A small metal sphere with a net charge of q1 = -2.90 μC stands attached to an insulating rod. A second small metal sphere with a net charge of -7.20 μC and a mass of 1.70 g is moving towards the charge q1. While the distance between the two spheres is 0.800 m, the speed of q2 is 22.0 m / s. (Figure 1) Consider both spheres as point charges and ignore the gravitational force. PART A What is the speed of the q2 charge when the distance between the two spheres is 0.390 m? PART B How close can the q2 load get to the q1 load?
A small metal sphere with a net charge of q1 = -2.90 μC stands attached to an insulating rod. A second small metal sphere with a net charge of -7.20 μC and a mass of 1.70 g is moving towards the charge q1. While the distance between the two spheres is 0.800 m, the speed of q2 is 22.0 m / s. (Figure 1) Consider both spheres as point charges and ignore the gravitational force. PART A What is the speed of the q2 charge when the distance between the two spheres is 0.390 m? PART B How close can the q2 load get to the q1 load?
College Physics
1st Edition
ISBN:9781938168000
Author:Paul Peter Urone, Roger Hinrichs
Publisher:Paul Peter Urone, Roger Hinrichs
Chapter1: Introduction: The Nature Of Science And Physics
Section: Chapter Questions
Problem 22PE: What is the area of a circle 3.102 cm in diameter?
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A small metal sphere with a net charge of q1 = -2.90 μC stands attached to an insulating rod. A second small metal sphere with a net charge of -7.20 μC and a mass of 1.70 g is moving towards the charge q1. While the distance between the two spheres is 0.800 m, the speed of q2 is 22.0 m / s. (Figure 1) Consider both spheres as point charges and ignore the gravitational force.
PART A
What is the speed of the q2 charge when the distance between the two spheres is 0.390 m?
PART B
How close can the q2 load get to the q1 load?
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