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1.5 Other Charge Distributions - Fields & Potentials

4 min readjune 18, 2024

Peter Apps

Peter Apps

Peter Apps

Peter Apps


AP Physics C: E&M 💡

26 resources
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This topic is a catch-all for more advanced applications of Charge Distributions, Gauss' Law, and calculating Electric Potentials. All of the concepts are covered in the previous sections, so if you need to, re-read those first.

Extended Charge Distributions

Up until now, we've dealt with charged objects as points, but sometimes we can't approximate the charge to be in a single location. These extended charge distributions are cases where the charge is in a ring, or line, or sheet.
The proccess for tackling all of these are very similar. We're going to chunk the total charge Q into into pieces, dq, which each contributes a partial field, dE. The entire equation is dE = k dq/r^2 * r, where r is the radius vector. By integrating that equation, we can sum up all of the dq which sums all of the dE to find the total field E.
Ring of Charge Example:
https://firebasestorage.googleapis.com/v0/b/fiveable-92889.appspot.com/o/images%2F-v1S5CQhDau3k.png?alt=media&token=8a9246ee-4b4f-4d94-a583-331e3d8cee7f

Image from dev.physicslab.org

https://firebasestorage.googleapis.com/v0/b/fiveable-92889.appspot.com/o/images%2F-SMay258Zr2uS.PNG?alt=media&token=615e16ba-114e-4491-8380-e9a39a4d2da3
If we assume that x >>> a, then we get the same result as for a point charge we found in Section 1. 2! This is a more general case, but we can see that it simplifies to the basic case!
https://firebasestorage.googleapis.com/v0/b/fiveable-92889.appspot.com/o/images%2F-AlNmUcLNZGYY.PNG?alt=media&token=441ed930-cba3-41c7-8526-78ad7a288e3b
Line of Charge Example:
https://firebasestorage.googleapis.com/v0/b/fiveable-92889.appspot.com/o/images%2F-DZIdQkMSeBWk.png?alt=media&token=706d2595-1450-47ac-b256-186c02846169

Image created by author

Start by finding dq in terms of y using linear charge density ƛ.
https://firebasestorage.googleapis.com/v0/b/fiveable-92889.appspot.com/o/images%2FScreenshot%202022-12-29%20at%202.16-UFZF8nR4VHQA.png?alt=media&token=88f316df-71e8-4eec-8e82-8152c693529f
Then, plug into our integral just like in the previous example. In this case, we can find r by using the pythagoreon theorem between y and x.
https://firebasestorage.googleapis.com/v0/b/fiveable-92889.appspot.com/o/images%2FScreenshot%202022-12-29%20at%202.17-z8tEQjtcZMkl.png?alt=media&token=9179139e-ce75-43ac-8825-5346f13ec882

Gauss' Law for Various Shapes

You should be able to use Gauss' Law to derive these if you need to. Check out hyperphysics for more info.
Line of Charge:
https://firebasestorage.googleapis.com/v0/b/fiveable-92889.appspot.com/o/images%2F-Beuigbr2OzdR.PNG?alt=media&token=7545bab0-b520-4248-9063-fc03ccb94a60
Imagine enclosing the line of charge in a cylinder, use linear charge density λ = Q/L to find the enclosed charge, and then use A=2πrL.
Point, Hoop, or Sphere (fully enclosed):
https://firebasestorage.googleapis.com/v0/b/fiveable-92889.appspot.com/o/images%2FScreenshot%202022-12-29%20at%202.19-Ko9vubD7YVa2.png?alt=media&token=4abb450d-01dd-4bcf-bf48-9a523a3ba3c8
Imagine wrapping the point or hoop in a sphere. Then use A = 4πr^2.
Sphere (not fully enclosed):
https://firebasestorage.googleapis.com/v0/b/fiveable-92889.appspot.com/o/images%2F-804RIXsSlmd5.PNG?alt=media&token=449fd4eb-d21a-4cb1-bd27-e3c8f54c70f3
Note for Spheres: The electric field inside a uniformly charged sphere is proportional to r until r = R, then it behaves as an inverse square.
https://firebasestorage.googleapis.com/v0/b/fiveable-92889.appspot.com/o/images%2F-anVgVuuEidYQ.jpg_revision%3D1?alt=media&token=2be99a40-e51c-4ccf-bbea-443280030676

Image Courtesy of phys.libretexts.org (CC BY 4.0)

Insulating Sheet of Charge:
https://firebasestorage.googleapis.com/v0/b/fiveable-92889.appspot.com/o/images%2FScreenshot%202022-12-29%20at%202.20-EZQ9NwtDlnKS.png?alt=media&token=7f9fe5b9-6290-4390-be96-3dfda8e295eb
Enclose the sheet in a rectangle, being careful because there are fields on both side of the sheet. Use area charge density σ = Q/A --> q_enc = σA and E∲dA=2EA.

Potential Difference for a Variety of Shapes

This is more straightforward. For all the shapes, simply apply Gauss' Law to find an expression for E, then plug that into
https://firebasestorage.googleapis.com/v0/b/fiveable-92889.appspot.com/o/images%2F-oN911m1hneBB.PNG?alt=media&token=9ab991ed-b2af-4906-b19d-4313c74d8e7a
Line of Charge Example:
https://firebasestorage.googleapis.com/v0/b/fiveable-92889.appspot.com/o/images%2F-HJ00jtXtQXEB.PNG?alt=media&token=7acbc9ae-2c58-4a68-a59f-b00be995601b
Conducting Sheets Example (moving from the sheet to a distance d away):
https://firebasestorage.googleapis.com/v0/b/fiveable-92889.appspot.com/o/images%2F-hZxflwENo5Nr.PNG?alt=media&token=ee659f1f-750d-4c1d-b971-873cc9665e76

Practice Questions

1.
https://firebasestorage.googleapis.com/v0/b/fiveable-92889.appspot.com/o/images%2F-i8OAyI6TDfgS.png?alt=media&token=74d7f969-8851-459a-9672-11ff53f1c8da
a)
https://firebasestorage.googleapis.com/v0/b/fiveable-92889.appspot.com/o/images%2F-lakjQHPDKgTX.png?alt=media&token=edbae3cb-cadf-4f47-80c9-afb164fa4100
b)
https://firebasestorage.googleapis.com/v0/b/fiveable-92889.appspot.com/o/images%2F-xL3MBxXBnFn6.png?alt=media&token=438fbb45-5c02-404b-bd49-7607e3e427e4

Image from collegeboard.org

Answer:
(a) The shells are conducting so the charge is only on their surfaces. Since we're in the region between r1 and r2, we fully enclose Q1. Using Gauss' Law, A is the correct answer.
(b) Relative to infinity, the total potential at r2 is V = k(Q1 + Q2)/r2, when we're between the sphere, we no longer have a change due to V_Q2 because the potential is CONSTANT inside of a conductor (while the Electric Field is zero -- this is an important thing to remember for the AP exam!). However, V_Q1 still varies according to 1/r. This means that E will be the correct answer.
2.
https://firebasestorage.googleapis.com/v0/b/fiveable-92889.appspot.com/o/images%2F-jgorktM8p9fU.png?alt=media&token=91396016-cbee-47ff-9a08-914ddb0bdc3c

Image from collegeboard.org

Answer:
Choice B Is correct. Every point is equidistant from a given x value so V = kQ/r where r =√x^2 + a^2
3.
https://firebasestorage.googleapis.com/v0/b/fiveable-92889.appspot.com/o/images%2Fquestion%203-qxhPHAVsLQLK.png?alt=media&token=253a75a7-d63c-4bb8-a31c-37a5556ca85d

Image from collegeboard.org

Answer:
D is correct. Outside the spheres E = 0 since the total charge enclosed is 0. Inside the negative shell, the potential looks like a positively charged sphere (constant when r < a, and proportional to 1/r when r > a).
Practice FRQ
(courtesy of the College Board website, AP Physics C: Electricity + Magnetism 2007 Free Response Section, Question #2)
https://firebasestorage.googleapis.com/v0/b/fiveable-92889.appspot.com/o/images%2FScreenshot%202022-12-29%20at%202.27-3lRLDDqcEi8L.png?alt=media&token=10ee2c35-404d-4a8b-8f32-c933bad7c6cc
In the figure above, a nonconducting solid sphere of radius a with charge +Q uniformly distributed throughout its volume is concentric with a nonconducting spherical shell of inner radius 2a and outer radius 3a that has a charge -Q uniformly distributed throughout its volume. Express all answers in terms of the given quantities and fundamental constants.
(a) Using Gauss’s law, derive expressions for the magnitude of the electric field as a function of radius r in the following regions.
i. Within the solid sphere (r < a)
ii. Between the solid sphere and the spherical shell (a < r < 2a)
iii. Within the spherical shell (2a < r < 3a)
iv. Outside the spherical shell (r > 3a)
(b) What is the electric potential at the outer surface of the spherical shell (r = 3a)? Explain your reasoning.
(c) Derive an expression for the electric potential difference V_X - V_Y between points X and Y shown in the figure.
Scoring Guidelines
The scoring guidelines are located at this PDF from the College Board website for Question #2.
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