Electric Potential and Potential Energy Due to Charged Particles

AI Thread Summary
Two charged particles of equal magnitude are positioned symmetrically along the y-axis, affecting the electric potential along the x-axis and y-axis. The potential is expressed in terms of (KeQ)/a, allowing for graphing without knowing the specific value of 'a' by using x/a instead. Absolute values are used for the y-axis calculations to ensure that distances remain positive, as potential is based on the distance from the charges. The discussion clarifies that the square root in the potential formula inherently accounts for the positive distance, negating the need for absolute values in that context. Understanding that distance cannot be negative is crucial for correctly interpreting electric potential due to charged particles.
brojas7
Messages
20
Reaction score
0
Two charged particles of equal magnitude are located along the y-axis equal distances above and below the x-axis.
Plot a graph of the electric potential at points along the x-axis over the interval -3a<x<3a. You should plot the potential in units of (KeQ)/a
Let the charge of the particle located at y=-a be negative. Plot the potential along the y-axis over the interval -4a<y<4a.

I was able to do :
(KeQ1)/r^2 + (KeQ2)/r^2 =
(KeQ)/ sqrt(x^2 + a^2) + (KeQ)/ sqrt(x^2 + -a^2) =
(2KeQ)/ sqrt(x^2 + -a^2)

Why did they factor out a KeQ/a, was it necessary? how do you plug in x to get the graph if you don't know 'a'.

and for the y axis, why did they get an absolute value for y-a and y+a.



ANSWER:


20130402_122805_zps53662169.jpg
 

Attachments

  • 20130402_122805.jpg
    20130402_122805.jpg
    28.5 KB · Views: 736
Physics news on Phys.org
brojas7 said:
Two charged particles of equal magnitude are located along the y-axis equal distances above and below the x-axis.
Plot a graph of the electric potential at points along the x-axis over the interval -3a<x<3a. You should plot the potential in units of (KeQ)/a
Let the charge of the particle located at y=-a be negative. Plot the potential along the y-axis over the interval -4a<y<4a.

I was able to do :
(KeQ1)/r^2 + (KeQ2)/r^2 =
(KeQ)/ sqrt(x^2 + a^2) + (KeQ)/ sqrt(x^2 + -a^2) =
(2KeQ)/ sqrt(x^2 + -a^2)

Why did they factor out a KeQ/a, was it necessary? how do you plug in x to get the graph if you don't know 'a'.
It made it possible to graph V as a function of x/a only. You don't need to know a if you're happy with x/a for the x-axis (really making it an "x/a" axis).
and for the y axis, why did they get an absolute value for y-a and y+a.

Because r is always positive, so the quantity y-a or y- (-a) must be positive and therefore put in absolute bars. y can be as negative as -4a, remember. (a is always positive.)

BTW your 1st eq. has a typo in it. r, not r^2, as you know.
 
Ok the first part makes sense as for the second, since r is always positive and must put in the absolute bars, why didn't we do that with the first? Is it because the square root already takes care of that?
 
Also, why must r always be positive? Or is this just a rule?
And thank you for the correction, I completely overlooked it, even on paper.
 
brojas7 said:
Ok the first part makes sense as for the second, since r is always positive and must put in the absolute bars, why didn't we do that with the first? Is it because the square root already takes care of that?

Right. You just ignore the negative root.
 
brojas7 said:
Also, why must r always be positive? Or is this just a rule?
And thank you for the correction, I completely overlooked it, even on paper.

You can't have negative distance! The sign of the potential due to a charge is determined solely by the sign of the charge.
 
Ok it all makes sense now. I didn't think of it as a distance. thank you so much
 
Back
Top