There is a uniform magnetic field `B` in a circular region of radius `R` as shown in Fig. 3.149 whose magnitude changes at the rate of `dB//dt`. The emf circular concentric conducting arc of radius `R_(1)` having an angle `theta` as shown `(-OAO' = theta)` is

The flux of electric field through the circular region of radius r as shown in the figure is

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

A part of a long wire carrying a current i is bent into a circle of radius r as shown in figure. The net magnetic field at the centre O of the circular loop is :

A part of a long wire carrying a current i is bent into a circle of radius r as shown in figure. The net magnetic field at the centre O of the circular loop is

The magnetic field perpendicular to the plane of a conducting ring of radius r changes at the rate. (dB)/(dt) . Then

A particle of charge q and mass m is projected with a velocity v_0 toward a circular region having uniform magnetic field B perpendicular and into the plane of paper from point P as shown in Fig. 1.136. R is the radius and O is the center of the circular region. If the line OP makes an angle theta with the direction of v_0 then the value of v_0 so that particle passes through O is

In a very long solenoid of radius R , if the magnetic field chabges at the rate of dB//dt.AB = BC The induced emf for the trianglar circuit ABC shown in Fig. 3.196 is

a uniform magnetic field of induction B fills a cylindrical volume of radius R . A rod AB of length 2l is placed as shown in . If B changing at the rate dB//dt , the emf that is produced by the changing magnetic field and that acts between the ends of the rod is

A uniform magneitc field B fills a cylindrical volume of radius R, A metal rod of length l is placed as shown. If B is changing at the rate of dB/dt, the emf that is produced by the changing magnetic field is xi here p = sqrt(R^(2) - ((l)/(2))^(2)) . then

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