3.3 Sound

The student measures the distance between the front of the metal block and the microphone.

She then uses this method to measure the time taken for sound to travel from the metal block to the microphone.

• start the timer by hitting the metal block with the hammer
• stop the timer when the sound produced reaches the microphone
• record the time taken for sound to reach the microphone in milliseconds

The student repeats the experiment six times, changing the distance between the metal block and the microphone for each experiment.

The table shows her results.

 

Use the student’s results to plot a graph of distance against time and draw the straight line of best fit.

speed = ......................... unit .....................

Describe an experiment to measure the speed of sound in air.

You may draw a diagram to support your answer.

The speed of sound in air is different for different heights above sea level.

The graph shows how the speed of sound varies with height.

Describe the pattern shown by the graph.

Some aeroplanes can travel faster than the speed of sound.

When an aeroplane travels faster than the speed of sound it causes a shock wave. People on the ground hear this shock wave as a sonic boom.

A student says

Do you agree with the student?

Explain why.

A student uses an oscilloscope to determine the speed of sound.

The diagram shows the oscilloscope trace the student obtains along with the oscilloscope settings used.

The student uses two microphones and a ruler to determine that the wavelength of the sound wave is 1.3 m

Use the oscilloscope trace to calculate the speed of the wave. 

speed = .............................................................. m/s

The student also uses an alternative method to determine the speed of sound. 

He follows the following method: 

1. The student stands 50 m away from his teacher, measuring the distance with a metre ruler.
2. The teacher makes a loud sound and flashes a light at the same time.
3. The student starts the stopwatch when he sees the flash of light.
4. He stops the stopwatch when he hears the loud sound.

The speed of sound is then calculated using the formula

speed of sound = 

Evaluate whether this method could produce an accurate value for the speed of sound in air.

The diagram shows two identical buzzers connected with springs.

Spring A is connected to a post.

A force acts on the apparatus for a short period of time, pulling both buzzers to the right.

During this time, buzzer A moves 2 cm and buzzer B moves 4 cm. 

Explain the difference between the average speeds of buzzers A and B.

The diagram shows the oscilloscope trace produced.

The trace represents the sound wave received by the microphone from buzzer A.

Determine the wavelength of the sound wave.

The speed of sound in air is 340 m/s.

Two students do an experiment to measure the speed of sound in air.

They carry out the experiment outdoors in a wide‑open space and plan to use two blocks of wood which they will hit together to produce a loud noise.

Describe how the students should use their equipment to measure the speed of sound in air.

One type of wave used in hospitals is ultrasound. Ultrasound waves are used to make images of internal organs.

A scanner emits an ultrasound wave into the patient and records any reflections.

The scanner records the time from when a wave is emitted to when its reflection is received.

A technician calculates the depth of the reflection using the equation

depth = × (speed of ultrasound in patient × time recorded by scanner)

Explain why the technician uses the value in the equation.

An ultrasound wave travels faster in the patient than it does in air.

Explain how a change in speed affects the wavelength of the ultrasound wave.

Ultrasound waves are sound waves with a very high frequency. They are often used for medical purposes.

Dentists use ultrasound waves to clean patients’ teeth.  

The diagram shows an ultrasound cleaner removing plaque from teeth.

The tip of the ultrasound cleaner vibrates 96 million times per second and is sprayed with water.

(1)

Other waves also have medical uses.

Ultraviolet waves are used by doctors to cure some skin conditions.

Suggest two differences between ultrasound waves and ultraviolet waves.

A student investigates how air vibrates in a plastic pipe.

She blocks one end of the pipe and blows across the other end.

The pipe emits a sound with a steady pitch. The student uses a microphone to monitor the sound.

Explain the meaning of the pitch of a sound.

The student measures the length of the pipe and the frequency of the microphone signal for two different lengths of pipe.

Name two instruments that she will need for these measurements.

Name the dependent and independent variables in her investigation.

The student collects this data.

Suggest three ways to improve this investigation.

A foghorn makes a loud, low-pitched warning sound when a ship is moving in fog.

A student investigates how the speed of sound in air varies with temperature.

The student’s results are shown on the graph.

 

Draw a straight line of best fit on the graph.

Use the graph to find the speed of sound when the air temperature is 20 °C.

The air temperature decreases while the foghorn continues to emit sound waves with a frequency of 160 Hz.

Explain how this decrease in temperature affects the wavelength of the sound waves.