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(a)
The effect on magnitude of field strength in the given situation.
(a)
Explanation of Solution
Given:
Electric field strength, E due to charge Q at distance d .
Distance d is tripled.
Formula Used:
Electric field:
Here, k is the Coulomb’s constant, Q is the charge and dis the distance.
Calculation:
When, d is tripled, electric field strength reduces by 9 times.
Conclusion:
The field strength decreases by 9 times when d is increased by 3 times.
(b)
The effect on magnitude of field strength in the given situation.
(b)
Explanation of Solution
Given:
Electric field strength, E due to charge Q at distance d .
Charge Q is tripled.
Formula Used:
Electric field:
Here, k is the Coulomb’s constant, Q is the charge and dis the distance.
Calculation:
When, Q is tripled, electric field strength is also tripled at distance d .
Conclusion:
The field strength increases by 3 times when Q is increased by 3 times.
(c)
The effect on magnitude of field strength in the given situation.
(c)
Explanation of Solution
Given:
Electric field strength, E due to charge Q at distance d .
Charge Q is tripled.
Formula Used:
Electric field:
Here, k is the Coulomb’s constant, Q is the charge and dis the distance.
Calculation:
When, Qand d are tripled, electric field strength is tripled due to tripled charge and reduced by 9 times due to tripled distance. So, overall, the field strength decreases by 3 times.
Conclusion:
The field strength decreased by 3 times.
(e)
The effect on magnitude of field strength in the given situation.
(e)
Explanation of Solution
Given:
Electric field strength, E due to charge Q at distance d .
Charge Q , distance d and test charge
Formula Used:
Electric field:
Here, k is the Coulomb’s constant, Q is the charge and dis the distance.
Calculation:
The field strength does not depend on test charge. Thus, tripling the test charge would not affect the it.
When, Q and d are tripled, electric field strength is tripled due to tripled charge and reduced by 9 times due to tripled distance. So, overall, the field strength decreases by 3 times.
Conclusion:
The field strength decreased by 3 times.
Chapter 23 Solutions
Glencoe Physics: Principles and Problems, Student Edition
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