34. ★★ A circular loop of radius R = 10.0 cm is coaxialwith a solenoid (r= 0.0500 m, € = 1.00 m, and 750 turns), asshown in Figure 25-58. The current in the circuit decreaseslinearly from 1.00 A to 4.60 A over 0.500 s.(a) Calculate the induced emf in the loop.(b)(c)Calculate the induced electric field in the loop.When the resistance of the loop is 20.02, how muchenergy will be dissipated by the loop in 10.0 s?mvariableresistorFigure 25-58 Problem 34.RE

Given data: A circular loop radius R=10 cm The solenoid radius r=0.05 m The solenoid length l=1.00 m…

34. ★★ A circular loop of radius R = 10.0 cm is coaxial ** with a solenoid (r= 0.0500 m, €= 1.00 m, and 750 turns), as shown in Figure 25-58. The current in the circuit decreases linearly from 1.00 A to 4.60 A over 0.500 s (a) Calculate the induced emf in the loop. (b) Calculate the induced electric field in the loop. (c) When the resistance of the loop is 20.02, how much energy will be dissipated by the loop in 10.0 s? cocazbootcon variable resistor

34. ★★ A circular loop of radius R = 10.0 cm is coaxial ** with a solenoid (r= 0.0500 m, €= 1.00 m, and 750 turns), as shown in Figure 25-58. The current in the circuit decreases linearly from 1.00 A to 4.60 A over 0.500 s (a) Calculate the induced emf in the loop. (b) Calculate the induced electric field in the loop. (c) When the resistance of the loop is 20.02, how much energy will be dissipated by the loop in 10.0 s? cocazbootcon variable resistor

College Physics

11th Edition

ISBN:9781305952300

Author:Raymond A. Serway, Chris Vuille

Publisher:Raymond A. Serway, Chris Vuille

Chapter1: Units, Trigonometry. And Vectors

Section: Chapter Questions

Problem 1CQ: Estimate the order of magnitude of the length, in meters, of each of the following; (a) a mouse, (b)...

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