Is the Electric Field Unique with Given Charge Density and Boundary Conditions?

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[SOLVED] Griffiths Problem 3.4

Homework Statement


Prove that the field is uniquelly determined when the charge density rho is given and either V or the normal derivative \frac{\partial{V}}{\partial{n}} is specified on each boundary surface. Do not assume the boundaries are conductors, or that V is constant over any given surface.


Homework Equations





The Attempt at a Solution


If you know V on the surface, this is the Corollary to the First Uniqueness Theorem. I don't see how knowing the normal derivative, \frac{\partial{V}}{\partial{n}}= \nabla{V}\cdot \hat{n}, helps at all.
 
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My guess: probably one of those Stoke's theorems (curl, divergence, gradient) will simplify things.
 
The divergence theorem and Poisson's equation tell us that \int_{S} \nabla V \cdot \hat{n} da = \int_{V}\nabla ^2V d\tau = \int_{V}\rho/\epsilon_0 d\tau. We know rho, so we didn't even need the normal derivative to get that integral. Thus, I don't see how the curl, divergence, gradient theorems will help.
 
anyone?
 
Never mind. I got it.
 

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