Tangent law is applicable to a dipole placed in two magnetic field `vec(B) and vec (Bo)` when

A magnetic dipole placed in two perpendicular magnetic fields vec(B) and vec(B)_(o) is in equilibrium making an angle theta with vec(B) then.

The torque and magnetic potential energy of a magnetic dipole in most stable position ina uniform magnetic field vec(B) having magnetic moment vec(m) will be

A conducting circular loop of radiius r carries a constant current i . It is placed in a uniform magnetic field vec(B)_(0) such that vec(B)_(0) is perpendicular to the plane of the loop . The magnetic force acting on the loop is

A bar magnet of magnetic moment vec(M) is placed in a magnetic field of induction vec(B) . The torque exerted on it is

A closed current-carrying loop having a current I is having area A. Magnetic moment of this loop is defined as vec(mu) = vec(IA) where direction of area vector is towards the observer if current is flowing in anticlockwise direction with respect to the observer. If this loop is placed in a uniform magnetic field vec(B) , then torque acting on the loop is given by vec(tau) = vec(mu) xx vec(B) . Now answer the following questions: A uniformly charged insulating ring is rotated in a uniform magnetic field about its own axis, then

When a current loop is placed in a uniform magnetic field (i)" " vec(F_(R))=0 and vec(tau) , (ii)vec(F_(R))=0 but vec(tau)cancel(=)0 (iii)vec(F_(R))cancel(=)0 but tau=0 , (iv)vec(F_(R))cancel(=)0 and taucancel(=)0

The magnetic flux linked with a vector area vec(A) in a uniform magnetic field vec(B) is

When a conductor of length l carrying a current I is placed in a magnetic field of induction B at an angle theta with respect to vec(B) , the force experienced by it is

Show that when an electric dipole is placed in a uniform electric field vec(E) , petential energy U is given by U = - vec(P) , vec(E)