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The invisible motion of still objects - Ran Tivony

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    Many of the inanimate objects around you
    probably seem perfectly still.
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    But look deep into the atomic structure
    of any of them,
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    and you'll see a world in constant flux.
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    Stretching,
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    contracting,
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    springing,
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    jittering,
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    drifting atoms everywhere.
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    And though that movement may seem chaotic,
    it's not random.
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    Atoms that are bonded together,
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    and that describes almost all substances,
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    move according to a set of principles.
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    For example, take molecules,
    atoms held together by covalent bonds.
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    There are three basic ways
    molecules can move:
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    rotation,
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    translation,
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    and vibration.
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    Rotation and translation
    move a molecule in space
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    while its atoms stay
    the same distance apart.
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    Vibration, on the other hand,
    changes those distances,
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    actually altering the molecule's shape.
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    For any molecule, you can count up
    the number of different ways it can move.
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    That corresponds to
    its degrees of freedom,
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    which in the context of mechanics
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    basically means the number of variables
    we need to take into account
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    to understand the full system.
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    Three-dimensional space is defined by
    x, y, and z axes.
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    Translation allows the molecule to move
    in the direction of any of them.
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    That's three degrees of freedom.
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    It can also rotate around
    any of these three axes.
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    That's three more,
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    unless it's a linear molecule,
    like carbon dioxide.
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    There, one of the rotations just spins
    the molecule around its own axis,
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    which doesn't count because it doesn't
    change the position of the atoms.
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    Vibration is where it gets a bit tricky.
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    Let's take a simple molecule,
    like hydrogen.
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    The length of the bond that holds the two
    atoms together is constantly changing
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    as if the atoms were connected
    by a spring.
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    That change in distance is tiny,
    less than a billionth of a meter.
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    The more atoms and bonds a molecule has,
    the more vibrational modes.
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    For example, a water molecule
    has three atoms:
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    one oxygen and two hydrogens,
    and two bonds.
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    That gives it three modes of vibration:
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    symmetric stretching,
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    asymmetric stretching,
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    and bending.
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    More complicated molecules have even
    fancier vibrational modes,
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    like rocking,
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    wagging,
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    and twisting.
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    If you know how many atoms a molecule has,
    you can count its vibrational modes.
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    Start with the total degrees of freedom,
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    which is three times the number
    of atoms in the molecule.
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    That's because each atom can move
    in three different directions.
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    Three of the total correspond
    to translation
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    when all the atoms
    are going in the same direction.
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    And three, or two for linear molecules,
    correspond to rotations.
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    All the rest, 3N-6
    or 3N-5 for linear molecules,
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    are vibrations.
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    So what's causing all this motion?
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    Molecules move because they absorb
    energy from their surroundings,
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    mainly in the form of heat
    or electromagnetic radiation.
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    When this energy gets transferred
    to the molecules,
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    they vibrate,
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    rotate,
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    or translate faster.
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    Faster motion increases the kinetic energy
    of the molecules and atoms.
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    We define this as an increase
    in temperature and thermal energy.
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    This is the phenomenon your microwave oven
    uses to heat your food.
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    The oven emits microwave radiation,
    which is absorbed by the molecules,
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    especially those of water.
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    They move around faster and faster,
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    bumping into each other and increasing
    the food's temperature and thermal energy.
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    The greenhouse effect is another example.
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    Some of the solar radiation
    that hits the Earth's surface
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    is reflected back to the atmosphere.
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    Greenhouse gases, like water vapor
    and carbon dioxide absorb this radiation
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    and speed up.
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    These hotter, faster-moving molecules
    emit infrared radiation in all directions,
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    including back to Earth, warming it.
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    Does all this molecular motion ever stop?
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    You might think that would happen
    at absolute zero,
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    the coldest possible temperature.
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    No one's ever managed to cool
    anything down that much,
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    but even if we could,
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    molecules would still move due to
    a quantum mechanical principle
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    called zero-point energy.
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    In other words, everything has been moving
    since the universe's very first moments,
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    and will keep going long,
    long after we're gone.
Title:
The invisible motion of still objects - Ran Tivony
Description:

View full lesson: http://ed.ted.com/lessons/the-invisible-motion-of-still-objects-ran-tivony

Many of the inanimate objects around you probably seem perfectly still. But look deep into the atomic structure of any of them, and you’ll see a world in constant flux — with stretching, contracting, springing, jittering, drifting atoms everywhere. Ran Tivony describes how and why molecular movement occurs and investigates if it might ever stop.

Lesson by Ran Tivony, animation by Zedem Media.
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Video Language:
English
Team:
closed TED
Project:
TED-Ed
Duration:
04:44

English subtitles

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