Surface Impedance of Metals

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Presentation transcript:

Surface Impedance of Metals Section 87

E = -(c/we) k x H where k = Ö(em)w/c

Inside and near a metal surface

Since Et and Ht are continuous at the surface, they are related by the same expression just outside

Surface impedance At low w

Time averaged energy flux through the metal surface

Fields don’t satisfy the macroscopic Maxwell equations in the metal As frequency increases, penetration depth eventually becomes comparable to the electron mean free path. The field is then too non-uniform to use the macroscopic description based on e. Fields don’t satisfy the macroscopic Maxwell equations in the metal

This is the only possible linear relation between the axial vector H and the polar vector E.

As frequency increases further…

Distance traveled by conduction electrons during one electromagnetic wave period Then we can neglect the spatial inhomogeneity of the field relative to the electron motion

On the other hand…

Superconductors