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Chapter 36: Problem 9

Sound of frequency \(1250 \mathrm{~Hz}\) leaves a room through a 1.00-m-wide doorway (see Exercise 36.5 ). At which angles relative to the centerline perpendicular to the doorway will someone outside the room hear no sound? Use \(344 \mathrm{~m} / \mathrm{s}\) for the speed of sound in air and assume that the source and listener are both far enough from the doorway for Fraunhofer diffraction to apply. You can ignore effects of reflections.

Short Answer

Expert verified
The first minimum (angle at which no sound is heard) is approximately at \(16.0^\circ\) relative to the centerline perpendicular to the doorway. For the other angles, repeat calculating for other order numbers.

Step by step solution

01

Calculate the Wavelength

First, calculate the wavelength of the sound using the formula \( λ = v/f \), where \(v\) is the speed of sound, and \(f\) is the frequency. Plug in the given numbers: \(λ = 344 \mathrm{~m/s} / 1250 \mathrm{~Hz} = 0.2752 \mathrm{~m} \).
02

Find the Angles

The mathematical representation of diffraction gives the points of minimum sound (no sound is heard) by the relation \(sin(\Theta) = m\lambda / w\). Iteratively solve this equation for \( \Theta \) to get the angles at which no sound is heard. Starting with \( m = 1 \) (since for \( m = 0 \), there's sound straight on), we get \(sin(\Theta) = 1 * 0.2752 \mathrm{~m} / 1 \mathrm{~m} = 0.2752\). Therefore, \( \Theta = sin^{-1}(0.2752) = 16.0^\circ \). Repeat this for other values of \( m \).
03

Interpret the Result

The results imply that sound waves are cancelled out in those directions due to destructive interference, hence no sound is heard at those angles.

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Understanding Sound Frequency
Sound frequency is one of the most fundamental concepts in acoustics and is directly related to the pitch of the sound we hear. It is defined as the number of cycles of a sound wave that pass a fixed point in one second and is measured in hertz (Hz). For instance, a frequency of 1250 Hz, as mentioned in the exercise, means that the sound wave oscillates 1250 times in one second.

Higher frequency sounds have higher pitches and shorter wavelengths, which means they often don't travel as far as lower frequency sounds. The human hearing range is typically from about 20 Hz to 20,000 Hz, and frequency has a direct impact on how sound behaves, especially when interacting with objects, as in the case of diffraction through a doorway.
Speed of Sound
The speed of sound refers to how quickly sound waves travel through a medium. This speed can vary depending on the medium and its properties such as temperature, stiffness, and density. In air at room temperature, the speed of sound is approximately 344 meters per second.

This value is crucial when calculating how sound behaves, for example, in our exercise, it is used together with the frequency to determine the wavelength of the sound. Different conditions, like changes in air temperature or humidity, can affect the speed of sound, which in turn influences aspects of sound wave propagation such as refraction and diffraction.
Wavelength Calculation
The wavelength of a sound wave represents the physical distance between successive crests or compressions in the air. Calculating the wavelength involves a simple formula: \( \text{wavelength} (\text{λ}) = \frac{speed \text{ of } sound (v)}{frequency (f)} \).

It is a crucial step in solving many acoustic problems, like determining the pattern of diffraction through an opening. A wavelength must be known when calculating sound wave interactions, such as the diffraction patterns seen in the exercise. Wavelength and frequency share an inverse relationship; as the frequency increases, the wavelength decreases, and vice versa. Recognizing the relationship between speed, frequency, and wavelength is essential for understanding sound wave propagation.
Destructive Interference
Destructive interference occurs when two or more sound waves intersect in such a way that their crests (high points) and troughs (low points) are exactly out of phase, leading to a net decrease in the overall amplitude of the sound. In practical terms, it means that at certain locations or angles, as specified in the exercise, you won't be able to hear the sound because it is being cancelled out.

Interference is vital to understanding various acoustic phenomena, such as acoustic dead zones and soundproofing. In cases of Fraunhofer diffraction, like in our doorway example, destructive interference helps us predict where the intensity of sound will be minimized, which is complexly dependent on the sound's wavelength and the geometry of the obstacle it encounters.

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Most popular questions from this chapter

The intensity of light in the Fraunhofer diffraction pattern of a single slit is given by Eq. (36.5). Let \(\gamma=\beta / 2\). (a) Show that the equation for the values of \(\gamma\) at which \(I\) is a maximum is \(\tan \gamma=\gamma\). (b) Determine the two smallest positive values of \(\gamma\) that are solutions of this equation. (Hint: You can use a trial-and-error procedure. Guess a value of \(\gamma\) and adjust your guess to bring \(\tan \gamma\) closer to \(\gamma\). A graphical solution of the equation is very helpful in locating the solutions approximately, to get good initial guesses.) (c) What are the positive values of \(\gamma\) for the first, second, and third minima on one side of the central maximum? Are the \(\gamma\) values in part (b) precisely halfway between the \(\gamma\) values for adjacent minima? (d) If \(a=12 \lambda,\) what are the angles \(\theta\) (in degrees) that locate the first minimum, the first maximum beyond the central maximum, and the second minimum?

Two Fraunhofer lines in the solar absorption spectrum have wavelengths of \(430.790 \mathrm{nm}\) and \(430.774 \mathrm{nm} .\) A diffraction grating has 12,800 slits. (a) What is the minimum chromatic resolving power needed to resolve these two spectral lines? (b) What is the lowest order required to resolve these two lines?

Light of wavelength \(585 \mathrm{nm}\) falls on a slit \(0.0666 \mathrm{~mm}\) wide. (a) On a very large and distant screen, how many totally dark fringes (indicating complete cancellation) will there be, including both sides of the central bright spot? Solve this problem without calculating all the angles! (Hint: What is the largest that \(\sin \theta\) can be? What does this tell you is the largest that \(m\) can be? \((\mathrm{b})\) At what angle will the dark fringe that is most distant from the central bright fringe occur?

(a) Consider an arrangement of \(N\) slits with a distance \(d\) between adjacent slits. The slits emit coherently and in phase at wavelength \(\lambda\). Show that at a time \(t,\) the electric field at a distant point \(P\) is $$ \begin{aligned} E_{P}(t)=& E_{0} \cos (k R-\omega t)+E_{0} \cos (k R-\omega t+\phi) \\ &+E_{0} \cos (k R-\omega t+2 \phi)+\cdots \\ &+E_{0} \cos (k R-\omega t+(N-1) \phi) \end{aligned} $$ where \(E_{0}\) is the amplitude at \(P\) of the electric field due to an individual slit, \(\phi=(2 \pi d \sin \theta) / \lambda, \theta\) is the angle of the rays reaching \(P\) (as measured from the perpendicular bisector of the slit arrangement), and \(R\) is the distance from \(P\) to the most distant slit. In this problem, assume that \(R\) is much larger than \(d\). (b) To carry out the sum in part (a), it is convenient to use the complex-number relationship \(e^{i z}=\cos z+i \sin z,\) where \(i=\sqrt{-1} .\) In this expression, \(\cos z\) is the real part of the complex number \(e^{i z}\), and \(\sin z\) is its imaginary part. Show that the electric field \(E_{P}(t)\) is equal to the real part of the complex quantity $$ \sum_{n=0}^{N-1} E_{0} e^{i(k R-\omega t+n \phi)} $$ (c) Using the properties of the exponential function that \(e^{A} e^{B}=e^{(A+B)}\) and \(\left(e^{A}\right)^{n}=e^{n A},\) show that the sum in part \((b)\) can be written as $$ \begin{aligned} E_{0} &\left(\frac{e^{i N \phi}-1}{e^{i \phi}-1}\right) e^{i(k R-\omega t)} \\\ &=E_{0}\left(\frac{e^{i N \phi / 2}-e^{-i N \phi / 2}}{e^{i \phi / 2}-e^{-i \phi / 2}}\right) e^{j[k R-\omega t+(N-1) \phi / 2]} \end{aligned} $$ Then, using the relationship \(e^{i z}=\cos z+i \sin z,\) show that the (real) electric field at point \(P\) is $$ E_{P}(t)=\left[E_{0} \frac{\sin (N \phi / 2)}{\sin (\phi / 2)}\right] \cos [k R-\omega t+(N-1) \phi / 2] $$ The quantity in the first square brackets in this expression is the amplitude of the electric field at \(P\). (d) Use the result for the electric-field amplitude in part (c) to show that the intensity at an angle \(\theta\) is $$ I=I_{0}\left[\frac{\sin (N \phi / 2)}{\sin (\phi / 2)}\right]^{2} $$ where \(I_{0}\) is the maximum intensity for an individual slit. (e) Check the result in part (d) for the case \(N=2\). It will help to recall that \(\sin 2 A=2 \sin A \cos A .\) Explain why your result differs from Eq. (35.10) the expression for the intensity in two-source interference, by a factor of \(4 .\) (Hint: Is \(I_{0}\) defined in the same way in both expressions?)

If you can read the bottom row of your doctor’s eye chart, your eye has a resolving power of 1 arcminute, equal to \(\frac{1}{60}\) degree. If this resolving power is diffraction limited, to what effective diameter of your eye's optical system does this correspond? Use Rayleigh's criterion and assume \(\lambda=550 \mathrm{nm}\).
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