Light Reflection: Path Length Difference?

AI Thread Summary
The discussion centers on determining the path length difference when light reflects from a thin film. The main options considered are that the difference is equal to the thickness of the film, twice the thickness, or half the thickness. The consensus leans towards the answer being twice the thickness of the film, factoring in the refractive index and a phase change upon reflection from a denser medium. The angle of incidence is noted to be approximately 90 degrees, which influences the calculations. Understanding these principles is crucial for accurately assessing light behavior in thin films.
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Homework Statement



When light reflects from a thin film back toward the source, what is the path length difference?


The Attempt at a Solution



A. It is equal to twice the thickness of the film.
B. It is equal to the thickness of the film.
C. It is equal to half the thickness of the film.

I have rules out C. I think the answer is A but I'm not sure.
 
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I'm leaning towards A now. Anyone have any ideas?
 


Tell us why you are leaning towards A and we can help you evaluate that thought process.
 


I guess the path length difference is between the rays reflected from the two surfaces of the film. When light reflects from a "thin" film back toward the source, the angle of incidence is approximately 90 degree. So, the optical path length difference is twice the film thickness times the refractive index of the film. One also has to take into account the fact that a phase change of 180 degree occurs upon reflection from an optically denser medium.
 
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