06 B4: A student performs an experiment to determine the ...
2006 B4: A student performs an experiment to determine the index of refraction n of a rectangular glass slab in air. She is asked to use a laser beam to measure angles of incidence θi in air and corresponding angles of refraction θr in glass. The measurements of the angles for five trials are given in the table below.
|Trial |θi |θr | | |
|1 |30o |20o | | |
|2 |40o |27o | | |
|3 |50o |32o | | |
|4 |60o |37o | | |
|5 |70o |40o | | |
(a) Complete the last two columns in the table by calculating the quantities that need to be graphed to provide a linear relationship from which the index of refraction can be determined. Label the top of each column.
(b) On the grid below, plot the quantities calculated in
(a) and draw an appropriate graph from which the index of refraction can be determined. Label the axes.
(c) Using the graph, calculate the index of refraction of the glass slab.
[pic]
The student is also asked to determine the thickness of a film of oil (n = 1.43) on the surface of water (n = 1.33). Light from a variable wavelength source is incident vertically onto the oil film as shown above. The student measures a maximum in the intensity of the reflected light when the incident light has a wavelength of 600 nm.
(d) At which of the two interfaces does the light undergo a 180° phase change on reflection?
_____ The air-oil interface only _____The oil-water interface only
_____Both interfaces _____Neither interface
(e) Calculate the minimum possible thickness of the oil film.
[pic]
2001B4. In an experiment a beam of red light of wavelength 675 nm in air passes from glass into air, as shown above. The incident and refracted angles are (1 and (2 , respectively. In the experiment, angle (2 is measured for various angles of incidence (1, and the sines of the angles are used to obtain the line shown in the following graph.
[pic]
a. Assuming an index of refraction of 1.00 for air, use the graph to determine a value for the index of refraction
of the glass for the red light. Explain how you obtained this value.
b. For this red light, determine the following.
i. The frequency in air
ii. The speed in glass
iii. The wavelength in glass
c. The index of refraction of this glass is 1.66 for violet light, which has wavelength 425 nm in air.
i. Given the same incident angle (1, show on the ray diagram on the previous page how the refracted ray for the violet light would vary from the refracted ray already drawn for the red light.
ii. Sketch the graph of sin (2 versus sin (1 for the violet light on the figure on the previous page that shows the same graph already drawn for the red light.
d. Determine the critical angle of incidence (c, for the violet light in the glass in order for total internal reflection to occur.
2000B4. A sheet of glass has an index of refraction
ng = 1.50. Assume that the index of refraction for air is na = 1.00.
a. Monochromatic light is incident on the glass sheet, as shown in the figure below, at an angle of incidence of 60°. On the figure, sketch the path the light takes the first time it strikes each of the two parallel surfaces. Calculate and label the size of each angle (in degrees) on the figure, including angles of incidence, reflection, and refraction at each of the two parallel surfaces shown.
[pic]
b. Next a thin film of material is to be tested on the
glass sheet for use in making reflective coatings. The
film has an index of refraction n f = 1.38. White light
is incident normal to the surface of the film as shown
below. It is observed that at a point where the light is
incident on the film, light reflected from the surface
appears green (( = 525 nm).
[pic]
i. What is the frequency of the green light in air?
ii. What is the frequency of the green light in the
film?
iii. What is the wavelength of the green light in
the film?
iv. Calculate the minimum thickness of film that
would produce this green reflection.
| |Wavelength in |Index of |
| |Vacuum |Refraction of |
| | |Glass |
|Red Light|700 nm |1.5 |
|Blue |480 nm |1.6 |
|Light | | |
[pic]
1993B4. The glass prism shown above has an index of refraction that depends on the wavelength of the light that enters it. The index of refraction is 1.50 for red light of wavelength 700 nanometers (700 x 10-9 meter) in vacuum and 1.60 for blue light of wavelength 480 nanometers in vacuum. A beam of white light is incident from the left, perpendicular to the first surface, as shown in the figure, and is dispersed by the prism into its spectral components.
a. Determine the speed of the blue light in the glass.
b. Determine the ( of the red light in the glass.
c. Find the frequency of the red light in the glass.
d. On the figure above, sketch the approximate paths of both the red and the blue rays as they pass through the glass and back out into the vacuum. Ignore any reflected light. It is not necessary to calculate any angles, but do clearly show the change in direction of the rays, if any, at each surface and be sure to distinguish carefully any differences between the paths of the red and the blue beams.
e. The figure below represents a wedge-shaped hollow space in a large piece of the type of glass described above. On this figure, sketch the approximate path of the red and the blue rays as they pass through the hollow prism and back into the glass.
[pic]
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