Calculate Resultant Force on Positive Charge in Rectangle with 4 Charges

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SUMMARY

The discussion focuses on calculating the resultant force on a positive charge located at the corners of a rectangle with dimensions a = 1.3 m and b = 0.8 m, influenced by four charges. Participants emphasize the application of Coulomb's law, expressed as F = k(q1)(q2)/r², and the principle of superposition to determine the net force. The method involves calculating the force from each negative charge individually and then vectorially summing these forces, taking into account their respective x and y components. The discussion clarifies that opposite charges attract while like charges repel, affecting the resultant force's direction and magnitude.

PREREQUISITES
  • Coulomb's Law (F = k(q1)(q2)/r²)
  • Vector addition of forces
  • Understanding of charge interactions (attraction and repulsion)
  • Trigonometric functions for resolving components (cosine and sine)
NEXT STEPS
  • Study the application of Coulomb's law in various charge configurations
  • Learn vector addition techniques for forces in two dimensions
  • Explore the concept of electric field and its relation to force on charges
  • Investigate the effects of multiple charges on a single charge in different geometries
USEFUL FOR

Students in physics, electrical engineers, and anyone interested in electrostatics and force calculations in multi-charge systems.

confused1
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Four charges are placed on the corners of a rectangle. What is the resultant force on the positive charge (a = 1.3 m, b = 0.8 m, q = 1.8 × 10-9C)?

HELP: Use Coulomb's law and superposition.

HELP: Superposition tells us that we can find the force on the positive charge by looking at the negative charges one at a time. First find the force on the positive charge from just one of the negative charges, then from only the second negative charge, then from only the third negative charge. Then just "add" up these forces...remembering the vector nature of forces. (How do we "add" vectors?)

HELP: Coulomb's law is F=k(q1)(q2)/r2. Remember, however, that force is a vector so the magnitude of the total force will be the square root of the sum of the forces in the x-direction squared plus the sum of the forces in the y-direction squared. To determine the x- and y-component of the force notice that o ne charge exerts a force in the x-direction only, one charge exerts a force in the y-direction only, and one charge exerts a force that needs to be broken down into x and y components. When breaking the diagonal force down into x and y components, remember cosq = a/r and sinq = b/r.
 
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confused1 said:
Four charges are placed on the corners of a rectangle. What is the resultant force on the positive charge (a = 1.3 m, b = 0.8 m, q = 1.8 × 10-9C)?
This would indicate all charges are + and given by q?

confused1 said:
HELP: Use Coulomb's law and superposition.
Yes

confused1 said:
HELP: Superposition tells us that we can find the force on the positive charge by looking at the negative charges one at a time. First find the force on the positive charge from just one of the negative charges, then from only the second negative charge, then from only the third negative charge. Then just "add" up these forces...remembering the vector nature of forces. (How do we "add" vectors?)
Well it applies to charge in general. Opposite charges (+ -) attract, like charges (+ +) or (- -) repel, but the magnitude of force would be the same dependent only on magnitudes of charges and distance of separation.

confused1 said:
HELP: Coulomb's law is F=k(q1)(q2)/r2. Remember, however, that force is a vector so the magnitude of the total force will be the square root of the sum of the forces in the x-direction squared plus the sum of the forces in the y-direction squared. To determine the x- and y-component of the force notice that o ne charge exerts a force in the x-direction only, one charge exerts a force in the y-direction only, and one charge exerts a force that needs to be broken down into x and y components. When breaking the diagonal force down into x and y components, remember cosq = a/r and sinq = b/r.
That is one way, or one simply adds corresponding components of the vectors.
 

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