Permittivity at high frequency Section 78. At high frequency, polarization processes cannot keep up. P = 0 D = E + 4  P = E How does  approach unity.

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Presentation transcript:

Permittivity at high frequency Section 78

At high frequency, polarization processes cannot keep up. P = 0 D = E + 4  P = E How does  approach unity mathematically?

If  exceeds frequencies of motion for all electrons, we can neglect electron interactions with each other and with nuclei. Then all electrons are regarded as free. Then, there is no difference between conductors and dielectrics.

Usually, electron velocities are non-relativistic, v << c. Then the distance traveled during once EM-wave cycle is Then, each electron is accelerated in a uniform field v’ = the additional velocity acquired from the field

Equation of motion Electron’s displacement caused by the field

Polarization = dipole moment per unit volume P(r,t) = N = number of electrons in all the atoms per unit volume

Electric Induction

Define the “plasma frequency” Valid for very high frequencies: Far UV for light elements X-ray for heavy elements Then

Real Negative for  <  p (metallic behavior) Positive for  >  p (dielectric behavior)

Which curve is a possible permittivity in the limit of high frequencies?