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Why the Arctic is climate change's canary in the coal mine - William Chapman

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    The area surrounding the North Pole
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    may seem like a frozen and desolate
    environment where nothing ever changes.
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    But it is actually a complex
    and finely balanced natural system,
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    and its extreme location
    makes it vulnerable to feedback processes
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    that can magnify even tiny changes
    in the atmosphere.
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    In fact, scientists often describe
    the Arctic as the canary in the coal mine
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    when it comes to predicting the impact
    of climate change.
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    One major type of climate feedback
    involves reflectivity.
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    White surfaces, like snow and ice,
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    are very effective at reflecting
    the sun's energy back into space,
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    while darker land and water surfaces
    absorb much more incoming sunlight.
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    When the Arctic warms just a little,
    some of the snow and ice melts,
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    exposing the ground and ocean underneath.
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    The increased heat absorbed by
    these surfaces causes even more melting,
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    and so on.
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    And although the current situation
    in the Arctic follows the warming pattern,
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    the opposite is also possible.
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    A small drop in temperatures
    would cause more freezing,
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    increasing the amount
    of reflective snow and ice.
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    This would result in less sunlight
    being absorbed,
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    and lead to a cycle of cooling,
    as in previous ice ages.
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    Arctic sea ice is also responsible
    for another feedback mechanism
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    through insulation.
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    By forming a layer on the ocean's surface,
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    the ice acts as a buffer between
    the frigid arctic air
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    and the relatively
    warmer water underneath.
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    But when it thins, breaks,
    or melts in any spot,
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    heat escapes from the ocean,
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    warming the atmosphere
    and causing more ice to melt in turn.
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    Both of these are examples
    of positive feedback loops,
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    not because they do something good,
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    but because the initial change
    is amplified in the same direction.
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    A negative feedback loop,
    on the other hand,
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    is when the initial change
    leads to effects
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    that work in the opposite direction.
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    Melting ice also causes
    a type of negative feedback
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    by releasing moisture into the atmosphere.
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    This increases the amount and thickness
    of clouds present,
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    which can cool the atmosphere
    by blocking more sunlight.
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    But this negative feedback loop
    is short-lived,
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    due to the brief Arctic summers.
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    For the rest of the year,
    when sunlight is scarce,
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    the increased moisture and clouds
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    actually warm the surface
    by trapping the Earth's heat,
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    turning the feedback loop positive
    for all but a couple of months.
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    While negative feedback loops
    encourage stability
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    by pushing a system towards equilibrium,
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    positive feedback loops destabilize it
    by enabling larger and larger deviations.
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    And the recently increased impact
    of positive feedbacks
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    may have consequences
    far beyond the Arctic.
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    On a warming planet,
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    these feedbacks ensure that the North Pole
    warms at a faster rate than the equator.
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    The reduced temperature differences
    between the two regions
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    may lead to slower jet stream winds
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    and less linear atmospheric circulation
    in the middle latitudes,
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    where most of the world's
    population lives.
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    Many scientists are concerned
    that shifts in weather patterns
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    will last longer and be more extreme,
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    with short term fluctuations becoming
    persistent cold snaps,
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    heat waves, droughts and floods.
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    So the Arctic sensitivity doesn't just
    serve as an early warning alarm
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    for climate change
    for the rest of the planet.
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    Its feedback loops can affect us
    in much more direct and immediate ways.
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    As climate scientists often warn,
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    what happens in the Arctic
    doesn't always stay in the Arctic.
Title:
Why the Arctic is climate change's canary in the coal mine - William Chapman
Description:

View full lesson: http://ed.ted.com/lessons/why-the-arctic-is-climate-change-s-canary-in-the-coal-mine-william-chapman

The Arctic may seem like a frozen and desolate environment where nothing ever changes. But the climate of this unique and remote region can be both an early indicator of the climate of the rest of the Earth and a driver for weather patterns across the globe. William Chapman explains why scientists often describe the Arctic as the “canary in the coal mine” when it comes to climate change.

Lesson by William Chapman, animation by Sandro Katamashvili.
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Video Language:
English
Team:
closed TED
Project:
TED-Ed
Duration:
03:59

English subtitles

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