< Return to Video

How epic solar winds make brilliant polar lights - Michael Molina

  • 0:15 - 0:17
    Every second,
  • 0:17 - 0:20
    one million tons of matter is blasted from the Sun
  • 0:20 - 0:24
    at the velocity of one million miles per hour,
  • 0:24 - 0:26
    and it's on a collision course
  • 0:26 - 0:27
    with Earth!
  • 0:27 - 0:29
    But don't worry,
  • 0:29 - 0:32
    this is the opening of a new Michael Bay movie.
  • 0:32 - 0:37
    This is "The Journey of the Polar Lights".
  • 0:37 - 0:38
    The Northern and Southern Lights,
  • 0:38 - 0:40
    also known as the Aurora Borealis
  • 0:40 - 0:42
    and Aurora Australis respectively,
  • 0:42 - 0:44
    occur when high energy particles from the Sun
  • 0:44 - 0:46
    collide with neutral atoms in our atmosphere.
  • 0:46 - 0:48
    The energy emitted from this crash
  • 0:48 - 0:50
    produces a spectacle of light
  • 0:50 - 0:52
    that mankind has marveled at for centuries.
  • 0:52 - 0:54
    But, the particles journey isn't just as simple
  • 0:54 - 0:56
    as leaving the Sun and arriving at Earth.
  • 0:56 - 0:58
    Like any cross-country road trip,
  • 0:58 - 0:59
    there's a big detour
  • 0:59 - 1:02
    and nobody asks for directions.
  • 1:02 - 1:03
    Let's track this intergalactic voyage
  • 1:03 - 1:06
    by focusing on three main points of their journey:
  • 1:06 - 1:07
    leaving the sun,
  • 1:07 - 1:09
    making a pit stop in the Earth's magnetic fields,
  • 1:09 - 1:12
    and arriving at the atmosphere above our heads.
  • 1:13 - 1:15
    The protons and electrons creating the Northern Lights
  • 1:15 - 1:17
    depart from the Sun's corona.
  • 1:17 - 1:18
    The corona is the outermost layer
  • 1:18 - 1:19
    of the Sun's atmosphere
  • 1:19 - 1:21
    and is one of the hottest regions.
  • 1:21 - 1:24
    Its intense heat causes the Sun's hydrogen
  • 1:24 - 1:25
    and helium atoms to vibrate
  • 1:25 - 1:27
    and shake off protons and electrons
  • 1:27 - 1:31
    as if they were stripping off layers on a hot, sunny day.
  • 1:31 - 1:33
    Impatient and finally behind the wheel,
  • 1:33 - 1:36
    these free protons and electrons move too fast
  • 1:36 - 1:38
    to be contained by the sun's gravity
  • 1:38 - 1:40
    and group together as plasma,
  • 1:40 - 1:42
    an electrically charged gas.
  • 1:42 - 1:43
    They travel away from the sun
  • 1:43 - 1:44
    as a constant gale of plasma,
  • 1:44 - 1:47
    known as the solar wind.
  • 1:55 - 1:58
    However, the Earth prevents the solar wind
  • 1:58 - 1:59
    from travelling straight into the planet
  • 1:59 - 2:00
    by setting up a detour,
  • 2:00 - 2:02
    the magnetosphere.
  • 2:02 - 2:03
    The magnetosphere is formed
  • 2:03 - 2:04
    by the Earth's magnetic currents
  • 2:04 - 2:06
    and shields our planet from the solar winds
  • 2:06 - 2:08
    by sending out the particles around the Earth.
  • 2:08 - 2:10
    Their opportunity to continue the journey
  • 2:10 - 2:11
    down to the atmosphere
  • 2:11 - 2:12
    comes when the magnetosphere is overwhelmed
  • 2:12 - 2:14
    by a new wave of travellers.
  • 2:14 - 2:17
    This events is coronal mass ejection
  • 2:17 - 2:18
    and it occurs when the Sun shoots out
  • 2:18 - 2:21
    a massive ball of plasma into the solar wind.
  • 2:22 - 2:23
    When one of these coronal mass ejections
  • 2:23 - 2:25
    collides with Earth,
  • 2:25 - 2:26
    it overpowers the magnetosphere
  • 2:26 - 2:28
    and creates a magnetic storm.
  • 2:28 - 2:30
    The heavy storm stresses the magnetosphere
  • 2:30 - 2:31
    until it suddenly snaps back,
  • 2:31 - 2:34
    like and overstretched elastic band,
  • 2:34 - 2:37
    flinging some of the detoured particles towards Earth.
  • 2:37 - 2:39
    The retracting band of the magnetic field
  • 2:39 - 2:41
    drags them down to the aurora ovals,
  • 2:41 - 2:42
    which are the locations
  • 2:42 - 2:44
    of the Northern and Southern Lights.
  • 2:45 - 2:48
    After travelling 93 million miles across the galaxy,
  • 2:48 - 2:50
    the Sun's particles finally produce
  • 2:50 - 2:52
    their dazzling light show with the help of some friends.
  • 2:52 - 2:55
    Twenty to two hundred miles above the surface,
  • 2:55 - 2:56
    the electrons and protons meet up
  • 2:56 - 2:58
    with oxygen and nitrogen atoms
  • 2:58 - 3:01
    and they sure are happy to see each other.
  • 3:01 - 3:03
    The Sun's particles high-five the atoms,
  • 3:03 - 3:04
    giving their energy
  • 3:04 - 3:07
    to the Earth's neutral oxygen and nitrogen atoms.
  • 3:07 - 3:08
    When the atoms in the atmosphere
  • 3:08 - 3:09
    are contacted by the particles,
  • 3:09 - 3:12
    they get excited and emit photons.
  • 3:12 - 3:14
    Photons are small bursts of energy
  • 3:14 - 3:15
    in the form of light.
  • 3:15 - 3:16
    The colors that appear in the sky
  • 3:16 - 3:19
    depend on the wavelength of the atom's photon.
  • 3:19 - 3:21
    Excited oxygen atoms are responsible
  • 3:21 - 3:22
    for the green and red colors,
  • 3:22 - 3:24
    where as excited nitrogen atoms produce
  • 3:24 - 3:26
    blue and deep red hues.
  • 3:26 - 3:28
    The collection of these interactions
  • 3:28 - 3:30
    is what creates the Northern and Southern Lights.
  • 3:35 - 3:37
    The polar lights are best seen on clear nights
  • 3:37 - 3:40
    in regions close to magnetic north and south poles.
  • 3:40 - 3:41
    Nighttime is ideal
  • 3:41 - 3:43
    because the Aurora is much dimmer than sunlight
  • 3:43 - 3:46
    and cannot be seen in daytime.
  • 3:46 - 3:47
    Remember to look up to the sky
  • 3:47 - 3:49
    and read up on the Sun's energy patterns,
  • 3:49 - 3:52
    specifically sunspots and solar flares,
  • 3:52 - 3:53
    as these will be good guides
  • 3:53 - 3:55
    for predicting the auroras.
Title:
How epic solar winds make brilliant polar lights - Michael Molina
Description:

View full lesson: http://ed.ted.com/lessons/how-epic-solar-winds-make-brilliant-polar-lights-michael-molina

Why do we see those stunning lights in the northern- and southernmost portions of the night sky? The Aurora Borealis and Aurora Australis occur when high-energy particles are flung from the Sun's corona toward the Earth and mingle with the neutral atoms in our atmosphere -- ultimately emitting extraordinary light and color. Michael Molina explains every step of this dazzling phenomenon.

Lesson by Michael Molina, animation by Franco Barroeta.
more » « less
Video Language:
English
Team:
closed TED
Project:
TED-Ed
Duration:
04:10

English subtitles

Revisions Compare revisions

Our website uses cookies for analysis purposes.