Why Is the Electric Field at the Origin Zero for This Charge Configuration?

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Homework Help Overview

The discussion revolves around calculating the electric field at the origin due to a specific configuration of charges: two positive charges and two negative charges positioned symmetrically around the origin. Participants are exploring the implications of symmetry and distance in the context of electric fields.

Discussion Character

  • Exploratory, Assumption checking, Conceptual clarification

Approaches and Questions Raised

  • Participants discuss the calculation of the electric field using the formula for electric field strength and consider the vector sum of the fields from each charge. There is an emphasis on symmetry and the potential for cancellation of the electric fields.

Discussion Status

Some participants have provided guidance on how to approach the problem, including suggestions to visualize the configuration and check distances. There is acknowledgment of a potential misunderstanding regarding the distance from the origin to the charges, indicating an ongoing exploration of the concepts involved.

Contextual Notes

Participants are working under the constraints of a homework assignment, which may limit the information they can use or the methods they can apply. There is a focus on ensuring the correct interpretation of distances in the context of the problem.

don23
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Can someone help with this? I want to say the answer is zero but I don't know how to explain it.

Calculate the electric field at the origin due to the following distribution of charges: +q at (x,y)=(a,a), +q at (-a,a), -q at (-a,-a) and -q at (a,-a).
 
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Each charge has an E field described by

\vec{E} = \frac{kq}{\vec{r}^2}.

Just find the vector sum at the origin, or better yet draw it out and see if you can cancel by symmetry.
 
thanks

Thank you for the reply.
would i be correct is saying that

E= (+q*k/a^2+a^2)+(+q*k/a^2+a^2)+(-q*k/a^2+a^2)+(-q*k/a^2+a^2)= 0

??
 
Your conclusion is correct, but you measured the distance from the origin incorrectly, remember the distance between the origin and the point (x,y) is

\sqrt{x^2+y^2}
 
thank you

thanks again.
in this case wouldn't the distance from the origin be (sq rt of (a^2+a^2))? In the original problem all the charges are at (a,a),(-a,a),(-a,-a) and (a,-a).
 
Yes that's correct, it simplifies to \sqrt{2}a[/tex]
 

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