How Does Charge Distribution Affect the Electric Field in a Cylindrical Hole?

weaver159
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Homework Statement


We have a infinite plate on the yz plane from x=-d/2 to x=d/2. The plate has a uniform volume charge distribution ρ_{0}. Parallel to the z axis at y=y_{0} we have a cylindrical hole with a radius a. At the center of the hole (paralle to the z-axis) we have an infinite line distribution λ_{0}.
We need to find the field everywhere and the condition that λ_{0}, ρ_{0} must satisfy in order to have zero field outside the hole.


Homework Equations


Gauss's law and the boundary contitions for E,D

The Attempt at a Solution


My first though was offcourse the superpossition principal. I found a problem using it:

The field inside the hole doesn't match the field from an infinite line, as it supposed to.
 
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What is the x-coordinate of the hole's central axis? Is it x = 0? Not sure it matters, but I think it does.
 
rude man said:
What is the x-coordinate of the hole's central axis? Is it x = 0? Not sure it matters, but I think it does.

Yep. My mistake. It is at x = 0.
 
weaver159 said:

Homework Statement


We have a infinite plate on the yz plane from x=-d/2 to x=d/2. The plate has a uniform volume charge distribution ρ_{0}. Parallel to the z axis at y=y_{0} we have a cylindrical hole with a radius a. At the center of the hole (paralle to the z-axis) we have an infinite line distribution λ_{0}.
We need to find the field everywhere and the condition that λ_{0}, ρ_{0} must satisfy in order to have zero field outside the hole.


Homework Equations


Gauss's law and the boundary contitions for E,D

The Attempt at a Solution


My first though was offcourse the superpossition principal. I found a problem using it:

The field inside the hole doesn't match the field from an infinite line, as it supposed to.

I'd go with superposition all right.

1. Sheet without the hole and line charge.
2. Right circular cylinder of where the hole is, charge density the negative of the charge density of the sheet.
3. Just the line charge by itself.
4. Add the whole business.
5. Invoke the requirement of zero E field outside the hole.
 
rude man said:
I'd go with superposition all right.

1. Sheet without the hole and line charge.
2. Right circular cylinder of where the hole is, charge density the negative of the charge density of the sheet.
3. Just the line charge by itself.
4. Add the whole business.
5. Invoke the requirement of zero E field outside the hole.

Thanks for the answer.
That's exactly what I did, but I have a small concern.
The field inside the hole should be λ_{0}/2πε_{0}r, because all we have in the hole is the line distribution. That is not result I get when I add the field from the above 3 distinct distributions. Do I miss anything?

*It is not actually a sheet but a plate, but that I think has minimal effect on the methodology.
 
The fied inside the hole is not just due to the line charge. It's also due to the plate's charge distribution. The field in the hole is due to three separate charge distributions, as I outlined.
 
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