A uniform magnetic field is restricted within a region of radius 1m. The magnetic field changes with time(t) as `vecB=B_0((2t)/3)hatk`. A loop of radius 2m is outside the region of magnetic field as shown in figure. The emf induced in loop is

A uniform magnetic field is restricted within a region of radius r. The magnetic field changes with time at a rate (dB)/(dt) . Loop 1 of radius R gt r encloses the region r and loop 2 of radius R is outside the region of magnetic field as shown in figure. Then, the emf generated is Zero in loop 1 and zero in loop 2 − d B d t π r 2 in loop 1 and − d B d t π 2 in loop 2 − d B d t π R 2 in loop 1 and zero in loop 2 − d B d t π r 2 in loop 1 and zero in loop 2

A semicircular loop of radius R is rotated with an angular velocity omega perpendicular to the plane of a magnetic field B as shown in the figure. Emf Induced in the loop is

Magnetic field in cylindrical region of radius R in inward direction is as shown in figure.

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

A semi-circular loop of radius R is placed in a uniform magnetic field as shown. It is pulled with a constant velocity. The induced emf in the loop is

A uniform but time varying magnetic field is present in a circular region of radius R. The magnetic field is perpendicular and into the plane of the loop and the magnitude of field is increasing at a constant rate alpha . There is a straight conducting rod of length 2R placed as shown in figure. The magnitude of induced emf across the rod is

A conductor of length 0.1m is moving with a velocity of 4m/s in a uniform magnetic field of 2T as shown in the figure. Find the emf induced ?

A conductor of length 0.1m is moving with a velocity of 4m/ s in a uniform magnetic field of 2T as shown in the figure. Find the emf induced ?

A metallic loop is placed in a nonuniform magnetic field. Will an emf be induced in the loop?

A time varying uniform magnetic field passes through a circular region of radius R. The magnetic field is directed outwards and it is a function of radial distance 'r' and time 't' according to relation B-B_(0)rt. The induced electric field strength at a radial distance R//2 from the centre will be.