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Chapter 17 NOTES Mechanical Waves and SOUND (Characteristics of Waves)

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1 Chapter 17 NOTES Mechanical Waves and SOUND (Characteristics of Waves)
Physical Science Chapter 17 NOTES Mechanical Waves and SOUND (Characteristics of Waves)

2 What are waves? Wave – when energy moves through a medium as a vibration Medium – the material through which a wave passes Waves travel through the medium without actually moving the medium with it. 3 main types Transverse Longitudinal Surface

3 Transverse Waves Cause the medium to vibrate at right angles to the direction the wave travels Has a crest (top) and trough (bottom) Draw this!!! Example – ripple on a pond Transverse Wave Video clip Wave animation

4 Longitudinal Waves Draw this!
move particles parallel to the direction the wave is moving, “push-pull” waves. Example – sound waves in air Draw this! Video clip transverse vs. longitudinal waves Has compression and rarefaction (decompression)

5 Grandpa John – Wave Motion
List examples of each type of wave as you watch the video. So, Examples of Transverse? Radio and light Examples of Longitudinal? Sound and earthquakes

6 Surface Waves Travel on a surface separating 2 media
object on the surface moves in circles - a combo of transverse and longitudinal wave movement Example – ocean waves Ocean waves animation

7 Ocean Waves Near Shore Wave simulation

8 Properties of Waves Period (T) Frequency (ƒ) Wavelength (λ) Speed (v)
Amplitude Properties of waves video clip

9 Period and Frequency Period (T) - time required to go through one cycle. Measured in seconds Frequency (ƒ)- number of cycles in a certain time. ƒ=1/T measured in s-1 or Hz HERTZ, one Hz

10 Wavelength Wavelength (λ)- distance between two identical points on consecutive waves measured in meters (or km, cm, etc) Increasing the frequency of a wave decreases its wavelength.

11 Speed Speed (v) - how fast the wave is moving v=λƒ
measured in m/s (or km/s, cm/s, etc)

12 Amplitude Amplitude - max displacement from its rest position (also known as wave height) measured in meters (or km, cm, etc) Example – dropping a pebble in the water vs. doing a “cannonball” jump into the water VERY IMPORTANT: The more energy a wave has, the greater is its amplitude!!!

13 Classwork/Homework p. 503) 1-7 p. 507) 2, 3, 8-10
Study the Chapt 17!

14 Warm-up Did you do these? p. 503) 1-7 p. 507) 2, 3, 8-10
Study your notes! You have a Quiz on Waves!!!

15 Speed Frequency & Wavelength
Speed (meters/sec)= wavelength x frequency Frequency (Hz = 1/sec)= speed / Wavelength Wavelength (meters) = speed / Frequency Designated by Greek letter lambda - Speed Wavelength x frequency S = x f = 1.5 m x 280 Hz = 420 m/s S = S / f = 5.0 m/s / 2.5 Hz = 2 m x f

16 Wavelength x frequency
Speed Wavelength x frequency p.506 in textbook

17 Interactions of Waves Reflection is when waves, whether physical or electromagnetic, bounce from a surface back toward the source. Ex - a mirror reflects the image of the observer. Refraction is when waves, whether physical or electromagnetic, are deflected when the waves go through a substance. The wave generally changes the angle of its general direction. Diffraction is the bending of a wave as it moves around an obstacle or passes through a narrow opening.

18 Interference- when two waves collide
Constructive Interference – the combining of waves to cause higher amplitude of any of the original waves. Destructive Interference – when the combining of the waves produce a new wave with a smaller amplitude than the beginning waves

19 Standing Waves appear to stay in one place
result of constructive and destructive interference between original wave and reflected wave contains node(s) and antinode(s) Forms only if half a wavelength or a multiple of it fits exactly into the length of the rope

20 Sound and Hearing 17-4

21 Properties of Sound Waves
Longitudinal waves speed- travels at different speeds in different media air- 343m/s fresh water- 1510m/s Salt water- 1550m/s Aluminum- 5000m/s Intensity- rate at which a wave's energy flows through an area measured in Decibels, dB Loudness- physical response to sound Pitch- frequency of sound as you hear it. Higher frequency, higher note Infrasound and Ultra sound

22

23 The Doppler Effect Change in frequency due to motion of source, listener, or both Ex: When a vehicle sounding a siren or horn approaches, passes, and recedes from an observer.

24 Sonic Boom- breaking of sound barrier
Basically the object goes faster than the speed of sound Sonic boom explained

25 Hearing and our Ears Outer Ear- gathers and focuses sound into middle ear Middle Ear- receives and amplifies vibrations Inner Ear- uses nerve endings to sense vibrations Hammer, anvil, cochlea

26 Instruments alter pitch by changing frequency of standing waves
change tension, length, and amplitude Resonance- increased amplitude over time because of added energy. Resonance animation

27 Video Clip Sonic Boom Sonic boom explained
Deadliest catch – monster waves World’s Biggest Wave ever surfed

28 Go over QS !! p. 503) 1-7 p. 507) 2, 3, 8-9 p. 527) 1-6, 13-15, 30-33

29 Wrap-up What is the Doppler effect? What is a sonic boom?


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