FORMULAS AND DERIVATIONS:
PROCEDURE:
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| Setup of the light beam with protractor underneath semicircle glass medium. |
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| Measurements of different angles at different angles of light beams. |
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| Reversing the semicircle and recording the refraction angles again. |
DATA & ANALYSIS:
Before the experiment, there were some predicted results and phenomena that were expected. The angle of incidence for the light ray at the flat surface would be zero and the angle of refraction at the flat surface would also be zero as well. As the light ray leaves the plastic piece at the curved edge and goes into the air the light will travel straight out since the light ray travels straight as it comes in. In the first situation light travels from a lower density to a higher density. These predictions were verified after turning on the light observing the results.
Trial 1
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θi
|
Error
|
θr
|
Error
|
Rad(θ1)
|
Error
|
Rad(θ2)
|
Error
|
sin(θi)
|
Error
|
sin(θr)
|
Error
|
10
|
± 1
|
7
|
± 1
|
0.1745
|
± 0.017
|
0.1222
|
± 0.017
|
0.1736
|
±0.841
|
0.1219
|
±0.841
|
15
|
± 1
|
10
|
± 1
|
0.2618
|
± 0.017
|
0.1745
|
± 0.017
|
0.2588
|
±0.841
|
0.1736
|
±0.841
|
20
|
± 1
|
12
|
± 1
|
0.3491
|
± 0.017
|
0.2094
|
± 0.017
|
0.3420
|
±0.841
|
0.2079
|
±0.841
|
30
|
± 1
|
21
|
± 1
|
0.5236
|
± 0.017
|
0.3665
|
± 0.017
|
0.5000
|
±0.841
|
0.3584
|
±0.841
|
40
|
± 1
|
24
|
± 1
|
0.6981
|
± 0.017
|
0.4189
|
± 0.017
|
0.6428
|
±0.841
|
0.4067
|
±0.841
|
45
|
± 1
|
32
|
± 1
|
0.7854
|
± 0.017
|
0.5585
|
± 0.017
|
0.7071
|
±0.841
|
0.5299
|
±0.841
|
50
|
± 1
|
28.5
|
± 1
|
0.8727
|
± 0.017
|
0.4974
|
± 0.017
|
0.7660
|
±0.841
|
0.4772
|
±0.841
|
60
|
± 1
|
35
|
± 1
|
1.0472
|
± 0.017
|
0.6109
|
± 0.017
|
0.8660
|
±0.841
|
0.5736
|
±0.841
|
70
|
± 1
|
39
|
± 1
|
1.2217
|
± 0.017
|
0.6807
|
± 0.017
|
0.9397
|
±0.841
|
0.6293
|
±0.841
|
80
|
± 1
|
40
|
± 1
|
1.3963
|
± 0.017
|
0.6981
|
± 0.017
|
0.9848
|
±0.841
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0.6428
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±0.841
|
For the 2nd Trial there were also predicted results that were stated. As the light ray hits the first curved surface of the semicircle prism, the light ray goes through as a straight light. This would occur because both the angle of incident and angle of refraction is zero. When the light ray comes out the flat surface there will be a refraction as it goes into the air. The experiment will has a situation where light travels from a higher density to lower density.
TRIAL 2
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θi
|
Error
|
θr
|
Error
|
Rad(θ1)
|
Error
|
Rad(θ2)
|
Error
|
sin(θi)
|
Error
|
sin(θr)
|
Error
|
6
|
± 1
|
10
|
± 1
|
0.0960
|
± 0.0174
|
0.1745
|
± 0.0174
|
0.0958
|
±0.8414
|
0.1736
|
±0.8414
|
11
|
± 1
|
15
|
± 1
|
0.1920
|
± 0.0174
|
0.2618
|
± 0.0174
|
0.1908
|
±0.8414
|
0.2588
|
±0.8414
|
12
|
± 1
|
20
|
± 1
|
0.2094
|
± 0.0174
|
0.3491
|
± 0.0174
|
0.2079
|
±0.8414
|
0.3420
|
±0.8414
|
19
|
± 1
|
30
|
± 1
|
0.3316
|
± 0.0174
|
0.5236
|
± 0.0174
|
0.3256
|
±0.8414
|
0.5000
|
±0.8414
|
23
|
± 1
|
40
|
± 1
|
0.3927
|
± 0.0174
|
0.6981
|
± 0.0174
|
0.3827
|
±0.8414
|
0.6428
|
±0.8414
|
26
|
± 1
|
45
|
± 1
|
0.4538
|
± 0.0174
|
0.7854
|
± 0.0174
|
0.4384
|
±0.8414
|
0.7071
|
±0.8414
|
29
|
± 1
|
50
|
± 1
|
0.5061
|
± 0.0174
|
0.8727
|
± 0.0174
|
0.4848
|
±0.8414
|
0.7660
|
±0.8414
|
32
|
± 1
|
60
|
± 1
|
0.5585
|
± 0.0174
|
1.0472
|
± 0.0174
|
0.5299
|
±0.8414
|
0.8660
|
±0.8414
|
34
|
± 1
|
70
|
± 1
|
0.5934
|
± 0.0174
|
1.2217
|
± 0.0174
|
0.5592
|
±0.8414
|
0.9397
|
±0.8414
|
38
|
± 1
|
80
|
± 1
|
0.6632
|
± 0.0174
|
1.3963
|
± 0.0174
|
0.6157
|
±0.8414
|
0.9848
|
±0.8414
|
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| Slope of the line gives the ratio of the index of refraction of the two mediums |
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The inverse of the glass and air gives the inverse of the slope, thus an inverse ratio of the index of refraction between the two mediums.
There was also a trial to see at what point the angle of refraction becomes 90 degrees or in others others, not being able to see the light beam itself. This is also known as the critical angle and can only be obtained when there light traveling from an object with a higher index of refraction to an object with a lower index of refraction. The maximum
value for the angle of refraction was recorded to being 42˚± 1. Using the law
of refraction again and setting the second angle to 90 degrees gives us the
equation θcritcal=sin-1(Nb/Na).
This equation can be used to verify the maximum angle value that was found in
the experiment.
Theoretical Calculations:
Using the theoretical of refraction of 1.5 for glass, the experimental value of the maximum angle could be verified. The theoretical value of the critical angle was about 42 degrees which gives an exact value of the value from the theoretical.
CONCLUSION
Using the
law of refraction, N1Sin(θ1)=N2Sin(θ2),
and setting θ1 as the incident ray and θ2 as the angle of
refraction, we can set the equation as Sin(θ1)/
Sin(θ2)= N2/N1. The slope of the line can also
be written as Sin(θ2)/Sin(θ1). Using the data of the
first trial we can see that the slope is 0.6588, which is also equal to N1/N2. By setting the index of refraction of air to being 1, we can clearly see that N2
= 1.52, and that it represents the index of refraction of glass. While N1
represents the index of refraction of air with an integer value of 1. Similar
results occur for trial two when the semicircle is reversed and the N1
is now the index of refraction of glass and N2 represents for the air. The slope of the given line in trial 2 gave a value of 1.6458. The
percent difference between the two index of refraction for glass is about 7%.
It can be verified that the two slopes of these graphs are inverses of ratio to
each other. The critical angle formula was also verified by finding the maximum angle at which the light beam can refract in a situation where there is a higher index of refraction to a lower one. This can be verified because the ratio can never be greater 1 for an inverse sin value. The angle of refraction at or past the critical angle becomes 90 degrees and so it cannot be measured because it cannot be seen. The relationship between the reflection and refraction as well as the critical angle was all verified using two mediums, glass and air.
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