< Return to Video

The unexpected math behind Van Gogh's "Starry Night" - Natalya St. Clair

  • 0:07 - 0:10
    One of the most remarkable aspects
    of the human brain
  • 0:10 - 0:14
    is its ability to recognize patterns
    and describe them.
  • 0:14 - 0:16
    Among the hardest patterns
    we've tried to understand
  • 0:16 - 0:21
    is the concept of
    turbulent flow in fluid dynamics.
  • 0:21 - 0:23
    The German physicist
    Werner Heisenberg said,
  • 0:23 - 0:27
    "When I meet God,
    I'm going to ask him two questions:
  • 0:27 - 0:31
    why relativity and why turbulence?
  • 0:31 - 0:35
    I really believe he will have
    an answer for the first."
  • 0:35 - 0:38
    As difficult as turbulence is
    to understand mathematically,
  • 0:38 - 0:42
    we can use art to depict the way it looks.
  • 0:42 - 0:47
    In June 1889, Vincent van Gogh
    painted the view just before sunrise
  • 0:47 - 0:52
    from the window of his room
    at the Saint-Paul-de-Mausole asylum
  • 0:52 - 0:54
    in Saint-Rémy-de-Provence,
  • 0:54 - 0:57
    where he'd admitted himself after
    mutilating his own ear
  • 0:57 - 0:58
    in a psychotic episode.
  • 0:59 - 1:02
    In "The Starry Night,"
    his circular brushstrokes
  • 1:02 - 1:08
    create a night sky filled
    with swirling clouds and eddies of stars.
  • 1:08 - 1:12
    Van Gogh and other Impressionists
    represented light in a different way
  • 1:12 - 1:13
    than their predecessors,
  • 1:13 - 1:16
    seeming to capture
    its motion, for instance,
  • 1:16 - 1:18
    across sun-dappled waters,
  • 1:18 - 1:22
    or here in star light
    that twinkles and melts
  • 1:22 - 1:24
    through milky waves of blue night sky.
  • 1:25 - 1:27
    The effect is caused by luminance,
  • 1:27 - 1:31
    the intensity of the light
    in the colors on the canvas.
  • 1:31 - 1:34
    The more primitive part
    of our visual cortex,
  • 1:34 - 1:38
    which sees light contrast
    and motion, but not color,
  • 1:38 - 1:41
    will blend two differently
    colored areas together
  • 1:41 - 1:43
    if they have the same luminance.
  • 1:43 - 1:45
    But our brains' primate subdivision
  • 1:45 - 1:48
    will see the contrasting colors
    without blending.
  • 1:49 - 1:51
    With these two interpretations
    happening at once,
  • 1:51 - 1:57
    the light in many Impressionist works
    seems to pulse, flicker and radiate oddly.
  • 1:58 - 2:00
    That's how this
    and other Impressionist works
  • 2:00 - 2:03
    use quickly executed
    prominent brushstrokes
  • 2:03 - 2:07
    to capture something strikingly real
    about how light moves.
  • 2:08 - 2:11
    Sixty years later, Russian
    mathematician Andrey Kolmogorov
  • 2:11 - 2:14
    furthered our mathematical
    understanding of turbulence
  • 2:14 - 2:18
    when he proposed that energy
    in a turbulent fluid at length R
  • 2:18 - 2:22
    varies in proportion to
    the 5/3rds power of R.
  • 2:22 - 2:24
    Experimental measurements show Kolmogorov
  • 2:24 - 2:28
    was remarkably close
    to the way turbulent flow works,
  • 2:28 - 2:30
    although a complete description
    of turbulence
  • 2:30 - 2:33
    remains one of the unsolved
    problems in physics.
  • 2:33 - 2:37
    A turbulent flow is self-similar
    if there is an energy cascade.
  • 2:38 - 2:41
    In other words, big eddies
    transfer their energy to smaller eddies,
  • 2:41 - 2:43
    which do likewise at other scales.
  • 2:44 - 2:47
    Examples of this include
    Jupiter's Great Red Spot,
  • 2:47 - 2:51
    cloud formations
    and interstellar dust particles.
  • 2:52 - 2:55
    In 2004, using the Hubble Space Telescope,
  • 2:55 - 3:00
    scientists saw the eddies of a distant
    cloud of dust and gas around a star,
  • 3:00 - 3:03
    and it reminded them
    of Van Gogh's "Starry Night."
  • 3:04 - 3:07
    This motivated scientists
    from Mexico, Spain and England
  • 3:07 - 3:11
    to study the luminance
    in Van Gogh's paintings in detail.
  • 3:11 - 3:16
    They discovered that there is a distinct
    pattern of turbulent fluid structures
  • 3:16 - 3:20
    close to Kolmogorov's equation
    hidden in many of Van Gogh's paintings.
  • 3:21 - 3:23
    The researchers digitized the paintings,
  • 3:23 - 3:27
    and measured how brightness varies
    between any two pixels.
  • 3:27 - 3:30
    From the curves measured
    for pixel separations,
  • 3:30 - 3:34
    they concluded that paintings from
    Van Gogh's period of psychotic agitation
  • 3:34 - 3:37
    behave remarkably similar
    to fluid turbulence.
  • 3:38 - 3:42
    His self-portrait with a pipe, from
    a calmer period in Van Gogh's life,
  • 3:42 - 3:44
    showed no sign of this correspondence.
  • 3:44 - 3:47
    And neither did other artists' work
  • 3:47 - 3:49
    that seemed equally
    turbulent at first glance,
  • 3:49 - 3:51
    like Munch's "The Scream."
  • 3:51 - 3:55
    While it's too easy to say
    Van Gogh's turbulent genius
  • 3:55 - 3:57
    enabled him to depict turbulence,
  • 3:57 - 4:02
    it's also far too difficult to accurately
    express the rousing beauty of the fact
  • 4:02 - 4:04
    that in a period of intense suffering,
  • 4:04 - 4:08
    Van Gogh was somehow
    able to perceive and represent
  • 4:08 - 4:10
    one of the most supremely
    difficult concepts
  • 4:10 - 4:14
    nature has ever brought before mankind,
  • 4:14 - 4:16
    and to unite his unique mind's eye
  • 4:16 - 4:20
    with the deepest mysteries
    of movement, fluid and light.
Title:
The unexpected math behind Van Gogh's "Starry Night" - Natalya St. Clair
Speaker:
Natalya St. Clair
Description:

View full lesson: http://ed.ted.com/lessons/the-unexpected-math-behind-van-gogh-s-starry-night-natalya-st-clair

Physicist Werner Heisenberg said, “When I meet God, I am going to ask him two questions: why relativity? And why turbulence? I really believe he will have an answer for the first.” As difficult as turbulence is to understand mathematically, we can use art to depict the way it looks. Natalya St. Clair illustrates how Van Gogh captured this deep mystery of movement, fluid and light in his work.

Lesson by Natalya St. Clair, animation by Avi Ofer.
more » « less
Video Language:
English
Team:
closed TED
Project:
TED-Ed
Duration:
04:39

English subtitles

Revisions Compare revisions

Our website uses cookies for analysis purposes.