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Electromagnetic waves: Multiple beam Interference

Electromagnetic waves: Multiple beam Interference. Friday November 8, 2002. Anti-Reflection coatings. 2. 1. A. Determine thickness of film. air. n 1. n 2. film. n 1 < n 2 < n 3. n 3. glass. Thus both rays (1 and 2) are shifted in phase by  on reflection.

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Electromagnetic waves: Multiple beam Interference

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  1. Electromagnetic waves: Multiple beam Interference Friday November 8, 2002

  2. Anti-Reflection coatings 2 1 A. Determine thickness of film air n1 n2 film n1 < n2 < n3 n3 glass Thus both rays (1 and 2) are shifted in phase by  on reflection. For destructive interference (near normal incidence) 2n2t=(m+1/2) Determines the thickness of the film (usually use m=0 for minimum t)

  3. Anti-Reflection coatings 2 1 air B. Determine refractive index of film n1 A’ A Near normal incidence Amplitude at A n2 film n3 glass Since  ’ ~ 1

  4. Anti-reflection coating B. Determine refractive index of film Amplitude at A’ To get perfect cancellation, we would like EA = E A’ should be index of AR film

  5. Multiple Beam interference • Thus far in looking at reflectivity from a dielectric layer we have assumed that the reflectivity is small • The problem then reduces to two beam interference • Now consider a dielectric layer of uniform thickness d and assume that the reflectivity is large e.g. || > 0.8 • This is usually obtained by coating the surface of the layer with a thin metallic coating – or several dielectric coatings to give high reflectivity • Or, one can put coatings on glass plates , then consider space between plates

  6. Multiple beam interference Let 12 =  21= ’ 12=  21= ’ ’’ Eo (’)5’Eo Eo (’)3’Eo (’)7’Eo  n1 n2 ’ A B C D n1  (’)2’Eo (’)6’Eo ’ Eo (’)4’Eo

  7. Multiple Beam Interference • Assume a (for the time being) a monochromatic source • , ’ small ( < 30o) usually • Now || = |’| >> , ’ • Thus reflected beams decrease rapidly in amplitude (from first to second) • But amplitude of adjacent transmitted beam is about the same amplitude • Amplitude of successfully reflected beams decreases slowly (from the second) • Thus treat in transmission where contrast should be somewhat higher • The latter is the configuration of most applications

  8. Multiple Beam Interference • Assume phase of transmitted beam at A is such that, • Now let ’be the phase shift in travelling across and back once, i.e.

  9. Multiple Beam interference • At B: • At C: • At D: etc…

  10. ’ ΔS1  Multiple beam interference • Consider N beams which interfere at infinity • We can use a lens and then beams shown interfere in focal plane of lens • The phase difference between adjacent rays outside is, n1 n2 d n1 ΔS1 N-4 N N-1 N-3 N-2

  11. Multiple beam interference • Amplitude at point P,

  12. Multiple beam interference • Amplitude at point P, Let

  13. Multiple beam interference This is just a geometric series with r < 1. Thus,

  14. Multiple beam interference Thus,

  15. Multiple beam interference Evaluate Thus,

  16. Multiple beam interference Now,

  17. Multiple beam interference Now recall the definition of the intensity of an electromagnetic wave Thus, is the intensity distribution in the focal plane of the lens.

  18. Multiple beam interference Fringe pattern

  19. Multiple beam interference • Maximum intensity when,

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