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Reading Quiz For a conductor which quantity is set to zero in last time’s Lorentz oscillator model? decay frequency, wD resonance frequency, w0 light frequency,

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Presentation on theme: "Reading Quiz For a conductor which quantity is set to zero in last time’s Lorentz oscillator model? decay frequency, wD resonance frequency, w0 light frequency,"— Presentation transcript:

1 Reading Quiz For a conductor which quantity is set to zero in last time’s Lorentz oscillator model? decay frequency, wD resonance frequency, w0 light frequency, w reflection frequency, wR

2 Reading Quiz The vector that gives the direction of energy transfer through space in an E-M wave is called the: Clausius vector flow vector Michelson vector polarization vector Poynting vector

3 Index of refraction

4 Common optical glass indices vs wavelength

5 Hint: what would these curves look like in the limit of N  0?
P3. If we increase the density of a gas (N), index n a) increases for all w b) decreases for all w c) increases with density below resonance, decreases above d) decreases with density below resonance, increases above Hint: what would these curves look like in the limit of N  0?

6 P6. In a glass that absorbs green light
the index , imaginary index k is greatest for ______ (same choices) yellow green blue P4. In a glass that absorbs green light best, the real index n is probably greatest for ______ light. yellow green blue

7 Last time: optical properties of spring-like oscillating dipoles: dielectric (i.e. insulator)

8 Optical properties of a conductor
Why do metals reflect so well? If there’s no damping, how to they respond to a steady E-field? A What will their motion be in an oscillating field?

9 Optical properties of a conductor
We can start with the math done for dielectric (insulator): A …and modify for free electrons:

10 Optical properties of a conductor
Case of very little damping g<<w: For w< wp , check the sign of Which must be nonzero? n b) k

11 Complex index, dielectric constant, k
g=0 n, k A What does n = 0 mean here? For dielectric, k creates absorption. For metal, k creates strong reflection

12 n,k for metal. Plasma frequency divides two regimes
g=wp/10 g=0 n, k A Which frequencies are transmitted well? Which are reflected well?

13 Typical plasma frequencies
density N (m-3) (Hz) metals 1028 1016 semicond. (pure) 1024 1014 semicond. (doped), fusion expts 1020 1012 ionosphere (60 to 450 km) 1011 107 interplanetary space 105

14 Reflectance vs. Wavelength
Plasma frequency of silver

15 Poynting Vector energy density in a vacuum
Its magnitude is the intensity: Power/area What equation in this course does this look like? So S is an energy flow vector: energy/area/time

16 For a plane wave in index n, derive the time average intensity
S or intensity For a plane wave in index n, derive the time average intensity From Maxwell Eqns

17 Directions of vectors The following are always true:!
(definition and Maxwell eqn for plane wave) Which vector pair is not guaranteed to be perpendicular? E, S E, k E, B S, B B, k

18 Preview of a birefringent crystal

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