A wire loop carrying current I is placed in the `x-y` plane as shown in the figure. If an external uniform magnetic field `vec(B)=B hat(i)` is switched on, then the torque acting on the loop is

A wire loop carrying a current I is placed in the xy-plane as shown in figure If an external uniform magnetic induction field B=Bhati is applied, find the force acting on the loop due to this field.

A wire loop carrying current I is placed in the x-y plane as shown. Magnetic induction at P is

A wire loop carrying current I is placed in the x-y plane as shown. Magnetic induction at P is

A loop carrying current I lies in the x-y plane as shown in the figure . The unit vector hat k is coming out of the plane of the paper . The magnetic moment of the current loop is

A loop carrying current I lies in the x-y plane as shown in the figure . The unit vector hat k is coming out of the plane of the paper . The magnetic moment of the current loop is

A loop carrying current I lies in the x-y plane as shown in the figure . The unit vector hat k is coming out of the plane of the paper . The magnetic moment of the current loop is

A wire loop carrying I is placed in the x-y plane as shown in fig. (a) If a particle with charge +Q and mass m is placed at the centre P and given a velocity vec(v) along NP (see figure), find its instantaneous acceleration. ( b) If an external uniform magnetic induction field vec(B) = Bhat(i) is applied , find the force and the torque acting on the loop due to this field.

A wire loop carrying a current I is placed in the x-y plane. (a) If a particle with charge +Q and mass m is placed at the center P and given a velocity vec(v) along NP, find its acceleration. (b) if an external uniform magnetic induction vec(B) =B hat(i) is applied, find the force and the torque acting on the top due to this field.