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The Nature of Light

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Title: The Nature of Light


1
The Nature of Light
Chapter 22
Preview
Section 1 What Is Light? Section 2 The
Electromagnetic Spectrum Section 3 Interactions
of Light Waves Section 4 Light and Color
Concept Mapping
2
Section 1 What Is Light?
Chapter 22
Bellringer
What do you think light is? Is light made of
matter? Can light travel through space? Explain
your answers in your science journal.
3
Section 1 What Is Light?
Chapter 22
Objectives
  • Describe light as an electromagnetic wave.
  • Calculate distances traveled by light by using
    the speed of light.
  • Explain why light from the sun is important.

4
Section 1 What Is Light?
Chapter 22
Light An Electromagnetic Wave
  • Light is a type of energy that travels as a
    wave. But unlike most other types of waves, light
    does not require matter through which to travel.
  • Light is an electromagnetic wave (EM wave).
  • An electromagnetic wave is a wave that consists
    of electric and magnetic fields that vibrate at
    right angles to each other.

5
Section 1 What Is Light?
Chapter 22
6
Section 1 What Is Light?
Chapter 22
Light An Electromagnetic Wave, continued
  • Electric and Magnetic Fields An electric field
    surrounds every charged object. You see the
    effect of electric fields whenever you see
    objects stuck together by static electricity.
  • A magnetic field surrounds every magnet. Because
    of magnetic fields, paper clips and iron filings
    are pulled toward magnets.

7
Section 1 What Is Light?
Chapter 22
Light An Electromagnetic Wave, continued
  • How EM Waves Are Produced An EM wave can be
    produced by the vibration of an electrically
    charged particle.
  • This vibration makes electric and magnetic
    fields vibrate also. Together, the vibrating
    fields are an EM wave that carries energy.
  • The transfer of energy as electromagnetic waves
    is called radiation.

8
Section 1 What Is Light?
Chapter 22
The Speed of Light
  • Scientists have yet to discover anything that
    travels faster than light.
  • In the near vacuum of space, the speed of light
    is about 300,000 km/s. Light travels slightly
    slower in air, glass, and other types of matter.

9
Section 1 What Is Light?
Chapter 22
10
Section 1 What Is Light?
Chapter 22
Light from the Sun
  • EM waves from the sun are the major source of
    energy on Earth. For example, plants use
    photosynthesis to store energy from the sun.
  • Animals use and store energy by eating plants or
    by eating other animals that eat plants.

11
Section 1 What Is Light?
Chapter 22
Light from the Sun, continued
  • Even fossil fuels store energy from the sun.
    Fossil fuels are formed from the remains of
    plants and animals that lived millions of years
    ago.
  • Only a very small part of the total energy given
    off by the sun reaches Earth. The sun gives off
    energy as EM waves in all directions. Most of
    this energy travels away in space.

12
Chapter 22
Section 2 The Electromagnetic Spectrum
Bellringer
Describe the weather conditions necessary to see
a rainbow. Why do rainbows form? Write your
answers in your science journal.
13
Chapter 22
Section 2 The Electromagnetic Spectrum
Objectives
  • Identify how electromagnetic waves differ from
    each other.
  • Describe some uses for radio waves and
    microwaves.
  • List examples of how infrared waves and visible
    light are important in your life.
  • Explain how ultraviolet light, X rays, and gamma
    rays can be both helpful and harmful.

14
Chapter 22
Section 2 The Electromagnetic Spectrum
Characteristics of EM Waves
  • The light that you can see is called visible
    light. However, there is light that you cant
    see.
  • The light that you can see and light that you
    cannot are both kinds of electromagnetic (EM)
    waves. Other kinds of EM waves include X rays,
    radio waves, and microwaves.
  • All EM waves travel at 300,000 km/s in a vacuum.

15
Chapter 22
Section 2 The Electromagnetic Spectrum
Characteristics of EM Waves, continued
  • The entire range of EM waves is called the
    electromagnetic spectrum. The electromagnetic
    spectrum is divided into regions according to the
    length of the waves.
  • The electromagnetic spectrum is shown on the
    next slide.

16
Chapter 22
Section 2 The Electromagnetic Spectrum
17
Chapter 22
Section 2 The Electromagnetic Spectrum
Radio Waves
  • Radio waves cover a wide range of waves in the
    EM spectrum. Radio waves have some of the longest
    wavelengths and the lowest frequencies of all EM
    waves.
  • Radio waves are any EM waves that have
    wavelengths longer than 30 cm. Radio waves are
    used for broadcasting radio signals.

18
Chapter 22
Section 2 The Electromagnetic Spectrum
Radio Waves, continued
  • Broadcasting Radio Signals Radio stations can
    encode sound information into radio waves by
    varying either the waves amplitude or frequency.
  • Changing amplitude or frequency of a wave is
    called modulation. AM stands for amplitude
    modulation, and FM stands for frequency
    modulation.

19
Chapter 22
Section 2 The Electromagnetic Spectrum
Radio Waves, continued
  • Comparing AM and FM Radio Waves AM radio waves
    have longer wavelengths than FM radio waves. AM
    radio waves can bounce off the atmosphere and
    thus can travel farther than FM radio waves.
  • But FM radio waves are less affected by
    electrical noise than AM radio waves, so music
    broadcast from FM sounds better than music from
    AM stations.

20
Chapter 22
Section 2 The Electromagnetic Spectrum
Radio Waves, continued
  • Radio Waves and Television TV signals are also
    carried by radio waves. Most TV stations
    broadcast radio waves that have shorter
    wavelengths and higher frequencies than those
    from radio stations.
  • Some waves carrying TV signals are transmitted
    to artificial satellites orbiting Earth. The
    waves are amplified and sent to ground antennas.
    They the signals travel through cables to TVs in
    homes.

21
Chapter 22
Section 2 The Electromagnetic Spectrum
Microwaves
  • Microwaves have shorter wavelengths and higher
    frequencies than radio waves. Microwaves have
    wavelengths between 1 mm and 30 cm.

22
Chapter 22
Section 2 The Electromagnetic Spectrum
23
Chapter 22
Section 2 The Electromagnetic Spectrum
Microwaves, continued
  • Microwaves and Communication Microwaves are
    used to send information over long distances.
  • Cellular phones send and receive signals using
    microwaves. Signals sent between Earth and
    artificial satellites in space are also carried
    by microwaves.

24
Chapter 22
Section 2 The Electromagnetic Spectrum
Microwaves, continued
  • Radar Microwaves are used in radar. Radar
    (radio detection and ranging) is used to detect
    the speed and location of objects.
  • Radar sends out microwaves that reflect off an
    object and return to the transmitter. The
    reflected waves are used to calculate speed.

25
Chapter 22
Section 2 The Electromagnetic Spectrum
Infrared Waves
  • Infrared waves have shorter wavelengths and
    higher frequencies than microwaves. The
    wavelengths of infrared waves vary between 700
    nanometers (nm) and 1 mm.
  • Almost everything give off infrared waves,
    including the sun, buildings, trees, and your
    body. The amount of infrared waves an object
    emits depends on the objects temperature. Warmer
    objects give off more infrared waves than cooler
    objects.

26
Chapter 22
Section 2 The Electromagnetic Spectrum
Visible Light
  • Visible Light from the Sun Visible light is the
    very narrow range of wavelengths and frequencies
    in the EM spectrum that humans eyes respond to.
    Visible light waves have wavelengths between 400
    nm and 700 nm.
  • The visible light from the sun is white light.
    White light is visible light of all wavelengths
    combined.

27
Chapter 22
Section 2 The Electromagnetic Spectrum
Visible Light, continued
  • Colors of Light Humans see different
    wavelengths of visible light as different colors.
    The longest wave-lengths are seen as red light.
    The shortest wave-lengths are seen as violet
    light.
  • The range of colors is called the visible
    spectrum.

28
Chapter 22
Section 2 The Electromagnetic Spectrum
Ultraviolet Light
  • Ultraviolet light (UV light) is another type of
    EM wave produced by the sun. Ultraviolet waves
    have shorter wavelengths and higher frequencies
    than visible light.
  • The wavelengths of UV light wave vary between 60
    nm and 400 nm.

29
Chapter 22
Section 2 The Electromagnetic Spectrum
Ultraviolet Light, continued
  • Bad Effects Too much UV light can cause
    sunburn. UV light can also cause skin cancer and
    wrinkles, and damage the eyes.
  • Good Effects Ultraviolet waves produced by UV
    lamps are used to kill bacteria on food and
    surgical tools. Small amounts of UV light are
    beneficial to your body, causing skin cells to
    produce vitamin D.

30
Chapter 22
Section 2 The Electromagnetic Spectrum
X Rays and Gamma Rays
  • X Rays have wavelengths between 0.001 nm and 60
    nm. X rays can pass through many materials,
    making them useful in the medical field.
  • However, too much exposure to X rays can damage
    or kill living cells.

31
Chapter 22
Section 2 The Electromagnetic Spectrum
32
Chapter 22
Section 2 The Electromagnetic Spectrum
X Rays and Gamma Rays, continued
  • Gamma Rays have wavelengths shorter than 0.1 nm.
    They can penetrate most materials easily.
  • Gammas rays are used to treat some forms of
    cancer. Doctors focus the rays on tumors inside
    the body to kill the cancer cells.
  • Gamma rays are also used to kill harmful
    bacteria in foods, such as meat and fresh fruits.

33
Section 3 Interactions of Light Waves
Chapter 22
Bellringer
Mirrors are common objects that most people use
every day. From your experience, how do mirrors
work and what do mirrors do to light waves?
Explain your answers in your science journal.
34
Chapter 22
Section 3 Interactions of Light Waves
Objectives
  • Describe how reflection allows you to see
    things.
  • Describe absorption and scattering.
  • Explain how refraction can create optical
    illusions and separate white light into colors.

35
Chapter 22
Section 3 Interactions of Light Waves
Objectives, continued
  • Explain the relationship between diffraction and
    wavelength.
  • Compare constructive and destructive
    interference of light.

36
Chapter 22
Section 3 Interactions of Light Waves
Reflection
  • Reflection happens when light waves bounce off
    an object. Light reflects off objects all around
    you.
  • The Law of Reflection states that the angle of
    incidence is equal to the angle of reflection.
  • This law is explained on the next slide.

37
Chapter 22
Section 3 Interactions of Light Waves
Law of Reflection
Click below to watch the Visual Concept.
Visual Concept
38
Chapter 22
Section 3 Interactions of Light Waves
Reflection, continued
  • Types of Reflection You see your image in a
    mirror because of regular reflection.
  • Regular reflection happens when light reflects
    off a very smooth surface. All the light beams
    bouncing off a smooth surface are reflected at
    the same angle.

39
Chapter 22
Section 3 Interactions of Light Waves
Reflection, continued
  • You cannot see your image in a wall because of
    diffuse reflection.
  • Diffuse reflection happens when light reflects
    off a rough surface, such as a wall. Light beams
    that hit a rough surface reflect at many
    different angles.

40
Section 3 Interactions of Light Waves
Chapter 22
41
Chapter 22
Section 3 Interactions of Light Waves
Reflection, continued
  • Light Source or Reflection? The tail of a
    firefly, flames, light bulbs, and the sun are
    light sources. You can see a light source in the
    dark because its light passes directly into your
    eyes.
  • Most things around you are not light sources.
    But you can see them because light from light
    sources reflects off the objects and the travels
    to your eyes.

42
Chapter 22
Section 3 Interactions of Light Waves
Absorption and Scattering
  • Absorption of Light The transfer of energy
    carried by light waves is called absorption.
  • When a beam of light shines through the air,
    particles in the air absorb some of the lights
    energy. As a result, the beam of light becomes
    dim.

43
Chapter 22
Section 3 Interactions of Light Waves
Absorption and Scattering, continued
  • Scattering of Light An interaction of light
    with matter that causes light to change direction
    is scattering. Light scatters in all directions
    after colliding with particles of matter.
  • Light can be scattered out of a beam by air
    particles. This scattered light allows you to see
    things outside of the beam. But, the beam becomes
    dimmer because light is scattered out of it.

44
Chapter 22
Section 3 Interactions of Light Waves
Refraction
  • Refraction is the bending of a wave as it passes
    at an angle from one material to another.
  • Refraction of light waves occurs because the
    speed of light varies depending on the material
    through which the waves are traveling.
  • When a wave enters a new material at an angle,
    the part of the wave that enters first begins
    traveling at a different speed from that of the
    rest of the wave.

45
Chapter 22
Section 3 Interactions of Light Waves
Refraction, continued
  • Refraction and Lenses A lens is a transparent
    object that refracts light to form an image.
  • Convex lenses are thicker in the middle than at
    the edges. When light beams pass through a convex
    lens, the beams are refracted toward each other.
  • Concave lenses are thinner in the middle than at
    the edges. When light beams pass through a
    concave lens, the beams are refracted away from
    each other.

46
Chapter 22
Section 3 Interactions of Light Waves
Refraction, continued
  • Refraction and Optical Illusions Your brain
    always interprets light as traveling in straight
    lines.
  • But when you look an an object that is
    underwater, the light reflecting off the object
    does not travel in a straight line. Instead, it
    refracts.

47
Chapter 22
Section 3 Interactions of Light Waves
Refraction, continued
  • Because of refraction, the cat and the fish see
    optical illusions.

48
Chapter 22
Section 3 Interactions of Light Waves
Refraction, continued
  • Refraction and Color Separation White light is
    composed of all the wavelengths of visible light.
    The different wavelengths of visible light are
    seen by humans as different colors.
  • When white light is refracted, the amount that
    the light bends depends on its wavelength.

49
Chapter 22
Section 3 Interactions of Light Waves
Refraction, continued
  • Waves with short wavelengths bend more than
    waves with long wavelengths.
  • White light can be separated into different
    colors during refraction, as shown below.

50
Chapter 22
Section 3 Interactions of Light Waves
Diffraction
  • Diffraction is the bending of waves around
    barriers or through openings.
  • The amount a wave diffracts depends on its
    wavelength and the size of the barrier or
    opening.
  • The greatest amount of diffraction occurs when
    the barrier or opening is the same size or
    smaller than the wavelength.

51
Chapter 22
Section 3 Interactions of Light Waves
Diffraction, continued
  • Diffraction and Wavelength The wavelength of
    visible light is very small.
  • So, a visible light wave cannot diffract very
    much unless it passes through a narrow opening,
    around sharp edges, or around a small barrier.

52
Chapter 22
Section 3 Interactions of Light Waves
Interference
  • Interference is a wave interaction that happens
    when two or more waves overlap.
  • Constructive Interference happens when waves
    combine to form a wave that has a greater
    amplitude than the original waves had.
  • Destructive Interference happens when waves
    combine to form a wave that has a smaller
    amplitude than the original waves had.

53
Chapter 22
Section 3 Interactions of Light Waves
Interference, continued
  • The image below shows what happens when light
    combines by interference.

54
Section 4 Light and Color
Chapter 22
Bellringer
What is your favorite color? In a short
paragraph, explain why you like your favorite
color. Also, explain how certain colors affect
your mood. Write your paragraph in your science
journal.
55
Section 4 Light and Color
Chapter 22
Objectives
  • Name and describe three ways light interacts
    with matter.
  • Explain how the color of an object is
    determined.
  • Explain why mixing colors of light is called
    color addition.
  • Describe why mixing colors of pigment is called
    color subtraction.

56
Section 4 Light and Color
Chapter 22
Light and Matter
  • When light strikes any form of matter, it can be
    reflected, absorbed, or transmitted.
  • Reflection happens when light bounces off an
    object.
  • Absorption is the transfer of light energy to
    matter.
  • Transmission is the passing of light through
    matter.

57
Section 4 Light and Color
Chapter 22
Light and Matter, continued
  • The image at right explains transmission,
    reflection, and absorption.

58
Section 4 Light and Color
Chapter 22
Light and Matter, continued
  • Transparent matter is matter though which light
    is easily transmitted. Glass is transparent.
  • Translucent matter transmits light but also
    scatters it. Frosted windows are translucent.
  • Opaque matter does not transmit any light.
    Computers and books are opaque.

59
Section 4 Light and Color
Chapter 22
Light and Matter, continued
  • The images below explain the difference between
    the terms transparent, translucent, and opaque.

60
Section 4 Light and Color
Chapter 22
Colors of Objects
  • Humans see different wavelengths of light as
    different colors.
  • The color that an object appears to be is
    determined by the wavelengths of light that reach
    your eyes.
  • Light reaches your eyes after being reflected
    off an object or after being transmitted through
    an object.

61
Section 4 Light and Color
Chapter 22
Colors of Objects, continued
  • Colors of Opaque Objects When white light
    strikes a colored opaque object, some colors of
    light are absorbed, and some are reflected.
  • Only the light that is reflected reaches your
    eyes and is detected. So, the colors of light
    that are reflected by an opaque object determine
    the color you see.

62
Section 4 Light and Color
Chapter 22
Colors of Objects, continued
  • Colors of Transparent and Translucent Objects
    Ordinary window glass is colorless in white light
    because it transmits all the colors of light that
    strike it. But some transparent objects are
    colored.
  • When you look through colored transparent or
    translucent objects, you see the color of light
    that was transmitted through the material.

63
Section 4 Light and Color
Chapter 22
Mixing Colors of Light
  • Red, blue, and green are the primary colors of
    light. These three colors can be combined in
    different ratios to produce white light and many
    colors of light.
  • Color Addition is combining colors of light.
  • Light and Color Television The colors on a
    color TV are produced by color addition of the
    primary colors of light.

64
Section 4 Light and Color
Chapter 22
Mixing Colors of Pigment
  • Pigments and Color A material that gives a
    substance its color by absorbing some colors of
    light and reflecting others is a pigment.
  • Color Subtraction When you mix pigments
    together, more colors of light are absorbed or
    taken away. So, mixing pigments is called color
    subtraction.
  • Yellow, cyan, and magenta are the primary
    pigments.

65
Section 4 Light and Color
Chapter 22
66
The Nature of Light
Chapter 22
Concept Mapping
Use the terms below to complete the Concept
Mapping on the next slide.
magnetic fields electromagnetic wave reflection electric fields light absorption transmission

67
The Nature of Light
Chapter 22
68
The Nature of Light
Chapter 22
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