A circular current carrying loop is placed in x-y plane as shown in figure. A uniform magnetic field `B=B_(0)hatK` is present in the region. Match the following.

A circular loop carrying a current I is placed in the xy-plane as shown in figure. A uniform magnetic fied B is oriented along the positive z-axis. The loop tends to

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 current carrying loop of radius R and mass 'm' is placed inside a uniform magnetic field an shown

the force on current carrying wire placed in uniform magnetic field B as shown in figure is

Assertion : A square loop is placed in x-y plane as shown in figure. Magnetic field in the region is B =- B_0x hatk . The induced current in the loop is anti-clockwise. Reason : If inward magnetic field from such a loop increases, then current should be anti-clockwise.

A conductor ABCDE, shaped as shown, carries current I. It is placed in the x-y plane with the end A and E on the x-axis. A uniform magnetic field of magnitude B exists in the region. The force acting on it will be

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

A square loop of wire carrying current I is lying in the plane of paper as shown in Fig. 1.141. The magnetic field is present in the region as shown. The loop will tend to rotate

A conducting loop carrying current 'l' is bent into two halves and placed in mutually perpendicular planes xy and yz planes as shown. A uniform magnetic field vecB=Bhatj is existing in the region. The net magnetic torque experienced by the loop is

A uniform magnetic field vec(B) = B_(0) hat(k) exists in a region. A current carrying wire is placed in x-y plane as show. Find the force acting on the wire AB, if each section of the wire is of length 'a'.