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Why is Mount Everest so tall? - Michele Koppes

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    Every spring,
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    hundreds of adventure-seekers dream
    of climbing Qomolangma,
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    also known as Mount Everest.
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    At base camp, they hunker down for months
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    waiting for the chance to scale
    the mountain's lofty, lethal peak.
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    But why do people risk life and limb
    to climb Everest?
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    Is it the challenge?
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    The view?
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    The chance to touch the sky?
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    For many, the draw is Everest's status
    as the highest mountain on Earth.
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    There's an important distinction
    to make here.
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    Mauna Kea is actually the tallest
    from base to summit,
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    but at 8850 meters above sea level,
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    Everest has the highest altitude
    on the planet.
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    To understand how
    this towering formation was born,
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    we have to peer deep
    into our planet's crust,
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    where continental plates collide.
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    The Earth's surface
    is like an armadillo's armor.
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    Pieces of crust constantly move over,
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    under,
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    and around each other.
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    For such huge continental plates,
    the motion is relatively quick.
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    They move two to four
    centimeters per year,
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    about as fast as fingernails grow.
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    When two plates collide,
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    one pushes into or underneath the other,
    buckling at the margins,
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    and causing what's known as uplift
    to accomodate the extra crust.
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    That's how Everest came about.
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    50 million years ago, the Earth's
    Indian Plate drifted north,
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    bumped into the bigger Eurasian Plate,
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    and the crust crumpled,
    creating huge uplift.
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    Mountain Everest lies at the heart
    of this action,
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    on the edge of the Indian-Eurasian
    collision zone.
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    But mountains are shaped by forces
    other than uplift.
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    As the land is pushed up,
    air masses are forced to rise as well.
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    Rising air cools, causing any water
    vapor within it to condense
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    and form rain or snow.
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    As that falls,
    it wears down the landscape,
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    dissolving rocks or breaking them down
    in a process known as weathering.
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    Water moving downhill carries
    the weathered material
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    and erodes the landscape,
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    carving out deep valleys and jagged peaks.
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    This balance between uplift and erosion
    gives a mountain its shape.
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    But compare the celestial peaks
    of the Himalayas
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    to the comforting hills of Appalachia.
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    Clearly, all mountains are not alike.
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    That's because time
    comes into the equation, too.
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    When continental plates first collide,
    uplift happens fast.
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    The peaks grow tall with steep slopes.
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    Over time, however, gravity and water
    wear them down.
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    Eventually, erosion overtakes uplift,
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    wearing down peaks
    faster than they're pushed up.
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    A third factor shapes mountains: climate.
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    In subzero temperatures, some snowfall
    doesn't completely melt away,
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    instead slowly compacting
    until it becomes ice.
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    That forms the snowline, which occurs
    at different heights around the planet
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    depending on climate.
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    At the freezing poles,
    the snowline is at sea level.
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    Near the equator, you have to climb
    five kilometers before it gets cold enough
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    for ice to form.
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    Gathered ice starts flowing under
    its own immense weight
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    forming a slow-moving frozen river
    known as a glacier,
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    which grinds the rocks below.
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    The steeper the mountains,
    the faster ice flows,
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    and the quicker it carves
    the underlying rock.
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    Glaciers can erode landscapes
    swifter than rain and rivers.
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    Where glaciers cling to mountain peaks,
    they sand them down so fast,
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    they lop the tops off
    like giant snowy buzzsaws.
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    So then, how did the icy Mount Everest
    come to be so tall?
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    The cataclysmic continental clash
    from which it arose
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    made it huge to begin with.
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    Secondly, the mountain lies
    near the tropics,
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    so the snowline is high,
    and the glaciers relatively small,
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    barely big enough to widdle it down.
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    The mountain exists in a perfect storm
    of conditions
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    that maintain its impressive stature.
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    But that won't always be the case.
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    We live in a changing world
    where the continental plates,
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    Earth's climate,
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    and the planet's erosive power
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    might one day conspire to cut
    Mount Everest down to size.
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    For now, at least, it remains legendary
    in the minds of hikers,
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    adventurers,
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    and dreamers alike.
Title:
Why is Mount Everest so tall? - Michele Koppes
Description:

View full lesson: http://ed.ted.com/lessons/why-is-mount-everest-so-tall-michele-koppes

At 8,850 meters above sea level, Qomolangma, also known as Mount Everest, has the highest altitude on the planet. But how did this towering formation get so tall? Michele Koppes peers deep into our planet’s crust, where continental plates collide, to find the answer.

Lesson by Michele Koppes, animation by Provincia Studio.
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Video Language:
English
Team:
closed TED
Project:
TED-Ed
Duration:
04:53

English subtitles

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