Are current-carrying wires made of dielectric material?

AI Thread Summary
Current-carrying wires are typically made of conductive materials like metals, which allow for the flow of electric current. The discussion highlights that while a current generates an electric field, this field cancels out within a conducting wire, allowing the magnetic field to dominate. The question raised concerns whether a dielectric material, which cannot carry current, would also result in a canceled electric field. It is clarified that dielectrics are insulators and not suitable for current-carrying applications. Overall, the consensus is that dielectrics do not function as current-carrying wires.
lonewolf219
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Here is an excerpt from my textbook:

"Ordinarily, this charge would simultaneously generate so large an electric force as to swamp the magnetic one. But if we arrange to keep the wire neutral, by embedding in it equal amount of opposite charge at rest, the electric field cancels out, leaving the magnetic field to stand alone."

If I understand correctly, this means that the current inside a wire produces an electric field, but that electric field vanishes inside a conducting wire.

My question is if the electric field inside the wire would still cancel if the material was a dielectric?
 
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Dielectrics cannot carry a current; they are generally insulators.

Wires are made of conductors, typically metals.
 
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UltrafastPED: Thanks for the reply!
 

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