As seen in Fig. 30-47, a square loop of wire has sides of length 3.0 cm. A magnetic field is directed out of the page, its magnitude is given by `B = 5.0t^(2)y` , where B is in teslas, t is in seconds, and y is in meters. At t = 2.5 s, what are the (a) magnitude and (b) direction of the emf induced in the loop?

The figure shows a square loop wire with sides of length l=2cm . A magnetic field position points into the page and its magnitude is given by B=4t^(2)yT,t is in second and y is in metre. Determine the emf induced around the square at t=2.5sec .

Induced emf due to a changing nonuniform B field Figure 30-9 shows a rectangular loop of wire immersed in a nonuniform and varying magnetic field vecB that is perpendicular to and directed into the page. The field's magnitude is given by B = 4t^(2)x^(2) , with B in teslas, tin seconds, and x in meters. (Note that the function depends on both time and position.) The loop has width W = 3.0 m and height H = 2.0 m. What are the magnitude and direction of the induced emf E around the loop at t = 0.10 s?

Induced emf and current due to a changing uniform B field Figure 30-8 shows a conducting loop consisting of a half-circle of radius r = 0.20 m and three straight sections. The halfcircle lies in a uniform magnetic field vecB that is directed out of the page, the field magnitude is given by B = 4.0t^(2) + 2.0t + 3.0 , with B in teslas and tin seconds. An ideal battery with emf E_("bat") = 2.0 V is connected to the loop. The resistance of the loop is 2.0 Omega . (a) What are the magnitude and direction of the emf E_("ind") induced around the loop by field vecB at t = 10 s? (b) What is the current in the loop at t = 10 s?

A square wire loop with 2.00 m sides is perpendicular to a uniform magnetic field, with half the area of the loop in the field as shown in Fig. 30-49. The loop contains an ideal battery with emf E = 12.0 V. If the magnitude of the field varies with time according to B = 0.603 - 1.25t, with B in teslas and I in seconds, what are (a) the net emf in the circuit and (b) the direction of the (net) current around the loop?

A square loop of side 22cm is converted into circular loop in 0.4s . A uniform magnetic field of 0.2T directed normal to the loop, then the induced in the loop is

The figure shows a uniform, 3.0 T magnetic field that is normal to the plane of a conducting, circular loop with a resistance of 1.5 Omega and a radius of 0.024 m. The magnetic field is directed out of the paper as shown . Note: The area of the non-circular portion of the wire is considered negligible compared to that of the circular loop. What is the magnitude of the average induced emf in the loop if the magnitude of the magnetic field is doubled in 0.4 s?

The displacement of a particle moving along an x axis is given by x=18t+5.0t^(2) , where x is in meters and t is in seconds. Calculate (a) the instantaneous velocity at t=2.0s and (b) the average velocity between t=2.0s and t=3.0s .

Figures shows a square loop of side 1m and resistance 1Omega . The magnetic field on left side of line PQ has a magnitude B=1.0T. The work done in pulling the loop out of the field uniformly in 1 s is

The mangnetic flux passsing perpendicular to the plane of a coil and directed into the paper is given by phi = 5t^(2) + 6t+ 2 where phi is in milliwebers and t in seconds. (a) What is the magnitude of the induced emf set up in the loop at t=1s ? (b) What is the direction of current through the resistor R ?