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Why do buildings fall in earthquakes? - Vicki V. May

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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 shock waves 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 building's 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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    During 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.
Title:
Why do buildings fall in earthquakes? - Vicki V. May
Description:

View full lesson: http://ed.ted.com/lessons/why-do-buildings-fall-in-earthquakes-vicki-v-may

Earthquakes have always been a terrifying phenomenon, and they’ve become more deadly as our cities have grown — with collapsing buildings posing one of the largest risks. But why do buildings collapse in an earthquake? And how can it be prevented? Vicki V. May explains the physics of why it is not the sturdiest buildings, but the smartest, that will remain standing.

Lesson by Vicki V. May, animation by Pew36 Animation Studios.
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Video Language:
English
Team:
closed TED
Project:
TED-Ed
Duration:
04:52

English subtitles

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