GRADE 10A: Physics 4. UNIT 10AP.4 9 hours. Waves and sound. Resources. About this unit. Previous learning. Expectations

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GRADE 10A: Physics 4 Waves and sound UNIT 10AP.4 9 hours About this unit This unit is the fourth of seven units on physics for Grade 10 advanced. The unit is designed to guide your planning and teaching of physics lessons. It provides a link between the standards for science and your lesson plans. The teaching and learning activities should help you to plan the content and pace of lessons. Adapt the ideas to meet your students needs. For extension or consolidation activities, look at the scheme of work for Grade 11A and Grade 9. You can also supplement the activities with appropriate tasks and exercises from your school s textbooks and other resources. Introduce the unit to students by summarising what they will learn and how this will build on earlier work. Review the unit at the end, drawing out the main learning points, links to other work and real world applications. Previous learning To meet the expectations of this unit, students should already know that waves transfer energy and they should know the relationship between wavelength, frequency and velocity of a wave. They should be able to explain, in terms of particle motion, how sounds are produced and transmitted, and know how pitch of a note is related to its frequency. Expectations By the end of the unit, students know that energy is transferred in the form of pulses and waves, and understand and manipulate the measurable parameters associated with waves. They know that sound is a waveform that requires a medium, they measure its speed in air and know how the ear detects sounds. Students who progress further distinguish between standing and progressive waves, know how harmonics are produced, and describe the phenomenon of resonance with reference to air columns and stretched strings. Resources The main resources needed for this unit are: ripple tanks Slinky springs wave machine model for demonstration starting pistol or equivalent producer of sound signal generator and loudspeaker dynamics trolleys linked by compressible springs storage oscilloscope or PC and appropriate software model or large diagram of the human ear sonometer xenon stroboscope sound analysis software vibration generator tuning forks with a range of frequencies Kundt tube Key vocabulary and technical terms Students should understand, use and spell correctly: terms relating to waves: crest, trough, compression, rarefaction, displacement, amplitude, phase difference, period, frequency, wavelength, velocity, longitudinal, transverse, wavefront terms relating to sound and hearing: ultrasound, infrasound terms relating to standing waves: frequency spectrum, fundamental, harmonic, travelling wave, standing wave, node, antinode, resonance 165 Qatar science scheme of work Grade 10 advanced Unit 10AP.4 Physics 4 Education Institute 2005

Standards for the unit Unit 10AP.4 9 hours SUPPORTING STANDARDS CORE STANDARDS Grade 10 standards EXTENSION STANDARDS 2 hours Waves 9.20.1 Know that energy can be transmitted down a rope or through water in the form of waves. 10A.28.1 Distinguish between a wave pulse and a continuous travelling wave, give examples of both and understand what is meant by wavefront. 4 hours Sound and hearing 3 hours Standing waves 9.20.2 Distinguish between longitudinal and transverse waves. 9.20.3 Understand the relationship between velocity, frequency and wavelength, and perform calculations using the relationship. 10A.28.2 10A.28.3 Know that waves transfer energy and distinguish between transverse and longitudinal waves. Know and use the terms crest, trough, compression, rarefaction, displacement, amplitude, phase difference, period, frequency, wavelength and velocity, and perform calculations using the relationships between velocity, frequency and wavelength. 11A.29.5 12A.28.1 Explain the phenomena of coherence and polarisation of transverse waves and describe applications of both. Describe examples of free oscillations and understand and use the terms amplitude, period, frequency, angular frequency and phase difference. Express the period in terms of both frequency and angular frequency. 9.20.8 Know how, in terms of the movement of particles, sound is transmitted through a medium and how the ear detects sounds. 10A.27.1 Describe the kinetic particle model for solids, liquids and gases, and relate the difference in the structures and densities of solids, liquids and gases to the spacing, ordering and motion of particles. 10A.28.4 Know that sound is a longitudinal vibration transmitted through a medium, and that it is created by a vibrating object such as a vibrating string or air column. 10A.28.5 10A.28.6 Know that the velocity of sound depends on the medium though which it travels, and that it travels faster and more efficiently through media in which the particles are close together. Describe the way in which the ear detects sounds and know the approximate limits of human hearing. 12A.26.1 Classify solids according to stiffness... use the concept of Young s modulus. 9.20.9 Know that pitch is determined by the frequency of a sound and that amplitude is a measure of the loudness... 10A.28.7 Distinguish between standing waves and progressive waves in terms of the production of sound by a musical instrument. Know how harmonics are produced and how the frequency and sound of the harmonics relate to the fundamental. 10A.28.8 Distinguish between a standing and a travelling wave, know the meaning of the terms node and antinode, and illustrate the phenomenon of resonance with particular reference to vibrating stretched strings and air columns. 11A.29.1... explain... superposition and constructive and destructive interference in terms of wave motion. Describe practical examples of forced oscillations and resonance 12A.28.5 166 Qatar science scheme of work Grade 10 advanced Unit 10AP.4 Physics 4 Education Institute 2005

Activities Unit 10AP.4 Objectives Possible teaching activities Notes School resources 2 hours Waves Distinguish between a wave pulse and a continuous travelling wave, give examples of both and understand what is meant by wavefront. Know that waves transfer energy and distinguish between transverse and longitudinal waves. Know and use the terms crest, trough, compression, rarefaction, displacement, amplitude, phase difference, period, frequency, wavelength and velocity, and perform calculations using the relationships between velocity, frequency and wavelength. Waves and pulses Hold a brainstorming session in which students give examples of different types of wave. List these on the board or OHP. Establish that each involves a transfer of energy without a net transfer of matter. By suitable questioning and discussion, establish that waves can be either short pulses (e.g. shock waves, tsunamis) or continuous travelling waves. Allow pairs or small groups of students to explore single pulses and continuous waves using ripple tanks. Tell them to produce short pulses of circular waves (e.g. by touching the water surface briefly with a finger) and study their movement (e.g. observe their reflection from a straight barrier). Similarly, tell them to produce a straight pulse by touching the water surface with a straight object. Then tell them to use a motor to produce continuous circular and straight travelling waves. Ask them to draw diagrams to record their observations. Introduce the term wavefront to denote the leading edge of a single pulse. Establish that the travelling wave is a continuous succession of pulses (i.e. a succession of wavefronts) and the behaviour of a travelling wave can be deduced by studying a single pulse. Travelling waves Use a Slinky spring to demonstrate continuous transverse and longitudinal waves. Display large labelled diagrams on the board or OHP to introduce the terms needed to describe the transverse waves (crest, trough, displacement, amplitude, wavelength, period, frequency) and the equivalent for longitudinal waves (i.e. compression and rarefaction in place of crest and trough). Use a wave machine model to demonstrate the motion of individual particles during the passage of a transverse and a longitudinal wave. Establish that each individual particle moves to and fro about a fixed position, and that each particle s motion lags slightly behind that of its neighbour. Introduce the term phase difference to describe this lag and describe the phase in terms of cycles (e.g. the motion of one particle is one-quarter of a cycle behind that of another). Establish the relationship between period and frequency and introduce the SI unit of frequency: 1 Hz = 1 s 1. Then use numerical examples to derive the relationship between frequency, wavelength and velocity (e.g. draw a wave of wavelength 2 cm, tell students that the frequency is 5 Hz and ask them how far a wavefront travels in 1 s). Examples might include: radio waves; sound waves; water waves; Mexican waves produced by spectators at large sporting events and concerts; shock waves; earthquake waves; tsunamis ( tidal waves ). If you do not have a wave machine, download a suitable applet. Use this column to note your own school s resources, e.g. textbooks, worksheets. Ask students, in pairs or small groups, to use ripple tanks to measure the frequency and wavelength of a travelling water wave and hence calculate its velocity. Ask them also to find the velocity of a single pulse by timing its motion over a fixed distance, and then to compare their two values. Provide plenty of examples of algebraic and numerical calculations that allow students to practise using wave quantities and the relationships between them. Enquiry skills 10A.1.1, 10A.1.3, 10A.3.1 10A.3.3, 10A.4.1, 10A.4.2 167 Qatar science scheme of work Grade 10 advanced Unit 10AP.4 Physics 4 Education Institute 2005

Objectives Possible teaching activities Notes School resources 4 hours Sound and hearing Know that sound is a longitudinal vibration transmitted through a medium, and that it is created by a vibrating object such as a vibrating string or air column. Know that the velocity of sound depends on the medium though which it travels, and that it travels faster and more efficiently through media in which the particles are close together. Describe the way in which the ear detects sounds and know the approximate limits of human hearing. Making sound waves Ask students individually to carry out a short series of activities to illustrate the production of sound. Either arrange the activities as a circus, or provide small groups of students with all the necessary apparatus. Provide a handout instructing students how to carry out each activity. Suitable activities include the following. Tuning fork. Strike the fork so that it makes a sound. Hold the fork so that the free end touches the surface of water or a suspended table-tennis ball. Throat. While speaking, touch the front of your own neck. Loudspeaker. Connect a loudspeaker to a signal generator set to a low frequency and large amplitude. Arrange the loudspeaker so that it faces upwards and place a few rice grains in the cone. Candle. Place a lighted candle in front of a loudspeaker connected to a signal generator. Observe the flame when it is in the path of a loud sound. String. Pluck a stretched string so that it makes a sound. Observe its motion. Establish that sound is produced by vibrating objects. Use a wave machine model and/or a Slinky to demonstrate how a source of vibration gives rise to longitudinal travelling waves. Encourage students to download and use applets to show the movement of particles as a sound wave passes through a medium. Ask students to use their knowledge of the kinetic particle model to predict whether sound travels most easily through a solid or through a gas. Invite them to test their predictions by tapping gently on a bench top and listening first through the air then pressing their ear against the bench; in the latter case, they will hear a louder sound. Speed of sound in air Take students to a suitable outdoor space to allow them to take measurements to determine the speed of sound in air. Possible methods include the following. Get all students to stand a measured distance (a few tens of metres) from a wall. Ask one student to clap hands once and listen for the echo, then to clap with a regular rhythm such that each new clap coincides exactly with hearing an echo. Ask other students to measure the time for several claps. They can then work out the interval between adjacent claps and hence calculate the speed of sound in air. Get two groups of students to stand a few hundred metres apart in a large open space (e.g. a playing field). Give one group a starting-pistol and the other group several stopwatches. Ask a third group to use a long tape to measure the distance between them. Ask the first group to fire the starting-pistol. Tell students in the second group to start their stop-watches when they see the pistol being fired and to stop them when they hear the sound. They can then use their measurements to calculate the speed of sound in air. Ask students to identify sources of inaccuracy and imprecision in the method(s) used. Encourage them to suggest how the method(s) could be improved. Prepare student handouts. Enquiry skill 10A.4.2 ICT opportunity: Use of Java applets. Enquiry skill 10A.1.2 Enquiry skills 10A.1.1, 10A.1.3 10A.1.5 This activity also relates to Standard 10A.25.2. Safety note: Ensure that the pistol is loaded only with blank cartridges and that students follow correct procedures for firing. 168 Qatar science scheme of work Grade 10 advanced Unit 10AP.4 Physics 4 Education Institute 2005

Objectives Possible teaching activities Notes School resources Speed of sound in a solid In a demonstration to the whole class, use a line of about six dynamics trolleys, linked by compressible springs, to model the passage of a sound wave through a solid. Send a longitudinal compression pulse along the row. Ask students to predict how its speed will be affected by (1) the mass of each trolley and (2) the stiffness of the springs. Test the predictions for (1) by adding extra mass to each trolley and those for (2) by joining pairs of springs in parallel to create a stiffer link. Relate these predictions to properties of solids. The denser the solid (i.e. the more massive its particles), the lower the sound speed. The stiffer the solid, the higher the speed. Encourage students to use the Internet to find data about the density, stiffness and sound speed for a range of solids. The model with trolleys illustrates a principle underlying a method for determining sound speed in a solid, which could be demonstrated to students. Push the whole row of trolleys so that one end collides with a wall. Point out that, while the trolleys and wall are in contact, a compression pulse travels from the wall to the free end, where it is reflected as a rarefaction pulse. When the rarefaction reaches the wall, the trolleys and wall break contact. The contact time thus represents the time for a pulse to travel twice the length of the row. Use a storage oscilloscope (CRO) or install suitable software onto a PC so that it acts as a storage CRO. Arrange a metal rod so that it is suspended horizontally but is free to move. Connect the rod to one terminal of the PC/CRO. The other PC/CRO terminal should be connected to the negative terminal of a 3 V battery, whose positive terminal is connected to a claw hammer. Gently tap one end of the rod with the hammer. The trace on the PC/CRO screen will indicate the contact time and hence the time for a longitudinal wave pulse to travel twice the length of the rod. Measure the length of the rod and hence calculate the sound speed. Ask students to compare this result with the sound speed data that they collected previously. Hearing sounds Connect a loudspeaker to a signal generator. Set the frequency to a few hundred hertz and adjust the amplitude so that the sound is loud without being unpleasant. Gradually increase the frequency and ask students to raise their hands when they are unable to hear a sound. You will probably need to increase the amplitude as well as increasing the frequency. When all hands are raised, reduce the frequency and ask students to lower their hands when the sound becomes audible again. Note the approximate frequency above which most students find the sound inaudible and introduce the term ultrasound. Repeat the exercise, only now reduce the frequency and hence find the frequency below which the sound is inaudible to most students. Introduce the term infrasound. Point out that there is no well-defined limit to human hearing. The limits vary between people, and the upper limit moves to a lower frequency with increasing age. Display a model and/or a large diagram showing the structure of the human ear. Hand out copies of a clear unlabelled diagram of the ear. Drawing on students knowledge from earlier grades, discuss the operation of the ear. Ask students to add labels and explanatory text to the diagrams. Enquiry skill 10A.1.2 Tell students that stiffness is denoted by the Young modulus of a solid. They will learn more about this in a later unit. ICT opportunity: Use of the Internet. ICT opportunity: Use of sound analysis software. Prepare student handouts. 169 Qatar science scheme of work Grade 10 advanced Unit 10AP.4 Physics 4 Education Institute 2005

Objectives Possible teaching activities Notes School resources 3 hours Standing waves Distinguish between standing waves and progressive waves in terms of the production of sound by a musical instrument. Know how harmonics are produced and how the frequency and sound of the harmonics relate to the fundamental. Distinguish between a standing and a travelling wave, know the meaning of the terms node and antinode, and illustrate the phenomenon of resonance with particular reference to vibrating stretched strings and air columns. Strings and tubes If any students play a string or wind instrument, ask them to bring their instruments into class and demonstrate how they make a sound. If musical instruments are not available, either obtain recordings and pictures of a variety of wind and string instruments, or demonstrate the sound produced by plucking a sonometer wire and blowing over the top of a test-tube. By suitable questioning, ensure that students recall work from earlier grades where they learned that the pitch of a note depends on its frequency. Use a signal generator and loudspeaker to illustrate the relationship between the frequency and the sound of a note (e.g. doubling the frequency raises the pitch by one octave). Ask pairs of students to explore how the pitch of a note is controlled in string and wind instruments. For strings, they should use either a real instrument (e.g. guitar, violin) or a sonometer, and obtain notes by plucking and/or bowing. In place of real wind instruments, they should use several test-tubes each containing a different depth of water and obtain notes by blowing over the top of each tube to make the trapped column of air vibrate. Ask them to produce a brief written report of their work. Establish that the pitch of note from a string instrument depends on the length of the vibrating string. Explain that the note from a wind instrument is produced by a vibrating air column and establish that the pitch depends on the length. Fundamental and harmonics Use a storage oscilloscope or a PC with suitable software to display the waveform of the sounds produced by a variety of musical instruments, or use pre-recorded samples. Discuss with students the interpretation of the traces displayed: though representing a longitudinal sound wave, they have the appearance of transverse waves. Explain that the traces are graphs showing how pressure varies with time as the wave passes. While such a trace is not a picture of an actual wave, it can be described as a waveform. Compare the waveforms produced by musical instruments with that produced by a loudspeaker connected to a signal generator producing a sine wave. Establish that, although the waveform is more complex than a sine wave, each trace representing a single note from an instrument has a well-defined frequency. Ask students, in pairs, to use suitable software to analyse one or more sound samples into their component frequencies and to display its frequency spectrum (i.e. a graph of amplitude plotted against frequency). Get each pair to analyse a different sample then print out a screen dump of the waveform and associated spectrum for distribution to the rest of the class. Discuss the results with the whole class. Show students the waveform and sound spectrum produced by a sine wave from a signal generator. Establish that, in contrast, each note from an instrument contains many frequencies, but that there is one (usually the lowest) that contributes the largest amplitude. Introduce the terms fundamental (i.e. lowest frequency) and harmonic. Point out that the frequencies of the harmonics are generally simple multiples of the fundamental frequency. Ask students to add labels to one of their printed spectra to identify the fundamental frequency and some of the harmonics. Using test-tubes rather than real wind instruments makes the relationship between pitch and length of air column apparent. It is not immediately obvious that holes in the side of a wind instrument effectively control the length of the vibrating air column. Students might observe that the pitch produced by a string also depends on its tension and its mass. ICT opportunity: Use of sound analysis software. 170 Qatar science scheme of work Grade 10 advanced Unit 10AP.4 Physics 4 Education Institute 2005

Objectives Possible teaching activities Notes School resources Standing waves on a string Demonstrate the vibration of a string. Tie one end of a horizontal string to a fixed support and the other to a vibrator driven by a signal generator. Show that there are several frequencies at which the string performs vibrations of large amplitude and introduce the term resonance. Establish that the lowest resonant frequency (the fundamental) produces a vibration with its greatest displacement at the mid-point of the string. Show that doubling the frequency creates a vibration where the mid-point of the string is at rest and the positions of maximum displacement lie between this point and the fixed ends. Introduce the terms node and antinode. Ask students to speculate as to the pattern of nodes and antinodes for higher harmonics, then demonstrate what happens. Establish that there is always a node at each fixed end of the string. Ask students to draw labelled diagrams showing nodes and antinodes in a standing wave. Explain that these vibrations of the string are called standing waves. Use a xenon strobe to show that, in a standing wave, all parts of the string between adjacent nodes vibrate in phase with each other, and that there is a phase difference of exactly half a cycle between parts of the string separated by a node. Explain that, in a string instrument, plucking or bowing the string gives rise to a large range of frequencies of vibration. Some of those frequencies match the fundamental and harmonic frequencies of the string, and these give rise to large-amplitude vibrations. The vibrations that make up standing waves on the string produce travelling waves in the air, which we hear as a musical note. Safety: Stroboscopes are dangerous to epilepsy sufferers. If students have never used a stroboscope, explain how it apparently freezes a regular repeating motion such as that of a vibrating string. For an effective demonstration, adjust the stroboscope frequency so that it freezes the motion of the string, then alter its frequency slightly so that the string appears to vibrate slowly. Standing waves in a tube Ask pairs or small groups of students to explore resonance in tubes. Tell them to look for a Enquiry skills 10A.1.1, 10A.1.3, 10A.4.1, 10A.4.2 relationship between resonant frequency and tube length, and to produce a written report of their work. Possible methods include the following. Use a long tube that can be raised or lowered into a container of water, thus altering the length of the air column. Strike a tuning fork so that it produces a note then hold it close to the open end of the tube and adjust the tube length until a loud sound is heard. Connect a small loudspeaker to a signal generator and mount it close to the end of a tube. Adjust the frequency of the signal generator until a loud sound is heard. Explain to the whole class that standing waves can be produced in tubes. Remind them that the waves are longitudinal and explain that a closed end always produces a displacement node, whereas there is always a displacement antinode at an open end. Explain how these are conventionally represented diagrammatically. Explain to advanced students that a displacement node corresponds to a pressure antinode, and vice versa. Use a Kundt tube to demonstrate the presence of nodes and antinodes in a tube. Explain that blowing the reed or mouthpiece of a wind instrument produces a wide range of frequencies, and the note produced contains the frequencies that correspond to the standing waves set up in the tube. Explain also that opening a hole in the side of a tube produces an antinode at that position, hence opening and closing the holes produces notes of different frequencies. 171 Qatar science scheme of work Grade 10 advanced Unit 10AP.4 Physics 4 Education Institute 2005

Assessment Unit 10AP.4 Examples of assessment tasks and questions Notes School resources Assessment Set up activities that allow students to demonstrate what they have learned in this unit. The activities can be provided informally or formally during and at the end of the unit, or for homework. They can be selected from the teaching activities or can be new experiences. Choose tasks and questions from the examples to incorporate in the activities. A student sitting on the wall of a marina looking at the water notices that wave crests pass by at regular intervals of about 1.5 s, and that the distance between crests is about 2 m. a. What is the wave frequency? b. What is the velocity of these waves? Draw a sequence of labelled diagrams to show how air particles move during the passage of a sound wave. Write about 500 words on the subject of detecting sounds. Include a labelled diagram showing how the human ear works. Use a stroboscope to measure the frequency of a vibrating string. Draw a labelled diagram showing a string vibrating at three times its fundamental frequency. Label the nodes and antinodes. Show which parts of the string are vibrating in phase with each other, and which are half a cycle out of phase. One student plays a note on a string instrument and another plays a note of the same pitch on a wind instrument. Explain why the notes sound different. Provide a stroboscope and a sonometer (or other string that can be made to vibrate). 172 Qatar science scheme of work Grade 10 advanced Unit 10AP.4 Physics 4 Education Institute 2005