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35. Special Relativity2h 10m

34. Wave Optics

Diffraction

Physics

34. Wave Optics

Diffraction

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3:49 minutes

Problem 37

Textbook Question

A Michelson interferometer uses red light with a wavelength of 656.45 nm from a hydrogen discharge lamp. How many bright-dark-bright fringe shifts are observed if mirror M₂ is moved exactly 1 cm?

Verified step by step guidance

Understand the concept: In a Michelson interferometer, fringe shifts occur when one of the mirrors is moved, causing a change in the optical path length. Each fringe shift corresponds to a change in the path length equal to one wavelength of the light used.

Calculate the total change in the optical path length: When mirror M₂ is moved by a distance \( d \), the optical path length changes by \( 2d \) because the light travels to the mirror and back. Here, \( d = 1 \; \text{cm} = 0.01 \; \text{m} \).

Determine the number of wavelengths in the total path length change: The number of fringe shifts \( N \) is given by \( N = \frac{2d}{\lambda} \), where \( \lambda \) is the wavelength of the light. Substitute \( \lambda = 656.45 \; \text{nm} = 656.45 \times 10^{-9} \; \text{m} \).

Substitute the values into the formula: Replace \( d \) and \( \lambda \) in the equation \( N = \frac{2d}{\lambda} \) to calculate the number of fringe shifts.

Interpret the result: The calculated value of \( N \) represents the total number of bright-dark-bright fringe shifts observed as the mirror is moved by 1 cm.

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Key Concepts

Here are the essential concepts you must grasp in order to answer the question correctly.

Interference

Interference is a phenomenon that occurs when two or more waves overlap and combine to form a new wave pattern. In the context of the Michelson interferometer, constructive interference leads to bright fringes, while destructive interference results in dark fringes. The pattern of these fringes is crucial for analyzing the changes in path length caused by moving mirrors.

Wavelength

Wavelength is the distance between successive peaks of a wave, typically measured in nanometers (nm) for light. In this question, the red light has a wavelength of 656.45 nm, which is essential for calculating the number of fringe shifts. The wavelength determines how many times the light wave can fit into the distance moved by the mirror.

Fringe Shift Calculation

Fringe shift calculation involves determining how many times the light wave's path length changes in relation to its wavelength when a mirror is moved. For every full wavelength (2 times the distance moved by the mirror), a bright fringe shifts to a dark fringe or vice versa. Thus, moving mirror M₂ by 1 cm will result in a specific number of fringe shifts based on the wavelength of the light used.

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Use your expression from part a to find an expression for the separation Δy on the screen of two fringes that differ in wavelength by Δλ.

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FIGURE EX33.17 shows the interference pattern on a screen 1.0 m behind an 800 lines/mm diffraction grating. What is the wavelength (in nm) of the light?

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Your artist friend is designing an exhibit inspired by circular-aperture diffraction. A pinhole in a red zone is going to be illuminated with a red laser beam of wavelength 670 nm, while a pinhole in a violet zone is going to be illuminated with a violet laser beam of wavelength 410 nm. She wants all the diffraction patterns seen on a distant screen to have the same size. For this to work, what must be the ratio of the red pinhole’s diameter to that of the violet pinhole?

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Textbook Question

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Textbook Question

The entrance to a boy’s bedroom consists of two doorways, each 1.0 m wide, which are separated by a distance of 3.0 m. The boy’s mother yells at him through the two doors as shown in Fig. 35–42, telling him to clean up his room. Her voice has a frequency of 400 Hz. Later, when the mother discovers the room is still a mess, the boy says he never heard her telling him to clean his room. The velocity of sound is 340 m/s. (a) Find all of the angles θ (Fig. 35–42) at which no sound will be heard within the bedroom when the mother yells. Assume sound is fully absorbed when it strikes a bedroom wall. (b) If the boy was at the position shown when his mother yelled, does he have a good explanation for not having heard her? Explain.

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Textbook Question

Monochromatic light falls on a transmission diffraction grating at an angle Φ to the normal.

(a) Show that Eq. 35–13 for diffraction maxima must be replaced by d(sinΦ + sinθ) = ±mλ. m = 0, 1, 2, ...

(b) Explain the ± sign.

(c) Green light with a wavelength of 550 nm is incident at an angle of 15° to the normal on a diffraction grating with 4500 slits/cm. Find the angles at which the first-order maxima occur.

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