Wave, Motion and Sound - Part II

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2. Sound  waves
Sound is a form of energy that travels in the form of a longitudinal wave. Sound is produced by vibration of a physical body. The air around it goes into compression and rarefaction and the sound wave thus travels from its source to farther distances. A plucked guitar string, a vibrating tuning fork, our voices, animal calls are all due to some physical objects set into vibrations. In case of human voice, there is a pair of vocal chords in our throat. When they vibrate, voice is emitted.  Voice, tone and pitch depends on the physical nature of our vocal chords.

The figure below shows what happens when a tuning fork is sounded.

Initially the density of air around the tuning fork is undisturbed. As the fork prongs go back and forth or oscillate, the density of the air is pushed and pulled and the air becomes compressed and rarefied alternately.  

The transmission of sound waves therefore occurs via pressure changes in the air, which is the medium in which the longitudinal waves are set into motion. Without a material medium, sound waves cannot be obtained.

A simple experiment will demonstrate this. Keep an alarm clock in a bell jar.  Connect the bell jar to a vacuum pump. Let the alarm sound. Now start the vacuum pump. You will notice that as the air is being pumped out of the bell jar, the sound starts diminishing and ultimately you will not be able to hear any sound.  The experiment clearly demonstrates that a material medium such as air is needed for transmission of the sound waves.  

Speed of sound depends directly on the elasticity of the medium and inversely on the density of the medium. For a gaseous medium, elasticity can be approximated to the pressure of the gas.  In air, the velocity of sound is about 340 m/s. If we change the air medium to a less denser medium like Helium gas, our voices will sound shrilly like the cartoon character Mickey mouse. On the other hand, if the medium surrounding our vocal chord is dense (say with Argon gas), then our voices will sound hoarse like the cartoon character Goofey.

The temperature of the medium also affects the speed of sound. As the temperature becomes higher, the density of the medium decreases, this make the sound waves travel faster.

The following table gives the speed of sound in different mediums at 0°C.  

Medium Velocity of sound at 0°C (m/s)
Air 331
Oxygen 460
Alcohol 1213
Water 1435
Copper 3560
Iron 5130

The table below gives the speed of sound in air at different temperatures.

Temperature °C Velocity of sound (m/s)
0 331
20 344
100 386
500 553
1000 700

Since sound waves travel because of local air pressure differences, in addition to temperature, humidity and air pressure also changes the velocity of sound.

Reflection of sound waves
Just as light waves bounce off or reflect from a surface, sound waves too are reflected. Reflection of sound waves can be demonstrated by a simple experiment described below.


Take a bell and a hollow tube.  Let the tube be placed at an angle to a reflecting surface such as a plate. Keep a screen vertical to the plate. Ask a friend to ring the bell. Take another hollow tube on the other side of the screen and keep it near your ear. Change the angle of the second tube with respect to the plate. At a particular angle, you will be able to hear the ringing of the bell clearly. This is the angle of reflection of the sound wave. You will notice that the angle of reflection = angle of incidence. The conclusion of the experiment is that the sound waves are reflected just like the light waves.

Focussing of sound waves occur with concave surfaces just like focussing of light rays with concave mirrors. This is demonstrated by two concave surfaces arranged as shown below.

If a source of sound such as a watch is kept at one focus, the sound of the ticking of the watch is clearly heard at the other focus. Such examples of sound reflections are a source of amazement in science museums where whispering galleries surprise visitors with their own voices reflected back. Also when we are unable to hear, we cup our hands near our ears in a concave geometry, which then gives us a better hearing.

Sound reflection is also seen in echoes.  Since our ears cannot distinguish sounds heard within a gap of 1/10th of a second. Thus an echo can be heard if the sound reflected back takes more than 0.1 second.  By taking the speed of sound to be about 340m/s at ordinary temperature and pressure, an echo can be heard if the distance of the reflecting object is more than 17 meters.


Measuring velocity of sound
A simple method of determining the velocity of sound is shown below.

One person A stands on a cliff with a gun. Another person stands on the cliff B with a stopwatch. The distance between A and B is known.  When the gun is fired by A, there is first a flash of light and then the sound. This is because the speed of light is 3 x 108m/s, many orders of magnitude larger than the speed of the sound.  B starts his stopwatch when he sees the flash of light and stops his stopwatch when he hears the sound. The time measured by the stopwatch is the time taken by the sound waves to travel distance AB. Dividing the distance between A and B by the time, we will get the velocity of sound. Since the sound velocity is dependent on various parameters such as air temperature, pressure, wind directions, etc. this experiment has to be performed several times with interchanging positions of A and B; Thus an average velocity of the sound can be determined.

 

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