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One of the most remarkable aspects
of the human brain
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is its ability to recognize patterns
and describe them.
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Among the hardest patterns
we've tried to understand
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is the concept of
turbulent flow in fluid dynamics.
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The German physicist
Werner Heisenberg said,
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"When I meet God,
I'm going to ask him two questions:
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why relativity and why turbulence?
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I really believe he will have
an answer for the first."
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As difficult as turbulence is
to understand mathematically,
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we can use art to depict the way it looks.
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In June 1889, Vincent van Gogh
painted the view just before sunrise
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from the window of his room
at the Saint-Paul-de-Mausole asylum
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in Saint-Rémy-de-Provence,
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where he'd admitted himself after
mutilating his own ear
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in a psychotic episode.
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In "The Starry Night,"
his circular brushstrokes
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create a night sky filled
with swirling clouds and eddies of stars.
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Van Gogh and other Impressionists
represented light in a different way
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than their predecessors,
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seeming to capture
its motion, for instance,
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across sun-dappled waters,
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or here in star light
that twinkles and melts
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through milky waves of blue night sky.
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The effect is caused by luminance,
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the intensity of the light
in the colors on the canvas.
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The more primitive part
of our visual cortex,
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which sees light contrast
and motion, but not color,
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will blend two differently
colored areas together
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if they have the same luminance.
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But our brains' primate subdivision
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will see the contrasting colors
without blending.
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With these two interpretations
happening at once,
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the light in many Impressionist works
seems to pulse, flicker and radiate oddly.
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That's how this
and other Impressionist works
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use quickly executed
prominent brushstrokes
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to capture something strikingly real
about how light moves.
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60 years later, Russian
mathematician Andrey Kolmogorov
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furthered our mathematical
understanding of turbulence
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when he proposed that energy
in a turbulent fluid at length R
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varies in proportion to
the 5/3rds power of R.
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Experimental measurements show Kolmogorov
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was remarkably close
to the way turbulent flow works,
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although a complete description
of turbulence
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remains one of the unsolved
problems in physics.
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A turbulent flow is self-similar
if there is an energy cascade.
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In other words, big eddies
transfer their energy to smaller eddies,
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which do likewise at other scales.
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Examples of this include
Jupiter's Great Red Spot,
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cloud formations
and interstellar dust particles.
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In 2004, using the Hubble Space Telescope,
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scientists saw the eddies of a distant
cloud of dust and gas around a star,
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and it reminded them
of Van Gogh's "Starry Night."
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This motivated scientists
from Mexico, Spain and England
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to study the luminance
in Van Gogh's paintings in detail.
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They discovered that there is a distinct
pattern of turbulent fluid structures
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close to Kolmogorov's equation
hidden in many of Van Gogh's paintings.
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The researchers digitized the paintings,
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and measured how brightness varies
between any two pixels.
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From the curves measured
for pixel separations,
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they concluded that paintings from
Van Gogh's period of psychotic agitation
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behave remarkably similar
to fluid turbulence.
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His self-portrait with a pipe, from
a calmer period in Van Gogh's life,
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showed no sign of this correspondence.
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And neither did other artists' work
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that seemed equally
turbulent at first glance,
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like Munch's "The Scream."
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While it's too easy to say
Van Gogh's turbulent genius
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enabled him to depict turbulence,
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it's also far too difficult to accurately
express the rousing beauty of the fact
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that in a period of intense suffering,
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Van Gogh was somehow
able to perceive and represent
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one of the most supremely
difficult concepts
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nature has ever brought before mankind,
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and to unite his unique mind's eye
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with the deepest mysteries
of movement, fluid and light.
closed TED
Krystian Aparta
The English transcript was updated on 3/23/2015.