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Earthquakes have always been
a terrifying phenomenon,
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and they've become more deadly
as our cities have grown,
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with collapsing buildings posing
one of the largest risks.
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Why do buildings collapse
in an earthquake,
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and how can it be prevented?
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If you've watched a lot of disaster films,
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you might have the idea
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that building collapse is caused directly
by the ground beneath them
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shaking violently,
or even splitting apart.
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But that's not really how it works.
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For one thing, most buildings
are not located right on a fault line,
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and the shifting tectonic plates
go much deeper than building foundations.
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So what's actually going on?
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In fact, the reality of earthquakes
and their effect on buildings
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is a bit more complicated.
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To make sense of it, architects
and engineers use models,
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like a two-dimensional array of lines
representing columns and beams,
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or a single line lollipop with circles
representing the building's mass.
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Even when simplified to this degree,
these models can be quite useful,
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as predicting a building's response
to an earthquake
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is primarily a matter of physics.
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Most collapses that occur
during earthquakes
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aren't actually caused
by the earthquake itself.
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Instead, when the ground moves
beneath a building,
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it displaces the foundation
and lower levels,
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sending shockwaves through
the rest of the structure
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and causing it to vibrate back and forth.
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The strength of this oscillation
depends on two main factors:
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the buildings mass,
which is concentrated at the bottom,
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and its stiffness,
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which is the force required
to cause a certain amount of displacement.
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Along with the building's material type
and the shape of its columns,
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stiffness is largely a matter of height.
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Shorter buildings tend to be stiffer
and shift less,
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while taller buildings are more flexible.
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You might think that the solution
is to build shorter buildlings
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so that they shift as little as possible.
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But the 1985 Mexico City earthquake is
a good example of why that's not the case.
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Durng the quake,
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many buildings between six
and fifteen stories tall collapsed.
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What's strange is that while shorter
buildings nearby did keep standing,
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buildings taller than fifteen stories
were also less damaged,
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and the midsized buildings that collapsed
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were observed shaking far more violently
than the earthquake itself.
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How is that possible?
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The answer has to do with something
known as natural frequency.
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In an oscillating system,
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the frequency is how many back and forth
movement cycles occur within a second.
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This is the inverse of the period,
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which is how many seconds it takes
to complete one cycle.
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And a building's natural frequency,
determined by its mass and stiffness,
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is the frequency that its vibrations
will tend to cluster around.
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Increasing a building's mass slows down
the rate at which it naturally vibrates,
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while increasing stiffness
makes it vibrate faster.
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So in the equation representing
their relationship,
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stiffness and natural frequency
are proportional to one another,
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while mass and natural frequency
are inversely proportional.
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What happened in Mexico City
was an effect called resonance,
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where the frequency
of the earthquake's seismic waves
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happen to match the natural frequency
of the midsized buildings.
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Like a well-timed push on a swingset,
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each additional seismic wave
amplified the building's vibration
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in its current direction,
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causing it to swing even further back,
and so on,
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eventually reaching a far greater extent
than the initial displacement.
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Today, engineers work
with geologists and seismologists
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to predict the frequency
of earthquake motions at building sites
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in order to prevent
resonance-induced collapses,
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taking into account factors
such as soil type and fault type,
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as well as data from previous quakes.
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Low frequencies of motion
will cause more damage to taller
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and more flexible buildings,
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while high frequencies of motion
pose more threat
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to structures that
are shorter and stiffer.
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Engineers have also devised ways
to abosrb shocks
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and limit deformation
using innovative systems.
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Base isolation uses flexible layers
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to isolate the foundation's displacement
from the rest of the building,
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while tuned mass damper systems
cancel out resonance
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by oscillating out of phase
with the natural frequency
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to reduce vibrations.
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In the end, it's not the sturdiest
buildings that will remain standing,
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but the smartest ones.
closed TED
