In the shown figure a conducting ring of mass = 2kg and radius R = 0.5 m. lies on a smooth horizontal plane with its plane vertical. The ring carries a current of `I = (1)/(pi)A`. A horizontal uniform magnetic field of B = 12T is switched on at t =0. The initial angular acceleration `alpha` in `rad//sec^(2)` of the ring will be 4x if x is :

A conducting ring of mass 2 kg and radius 0.5 m is placed on a smooth horizontal plane. The ring carries a current . A horizontal magnetic field B = 10T is switched on at time t = 0 as shown in figure. The initial angular acceleration of the ring will be:

A conducting rign of mass 100 gram and radius 0*5m is placed on a smooth horizontal plane. The ring carries a current of I=4A . A horizontal magnetic field B=10T is switched on at time t=0 as shown in figure. The initial angular acceleration of the ring is

A non - conducting ring of mass m = 4 kg and radius R = 10 cm has charge Q = 2 C uniformly distributed over its circumference. The ring is placed on a rough horizontal surface such that the plane of the ring is parallel to the surface. A vertical magnetic field B=4t^(3)T is switched on at t = 0. At t = 5 s ring starts to rotate about the vertical axis through the centre. The coefficient of friction between the ring and the surface is found to be (k)/(24) . Then the value of k is

A uniformly conducting wire is bent to form a ring of mass 'm' and radius 'r' , and the ring is placed on a rough horizontal surface with its plane horizontal. There exists a uniform and constant horizontal magnetic field of induction B . Now a charge q is passed through the ring in a very small time interval Deltat . As a result the ring ultimately just becomes vertical. Calculate the value of g (acceleration due to gravity) in terms of other given quantities. Assume that friction is sufficient to prevent slipping and ignore any loss in energy.

A non-conducting ring of mass m and radius R has a charge Q uniformly distributed over its circumference. The ring is placed on a rough horizontal surface such that plane of the ring is parallel to the surface. A vertical magnetic field B = B_0t^2 tesla is switched on. After 2 a from switching on the magnetic field the ring is just about to rotate about vertical axis through its centre. (a) Find friction coefficient mu between the ring and the surface. (b) If magnetic field is switched off after 4 s , then find the angle rotated by the ring before coming to stop after switching off the magnetic field.

There is a non conducting ring of radius R and mass m having charge q uniformly distributed over its circumference. It is placed on a rough horizontal surface. A vertical time varying uniform magnetic field B = 4t^(2) is switched on at time t= 0. The coefficient of friction between the ring and the table, if the ring starts rotating at t= 1 sec, is :

A horizontal ring of radius r spins about its axis with an angular velocity omega in a uniform vertical magnetic field of magnitude B . The emf induced in the ring is