Problem 8: An oscillating LC circuit has inductance L and capacitance C. The maximum charge on the capacitor during oscillations is qmax- Part (a) Enter an expression for the charge on the capacitor, when energy is shared equally between the electric field in the capacitor and the magnetic neld in the inductor. Form your expression in terms of qmax- q = Y 7 8 9 НОМE C d g 4 6 h j k 1 2 3 n P + END qm qmax S VO BACKSPACE CLEAR DEL Submit Hint Feedback I give up! Part (b) Using the value qmax = 5 nC, find the charge on the capacitor, in nanocoulombs, when energy is shared equally between the electric field in the capacitor and the magnetic field in the inductor. Be careful with your charge units. |Part (c) Enter an expression for the current through the inductor, when energy is shared equally between the electric field in the capacitor and the magnetic field in the inductor. Form your expression in terms of the inductance, L, the capacitance, C, and qmax- Part (d) Given the values qmax =5 nC, L= 22 mH, and C = 1.2 µF, find the current through the inductor, in amperes, when energy is shared equally between the electric field in the capacitor and the magnetic field in the inductor.

Problem 8: An oscillating LC circuit has inductance L and capacitance C. The maximum charge on the capacitor during oscillations is qmax- Part (a) Enter an expression for the charge on the capacitor, when energy is shared equally between the electric field in the capacitor and the magnetic neld in the inductor. Form your expression in terms of qmax- q = Y 7 8 9 НОМE C d g 4 6 h j k 1 2 3 n P + END qm qmax S VO BACKSPACE CLEAR DEL Submit Hint Feedback I give up! Part (b) Using the value qmax = 5 nC, find the charge on the capacitor, in nanocoulombs, when energy is shared equally between the electric field in the capacitor and the magnetic field in the inductor. Be careful with your charge units. |Part (c) Enter an expression for the current through the inductor, when energy is shared equally between the electric field in the capacitor and the magnetic field in the inductor. Form your expression in terms of the inductance, L, the capacitance, C, and qmax- Part (d) Given the values qmax =5 nC, L= 22 mH, and C = 1.2 µF, find the current through the inductor, in amperes, when energy is shared equally between the electric field in the capacitor and the magnetic field in the inductor.

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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