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What is chirality and how did it get in my molecules? - Michael Evans

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    In the early days of organic chemistry,
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    chemists understood
    that molecules were made of atoms
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    connected through chemical bonds.
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    However, the three-dimensional
    shapes of molecules
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    were utterly unclear, since they couldn't
    be observed directly.
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    Molecules were represented using
    simple connectivity graphs
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    like the one you see here.
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    It was clear to savvy chemists
    of the mid-19th century
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    that these flat representations
    couldn't explain
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    many of their observations.
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    But chemical theory hadn't provided
    a satisfactory explanation
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    for the three-dimensional
    structures of molecules.
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    In 1874, the chemist Van't Hoff
    published a remarkable hypothesis:
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    the four bonds of a saturated carbon atom
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    point to the corners of a tetrahedron.
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    It would take over 25 years
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    for the quantum revolution
    to theoretically validate his hypothesis.
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    But Van't Hoff supported
    his theory using optical rotation.
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    Van't Hoff noticed that only compounds
    containing a central carbon
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    bound to four different atoms or groups
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    rotated plane-polarized light.
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    Clearly there's something unique
    about this class of compounds.
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    Take a look at the two molecules
    you see here.
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    Each one is characterized
    by a central, tetrahedral carbon atom
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    bound to four different atoms:
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    bromine, chlorine, fluorine, and hydrogen.
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    We might be tempted to conclude
    that the two molecules
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    are the same, if we just concern
    ourselves with what they're made of.
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    However, let's see if we can
    overlay the two molecules
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    perfectly to really prove
    that they're the same.
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    We have free license to rotate
    and translate both of the molecules
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    as we wish. Remarkably though,
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    no matter how we move the molecules,
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    we find that perfect superposition
    is impossible to achieve.
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    Now take a look at your hands.
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    Notice that your two hands
    have all the same parts:
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    a thumb, fingers, a palm, etc.
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    Like our two molecules under study,
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    both of your hands are made
    of the same stuff.
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    Furthermore, the distances between stuff
    in both of your hands are the same.
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    The index finger
    is next to the middle finger,
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    which is next to the ring finger, etc.
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    The same is true
    of our hypothetical molecules.
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    All of their internal distances
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    are the same. Despite
    the similarities between them,
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    your hands, and our molecules,
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    are certainly not the same.
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    Try superimposing
    your hands on one another.
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    Just like our molecules from before,
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    you'll find that it can't
    be done perfectly.
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    Now, point your palms toward one another.
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    Wiggle both of your index fingers.
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    Notice that your left hand
    looks as if it's looking
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    in a mirror at your right.
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    In other words, your hands
    are mirror images.
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    The same can be said of our molecules.
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    We can turn them so
    that one looks at the other
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    as in a mirror. Your hands
    - and our molecules -
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    possess a spatial property
    in common called chirality,
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    or handedness.
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    Chirality means exactly
    what we've just described:
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    a chiral object is not
    the same as its mirror image.
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    Chiral objects are very special
    in both chemistry and everyday life.
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    Screws, for example, are also chiral.
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    That's why we need the terms
    right-handed and left-handed screws.
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    And believe it or not,
    certain types of light
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    can behave like chiral screws.
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    Packed into every linear,
    plane-polarized beam of light
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    are right-handed and left-handed parts
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    that rotate together
    to produce plane polarization.
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    Chiral molecules, placed
    in a beam of such light,
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    interact differently
    with the two chiral components.
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    As a result, one component of the light
    gets temporarily slowed down
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    relative to the other. The
    effect on the light beam
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    is a rotation of its plane
    from the original one,
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    otherwise known as optical rotation.
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    Van't Hoff and later chemists
    realized that the chiral nature
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    of tetrahedral carbons can explain
    this fascinating phenomenon.
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    Chirality is responsible for all kinds
    of other fascinating effects
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    in chemistry, and everyday life.
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    Humans tend to love symmetry
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    and so if you look around you,
    you'll find that chiral objects
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    made by humans are rare.
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    But chiral molecules
    are absolutely everywhere.
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    Phenomena as separate as optical rotation,
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    Screwing together furniture,
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    and clapping your hands
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    all involve this intriguing
    spatial property.
Title:
What is chirality and how did it get in my molecules? - Michael Evans
Description:

Improve your understanding of molecular properties with this lesson on the fascinating property of chirality. Your hands are the secret to understanding the strange similarity between two molecules that look almost exactly alike, but are not perfect mirror images.

Lesson by Michael Evans, animation by Safwat Saleem and Qa'ed Tung.

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Video Language:
English
Team:
closed TED
Project:
TED-Ed
Duration:
05:05

English subtitles

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