1. CHAPTER 15 WAVES

2. Section 15.1 Types of Waves What does a wave carry?
How are waves generated?
What is the difference between a transverse wave and a longitudinal waves?
How do the particles in ocean waves move?
Intro to Waves Clip

3. What is a wave?
Wave- a disturbance that transmits energy through matter or space
Energy may spread out as a wave travels.
Waves are all around us:
light from the stoplight
ripples in a puddle of
electricity flowing in wires
radio and television and cell phone transmissions

4. Waves Medium- the matter through which a wave travels
Water
Air
Earth-seismic waves
Mechanical wave- a wave that requires a medium through which to travel
sound waves (air)
water waves
waves in a spring

5. Waves
Electromagnetic wave-a wave caused by a disturbance in electric and magnetic fields
Does not require a medium
Also called a light wave
can transfer energy through a vacuum
can also transfer energy through a material medium
Example: light waves through space, through air, through glass

6. Waves transfer Energy Animation
A wave caused by dropping a stone in a pond might carry enough energy to move a leaf up and down several centimeters
A tsunami is a huge ocean wave caused by earthquakes.
A tsunami can carry enough energy to damage coastal dwellings.
Animation

7. Vibrations and Waves Most waves are caused by vibrating objects.
Electromagnetic waves may be caused by vibrating charged particles.
Mechanical waves are caused by the vibration of particles within the medium.

8. Vibrations and Waves Vibrations involve transformations of energy
A wave can pass through a series of vibrating objects.
The disturbance travels down the row as energy is transferred from one mass to another.

9. Waves Transverse wave Longitudinal wave
Particles oscillate up and down about their equilibrium positions, perpendicular to the direction of wave propagation
its oscillations perpendicular to the direction the wave moves
Particles oscillate back and forth about their equilibrium positions, parallel to the direction of wave motion
oscillations in the same direction as the wave moves
Examples: light waves, water waves, all waves belonging to the electromagnetic spectrum
Example: Sound waves

10. longitudinal wave
transverse wave
Clip

11. Waves Properties
Waves have crests and troughs or compressions and rarefactions.
compressions: the crowded areas of a longitudinal wave
rarefactions: the stretched-out areas of a longitudinal wave
Do longitudinal wave have crest and troughs?

12. Surface Waves In a surface wave, particles move in circles.
Water waves are an example of surface waves.
Surface waves occur at the boundary between two different media
Ex: water and air

13. Section 15.2 Characteristics of Waves
What are some ways to measure and compare waves?
How can you calculate the speed of a wave?
Why does the pitch of an ambulance siren change as the ambulance rushes past you?

14. Wave Properties Crest-the highest point of a transverse wave
Trough-the lowest point of a transverse wave
Amplitude-the greatest distance that particles in a medium move from their normal position when a wave passes
Rest position

15. Wavelength
Wavelength-the distance between any two successive identical parts of a wave
represented by the symbol l
expressed in the SI unit meters (m)
Amplitude and wavelength tell you about energy.
larger amplitude = more energy
shorter wavelength = more energy

16. A Longitudinal Waveform
A cycle consists of one compression and one expansion of the particles of the medium.
Particles of medium then return to their equilibrium positions

17. A Transverse Waveform A cycle consists of one crest and one trough.
amplitude
crest
trough
wavelength, l
equilibrium
position

18. Period
Period-the time required for one full wavelength to pass a certain point
the time that it takes a complete cycle or wave oscillation to occur
represented by the symbol T
expressed in the SI unit seconds (s)

19. Frequency
frequency: the number of cycles or vibrations per unit of time;
also the number of waves produced in a given amount of time
represented by the symbol f
expressed in the SI unit hertz (Hz), which equals 1/s

20. Frequency The frequency and period of a wave are related.
The frequency is the inverse of the period.
in the diagram,
f = 0.5 Hz

21. Calculating Wave Speed
Wave speed-the speed at which a wave passes through a medium
Wave speed equals frequency times wavelength.
Wave speed= frequency x wavelength
V= f x  V
f= 1 T f 
Wave speed = v
Wavelength = 
Period= T
Frequency= f

22. Practice Problem: Wave Speed
1. The musical note A above middle has a frequency of 440 Hz. If the speed of sound is known to be 350 m/s, what is the wavelength of this note?
f = 440 Hz
v = 350m/s
 = ?
 = v/f
 = 350 m/s
440 Hz
 = 0.80 m
2. A certain FM radio station broadcasts electromagnetic waves at a frequency of 9.05 x 107 Hz. These radio waves travel at a speed of 3.00 x 108 m/s. What is the wavelength of these radio waves?

23. Practice Problem: Wave Speed
3. The average wavelength in a series of ocean waves is 15.0 m. A wave crest arrives at the shore on average every 10.0 s, so the frequency is Hz. What is the average speed of the wave?
4. Yellow light with a wavelength of 5.89 x 10-7 m travels trough quartz glass with a speed of 1.94 x 108 m/s. What is the frequency of the light?

24. Practice Problems: Wave Speed
5. Waves in a lake are 6 m apart and pass a person on a raft every 2 s. What is the speed of the wave?
6. A drum is struck, producing a wave with a wavelength of 1.1m and a speed of 2.42 x 104 m/s. What is the frequency of the wave?
What is the period?

25. Wave Speed The speed of a wave depends on the medium
Greatest in solids and least in gases
Kinetic theory explains differences in wave speed
Light has a finite speed
Speed of light: c = 3 x108 m/s
3 x108 m/s or 186,000 mi/s

26. Wave Speed
Ranges of waves from lowest to highest are: radio waves, microwaves, infrared waves, visible light, ultraviolet light, X-rays, and gamma rays
The full range of light frequencies is called the electromagnetic spectrum

27. Doppler Effect Pitch is determined by the frequency of sound waves.
The pitch of a sound =how high or low it is
A higher-pitched sound is caused by sound waves of higher frequency.
Frequency changes when the source of waves is moving
Ex. Siren moving toward you sounds different than a siren moving away from you
Doppler effect occurs for light and other type of waves as well

28. Doppler Effect
Doppler effect-an observed change in the frequency of a wave when the source or observer is moving
A sound wave frequency change is noticed as a change in pitch.
The Doppler effect occurs for many types of waves, including sound waves and light waves.

29. Section 15.3 Wave Interactions
How do waves behave when they hit a boundary, when they pass around an edge or opening, and when they pass from one medium to another?
What happens when two or more waves are in the same location?
How does a standing wave affect the medium in which it travels?

30. Wave Interactions
Waves bend when they pass from one medium to another at an angle.
Waves will experience :
Reflection
Diffraction
Refraction

31. Reflection
Reflection – the bouncing back of a wave as it meets a surface or boundary
Examples:
The reflection of light waves in a lake can create a mirror image of a landscape.
Water waves are reflected when they hit the side of a boat.

32. Diffraction
Diffraction – the bending of a wave as it passes an edge or an opening
Examples:
Water waves diffract around a block in a tank of water.
Sound waves passing through a door diffract.

33. Refraction
Refraction – the bending of waves as they pass from one medium to another
All waves are refracted when they pass from one medium to another at an angle.

34. Interference
Interference- the combination of two or more waves that exist in the same place at the same time
Two types
Constructive interference
Destructive interference

35. Constructive Interference
Waves combine without any phase difference
Waves combine to form a bigger wave
Increases amplitude

36. Wave Addition
Amplitude ~ Intensity

37. Destructive Interference
Waves combine differing by multiples of 1/2 wavelength
waves combine to form a wave smaller than the largest of the original waves
Decreases amplitude

38. Wave Subtraction

39. Interference Interference of light waves creates colorful displays
Ex. Rainbows, oil in water, soap bubbles

40. Interference
Interference of sound waves produces beats

41. Standing Waves Standing waves have nodes and antinodes
Standing waves-wave caused by interference that shows some regions of no vibrations
Does not move along the medium
Standing waves have nodes and antinodes
Nodes
Each loop of a standing wave is separated by a point
Nodes have no vibrations
Nodes are where the crests of the original waves meet the troughs of the reflected wave (destructive interference)

42. Standing Waves Standing waves can have only certain wavelengths
Antinodes
lie midway between the nodes
point of maximum vibration
form where the crests of the original waves line up with the crests of the reflected waves (constructive interference)
Standing waves can have only certain wavelengths