Up: Experiment 8: INTERFERENCE Previous: 8.3 The Index of Refraction of Air

8.4 Index of Refraction of Glass

In the above section the index of refraction of air was measured by slowly varying the density of air along a fixed length of one beam path in the Michelson Interferometer. That method obviously won't work with a solid substance, such as glass. Therefore, in order to measure the index of refraction of glass, it's necessary to slowly vary the length of glass through which the interferometer beam passes. This experiment introduces a technique for making such a measurement.

  1. Align the laser and interferometer in the Michelson mode.
  2. Place the rotating talbe between the beam splitter and movable mirror, perpendicular to the optical path.
  3. Mount the glass plate on the magnetic backing of the rotational pointer.
  4. Position the pointer so that its ``0'' edge on the Vernier scale is lined up with the zero on the degree scale on the interferometer base.
  5. Remove the lens from in front of the laser. Hold the viewing screen between the glass plate and the movable mirror. If there is one bright dot and some secondary dots on the viewing screen, adjust the angle of the rotating table until there is one
  6. Replace the viewing screen and the lens and make any minor adjustments that are necessary to get a clear set of fringes on the viewing screen.
  7. Slowly rotate the table by moving the lever arm. Count the number of fringe transitions that occur as you rotate the table from 0 degrees to an angle tex2html_wrap_inline268 (where tex2html_wrap_inline268 is at least 10 degrees).

In principle, the method for calculating the index of refraction is relatively simple. The light passes through a greater length of glass as the plate is rotated. The general steps for measureing the index of refraction is as follows:

  1. Determine the change in the path length of the light beam as the glass plate is rotated. Determine how much of the change in path length is through glass tex2html_wrap_inline272 , and how much is through air, tex2html_wrap_inline274 .
  2. Relate the change in path length to your measured fringe transitions with the following equation:

    equation84

    where tex2html_wrap_inline276 is the index of refraction of air (measured above), tex2html_wrap_inline278 is the index of refraction of glass (as yet unknown), tex2html_wrap_inline228 is the wavelength of the laser in vacuum and N is the number of fringe transitions that you counted.

Carrying out this analysis (a bonus point for those who work this out before the lab and show the T.A. the analysis), gives the following result for the index of refraction in glass:

equation89

where t is the thickness of the glass plate.


Up: Experiment 8: INTERFERENCE Previous: 8.3 The Index of Refraction of Air