How do crystals work? - Graham Baird
-
0:07 - 0:11Deep beneath the geysers and hot springs
of Yellowstone Caldera -
0:11 - 0:16lies a magma chamber produced by a
hot spot in the earth’s mantle. -
0:16 - 0:19As the magma moves towards
the Earth’s surface, -
0:19 - 0:23it crystallizes to form young,
hot igneous rocks. -
0:23 - 0:27The heat from these rocks drives
groundwater towards the surface. -
0:27 - 0:33As the water cools, ions precipitate out
as mineral crystals, -
0:33 - 0:37including quartz crystals from silicon
and oxygen, -
0:37 - 0:42feldspar from potassium, aluminum,
silicon, and oxygen, -
0:42 - 0:45galena from lead and sulfur.
-
0:45 - 0:48Many of these crystals have signature
shapes— -
0:48 - 0:53take this cascade of pointed quartz,
or this pile of galena cubes. -
0:53 - 0:57But what causes them to grow into these
shapes again and again? -
0:57 - 1:00Part of the answer lies in their atoms.
-
1:00 - 1:05Every crystal’s atoms are arranged
in a highly organized, repeating pattern. -
1:05 - 1:09This pattern is the defining
feature of a crystal, -
1:09 - 1:11and isn’t restricted to minerals—
-
1:11 - 1:16sand, ice, sugar, chocolate, ceramics,
metals, DNA, -
1:16 - 1:20and even some liquids have
crystalline structures. -
1:20 - 1:22Each crystalline material’s atomic
arrangement -
1:22 - 1:26falls into one of six different families:
-
1:26 - 1:32cubic, tetragonal, orthorhombic,
monoclinic, triclinic, and hexagonal. -
1:32 - 1:34Given the appropriate conditions,
-
1:34 - 1:37crystals will grow into geometric shapes
-
1:37 - 1:40that reflect the arrangement
of their atoms. -
1:40 - 1:45Take galena, which has a cubic structure
composed of lead and sulfur atoms. -
1:45 - 1:47The relatively large lead atoms
-
1:47 - 1:51are arranged in a three-dimensional
grid 90 degrees from one another, -
1:51 - 1:56while the relatively small sulfur atoms
fit neatly between them. -
1:56 - 2:00As the crystal grows, locations like these
attract sulfur atoms, -
2:00 - 2:04while lead will tend to
bond to these places. -
2:04 - 2:07Eventually, they will complete the grid
of bonded atoms. -
2:07 - 2:11This means the 90 degree grid pattern
of galena’s crystalline structure -
2:11 - 2:15is reflected in the visible
shape of the crystal. -
2:15 - 2:18Quartz, meanwhile, has a hexagonal
crystalline structure. -
2:18 - 2:22This means that on one plane its atoms
are arranged in hexagons. -
2:22 - 2:28In three dimensions, these hexagons are
composed of many interlocking pyramids -
2:28 - 2:32made up of one silicon atom
and four oxygen atoms. -
2:32 - 2:34So the signature shape of a quartz
crystal -
2:34 - 2:40is a six-sided column with pointed tips.
-
2:40 - 2:42Depending on environmental conditions,
-
2:42 - 2:46most crystals have the potential to form
multiple geometric shapes. -
2:46 - 2:50For example, diamonds, which form deep
in the Earth’s mantle, -
2:50 - 2:56have a cubic crystalline structure and can
grow into either cubes or octahedrons. -
2:56 - 2:59Which shape a particular
diamond grows into -
2:59 - 3:01depends on the conditions where it grows,
-
3:01 - 3:05including pressure, temperature,
and chemical environment. -
3:05 - 3:09While we can’t directly observe growth
conditions in the mantle, -
3:09 - 3:12laboratory experiments have shown some
evidence -
3:12 - 3:16that diamonds tend to grow into cubes at
lower temperatures -
3:16 - 3:19and octahedrons at higher temperatures.
-
3:19 - 3:23Trace amounts of water, silicon,
germanium, or magnesium -
3:23 - 3:27might also influence a diamond’s shape.
-
3:27 - 3:31And diamonds never naturally grow into the
shapes found in jewelry— -
3:31 - 3:36those diamonds have been cut to
showcase sparkle and clarity. -
3:36 - 3:42Environmental conditions can also
influence whether crystals form at all. -
3:42 - 3:44Glass is made of melted quartz sand,
-
3:44 - 3:46but it isn’t crystalline.
-
3:46 - 3:49That’s because glass cools
relatively quickly, -
3:49 - 3:52and the atoms do not have time to arrange
themselves -
3:52 - 3:55into the ordered structure
of a quartz crystal. -
3:55 - 3:58Instead, the random arrangement
of the atoms in the melted glass -
3:58 - 4:01is locked in upon cooling.
-
4:01 - 4:04Many crystals don’t form geometric shapes
-
4:04 - 4:08because they grow in extremely close
quarters with other crystals. -
4:08 - 4:11Rocks like granite are full of crystals,
-
4:11 - 4:13but none have recognizable shapes.
-
4:13 - 4:16As magma cools and solidifies,
-
4:16 - 4:21many minerals within it crystallize at the
same time and quickly run out of space. -
4:21 - 4:24And certain crystals, like turquoise,
-
4:24 - 4:29don’t grow into any discernible geometric
shape in most environmental conditions, -
4:29 - 4:31even given adequate space.
-
4:31 - 4:34Every crystal’s atomic structure has
unique properties, -
4:34 - 4:39and while these properties may not have
any bearing on human emotional needs, -
4:39 - 4:44they do have powerful applications
in materials science and medicine.
- Title:
- How do crystals work? - Graham Baird
- Speaker:
- Graham Baird
- Description:
-
more » « less
View full lesson: https://ed.ted.com/lessons/how-do-crystals-work-graham-baird
Many crystals have signature shapes— like the cascade of pointed quartz or a pile of galena cubes. Every crystal's atoms have a defining feature: their organized, repeating pattern. The pattern isn't restricted to minerals- sand, ice, metals and DNA also have crystalline structures. So what causes them to grow into these shapes again and again? Graham Baird dives into the unique properties of crystals.
Lesson by Graham Baird, directed by Franz Palomares.
- Video Language:
- English
- Team:
closed TED
- Project:
- TED-Ed
- Duration:
- 04:45
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