Activities for total refl lab

College Physics II Labs
Lab Activities Return to lab main Refraction and Total Internal Reflection

1. Complete laser mini-labs:

a. Reflection: Experiment 5 Metrologic ML211 Laser Pointer Education Kit
b. Refraction: Experiment 6 Metrologic ML211 Laser Pointer Education Kit
c. Total internal reflection: Demo: Observing Internal reflections in a test tube, p. 6
Metrologic ML211 Laser Pointer Education Kit
Experiment Total Internal Reflection 2. Solve Problem #1 (below). Then explain in words how the solution to Problem #2 would differ.

3. Solve Problem #3 or #4 (below). You may wish to refer to the formulation (eq.22.2) of Snell's Law on p.691 (Wilson & Buffa, 4th Ed.):
n = c/v so n₁sinq₁ = n₂sinq₂ = csinq₁/v₁ = csinq₂/v₂

Problems:

1. Blue light of wavelength 470 nm strikes the side of an equilateral prism.(each angle is 60^o). The angle of incidence is 53.8^o. The index of refraction for blue light is 1.636 in this prism.
a. Calculate the refracted angle relative to a line perpendicular to the first air-glass interface.
b. If the prism has three 60^o angles, calculate the incident angle at the second glass-air interface.
c. Calculate the refracted angle relative to a line perpendicular to this surface.
[Ans: a. 29.6^o b. 30.4^o c. 56^o]

2. Repeat problem #1, but imagine that the prism is immersed in water. Assume that the index of refraction of water for blue light of this wave length is 1.330.

3. Sound passes from limestone, where it moves at a speed of 4000 m/s, into another unknown material. The angle of incidence at the interface is 24^o and the angle of refraction in the unknown material is 38^o.
a. Calculate the speed of sound in the unknown material.
b. Make a qualitative sketch of the situation and identify relevant quantities.
[Ans: a. 6050 m/s]

4. Sound traveling in limestone enters the top surface of a cubical salt dome at an angle of incidence of 35^o. After passing through the salt dome, the sound leaves the right side and reenters the limestone. Calculate its final direction in the limestone and show in a figure the directions of the ray as it enters, passes through, and leaves the salt dome.
(v_limestone = 4000 m/s and v_salt = 6000 m/s) {Ans: 20^o below horizontal}

College Physics II Lab

Total Internal Reflection

Measurement of the Index of Refraction

Background:

In any homogeneous material, light travels in straight lines. However, when light encounters a boundary, a change in material, some of the light reflects back and some of the light is transmitted forward into the new material. The transmitted light does not travel in the same direction as the original light. Instead it is bent at the boundary and travels in a slightly different direction. When light is bent in this way, the phenomenon is called refraction.

The refraction of light at the boundary between two materials is described quantitatively by Snell's Law. Consider the situation depicted in Figure 1. A ray of light is incident on the surface between two different materials. The long dashed line represents a line perpendicular to the surface. The angle q measures the angle between the incident ray and the line perpendicular to the surface. This angle is the angle of incidence. The angle f measures the angle between the refracted ray and the line perpendicular to the surface. This angle is the angle of refraction. Snell's Law states:

n_i*sin(q) = n_r*sin(f)

The quantity n_iis the index of refraction for the material in which the light was incident. The quantity n_ris the index of refraction for the material in which the light was refracted.

The phenomenon of total internal reflection can occur when the light travels from a material with higher index of refraction to a material with a lower index of refraction. When n_i > n_r, the refracted ray is bent away from the line perpendicular to the surface. If the angle of incidence is large enough, the angle of refraction will be 90^o, and the light is refracted parallel to the surface. The angle of incidence for which this occurs is called the critical angle. If the angle of incidence is any greater than the critical angle, it is not possible for there to be a refracted ray. [Applying Snell's Law for this case would lead one to predict that sin(f) > 1, which contradicts what is known of the sine function ( -1< sin(f) < 1).] When there is no refracted ray, all of the energy of the light goes into the reflected ray.

Through investigation of total internal reflection one can determine the index of refraction of various substances. By measuring the critical angle for a situation in which light goes from a material of higher index of refraction to a material of lower index of refraction, and by knowing the index of refraction of one of the materials, you can determine the index of refraction of the other material. The critical angle q_crit is the largest angle for which there is not evidence of total internal reflection. The angle of refraction would be 90^o in that case. Therefore, sin(f) = 1, because f = 90^o. Air has an index of refraction equal to 1. If the second material, into which the light was traveling, was air, then n_r= 1. If this information is substituted into Snell's Law:

n_i*sin(q) = n_r*sin(f)

n_i*sin(q_crit) = (1)*(1)

n_i = 1/sin(q_crit)

The phenomenon of total internal reflection is important in numerous technologies. Total internal reflection explains how light can be shined into one end of a glass fiber and transmitted great distances with little loss of energy. Such fiber optics are used in electronic communication to replace copper wires and in modern diagnostic and surgical medical devices, which minimize the amount of trauma to the body.

Materials:
semi-circular plastic dish, protractor or polar graph paper
laser pen pointer, non-dairy creamer
water, aqueous cane sugar solution (i.e. sugar-water)

Procedure:
1. Set-up:
Place a sheet of polar graph paper on the table. Place the semi-circular plastic dish at the origin of the polar graph paper and turn it until the line perpendicular to the flat wall of the dish is directed along the 0^o line. Add liquid to the dish and a light sprinkle of non-dairy creaner as needed. A very small amount of non-dairy creamer added to a liquid will make the laser beam visible in the liquid, just as sprinkling chalk dust in the air will make the laser beam visible in air. You may have to experiment to get the right amount of creamer.

2. Exploration of total internal reflection:
Shine the laser into the dish through the curved wall of the dish. Aim the beam so that it hits the midpoint of the flat wall of the dish. Vary the angle of incidence of the laser beam relative to the flat wall of the dish by moving the laser pointer around the curve of the dish. Always shine the laser perpendicular to curved wall and so that the beam strikes the midpoint of the flat wall. As you vary the angle of incidence of the laser beam relative to the flat wall you will be able to observe the phenomenon of total internal reflection.

3. Measurement of the index of refraction of a liquid:
Move the laser pointer until you have established a condition of total internal reflection. Then move the pointer so that the angle of incidence of the laser light on the flat wall of the dish becomes smaller. Continue this process carefully until a total internal reflection is no longer observed. Measure the angle of incidence at this time. This angle is the critical angle. Determine the index of refraction for the liquid using the relationship:

n_i = 1/sin(q_crit)

[Verify that when total internal reflection occurs, the angle of reflection equals the angle of incidence.]

4. Compare your value of nwater with the best known value n_water = 1.33. What is the % difference?

5. Repeat step 3 for an aqueous cane sugar solution. What value do you infer for

n_sugar-water? Based on your value of n_sugar-water, what would you predict to be the concentration of sugar (by weight) for this solution?

SKIP

6. Using Dr. Landis' refractometer, this index of refraction for this solution has been determined to be _____, thus indicating a concentration of ____ % sugar by weight. What is the % difference between your value of nsugar-water and that obtained by Dr. Landis? What factors might account for any difference you may find? [Hint: Does l make a difference to n?