How Do Electric Fields Interact in an Equilateral Triangle Setup?

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In an equilateral triangle setup with charges at each corner, the electric field at charge q due to the other two charges is calculated using Coulomb's law. The electric field contributions from the 7.00 µC and -4.00 µC charges are computed separately, resulting in an electric field of 30.94 kN/C in the x-direction and 53.61 kN/C in the y-direction from the 7.00 µC charge. The calculations involve breaking down the electric fields into their respective components using trigonometric functions based on the 60-degree angles. The total electric field at charge q is the vector sum of the contributions from both charges. Accurate placement of charges and careful attention to signs are crucial for correct results.
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Three charges are at the corners of an equilateral triangle with angles 60 degrees (q = 3.00 µC, L = 0.800 m).


(a) Calculate the electric field at the position of charge q due to the 7.00 µC and -4.00 µC charges.

>> I thought I had this right. Not sure why it isn't working! Okay, I used E=ke(|q1|/r^2). I did this twice, for both charges. Then I broke it into x and y components and added the two together and got an answer of 105 i + 85.1 j kN/C.

The only thing I can think of is that I messed up a sign somewhere?? But I'm pretty sure they should all be positive...
 
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One thing to consider: The specific answer depends on which charge is at which corner, and where the corners are located.
 


First, let's review the formula for electric field:

E = k * |q| / r^2

Where:
- E is the electric field
- k is the Coulomb's constant (9 x 10^9 N*m^2/C^2)
- |q| is the magnitude of the charge
- r is the distance between the two charges

Since we are dealing with three charges, we will need to calculate the electric field at the position of charge q due to both the 7.00 µC and -4.00 µC charges separately, and then add them together to get the total electric field.

For the 7.00 µC charge:
- |q| = 7.00 µC
- r = 0.800 m

Plugging these values into the formula, we get:
E = (9 x 10^9 N*m^2/C^2) * (7.00 x 10^-6 C) / (0.800 m)^2
E = 61.88 kN/C

To find the x and y components of this electric field, we need to use trigonometry. Since the angle between the 7.00 µC charge and charge q is 60 degrees, we can use the cosine and sine functions to find the x and y components respectively.

x component:
E_x = E * cos(60)
E_x = 61.88 kN/C * cos(60)
E_x = 61.88 kN/C * 0.5
E_x = 30.94 kN/C

y component:
E_y = E * sin(60)
E_y = 61.88 kN/C * sin(60)
E_y = 61.88 kN/C * 0.866
E_y = 53.61 kN/C

Therefore, the electric field at the position of charge q due to the 7.00 µC charge is:
E = 30.94 i + 53.61 j kN/C

For the -4.00 µC charge:
- |q| = 4.00 µC
- r = 0.800 m

Plugging these values into the formula, we get:
E = (9 x 10^9 N*m^2/C^2) * (4.00 x 10^-6 C) / (0
 

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