A point particle with charge q = -200 nC and mass m = 3.0x10-6 g is released from rest at the midpoint of a parallel-plate capacitor. The capacitor has plate separation d = 3.0 mm. The negative electrode is at x = 0 and the positive electrode is at x = d. The voltage across the capcitor has been measured to be AVC = 2.5 V. In this problem, ignore the weight of the particle. Give all numerical answers to two significant figures. a) How long does it take the particle to strike the capacitor plate, in seconds? b) Through what potential difference has the particle moved, in V?

A point particle with charge q = -200 nC and mass m = 3.0x10-6 g is released from rest at the midpoint of a parallel-plate capacitor. The capacitor has plate separation d = 3.0 mm. The negative electrode is at x = 0 and the positive electrode is at x = d. The voltage across the capcitor has been measured to be AVC = 2.5 V. In this problem, ignore the weight of the particle. Give all numerical answers to two significant figures. a) How long does it take the particle to strike the capacitor plate, in seconds? b) Through what potential difference has the particle moved, in V?

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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Combination of Capacitors

The connection of capacitors can be established in a circuit in two ways.

Question

A point particle with charge q = -200 nC and mass m = 3.0x10-6 g is released from rest at the
midpoint of a parallel-plate capacitor. The capacitor has plate separation d = 3.0 mm. The negative
electrode is at x = 0 and the positive electrode is at x = d. The voltage across the capcitor has been
measured to be AVC = 2.5 V. In this problem, ignore the weight of the particle. Give all numerical
answers to two significant figures.
a) How long does it take the particle to strike the capacitor plate, in seconds?
b) Through what potential difference has the particle moved, in V?

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