Electric Field Zero: Point Charges on a Horizontal Axis

AI Thread Summary
The discussion centers on finding the point along a horizontal axis where the electric field is zero between two point charges: +3.0 µC at x = 0 cm and -7.0 µC at x = 20 cm. Participants clarify that the electric fields from each charge must be equal in magnitude but opposite in direction, leading to the equation Ea = Eb. They emphasize the need to define distances R1 and R2 from the point of interest to each charge, noting that R1 + R2 equals the total distance of 20 cm. The final setup involves solving the equation A/R1^2 = B/(R-R1)^2 to find the location where the electric field cancels out. Understanding this setup is crucial for solving the problem effectively.
BuBbLeS01
Messages
602
Reaction score
0

Homework Statement


Two point charges are placed along a horizontal axis with the following values and positions: +3.0 �C at x = 0 cm and -7.0 �C at x = 20 cm. At what point along the x-axis is the electric field zero?


Homework Equations





The Attempt at a Solution


Can I just set Ea = Eb
Ea = K*A/R^2
Eb = K*B/R^2
 
Physics news on Phys.org
thats the basic idea.
but keep in mind that the distances will be different (the R's) and that's what you need to solve for.
Make 2 variables R1 and R2 (for each distance), how are they related?
 
Oh I thought the distance was just the distance between A and B...but its the distance from point A to the point where the electric field and same for B?
 
correct. this is a little strange, we're using the method of a "test charge" which essentially means a pretend charge (you can call the charge "q" but it should always end up canceling in cases like this). a test charge is a way to "test" the field at a certain point where there isn't actually a charge. if you use the distance R (from A to B), that will give you the field at A and at B, note that the forces will be the same at those points (in accordance with Newton's second law), but you are looking for a point inbetween the A and B where the pulls (or pushes) are equal and cancel each other out.
 
So I just use R?
 
no.
you have to use R1 and R2, where R1 + R2 = R (the total distance)
 
I don't get it lol...I'm sorry...
 
Ea = Eb
Ea = K*A/R1^2
Eb = K*B/R2^2
where R2 = R - R1 (in this case R = 20cm the total distance between A and B).
|---------------|-----------------------------|
A_____________C_________________________B
|------R1------||--------------R2------------|
|-------------------R-------------------------|
You're are trying to find the point C, such that the field (or force) is zero.
How about that?
 
Oh wow thanks :)...I see now...So I end up with...
Ea = K*A/R1^2
Eb = K*B/(R-R1)^2

A/R1^2 = B/(R-R1)^2
And I solve for R1??
 
  • #10
exactly!
More importantly, does it makes sense why we set it up like that?
 
  • #11
Yup I completely understand why you set it up like that...thanks!
 

Similar threads

Why is electric field at the center of a charged disk not zero?
Replies
4
Views
3K
How do we know the point of 0 electric field is on the axis?
Replies
3
Views
836
Electric field at a point problem
Replies
1
Views
2K
Can a dipole be modeled as a point charge?
Replies
10
Views
534
Finding the position where the electric field is zero
Replies
2
Views
1K
Direction of electric field vector on the surface of charged conductor
Replies
9
Views
2K
Find the electric field between 2 finite discs
Replies
16
Views
1K
Calculating eletric potential using line integral of electric field
Replies
1
Views
2K
Electric Field Inside a Gaussian Surface with Point Charge q
Replies
4
Views
2K
Electric field strength at a point due to 3 charges
Replies
3
Views
2K

Hot Threads

Recent Insights

Back
Top