Complex permitivity of good conductors

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iVenky
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We can define complex permitivity of any medium as
Code:
[tex]\epsilon=\epsilon'-j\epsilon''[/tex]
And the loss tangent as
Code:
[tex]tan \delta = \frac{\omega \epsilon'' + \sigma}{\omega \epsilon'} [/tex]
The question that I have is for good conductors. I read that for good conductors, we are dominated by σ rather than displacement current, which makes sense. What I don't get it, for good conductors, ε''>>ε'. Why is that? I understand ε'' is dominant but ε' (=ε0εr -> ∞ since εr -> ∞ for good conductors). What's the fallacy in this logic?
 
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\epsilon' does not approach infinity for good conductors. You have been misled by the fact that letting epsilon' become infinite in a relation for a dielectric in a static electric field gives the corresponding relation for a conductor, but that is just a convenient mathematical trick. The physical epsilon' does not get particularly large in a conductor.
 
Meir Achuz said:
\epsilon' does not approach infinity for good conductors. You have been misled by the fact that letting epsilon' become infinite in a relation for a dielectric in a static electric field gives the corresponding relation for a conductor, but that is just a convenient mathematical trick. The physical epsilon' does not get particularly large in a conductor.
Thanks, how much is the epsilon for a conductor?