Calculating Electric Field at Multiple Points in a Charged System

AI Thread Summary
The discussion focuses on calculating the electric field at points A, B, C, and D in a charged system using the formula E = kQ / r^2. The user expresses confusion about the direction and components of the electric field at point A, particularly regarding whether to include angles when calculating the contributions from multiple charges. Clarification is provided on how to split the electric field vectors into their horizontal and vertical components, emphasizing the need to use trigonometric functions to resolve these components accurately. The user ultimately concludes that they can combine the vertical components and the horizontal component to form a triangle, allowing them to calculate the total electric field's magnitude and direction. The conversation highlights the importance of vector addition in electric field calculations.
fymdmk
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Homework Statement


In the figure (attached), find the magnitude and direction of the electric field at points A, B, C and D.

Homework Equations


E = kQ / r^2

The Attempt at a Solution


I'm just a little lost with the directions/if I need to be including angles
so for point A:
E = k 7.5e^5C / 0.25m + k 7.5e^5C / ?
is it 0.55m (as figured out by Pythagorean theorem) or would it be the X is 0.55cos26 and Y is 0.55 sin26 + the other charge (since it is only in the Y direction)

thanks!
 

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fymdmk said:
E = k 7.5e^5C / 0.25m + k 7.5e^5C / ?
Electric field is a vector quantity. You don't in general add two electric fields like you did above. Do you know how to add two vectors?
 
right - okay so then its probably my second guess? splitting it into X and Y?

so point A would have the Y of the first 75 charge plus the Y of the second 75 charge which would be sin26 0.55 and then the X's would just be the cos26 0.55 of the second 75 charge? does that make sense
 
fymdmk said:
so point A would have the Y of the first 75 charge plus the Y of the second 75 charge which would be sin26 0.55 and then the X's would just be the cos26 0.55 of the second 75 charge? does that make sense
You don't elaborate your second attempt in a good mathematical language. You merely guessed that some expression of the form 0.55 cos 26 is involved, which I don't know how you will make it relevant with the problem.
To start, let's first consider the field at point A. Then write out the field vectors from each charge at this point.
 
sorry! okay so point A:

charge 1 (bottom left) would be: k (7.5e^5C)/0.25m in the upwards direction

charge 2 (bottom right) would be split into 2 vectors.
1) find the hypotenuse of the triangle that would get from the charge to point A. this value would be x = sqr rt (50^2 + 25^2) = 55cm = 0.55m
2) find the angle between the 50cm bottom and 55cm hypotanuse. If I use cos that would be cos^-1 (50/55) = 25 degrees.
3) split the bottom charge into 2 vectors:
vertical vector = k (7.5e^5 C) / 0.55 sin25 in the upwards direction
horizontal vector = k (7.5e^5 C) / 0.55 cos25 in the leftwards direction

so in order to get the total I would add the two vertical components of the different charges and then...I get stuck, do I need to make another triangle?
 
fymdmk said:
k (7.5e^5C)/0.25
The magnitude of electric field from a point charge is inversely proportional to the square of the distance between the source point and the observation point.
fymdmk said:
k (7.5e^5 C) / 0.55 sin25
Where is the ##\sin 25^o## located, in the denominator or numerator? Also, take my first statement above into account.
 
sorry I forgot that the direction is squared, so it would be 0.25 (or 055) ^2

is the sin25 in the numerator then? because it is affecting the charge?

that still leaves me with 2 upwards vertical components, and 1 left horizontal component - so then do I make a new triangle to get the total and direction of the electric field on A?
 
fymdmk said:
is the sin25 in the numerator then?
I was asking you. Ok, let's say we have a vector ##\mathbf{a} = a_x\hat{i} + a_y\hat{j}## (see picture below)
components.png

the magnitude of ##\mathbf{a}## is ##a = \sqrt{a_x^2+a_y^2}##. Given this information, how does ##a_x## and ##a_y## look like in terms of ##a## and ##\theta##?
 
okay so sin25 is definitely in the numerator, I see what you're saying.

and I think I've got that ax would be a acostheta and ay would be asintheta. so I add my two vertical vectors, and create a triangle using my combined two vertical vectors tip to toe with the horizontal vector, and find the hypotenuse which would be the total electric field magnitude, and then solve the new angle theta which would be the direction
 
  • #10
fymdmk said:
I think I've got that ax would be a acostheta and ay would be asintheta.
Yes.
fymdmk said:
so I add my two vertical vectors, and create a triangle using my combined two vertical vectors tip to toe with the horizontal vector, and find the hypotenuse which would be the total electric field magnitude, and then solve the new angle theta which would be the direction
Yes.
 
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Likes gracy
  • #11
awesome, thanks!
 

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