College Physics
2nd Edition
ISBN: 9780134601823
Author: ETKINA, Eugenia, Planinšič, G. (gorazd), Van Heuvelen, Alan
Publisher: Pearson,
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Textbook Question
Chapter 18, Problem 1RQ
Review Question 18.1 How do you estimate the direction of the
Expert Solution & Answer
To determine
The way to estimate the direction of
Answer to Problem 1RQ
Solution:
The direction of the electric field near the two-point charged objects can be estimated by knowing the sign of charge of the charged object and using the law of vector addition in the direction of electric field due to an individual object.
Explanation of Solution
Introduction:
The direction of the electric field near any charged particle can be found by knowing the direction of the electrostatic force experienced by a positive test charge at that point. A test charge is considered to have a unit magnitude.
Explanation:
The direction of the electric-field near two point-like charged objects can be estimated by knowing the sign of the charge on the charged objects.
Place a test charge at the location where the electric field has to be determined. Three possibilities arise:
1. When both the charges are positive, then the test charge is repelled by the charges. So, the electric field due to an individual charge is radially outwards along the line joining the test charge with the respective charged object. The resultant direction of the electric field can be estimated by using the law of vector addition.
2. When both the charges are negative, then the test charge is attracted by the charges. So, the electric field due to an individual charge is radially inwards along the line joining the test charge with the respective charged object. The resultant direction of the electric field can be estimated by using the law of vector addition.
3. When one charge is positive and the other is negative, then the electric field experienced by the test charge due to the positive charge is radially outwards along the line joining the positively charged object with the test charge and the electric field due to the negatively charged object is radially inwards along the line joining the negatively charged object with the test charge. The resultant direction of the electric field can be estimated by using the law of vector addition.
Conclusion:
The direction of the electric field at a point near two point-like charged objects depends on the sign of the two charges.
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Chapter 18 Solutions
College Physics
Ch. 18 - Review Question 18.1 How do you estimate the...Ch. 18 - Review Question 18.2 You have a point-like object...Ch. 18 - Review Question 18.3 Compare the work needed to...Ch. 18 - Review Question 18.4 Imagine that you have an...Ch. 18 - Review Question 18.5 In this section you read that...Ch. 18 - Review Question 18.6 What are the differences...Ch. 18 - Review Question 18.7 A parallel plate capacitor...Ch. 18 - Review Question 18.8 Why do heart contractions...Ch. 18 - 1 What does the field at point A, which is a...Ch. 18 - Why can you shield an object from an external...
Ch. 18 - If you place a block made of a conducting material...Ch. 18 - 4. If you place a block made of a dielectric...Ch. 18 - 5. Two identical positive charges are located at a...Ch. 18 - An electric dipole is placed between the...Ch. 18 - 7. A positive charge is fixed at some distance d...Ch. 18 - Figure Q18.8 shows E field lines in a region of...Ch. 18 - How do we use the model of the electric field to...Ch. 18 - Describe a procedure to determine the E field at...Ch. 18 - What does it mean if the E field at a certain...Ch. 18 - A very small positive charge is placed at one...Ch. 18 - 13. How do we create an E field with parallel...Ch. 18 - 14. Draw a sketch of the field lines caused by...Ch. 18 - 15. Draw a sketch of the field lines caused by...Ch. 18 - 16. Jim thinks that E field lines are the paths...Ch. 18 - Can E field lines cross? Explain why or why not.Ch. 18 - An electron moving horizontally from left to right...Ch. 18 - 19. (a) What does it mean if the electric...Ch. 18 - 20. Explain how grounding works.
Ch. 18 - 21. Explain how shielding works.
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