Return to Video

Light waves, visible and invisible - Lucianne Walkowicz

  • 0:07 - 0:10
    What if you could only see one color?
  • 0:10 - 0:12
    Imagine, for instance,
  • 0:12 - 0:14
    that you could only see things that were red
  • 0:14 - 0:15
    and that everything else
  • 0:15 - 0:17
    was completely invisible to you.
  • 0:17 - 0:18
    As it turns out,
  • 0:18 - 0:20
    that's how you live your life all the time
  • 0:20 - 0:22
    because your eyes can only see
  • 0:22 - 0:25
    a minuscule part of the full spectrum of light.
  • 0:25 - 0:28
    Different kinds of light are all around you everyday
  • 0:28 - 0:30
    but are invisible to the human eye,
  • 0:30 - 0:33
    from the radio waves that carry your favorite songs,
  • 0:33 - 0:35
    to the x-rays doctors use to see inside of you,
  • 0:35 - 0:38
    to the microwaves that heat up your food.
  • 0:39 - 0:40
    In order to understand
  • 0:40 - 0:41
    how these can all be light,
  • 0:41 - 0:43
    we'll need to know a thing or two
  • 0:43 - 0:44
    about what light is.
  • 0:44 - 0:47
    Light is electromagnetic radiation
  • 0:47 - 0:49
    that acts like both a wave and a particle.
  • 0:49 - 0:52
    Light waves are kind of like waves on the ocean.
  • 0:52 - 0:54
    There are big waves and small waves,
  • 0:54 - 0:56
    waves that crash on the shore
  • 0:56 - 0:57
    one right after the other,
  • 0:57 - 1:00
    and waves that only roll in every so often.
  • 1:00 - 1:03
    The size of a wave is called its wavelength,
  • 1:03 - 1:04
    and how often it comes by
  • 1:04 - 1:06
    is called its frequency.
  • 1:07 - 1:09
    Imagine being a boat in that ocean,
  • 1:09 - 1:11
    bobbing up and down as the waves go by.
  • 1:11 - 1:14
    If the waves that day have long wavelengths,
  • 1:14 - 1:16
    they'll make you bob only so often,
  • 1:16 - 1:18
    or at a low frequency.
  • 1:18 - 1:20
    If the waves, instead, have short wavelengths,
  • 1:20 - 1:21
    they'll be close together,
  • 1:21 - 1:24
    and you'll bob up and down much more often,
  • 1:24 - 1:25
    at a high frequency.
  • 1:25 - 1:28
    Different kinds of light are all waves,
  • 1:28 - 1:30
    they just have different wavelengths and frequencies.
  • 1:31 - 1:33
    If you know the wavelength or frequency
  • 1:33 - 1:34
    of a wave of light,
  • 1:34 - 1:37
    you can also figure out its energy.
  • 1:37 - 1:39
    Long wavelengths have low energies,
  • 1:39 - 1:41
    while short wavelengths have high energies.
  • 1:41 - 1:43
    It's easy to remember
  • 1:43 - 1:45
    if you think about being in that boat.
  • 1:45 - 1:46
    If you were out sailing on a day
  • 1:46 - 1:48
    with short, choppy waves,
  • 1:48 - 1:50
    you'd probably be pretty high energy yourself,
  • 1:50 - 1:54
    running around to keep things from falling over.
  • 1:54 - 1:55
    But on a long wavelength sea,
  • 1:55 - 1:57
    you'd be rolling along, relaxed,
  • 1:57 - 1:58
    low energy.
  • 1:59 - 2:01
    The energy of light tells us
  • 2:01 - 2:03
    how it will interact with matter,
  • 2:03 - 2:05
    for example, the cells of our eyes.
  • 2:05 - 2:08
    When we see, it's because the energy of light
  • 2:08 - 2:10
    stimulates a receptor in our eye
  • 2:10 - 2:11
    called the retina.
  • 2:11 - 2:13
    Our retina are only sensitive to light
  • 2:13 - 2:15
    with a very small range in energy,
  • 2:15 - 2:18
    and so we call that range of light visible light.
  • 2:18 - 2:21
    Inside our retina are special receptors
  • 2:21 - 2:23
    called rods and cones.
  • 2:23 - 2:25
    The rods measure brightness,
  • 2:25 - 2:27
    so we know how much light there is.
  • 2:27 - 2:30
    The cones are in charge of what color of light we see
  • 2:30 - 2:31
    because different cones are sensitive
  • 2:31 - 2:33
    to different energies of light.
  • 2:33 - 2:35
    Some cones are more excited by light
  • 2:35 - 2:38
    that is long wavelength and low energy,
  • 2:38 - 2:40
    and other cones are more excited
  • 2:40 - 2:43
    by short wavelength, high-energy light.
  • 2:43 - 2:44
    When light hits our eye,
  • 2:44 - 2:46
    the relative amount of energy each cone measures
  • 2:46 - 2:49
    signals our brain to perceive colors.
  • 2:49 - 2:50
    The rainbow we perceive
  • 2:50 - 2:54
    is actually visible light in order of its energy.
  • 2:54 - 2:55
    At one side of the rainbow
  • 2:55 - 2:57
    is low-energy light we see as red,
  • 2:57 - 3:00
    and at the other side is high-energy light
  • 3:00 - 3:02
    we see as blue.
  • 3:02 - 3:03
    If light shines on us
  • 3:03 - 3:05
    that has an energy our retina can't measure,
  • 3:05 - 3:07
    we won't be able to see it.
  • 3:08 - 3:10
    Light that is too short wavelength or high energy
  • 3:10 - 3:12
    gets absorbed by the eye's surface
  • 3:12 - 3:14
    before it can even get to the retina,
  • 3:14 - 3:17
    and light that is too long wavelength
  • 3:17 - 3:17
    doesn't have enough energy
  • 3:17 - 3:20
    to stimulate our retina at all.
  • 3:20 - 3:22
    The only thing that makes one kind of light
  • 3:22 - 3:24
    different from another is its wavelength.
  • 3:24 - 3:26
    Radio waves have long wavelengths,
  • 3:26 - 3:29
    while x-rays have short wavelengths.
  • 3:29 - 3:31
    And visible light, the kind you can actually see,
  • 3:31 - 3:33
    is somewhere in between.
  • 3:33 - 3:35
    Even though our eyes can't detect light
  • 3:35 - 3:37
    outside of the visible range,
  • 3:37 - 3:39
    we can build special detectors
  • 3:39 - 3:40
    that are stimulated
  • 3:40 - 3:42
    by these other wavelengths of light,
  • 3:42 - 3:43
    kind of like digital eyes.
  • 3:43 - 3:45
    With these devices,
  • 3:45 - 3:46
    we can measure the light that is there,
  • 3:46 - 3:49
    even though we can't see it ourselves.
  • 3:50 - 3:52
    So, take a step back and think about
  • 3:52 - 3:54
    all of this for a moment.
  • 3:54 - 3:55
    Even though they seem different,
  • 3:55 - 3:57
    the warmth you feel from a crackling fire
  • 3:57 - 3:59
    is the same as the sun shining on you
  • 3:59 - 4:00
    on a beautiful day,
  • 4:00 - 4:02
    the same as ultraviolet light
  • 4:02 - 4:04
    you put on sunscreen to protect yourself from,
  • 4:04 - 4:06
    the same thing as your TV,
  • 4:06 - 4:07
    your radio,
  • 4:07 - 4:08
    and your microwave.
  • 4:09 - 4:11
    Now, those examples are all things here on Earth,
  • 4:11 - 4:14
    things you experience in your everyday life,
  • 4:14 - 4:17
    but here's something even more amazing.
  • 4:17 - 4:20
    Our universe gives off the full spectrum of light, too.
  • 4:21 - 4:22
    When you think of the night sky,
  • 4:22 - 4:24
    you probably think of being able
  • 4:24 - 4:27
    to see the stars shining with your own eyes,
  • 4:27 - 4:28
    but that's just visible light,
  • 4:28 - 4:30
    which you now know is only a tiny part
  • 4:30 - 4:32
    of the full spectrum.
  • 4:32 - 4:33
    If we had to draw the universe
  • 4:33 - 4:36
    and could only use visible light,
  • 4:36 - 4:37
    it would be like having only one crayon --
  • 4:37 - 4:39
    pretty sad.
  • 4:39 - 4:42
    To see the universe in its full spectrum,
  • 4:42 - 4:43
    we need to have the right eyes,
  • 4:43 - 4:45
    and that means using special telescopes
  • 4:45 - 4:48
    that can help us see beyond visible light.
  • 4:48 - 4:50
    You've probably heard of the Hubble Space Telescope
  • 4:50 - 4:52
    and seen its beautiful pictures
  • 4:52 - 4:55
    taken in visible and ultraviolet light.
  • 4:55 - 4:56
    But you might not know
  • 4:56 - 4:58
    that there are 20 space telescopes in orbit,
  • 4:58 - 5:00
    missions that can each see part
  • 5:00 - 5:02
    of the full spectrum of light.
  • 5:02 - 5:05
    With telescopes acting as our virtual eyes,
  • 5:05 - 5:07
    both in space and here on Earth,
  • 5:07 - 5:09
    we can see some amazing things.
  • 5:09 - 5:11
    And the coolest thing of all,
  • 5:11 - 5:13
    no matter the wavelength or energy,
  • 5:13 - 5:16
    the light that we see out in the distant universe
  • 5:16 - 5:17
    is the same thing as the light
  • 5:17 - 5:20
    that we can experience and study here on Earth.
  • 5:20 - 5:21
    So, since we know the physics
  • 5:21 - 5:22
    of how x-ray,
  • 5:22 - 5:23
    ultraviolet light,
  • 5:23 - 5:25
    or microwaves work here,
  • 5:25 - 5:28
    we can study the light of a distant star or galaxy
  • 5:28 - 5:30
    and know what kinds of things
  • 5:30 - 5:32
    are happening there too.
  • 5:32 - 5:33
    So, as you go about your daily life,
  • 5:33 - 5:36
    think beyond what your eyes can and can't see.
  • 5:36 - 5:38
    Knowing just a little bit about the natural world
  • 5:38 - 5:40
    can help you perceive the full spectrum
  • 5:40 - 5:42
    around you all the time.
Title:
Light waves, visible and invisible - Lucianne Walkowicz
Speaker:
Lucianne Walkowicz
Description:

View full lesson: http://ed.ted.com/lessons/light-waves-visible-and-invisible-lucianne-walkowicz

Each kind of light has a unique wavelength, but human eyes can only perceive a tiny slice of the full spectrum -- the very narrow range from red to violet. Microwaves, radio waves, x-rays and more are hiding, invisible, just beyond our perception. Lucianne Walkowicz shows us the waves we can't see.

Lesson by Lucianne Walkowicz, animation by Pew36 Animation Studios.
more » « less
Video Language:
English
Team:
closed TED
Project:
TED-Ed
Duration:
05:58

English subtitles

Revisions Compare revisions

Our website uses cookies for analysis purposes.