How Does Charge Distribution Affect Forces in a Polygonal Arrangement?

AI Thread Summary
The discussion centers on the forces experienced by a test charge at the center of a regular polygon with 13 equal charges at its corners. For part a, it is established that the symmetrical arrangement results in a net force of zero on the test charge due to the cancellation of forces from all charges. In part b, when one charge is removed, the approach suggests that this can be treated as adding a negative charge in its place, allowing for straightforward calculation of the resultant forces. The symmetry of the polygon plays a crucial role in simplifying the analysis, indicating that the resultant force remains unchanged under rotation. Overall, the key takeaway is that symmetry in charge distribution leads to predictable outcomes in force calculations.
Imo
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Finite Number of Charges around a regular Polygon

I know this is probably an easy one, but I'm just unsure...

There are 13 equal charges, q, that are placed at the corners of a regular 13-sided polygon.

a) What is the Force on a test charge Q at the centre?

What I've been donig is simply saying that all but three of the charges will cancel with the remaining three charges having a Y shape. then here, the total force F =2Fcos(theta) -F and then calculated theta as 2pi/13 (F is the force of one point charge).

Is this right? it seems very complicated for what at first glance seems like a simple question.

b) If one of the 13 charges is removed, what is the force on Q?

In this case I have: F=Fcos[theta] - F. Again, this just doesn't "feel" right.

Can anyone help?
 
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use symmetry in your part a, the answer need no calculation at all...
remove a positive charge is same as place a negative charge on top of that positive charge... after you get part a, just add a negative charge and you'll get the answer, again, no calculation is needed
 
Imo said:
I know this is probably an easy one, but I'm just unsure...

There are 13 equal charges, q, that are placed at the corners of a regular 13-sided polygon.

a) What is the Force on a test charge Q at the centre?

What I've been donig is simply saying that all but three of the charges will cancel with the remaining three charges having a Y shape. then here, the total force F =2Fcos(theta) -F and then calculated theta as 2pi/13 (F is the force of one point charge).

Is this right? it seems very complicated for what at first glance seems like a simple question.

The resultant of all forces will be zero because of symmetry. Think: if there is a nonzero resultant force, and you turn the whole polygon by 2pi/13 the resultant force vector would turn with the same angle. But the configuration is the same as before, you can not see any difference if the "first" charge is upmost or the "second" one. That means that the resultant should be the same as before. What is the vector that stays the same if you turn it?

b) If one of the 13 charges is removed, what is the force on Q?

You can remove a charge by putting an opposite one at the same place. You know the resultant of all 13 equal charges, now you have an additional charge, and the forces add up...

ehild
 

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