Green's Function Using Image Charge

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ahmad1992
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Homework Statement


Write an expression for the Dirichlet Green's function of the part of the space bounded by two infinite conducting plates parallel each other and separated by distance of d. Use Image charge method

Homework Equations


G (at z=0) =0, G (at z=d) =0
I guess

The Attempt at a Solution


I am confuse about image charge method. What is the actual principles of this method?
On most of problem I ever seen, when we use image method, there is always a point charge in the system, however in this case not. Can anyone help me?
 
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Is this a QM greensfunction, such as the ones used in perturbation theory, or a classical?
 
Ah yes just saw, can't help you sorry. I know QM but my classical physics is a bit rusty.
 
I have not done this problem before, but if you are building the green's function for one infinite plate, it is the limit as the point charge approaches the plate + its image being reflected back at it. It seems like for 2 plates, you will have to satisfy the 2 boundary conditions. Here is what appears to be a good explanation of the single plate case (and other examples).
http://www.phys.lsu.edu/~jarrell/COURSES/ELECTRODYNAMICS/Chap2/chap2.pdf
 
ahmad1992 said:

Homework Statement


Write an expression for the Dirichlet Green's function of the part of the space bounded by two infinite conducting plates parallel each other and separated by distance of d. Use Image charge method

Homework Equations


G (at z=0) =0, G (at z=d) =0
I guess

The Attempt at a Solution


I am confuse about image charge method. What is the actual principles of this method?
On most of problem I ever seen, when we use image method, there is always a point charge in the system, however in this case not. Can anyone help me?
The Green's function is essentially the potential due to a point charge. The potential will be a function of ##\vec{r}##, the position of the point charge.