WEBVTT 00:00:06.886 --> 00:00:11.216 Deep beneath the geysers and hot springs of Yellowstone Caldera 00:00:11.216 --> 00:00:16.184 lies a magma chamber produced by a hot spot in the earth’s mantle. 00:00:16.184 --> 00:00:19.077 As the magma moves towards the earth’s surface, 00:00:19.077 --> 00:00:23.337 it crystallizes to form young, hot igneous rocks. 00:00:23.337 --> 00:00:27.392 The heat from these rocks drives groundwater towards the surface. 00:00:27.392 --> 00:00:32.882 As the water cools, ions precipitate out as mineral crystals, 00:00:32.882 --> 00:00:36.876 including quartz crystals from silicon and oxygen, 00:00:36.876 --> 00:00:41.886 feldspar from potassium, aluminum, silicon, and oxygen, 00:00:41.886 --> 00:00:45.126 galena from lead and sulfur. 00:00:45.126 --> 00:00:47.736 Many of these crystals have signature shapes— 00:00:47.736 --> 00:00:52.856 take this cascade of pointed quartz, or this pile of galena cubes. 00:00:52.856 --> 00:00:57.321 But what causes them to grow into these shapes again and again? 00:00:57.321 --> 00:01:00.013 Part of the answer lies in their atoms. 00:01:00.013 --> 00:01:04.933 Every crystal’s atoms are arranged in a highly organized, repeating pattern. 00:01:04.933 --> 00:01:08.508 This pattern is the defining feature of a crystal, 00:01:08.508 --> 00:01:10.518 and isn’t restricted to minerals— 00:01:10.518 --> 00:01:15.758 sand, ice, sugar, chocolate, ceramics, metals, DNA, 00:01:15.758 --> 00:01:19.679 and even some liquids have crystalline structures. 00:01:19.679 --> 00:01:22.459 Each crystalline material’s atomic arrangement 00:01:22.459 --> 00:01:25.699 falls into one of six different families: 00:01:25.699 --> 00:01:32.319 cubic, tetragonal, orthorhombic, monoclinic, triclinic, and hexagonal. 00:01:32.319 --> 00:01:34.359 Given the appropriate conditions, 00:01:34.359 --> 00:01:37.009 crystals will grow into geometric shapes 00:01:37.009 --> 00:01:39.699 that reflect the arrangement of their atoms. 00:01:39.699 --> 00:01:44.579 Take galena, which has a cubic structure composed of lead and sulfur atoms. 00:01:44.579 --> 00:01:46.622 The relatively large lead atoms 00:01:46.622 --> 00:01:50.932 are arranged in a three-dimensional grid 90 degrees from one another, 00:01:50.932 --> 00:01:55.662 while the relatively small sulfur atoms fit neatly between them. 00:01:55.662 --> 00:02:00.174 As the crystal grows, locations like these attract sulfur atoms, 00:02:00.174 --> 00:02:03.656 while lead will tend to bond to these places. 00:02:03.656 --> 00:02:07.096 Eventually, they will complete the grid of bonded atoms. 00:02:07.096 --> 00:02:11.236 This means the 90 degree grid pattern of galena’s crystalline structure 00:02:11.236 --> 00:02:14.593 is reflected in the visible shape of the crystal. 00:02:14.593 --> 00:02:17.973 Quartz, meanwhile, has a hexagonal crystalline structure. 00:02:17.973 --> 00:02:22.103 This means that on one plane its atoms are arranged in hexagons. 00:02:22.103 --> 00:02:27.564 In three dimensions, these hexagons are composed of many interlocking pyramids 00:02:27.564 --> 00:02:31.794 made up of one silicon atom and four oxygen atoms. 00:02:31.794 --> 00:02:34.171 So the signature shape of a quartz crystal 00:02:34.171 --> 00:02:39.571 is a six-sided column with pointed tips. 00:02:39.571 --> 00:02:41.691 Depending on environmental conditions, 00:02:41.691 --> 00:02:46.111 most crystals have the potential to form multiple geometric shapes. 00:02:46.111 --> 00:02:50.041 For example, diamonds, which form deep in the earth’s mantle, 00:02:50.041 --> 00:02:56.261 have a cubic crystalline structure and can grow into either cubes or octahedrons. 00:02:56.261 --> 00:02:58.861 Which shape a particular diamond grows into 00:02:58.861 --> 00:03:01.151 depends on the conditions where it grows, 00:03:01.151 --> 00:03:05.451 including pressure, temperature, and chemical environment. 00:03:05.451 --> 00:03:09.128 While we can’t directly observe growth conditions in the mantle, 00:03:09.128 --> 00:03:11.868 laboratory experiments have shown some evidence 00:03:11.868 --> 00:03:15.838 that diamonds tend to grow into cubes at lower temperatures 00:03:15.838 --> 00:03:19.026 and octahedrons at higher temperatures. 00:03:19.026 --> 00:03:23.496 Trace amounts of water, silicon, germanium, or magnesium 00:03:23.496 --> 00:03:26.646 might also influence a diamond’s shape. 00:03:26.646 --> 00:03:31.256 And diamonds never naturally grow into the shapes found in jewelry— 00:03:31.256 --> 00:03:36.474 those diamonds have been cut to showcase sparkle and clarity. 00:03:36.474 --> 00:03:41.621 Environmental conditions can also influence whether crystals form at all. 00:03:41.621 --> 00:03:44.126 Glass is made of melted quartz sand, 00:03:44.126 --> 00:03:45.686 but it isn’t crystalline. 00:03:45.686 --> 00:03:48.706 That’s because glass cools relatively quickly, 00:03:48.706 --> 00:03:51.646 and the atoms do not have time to arrange themselves 00:03:51.646 --> 00:03:54.576 into the ordered structure of a quartz crystal. 00:03:54.576 --> 00:03:58.346 Instead, the random arrangement of the atoms in the melted glass 00:03:58.346 --> 00:04:00.906 is locked in upon cooling. 00:04:00.906 --> 00:04:03.546 Many crystals don’t form geometric shapes 00:04:03.546 --> 00:04:08.146 because they grow in extremely close quarters with other crystals. 00:04:08.146 --> 00:04:10.809 Rocks like granite are full of crystals, 00:04:10.809 --> 00:04:13.379 but none have recognizable shapes. 00:04:13.379 --> 00:04:15.539 As magma cools and solidifies, 00:04:15.539 --> 00:04:21.249 many minerals within it crystallize at the same time and quickly run out of space. 00:04:21.249 --> 00:04:23.881 And certain crystals, like turquoise, 00:04:23.881 --> 00:04:28.891 don’t grow into any discernible geometric shape in most environmental conditions, 00:04:28.891 --> 00:04:31.014 even given adequate space. 00:04:31.014 --> 00:04:34.204 Every crystal’s atomic structure has unique properties, 00:04:34.204 --> 00:04:39.134 and while these properties may not have any bearing on human emotional needs, 00:04:39.134 --> 00:04:44.204 they do have powerful applications in materials science and medicine.