Presentation is loading. Please wait.

Presentation is loading. Please wait.

Waves and Electromagnetic Radiation The Sciences chapter 6.

Similar presentations


Presentation on theme: "Waves and Electromagnetic Radiation The Sciences chapter 6."— Presentation transcript:

1 Waves and Electromagnetic Radiation The Sciences chapter 6

2 Maxwell, in 1867, proposed that light is an electromagnetic wave. “The spectrum of visible light, from red to violet, is only an octave or so in the range of invisible radiations. There is a whole keyboard of information all the way from the longest wavelengths of radiowaves (the low notes) to the shortest wavelengths of X- rays and beyond (the highest notes)” (Bronowski, p. 353).

3 Figure 6-11 The electromagnetic spectrum includes all kinds of waves that travel at the speed of light, including radio, microwave, infrared, visible light, ultraviolet, X-rays, and gamma rays. Note that sound waves, water waves, seismic waves, and other kinds of waves that require matter in order to move travel much slower than light speed.

4 Waves transfer energy without transferring mass.

5 Figure 6-1 You can use a domino to knock over other dominoes in two different ways: (a) you can throw a domino, or (b) you can trigger a wave of dominoes. Energy Transfer by Waves

6 A wave… Is a traveling disturbance It carries energy from place to place without requiring matter to travel across the intervening distance.

7 Properties of Waves Wavelengths Frequency Velocity Amplitude

8 Figure 6-2 A cross section of a wave reveals the characteristics of wavelength, velocity, and amplitude. Successive wave crests are numbered 1, 2, 3, and 4. An observer at the position of the clock records the number of crests that pass by in a second. This is the frequency, which is measured in cycles per second, or hertz.

9 Relationship among wavelength, frequency, and velocity The velocity of a wave is equal to the length of each wave times the number of waves that pass by each second. Wave velocity (m/s) = wavelength (m) x frequency (Hz) Sample Problem: One tube of a wind chime produces sound at a frequency of 440 Hz. Assuming the speed of sound is 340 m/s, what is the wavelength of sound produced by this chime? Wavelength = velocity / frequency 340 meters per second / 440 Hertz = 0.77 m Also see Example 6-1, p. 119.

10 Figure 6-4 Transverse (a) and longitudinal (b) waves differ in the motion of the wave relative to the motion of individual particles. Two kinds of waves

11 Speed of Light Speed of Sound 300,000,000 m/s 186,000 miles/s 340 m/s 760 miles/hr

12 Example problem 6-2: The human ear can hear sounds at frequencies from 20 to 20,000 Hz. Organ pipes producing these notes would be about half the wavelength. Lowest note wavelength: Velocity / frequency 340 m/s / 20 Hz = 17 m Organ pipe 8.5 m Highest note wavelength: Velocity / frequency 340 m/s / 20,000 Hz = 0.017 m Organ pipe 0.009 m

13 How Sound is Produced… Sound is a form of energy caused by vibrating matter.

14 How Sounds Travel  Vibrations push against molecules in the air and press them closer together  Molecules pushed = compression  Molecules spread = rarefaction

15 Sound Travel in Different States The speed of sound in air is about 336 meters/sec or 1100 ft/sec In liquids, the molecules are closer together and carry the vibrations more easily and quickly (4X >). In solids, the atoms are very close together and carry the vibrations very easily and quickly (9-15X >).

16 Characteristics of Sound Intensity = the “loudness” or “softness” of a sound Pitch = how “high” or “low” the sound seems

17 Characteristics of Sound Pitch - how “high” or “low” sound seems Intensity - “loudness” or “softness” Quality - the mix of frequencies that allow us to distinguish between different sounds Interference –waves from two different sources come together (constructive or destructive)

18 Echoes An echo is a sound wave that bounces back must be at least 17 meters (or 56 ft) away from the reflecting surface (closer and reflected sound wave blends with original)

19 The Human Voice 2 strong bands of tissue called vocal cords --The tighter the vocal cords, faster they vibrate, the higher the pitch. --Increase volume by increasing force of air blown between the vocal cords.

20 Speed of Light Speed of Sound 300,000,000 m/s 186,000 miles/s 331 m/s 760 miles/hr

21 Doppler Effect If a listener or the source of a sound is moving, the listener may hear a pitch that is different from the frequency of the source. The change in pitch heard when the source of sound is moving relative to the listener is the Doppler effect.

22 Figure 6-9 The Doppler effect occurs whenever a source of waves is moving relative to the observer of the waves. (a) Sound waves spread out from a source in all directions; stationary listeners hear the same pitch. (b) Sound waves from a moving source seem to increase or decrease in pitch, depending on whether the sound is approaching or receding. (c) The Doppler shift for light waves cause a blueshift for approaching sources, and a redshift for receding sources.

23

24 Electromagnetic “waves”

25 Electromagnetic spectrum

26 Figure 6-11 The electromagnetic spectrum includes all kinds of waves that travel at the speed of light, including radio, microwave, infrared, visible light, ultraviolet, X-rays, and gamma rays. Note that sound waves, water waves, seismic waves, and other kinds of waves that require matter in order to move travel much slower than light speed.

27 Anatomy of the Electromagnetic Wave Electrical and magnetic fields arranged at right angles to each other Perpendicular to the direction the wave is moving

28 The nature of light  Light is a form of radiant energy given out by the Sun and other light producing bodies in the form of waves.  Light is the one part of a group of the em spectrum that we can see. --Consists of transverse waves, --move up and down as they travel forward

29 Same Speed across the whole em spectrum! Velocity of em waves depends on electrical and magnetic interactions, not on the properties of the wave itself. All em waves move at the speed of light! Wavelength x frequency = 300,000 km/s or 186,000 mi/s

30 The energy of em waves Oscillating comb and glowing embers – p.125-6

31 Light travels in straight lines Light travels at a speed of 186,000 miles/sec (300,000 km/sec) (in 8 minutes, light to travels Sun to Earth) Thus we see things happen at the exact moment they are happening.

32 With regard to light, materials are… Transparent Translucent Opaque

33 Law of Refection:  angle of incidence is equal to the angle of reflection (holds true for all smooth, polished surfaces)

34 The Plane Mirror light striking the mirror passes thru the transparent glass, and then almost all the light is reflected back by the shiny, opaque silver

35 Mirror Convex Concave

36 Refraction of Light & lenses convex lens light rays passing thru a convex lens are bent toward the thicker middle concave lens light rays passing thru a concave lens are bent toward the thicker ends

37 Spectrum of visible light

38

39 Mixing Colors of Light

40 Electromagnetic Spectrum Radio Waves Microwaves Infrared Radiation Visible Light Ultraviolet Radiation X-rays Gamma Rays

41 Study Guide, end of chapter 6 Discussion Questions 1, 2, 3, 4, 6, 8, 9. Problems 1, 5, 6, 7. Chemistry Reading, push on to read chapters 8 & 10.


Download ppt "Waves and Electromagnetic Radiation The Sciences chapter 6."

Similar presentations


Ads by Google