Question 1

Two waves, one with amplitude A and the second with amplitude 2A, are out of phase by 180 $\degree$. The resultant intensity is A) zero B) A C) A² D) 2A² E) (3A)²

Accepted Answer

The equation for the resultant intensity of two waves out of phase by 180 degrees is given by: I = I1 + I2 + 2√(I1*I2)*cos(Δφ) where I1 and I2 are the intensities of the two waves, Δφ is the phase difference between them. Here, I1 = A^2 and I2 = (2A)^2 = 4A^2 Thus, I = A^2 + 4A^2 + 2√(A^2 * 4A^2)*cos(180°) I = 5A^2 - 2A^2 = 3A^2 Therefore, the resultant intensity is 3A^2 or A² (option C).

Question 2

In the figure, a beam of light from an underwater source is incident on a layer of carbon disulfide and the glass bottom of the container. Some of the refracted and reflected rays are shown in the diagram. For the rays shown, the interface at which the reflected light changes phase is&#10;A) 1 only&#10;B) 2 only&#10;C) 3 only&#10;D) 1 and 2&#10;E) 2 and 3

Accepted Answer

1 only

Question 3

The phase difference for the two waves shown in the figure is&#10;A) 2 $\pi$&#10;B)  $\pi$&#10;C) 3 $\pi$/2&#10;D)  $\pi$/2&#10;E) It is not possible to answer this question without additional information.

Accepted Answer

The phase difference between the two waves can be found by calculating the difference in their phase angles at a particular point in time. From the figure, it can be observed that the two waves have the same amplitude and frequency, but one wave leads the other by half a wavelength or π radians. Therefore, the phase difference is given by (π)/2 = (1/2)π = F1F1F1S1πF1F1F10/2. The correct answer is D.

Question 4

Two waves, one with amplitude A and the second with amplitude 2A, are in phase. The resultant intensity is A) zero B) A C) 3A D) 3A² E) (3A)²

Accepted Answer

The intensity of a wave is proportional to the square of its amplitude. When two waves are in phase, their amplitudes add before squaring. Thus, the resultant amplitude is $A + 2A = 3A$, and the intensity, being proportional to the square of the amplitude, is $(3A)^2$.

Question 5

Visible light from an ordinary source such as a sodium lamp can be used to produce interference effects that demonstrate the wave nature of light, provided that&#10;A) the light beam from the single source is split into two (or more) beams that have a constant phase relationship to one another.&#10;B) the light is polarized.&#10;C) the light is not polarized.&#10;D) Interference effects cannot be demonstrated with ordinary light sources.&#10;E) None of these conditions are satisfied.

Accepted Answer

Interference effects require two or more coherent light sources (i.e. sources with a constant phase relationship). Splitting the beam from a single source into two beams that meet at an angle can create the necessary conditions for interference. Polarization is not a requirement for interference effects, although it may affect the specific nature of the interference pattern.

Question 6

For us to see interference phenomena in a thin film,&#10;A) the incoming light must be monochromatic.&#10;B) the index of refraction of the thin film must be greater than the index of refraction of the material below it.&#10;C) the index of refraction of the thin film must be less than the index of refraction of the material below it.&#10;D) the incoming light must be multicolored.&#10;E) none of these conditions need exist

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Question 7

The minimum path difference that will produce a phase difference of 180&#186; for light of wavelength 600 nm is&#10;A) 600 nm&#10;B) 500 nm&#10;C) 300 nm&#10;D) 200 nm&#10;E) 100 nm

Accepted Answer

For two waves to have a phase difference of 180º, the path difference between them has to be half of the wavelength, i.e., λ/2. Therefore, the minimum path difference that produces a phase difference of 180º for light of wavelength 600 nm is 300 nm. Hence, the correct choice is C.

Question 8

The path difference for the two waves shown in the figure could be&#10;A) &#190;$\lambda$&#10;B) &#189;$\lambda$&#10;C) &#188;$\lambda$&#10;D)$\lambda$&#10;E) It is not possible to answer this question without additional information.

Accepted Answer

The answer of   The path difference for the...

Question 9

Two side-by-side coherent light sources radiate at 633 nm. At a point in space where the path difference to these two sources is 30 nm, the phase difference could be&#10;A) 0.238 radians&#10;B) 0.298 radians&#10;C) 0.324 radians&#10;D) 0.356 radians&#10;E) 0.429 radians

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Question 10

Why are fringes not observed if the angle of the wedge of air in the diagram is too large?&#10;A) For a large angle, the small-angle approximation (sin $\theta$ $\approx$ $\theta$) is not valid.&#10;B) the light passing through the wedge of air loses its coherence&#10;C) the fringes overlap&#10;D) the fringes are too close together to be seen individually&#10;E) None of these is correct.

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Question 11

Two coherent sources of monochromatic light are located at S₁ and S₂ as shown. If the sources are in phase, the intensity at point P is a maximum when A) d =$\lambda$ B) r₂ + r₁ = $\lambda$ C) r₂ - r₁ = $\lambda$ D) r₂ + r₁ = $\lambda$/2 E) r₂ - r₁ = $\lambda$/2

Accepted Answer

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Question 12

Which, if any, of the following conditions is not necessary for the light waves from two sources to be coherent?&#10;A) They must have the same frequency.&#10;B) They must have the same amplitude.&#10;C) They must have the same wavelength.&#10;D) They must have a constant phase difference.&#10;E) All of these conditions are necessary.

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Question 13

Two side-by-side coherent light sources radiate at 450 nm. The phase difference between these two sources at a point in space is 0.333 radians. The path difference between the two sources could be&#10;A) 15.8 nm&#10;B) 20.3 nm&#10;C) 23.8 nm&#10;D) 29.7 nm&#10;E) 32.1 nm

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Question 14

Two side-by-side coherent light sources radiate at 600 nm. The phase difference between these two sources at a point in space is 0.582 radians. The path difference between the two sources could be&#10;A) 43.5 nm&#10;B) 55.6 nm&#10;C) 62.4 nm&#10;D) 75.9 nm&#10;E) 87.4 nm

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Question 15

The minimum path difference that will produce a phase difference of 90&#186; for light of wavelength 500 nm is&#10;A) 62.5 nm&#10;B) 125 nm&#10;C) 250 nm&#10;D) 375 nm&#10;E) 400 nm

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Question 16

A phase shift of 180&#186; occurs when a light wave&#10;A) is transmitted through a boundary surface into a medium that is more dense than the medium from which the wave came.&#10;B) is transmitted through a boundary surface into a medium that is less dense than the medium from which the wave came.&#10;C) reflects from the boundary surface of a medium that is less dense than the medium in which the wave is traveling.&#10;D) reflects from the boundary surface of a medium that is more dense than the medium in which the wave is traveling.&#10;E) Both c and d are correct.

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Question 17

Which of the following statements is true?&#10;A) When two harmonic waves of the same frequency and wavelength but differing in phase combine, the resultant wave is a harmonic wave whose amplitude depends on the phase difference.&#10;B) A phase difference between two waves can be the result of a difference in path length.&#10;C) A path difference of one wavelength is equivalent to no phase difference at all.&#10;D) A phase difference between two waves can be the result of reflection from a boundary surface.&#10;E) All of these are correct.

Accepted Answer

The answer of Which of the following statements is true?&#10;A)...

Question 18

Diffraction of sound waves is more readily observable than that of light waves because&#10;A) sound waves are longitudinal and not transverse.&#10;B) sound waves have a higher frequency than light waves.&#10;C) sound waves have a lower velocity than light waves.&#10;D) sound waves have longer wavelengths than do light waves.&#10;E) interference occurs more readily for longitudinal waves.

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Question 19

Two side-by-side coherent light sources radiate at 480 nm. At a point in space where the path difference to these two sources is 50 nm, the phase difference could be&#10;A) 0.238 radians&#10;B) 0.375 radians&#10;C) 0.466 radians&#10;D) 0.582 radians&#10;E) 0.654 radians

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Question 20

For two identical rays of light to interfere destructively, their path lengths&#10;A) must be equal.&#10;B) must differ by an odd number of half wavelengths.&#10;C) must differ by an even number of half wavelengths.&#10;D) must differ by an integral number of wavelengths.&#10;E) need not satisfy any of these conditions.

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Question 21

You dip a wire loop into soapy water (n = 1.33) and hold it up vertically to look at the soap film in white light. The soap film looks dark at the top because it has sagged, and its thickness there is nearly zero, causing the reflected wavelengths to interfere destructively. Part way down the loop you see the first red band of the reflected white light. What is the thickness of the soap film there? (Take the wavelength of red light to be 680 nm.)

A) 130 nm
B) 170 nm
C) 220 nm
D) 250 nm
E) 340 nm

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The answer of You dip a wire loop into soapy...

Question 22

A wedge-shaped film of air is formed by placing a glass plate on second flat glass plate. The wedge is then illuminated using a monochromatic light from above and a fringe pattern is shown. From the fringe pattern one can conclude that the surface of the first glass plate is

A) much flatter than the wavelength used.
B) flat on the left side but then has a concave to the right side.
C) flat on the left side but then has a convex to the right side.
D) flat on the right side but then has a concave to the left side.
E) flat on the right side but then has a convex to the left side.

Accepted Answer

The answer of   A wedge-shaped film of air...

Question 23

Two parallel glass plates of index of refraction n are separated by an air film of thickness d. Light of wavelength $\lambda$ in air, normally incident on the plates, is intensified on reflection when, for some integer m&#10;A) 2d = m$\lambda$&#10;B) 2d = m$\lambda$0/n&#10;C) 2d = mn$\lambda$&#10;D) 2d = (m + 1/2)$\lambda$&#10;E) 2nd = m$\lambda$ /2

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Question 24

You deposit a thin film of magnesium difluoride on a glass lens (n > 1.60), reducing the reflection of yellow light, at normal incidence, to a minimum. You find that the thinnest coating that accomplishes this is 106 nm thick. The index of refraction for MgF₂ for yellow light ( $\lambda$ = 585 nm) is

A) 1.50
B) 1.38
C) 1.15
D) 1.00
E) 0.707

Accepted Answer

The answer of You deposit a thin film of magnesium...

Question 25

Use the figure for the next two questions.  &#10;&#10;-The interference pattern is from a convex lens placed on a flat reflecting surface using a monochromatic light of wavelength $\lambda$ = 550 nm. The distance between the lens and the flat surface at position A is&#10;A) 275 nm&#10;B) 550 nm&#10;C) 687.5 nm&#10;D) 825 nm&#10;E) 962.5 nm

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Question 26

You create a wedge-shaped film of air between two flat plates of glass 2.5 cm wide by laying one on top of the other and placing a small slip of paper 1.0 mm thick between their edges at one end. You illuminate the glass plates with normally incident monochromatic light of unknown wavelength. Observing the reflection, you see dark fringes at both ends of the plates. Between the ends you see three other dark fringes. What is the wavelength of the incident light?

A) 250 nm
B) 400 nm
C) 440 nm
D) 500 nm
E) 620 nm

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The answer of You create a wedge-shaped film of air...

Question 27

You place a convex lens on top of a flat plate of glass and illuminate it with monochromatic light of wavelength 600 nm. You observe a dark circle at the center of the lens, surrounded by a series of concentric dark rings. What is the thickness of the air space between the lens and the flat glass plate where you see the sixth dark ring?

A) 3.90 µm
B) 3.60 µm
C) 1.80 µm
D) 1.95 µm
E) 2.10 µm

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The answer of You place a convex lens on top...

Question 28

Light of wave length$\lambda$is incident on two thin films that are in contact and surrounded by air. The top layer is $\lambda$/4 thick and has an index of refraction of 1.33. The bottom layer is $\lambda$/2 thick and has an index of refraction of 1.50. At normal incidence, the reflected rays that are in phase with each other are&#10;A) 1 and 2&#10;B) 1 and 3&#10;C) 2 and 3&#10;D) 1, 2, and 3&#10;E) None of these is correct.

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Question 29

Use the figure for the next two questions.  &#10;&#10;-The interference pattern is from a spherical lens placed on a flat reflecting surface using a monochromatic light of wavelength $\lambda$ = 550 nm. If the distance from the center to A is 0.6 mm, the radius of curvature of the lens is&#10;A) 41.3 cm&#10;B) 82.5 cm&#10;C) 18.7 cm&#10;D) 37.4 cm&#10;E) 26.2 cm

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The answer of Use the figure for the next two...

Question 30

You apply a material with n = 1.25 to a lens (n_g = 1.5) to make a nonreflective coating due to destructive interference at a wavelength (in a vacuum) of 555 nm. What is the minimum thickness of the coating that you need?

A) 56 nm
B) 110 nm
C) 220 nm
D) 280 nm
E) 140 nm

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Question 31

Light of wavelength 640 nm is incident perpendicularly from air onto a film 1000 nm thick and of 1.60 refractive index. When part of the light enters the film and is reflected back at the second face, the number of wavelengths contained along the path of this light in the film is

A) 1.0
B) 1.6
C) 2.0
D) 3.2
E) 5.0

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The answer of Light of wavelength 640 nm is incident...

Question 32

A broad spectrum of light ($\lambda$ = 550 nm) illuminates normally a thin wedge of glass (n = 1.50). If the thick edge of the glass is 0.02 mm, the number of dark fringes observed is&#10;A) 109&#10;B) 99&#10;C) 73&#10;D) 55&#10;E) 33

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Question 33

You coat a glass lens (n = 1.65) with MgF₂ (n = 1.38) to reduce reflection. The minimum thickness of coating required to produce destructive interference in reflected light whose wavelength in air is 560 nm is

A) 102 nm
B) 140 nm
C) 203 nm
D) 280 nm
E) None of these is correct.

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The answer of You coat a glass lens (n =...

Question 34

If we assume normal incidence, the minimum thickness of a soap film (n = 1.33) in air that gives constructive interference when viewed by reflected light of wavelength
400 nm is

A) 225 nm
B) 200 nm
C) 100 nm
D) 75 nm
E) 57 nm

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Question 35

The interference pattern is from a lens placed on a flat reflecting surface illuminate using a monochromatic light from above. From the pattern one can conclude that the lens&#10;A) is more curved on the left and right sides compared to top and bottom.&#10;B) is more curved on the top and bottom compared to the left and right sides.&#10;C) has a spherical surface.&#10;D) has a concave surface.&#10;E) none of the above

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Question 36

A 3.5-cm-long microscope glass slide has one edge in contact with a flat plane of glass, while the other edge is slightly raised due to the insertion of a thin piece of paper. Sodium light of wavelength 589 nm is normally incident on the glass from above and interference fringes are observed by reflection with a regular spacing of 0.22 mm. Calculate the thickness of the piece of paper.

A) 9.4 * 10^-5 m
B) 5.5 * 10^-5 m
C) 2.4 *10^-5 m
D) 4.7*10^-5 m
E) None of these is correct.

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The answer of A 3.5-cm-long microscope glass slide has one...

Question 37

Two optically flat plates lie one on top of the other. A sheet of paper 0.1 mm thick is inserted between the plates at one edge. When the plates are illuminated by light of wavelength 589 nm, the number of interference fringes observed by reflected light is approximately

A) 470
B) 340
C) 294
D) 170
E) 123

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The answer of Two optically flat plates lie one on...

Question 38

The different colors seen on a soap bubble are produced by&#10;A) the dispersion of light by the water in the soap.&#10;B) the interference of light reflected from the front and back of the soap film.&#10;C) the different angles light strikes the surface of the soap film.&#10;D) total internal reflection of light in the soap film.&#10;E) None of the statements is correct.

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The answer of The different colors seen on a soap...

Question 39

A wedge-shaped film of air is formed by placing a glass plate on second flat glass plate. The wedge is then illuminated using a monochromatic light from above and a fringe pattern is shown. From the fringe pattern one can conclude that the surface of the first glass plate is

A) much flatter than the wavelength used.
B) flat on the left side but then has a concave to the right side.
C) flat on the left side but then has a convex to the right side.
D) flat on the right side but then has a concave to the left side.
E) flat on the right side but then has a convex to the left side.

Accepted Answer

The answer of   A wedge-shaped film of air...

Question 40

At normal incidence, the minimum thickness of a soap film (n = 1.33) that causes constructive interference when viewed by reflected light of wavelength 400 nm is&#10;A) 225 nm&#10;B) 200 nm&#10;C) 100 nm&#10;D) 750 nm&#10;E) 570 nm

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Question 41

You set two parallel slits 0.1 mm apart at a distance of 2 m from a screen and illuminate them with light of wavelength 450 nm. The distance between a bright spot in the interference pattern and the dark spot adjacent to it is

A) 0.560 mm
B) 1.12 mm
C) 2.25 mm
D) 4.50 mm
E) 9.00 mm

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Question 42

The distance between the slits in a double-slit experiment is increased by a factor of 4. If the distance between the fringes is small compared with the distance from the slits to the screen, the distance between adjacent fringes near the center of the interference pattern

A) increases by a factor of 2.
B) increases by a factor of 4.
C) depends on the width of the slits.
D) decreases by a factor of 2.
E) decreases by a factor of 4.

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Question 43

Two slits separated by 1.0 mm are illuminated with light of a single unknown wavelength. The tenth bright line from the central point of the interference pattern is observed to be at an angle of 0.34º. What is the wavelength of the light?

A) 620 nm
B) 590 nm
C) 560 nm
D) 450 nm
E) 600 nm

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Question 44

In a double-slit experiment, the distance from the slits to the screen is decreased by a factor of 2. If the distance between the fringes is small compared with the distance from the slits to the screen, the distance between adjacent fringes

A) increases by a factor of 2.
B) increases by a factor of 4.
C) depends on the width of the slits.
D) decreases by a factor of 2.
E) decreases by a factor of 4.

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Question 45

You illuminate two slits 0.50 mm apart with light of wavelength 555 nm and observe interference fringes on a screen 6.0 m away. What is the spacing between the fringes on the screen?&#10;A) 4.5 mm&#10;B) 3.3 mm&#10;C) 6.7 mm&#10;D) 10 mm&#10;E) 5.0 mm

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Question 46

The distance between the slits in a double-slit experiment is increased by a factor of 4. If the distance between the fringes is small compared with the distance from the slits to the screen, the distance between adjacent fringes near the center of the interference pattern

A) increases by a factor of 2.
B) increases by a factor of 4.
C) depends on the width of the slits.
D) decreases by a factor of 2.
E) decreases by a factor of 4.

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The answer of The distance between the slits in a...

Question 47

You set two parallel slits 0.2 mm apart at a distance of 1 m from a screen and illuminate them with light of wavelength 600 nm. The distance between a bright spot in the interference pattern and the dark spot adjacent to it is

A) 0.375 mm
B) 0.750 mm
C) 1.50 mm
D) 3.00 mm
E) 6.00 mm

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Question 48

In an experiment to demonstrate interference of light, it is essential that&#10;A) coherent sources of light be used.&#10;B) the light paths differ by not more than one-half wavelength.&#10;C) the light be monochromatic.&#10;D) the beam of light be a parallel beam.&#10;E) there be no difference in light paths.

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Question 49

Light of wavelength 500 nm illuminates parallel slits and produces an interference pattern on a screen that is 1 m from the slits. In terms of the initial intensity I₀, the light's intensity in the interference pattern at a point for which the path difference is 100 nm is A) 2.62 I₀ B) 2.87 I₀ C) 3.08 I₀ D) 3.31 I₀ E) 4.39 I₀

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Question 50

You set two parallel slits 0.2 mm apart at a distance of 1 m from a screen and illuminate them with light of wavelength 600 nm. The distance between a bright spot in the interference pattern and the dark spot adjacent to it is

A) 0.375 mm
B) 0.750 mm
C) 1.50 mm
D) 3.00 mm
E) 6.00 mm

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Question 51

A narrow, horizontal slit is 0.50 mm above a horizontal plane mirror. The slit is illuminated by light of wavelength 400 nm. The interference pattern is viewed on a screen 10.0 m from the slit. What is the vertical distance from the mirror to the first bright line?&#10;A) 1.0 mm&#10;B) 2.0 mm&#10;C) 3.0 mm&#10;D) 4.0 mm&#10;E) 1.2 mm

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Question 52

In order to produce several visible interference fringes from two narrow slits using light of a single wavelength, the distance between the slits must be of the order&#10;A) of a few tenths of the wavelength.&#10;B) of a few wavelengths.&#10;C) of a few tens wavelengths.&#10;D) of a few hundreds wavelengths.&#10;E) The distance does not matter.

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Question 53

When the slits in Young's experiment are moved closer together, the fringes&#10;A) remains unchanged.&#10;B) move closer together.&#10;C) move further apart.&#10;D) are less intense.&#10;E) none of the above

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Question 54

Two flat planes of glass are laid on top of one another. The upper plane is slightly raised due to the insertion of a thin piece of paper at one end and an air wedge is thus formed. Light of wavelength 500 nm is normally incident on the glass from above and interference fringes are observed by reflection with 2.5 fringes per cm. Calculate the angle of the wedge. A) 6.3 * 10^-5 deg B) 1.8 * 10^-3 deg C) 4.0 * 10^-4 deg D) 3.6 * 10^-3 deg E) 5.7 * 10^-4 deg

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Question 55

If a thin soap film (n = 1.36) reflects predominately red light (about 680 nm), then what is the minimum thickness of the soap film? A) 1.25 * 10^-7 m B) 6.80* 10^-7 m C) 2.50 * 10^-7 m D) 5.00 *10^-7 m E) None of these is correct.

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Question 56

Light of wavelength 500 nm illuminates parallel slits and produces an interference pattern on a screen that is 1 m from the slits. In terms of the initial intensity I₀, the light's intensity in the interference pattern at a point for which the path difference is 300 nm is A) 0.262 I₀ B) 0.382 I₀ C) 0.447 I₀ D) 0.581 I₀ E) 0.629 I₀

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Question 57

In a double slit experiment, a very thin plate of glass of refractive index 1.58 is placed in the light path of one of the slit beams. When this was done, the center of the fringe pattern was displaced by 35 fringe widths. Calculate the thickness of the glass plate if the wavelength of light is 680 nm. A) 4.1 * 10^-5 m B) 1.5 * 10^-5 m C) 3.0 * 10^-5 m D) 8.2 * 10^-5 m E) 3.8 * 10^-5 m

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Question 58

You set two slits 30 mm apart and 50 cm from a screen. When you illuminate the slits with light of wavelength 600 nm, the distance between the second and third dark interference lines is&#10;A) 1.0 mm&#10;B) 2.0 mm&#10;C) 3.0 mm&#10;D) 0.30 mm&#10;E) 6.0 mm

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Question 59

Two narrow slits, their centers separated by 15 cm, are illuminated by monochromatic radiation and produce the pattern in the figure on a distant screen. The wavelength of the radiation is&#10;A) 0.52 cm&#10;B) 1.0 cm&#10;C) 1.6 cm&#10;D) 2.1 cm&#10;E) 3.0 cm

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Question 60

Which of the following statements about Young's double-slit experiment is false?&#10;A) The bands of light are caused by the interference of the light coming from the two slits.&#10;B) The results of the double-slit experiment support the particle theory of light.&#10;C) Double-slit interference patterns can also be produced with sound and water waves.&#10;D) If the slits are moved closer together, the bands of light on the screen are spread farther apart.&#10;E) The pattern of light on the screen consists of many bands, not just two bands.

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Question 61

The pattern of light and dark fringes formed in Young's double-slit experiment is due to&#10;A) interference and dispersion.&#10;B) diffraction and refraction.&#10;C) refraction and interference.&#10;D) refraction and dispersion.&#10;E) interference and diffraction.

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Question 62

The graphs are plots of relative intensities of various diffraction patterns versus the sine of the angle from the central maximum. The graph that represents the diffraction pattern from the widest single slit is&#10;A) 1&#10;B) 2&#10;C) 3&#10;D) 4&#10;E) 5

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Question 63

Five coherent sources are used to produce an interference pattern. The phasor diagram shown could be used to calculate the intensity of the&#10;A) first minimum in the interference pattern.&#10;B) second maximum in an interference pattern.&#10;C) first maximum in an interference pattern.&#10;D) second minimum in an interference pattern.&#10;E) None of these is correct.

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Question 64

The interference and diffraction envelopes of a double slit are shown separately but to the same scale in the figure. For this arrangement, the number of fringes in the second diffraction maximum is&#10;A) 3&#10;B) 4&#10;C) 5&#10;D) 7&#10;E) 0

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Deck 13: Interference and Diffraction