angular velocity omega about axis AB. Find costheta .

Consider a hypothetic spherical body. The body is cut into two parts about the diameter. One of hemispherical portion has mass distribution m while the other portion has indentical charge distribution q. The body is rotated about the axis with constant speed omega. Then, the ratio of magnetic moment to angular momentum is

A ring of mass m and radius R is given a charge q. It is then rotated about its axis with angular velocity omega .Find (ii) Magnetic field produced at the centre of ring.

A solid cylinder of mass M and radius R rotates about its axis with angular speed omega . Its rotational kinetic energy is