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In 1992,
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a cargo ship carrying bath toys
got caught in a storm.
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Shipping containers washed overboard,
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and the waves swept 28,000 rubber ducks
and other toys into the North Pacific.
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But they didn’t stick together.
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Quite the opposite–
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the ducks have since washed up
all over the world,
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and researchers have used their paths
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to chart a better understanding
of ocean currents.
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Ocean currents are driven
by a range of sources:
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the wind, tides, changes in water density,
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and the rotation of the Earth.
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The topography of the ocean floor
and the shoreline modifies those motions,
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causing currents to speed up,
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slow down, or change direction.
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Ocean currents fall into
two main categories:
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surface currents and deep ocean currents.
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Surface currents control the motion
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of the top 10 percent
of the ocean’s water,
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while deep-ocean currents mobilize
the other 90 percent.
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Though they have different causes,
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surface and deep ocean currents
influence each other
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in an intricate dance that keeps
the entire ocean moving.
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Near the shore,
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surface currents are driven
by both the wind and tides,
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which draw water back and forth
as the water level falls and rises.
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Meanwhile, in the open ocean, wind is the
major force behind surface currents.
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As wind blows over the ocean,
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it drags the top layers
of water along with it.
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That moving water pulls on
the layers underneath,
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and those pull on the ones beneath them.
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In fact, water as deep as 400 meters
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is still affected by the wind
at the ocean’s surface.
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If you zoom out to look at the patterns
of surface currents all over the earth,
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you’ll see that they form
big loops called gyres,
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which travel clockwise
in the northern hemisphere
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and counter-clockwise
in the southern hemisphere.
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That’s because of the way
the Earth’s rotation
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affects the wind patterns that
give rise to these currents.
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If the earth didn’t rotate,
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air and water would simply
move back and forth
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between low pressure at the equator
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and high pressure at the poles.
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But as the earth spins,
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air moving from the equator to the
North Pole is deflected eastward,
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and air moving back down
is deflected westward.
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The mirror image happens
in the southern hemisphere,
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so that the major streams of wind
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form loop-like patterns
around the ocean basins.
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This is called the Coriolis Effect.
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The winds push the ocean beneath
them into the same rotating gyres.
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And because water holds onto heat
more effectively than air,
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these currents help redistribute
warmth around the globe.
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Unlike surface currents,
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deep ocean currents are driven primarily
by changes in the density of seawater.
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As water moves towards the North Pole,
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it gets colder.
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It also has a higher
concentration of salt,
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because the ice crystals that form
trap water while leaving salt behind.
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This cold, salty water is more dense,
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so it sinks,
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and warmer surface water takes its place,
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setting up a vertical current called
thermohaline circulation.
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Thermohaline circulation of deep water
and wind-driven surface currents
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combine to form a winding loop
called the Global Conveyor Belt.
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As water moves from the depths of
the ocean to the surface,
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it carries nutrients that nourish the
microorganisms
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which form the base of many
ocean food chains.
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The global conveyor belt is the
longest current in the world,
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snaking all around the globe.
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But it only moves a few
centimeters per second.
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It could take a drop of water
a thousand years to make the full trip.
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However, rising sea temperatures are
causing the conveyor belt
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to seemingly slow down.
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Models show this causing havoc with
weather systems
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on both sides of the Atlantic,
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and no one knows what would happen if it
continues to slow
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or if it stopped altogether.
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The only way we’ll be able to forecast
correctly and prepare accordingly
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will be to continue to study currents
and the powerful forces that shape them.
closed TED
