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In 1956,
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architect Frank Lloyd Wright
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proposed a mile-high skyscraper.
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It was going to be the world’s
tallest building,
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by a lot —
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five times as high as the Eiffel Tower.
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But many critics laughed at the architect,
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arguing that people would have to wait
hours for an elevator,
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or worse, that the tower would collapse
under its own weight.
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Most engineers agreed,
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and despite the publicity
around the proposal,
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the titanic tower was never built.
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But today,
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bigger and bigger buildings are going up
around the world.
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Firms are even planning skyscrapers
more than a kilometer tall,
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like the Jeddah Tower in Saudi Arabia,
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three times the size of the Eiffel Tower.
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Very soon,
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Wright’s mile-high miracle
may be a reality.
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So what exactly was stopping us
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from building these megastructures
70 years ago,
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and how do we build something
a mile high today?
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In any construction project,
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each story of the structure needs to be
able to support the stories on top of it.
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The higher we build,
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the higher the gravitational pressure
from the upper stories on the lower ones.
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This principle has long dictated
the shape of our buildings,
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leading ancient architects to favor
pyramids with wide foundations
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that support lighter upper levels.
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But this solution doesn’t quite translate
to a city skyline–
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a pyramid that tall would be roughly
one-and-a-half miles wide,
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tough to squeeze into a city center.
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Fortunately, strong materials like
concrete can avoid this impractical shape.
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And modern concrete blends are reinforced
with steel-fibers for strength
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and water-reducing polymers
to prevent cracking.
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The concrete in the world’s tallest tower,
Dubai’s Burj Khalifa,
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can withstand about 8,000 tons of pressure
per square meter–
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the weight of over 1,200
African elephants!
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Of course, even if a building
supports itself,
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it still needs support from the ground.
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Without a foundation,
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buildings this heavy would sink, fall,
or lean over.
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To prevent the roughly half a million
ton tower from sinking,
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192 concrete and steel supports called
piles were buried over 50 meters deep.
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The friction between the piles
and the ground
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keeps this sizable structure standing.
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Besides defeating gravity,
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which pushes the building down,
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a skyscraper also needs to overcome
the blowing wind,
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which pushes from the side.
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On average days,
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wind can exert up to 17 pounds of force
per square meter on a high-rise building–
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as heavy as a gust of bowling balls.
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Designing structures to be aerodynamic,
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like China’s sleek Shanghai Tower,
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can reduce that force by up to a quarter.
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And wind-bearing frames inside or
outside the building
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can absorb the remaining wind force,
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such as in Seoul’s Lotte Tower.
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But even after all these measures,
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you could still find yourself swaying back
and forth
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more than a meter on top floors
during a hurricane.
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To prevent the wind from
rocking tower tops,
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many skyscrapers employ a counterweight
weighing hundreds of tons
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called a “tuned mass damper.”
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The Taipei 101, for instance,
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has suspended a giant metal orb
above the 87th floor.
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When wind moves the building,
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this orb sways into action,
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absorbing the building’s kinetic energy.
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As its movements trail the tower’s,
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hydraulic cylinders between the ball
and the building
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convert that kinetic energy into heat,
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and stabilize the swaying structure.
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With all these technologies in place,
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our mega-structures can stay
standing and stable.
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But quickly traveling through buildings
this large is a challenge in itself.
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In Wright’s age,
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the fastest elevators moved
a mere 22 kilometers per hour.
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Thankfully, today’s elevators are much
faster, traveling over 70 km per hour
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with future cabins potentially using
frictionless magnetic rails
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for even higher speeds.
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And traffic management algorithms
group riders by destination
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to get passengers and empty cabins
where they need to be.
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Skyscrapers have come a long way since
Wright proposed his mile-high tower.
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What were once considered impossible ideas
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have become architectural opportunities.
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Today it may just be a matter of time
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until one building goes the extra mile.
closed TED
