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Deep beneath the geysers and hot springs
of Yellowstone Caldera
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lies a magma chamber produced by a
hot spot in the earth’s mantle.
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As the magma moves towards
the earth’s surface,
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it crystallizes to form young,
hot igneous rocks.
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The heat from these rocks drives
groundwater towards the surface.
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As the water cools, ions precipitate out
as mineral crystals,
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including quartz crystals from silicon
and oxygen,
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feldspar from potassium, aluminum,
silicon, and oxygen,
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galena from lead and sulfur.
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Many of these crystals have signature
shapes—
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take this cascade of pointed quartz,
or this pile of galena cubes.
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But what causes them to grow into these
shapes again and again?
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Part of the answer lies in their atoms.
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Every crystal’s atoms are arranged
in a highly organized, repeating pattern.
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This pattern is the defining
feature of a crystal,
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and isn’t restricted to minerals—
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sand, ice, sugar, chocolate, ceramics,
metals, DNA,
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and even some liquids have
crystalline structures.
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Each crystalline material’s atomic
arrangement
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falls into one of six different families:
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cubic, tetragonal, orthorhombic,
monoclinic, triclinic, and hexagonal.
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Given the appropriate conditions,
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crystals will grow into geometric shapes
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that reflect the arrangement
of their atoms.
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Take galena, which has a cubic structure
composed of lead and sulfur atoms.
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The relatively large lead atoms
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are arranged in a three-dimensional
grid 90 degrees from one another,
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while the relatively small sulfur atoms
fit neatly between them.
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As the crystal grows, locations like these
attract sulfur atoms,
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while lead will tend to
bond to these places.
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Eventually, they will complete the grid
of bonded atoms.
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This means the 90 degree grid pattern
of galena’s crystalline structure
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is reflected in the visible
shape of the crystal.
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Quartz, meanwhile, has a hexagonal
crystalline structure.
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This means that on one plane its atoms
are arranged in hexagons.
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In three dimensions, these hexagons are
composed of many interlocking pyramids
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made up of one silicon atom
and four oxygen atoms.
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So the signature shape of a quartz
crystal
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is a six-sided column with pointed tips.
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Depending on environmental conditions,
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most crystals have the potential to form
multiple geometric shapes.
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For example, diamonds, which form deep
in the earth’s mantle,
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have a cubic crystalline structure and can
grow into either cubes or octahedrons.
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Which shape a particular
diamond grows into
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depends on the conditions where it grows,
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including pressure, temperature,
and chemical environment.
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While we can’t directly observe growth
conditions in the mantle,
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laboratory experiments have shown some
evidence
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that diamonds tend to grow into cubes at
lower temperatures
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and octahedrons at higher temperatures.
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Trace amounts of water, silicon,
germanium, or magnesium
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might also influence a diamond’s shape.
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And diamonds never naturally grow into the
shapes found in jewelry—
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those diamonds have been cut to
showcase sparkle and clarity.
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Environmental conditions can also
influence whether crystals form at all.
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Glass is made of melted quartz sand,
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but it isn’t crystalline.
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That’s because glass cools
relatively quickly,
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and the atoms do not have time to arrange
themselves
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into the ordered structure
of a quartz crystal.
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Instead, the random arrangement
of the atoms in the melted glass
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is locked in upon cooling.
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Many crystals don’t form geometric shapes
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because they grow in extremely close
quarters with other crystals.
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Rocks like granite are full of crystals,
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but none have recognizable shapes.
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As magma cools and solidifies,
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many minerals within it crystallize at the
same time and quickly run out of space.
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And certain crystals, like turquoise,
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don’t grow into any discernible geometric
shape in most environmental conditions,
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even given adequate space.
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Every crystal’s atomic structure has
unique properties,
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and while these properties may not have
any bearing on human emotional needs,
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they do have powerful applications
in materials science and medicine.
closed TED
