A circular loop is bent so that half of `(OAB)` lies in xy- plane ane the other half `(OCB)` lie in xz-plane. A time varying magnetic field axis here given by `B=alpha(thatj-2thatk)` where `alpha` is a positive constant. What will be the direction of induced current.

A rectangular wire loop with length a and width b lies in the xy-plane as shown. Within the loop, there is a time dependent magnetic field given by vecB = c[(x cos omega t)hati+ (y sin omega t)hatk] . Here , c and omega are constants. The magnitude of emf induced in the loop as function of time is

A non-planar circular loop consists of two semi-circles one of which lies in yz -plane & the other is in xz -plane as shown.The magnetic force experienced by positive charge of value Q moving with velocity v along x direction when it is at the origin is:

A rectangular loop of sides of length l and b is placed in x-y plane. A uniform but time varying magnetic field of strength vec B = 20 t hat i +10 t^2 hat j+50 hat k where t is time elapsed. The magnitude of induced emf at time t is:

In Fig ABCDEFA was a square loop of side l, but is folded in two equal parts so that half of it lies in the x-z plane and the other half lies in the y-z plane. The origin O is centre of the frame also. The loop carries current 'i'. The magnetic field at the centre is

A circular loop of radius R carrying current I is kept in XZ plane. A uniform and constant magnetic field vecB=(B_(0)hati+2B_(0)hatj+3B_(0)hatk) exists in the region ( B_(0)- a positive constant). Then the magnitude of the torque acting on the loop will be

A rectangular loop of wire oriented with the left corner at the origin one edge along X -axis and the other along Y axis as shown in the A magnetic field is into the page and has a magnitude that is given by b=alphay where alpha is contant Find the total magnetic force on the loop if it carries current

A square loop ABCD of side l is moving the xy plane with velocity vecv=betat hatj .There exists a non-uniform magnetic field vecB=-B_(0)(1+alphay^(2)) hatk (y gt 0) , where B_(0) and alpha are positive constants. Initially, the upper wire of the loop is at y=0 .Find the induced voltage across the resistance R as a function of time.Neglect the magnetic force due to induced current.

A rectangular loop of wire is oriented with the left corner at the origin, one edge along X-axis and the other edge along Y-axis as shown in the figure. A magnetic field is into the page and has a magnitude that is given by beta=alphay where alpha is constant. Find the total magnetic force on the loop if it carries carrent i.

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 is bent in the form of a square of side 'a' in a varying magnetic field bar(B) = alpha B_(0) t hat(k) . If the resistance per unit length is lambda , then find the following. {:i) The direction of induction current {:ii) The current in the loop {:iii) Potential difference between P and Q