0:00:06.791,0:00:08.525 Steel and plastic. 0:00:08.525,0:00:13.423 These two materials are essential to so[br]much of our infrastructure and technology, 0:00:13.423,0:00:17.129 and they have a complementary set[br]of strengths and weaknesses. 0:00:17.129,0:00:18.900 Steel is strong and hard, 0:00:18.900,0:00:21.249 but difficult to shape intricately. 0:00:21.249,0:00:23.885 While plastic can take on [br]just about any form, 0:00:23.885,0:00:26.072 it's weak and soft. 0:00:26.072,0:00:28.424 So wouldn't it be nice if there[br]were one material 0:00:28.424,0:00:30.616 as strong as the strongest steel 0:00:30.616,0:00:33.507 and as shapeable as plastic? 0:00:33.507,0:00:36.092 Well, a lot of scientists [br]and technologists 0:00:36.092,0:00:41.039 are getting excited about a relatively[br]recent invention called metallic glass 0:00:41.039,0:00:44.290 with both of those properties, and more. 0:00:44.290,0:00:47.509 Metallic glasses look shiny and opaque,[br]like metals, 0:00:47.509,0:00:51.120 and also like metals,[br]they conduct heat and electricity. 0:00:51.120,0:00:53.500 But they're way stronger than most metals, 0:00:53.500,0:00:56.101 which means they can withstand[br]a lot of force 0:00:56.101,0:00:58.449 without getting bent or dented, 0:00:58.449,0:01:00.193 making ultrasharp scalpels, 0:01:00.193,0:01:02.253 and ultrastrong electronics cases, 0:01:02.253,0:01:03.089 hinges, 0:01:03.089,0:01:04.132 screws; 0:01:04.132,0:01:05.632 the list goes on. 0:01:05.632,0:01:08.019 Metallic glasses also [br]have an incredible ability 0:01:08.019,0:01:10.755 to store and release elastic energy, 0:01:10.755,0:01:13.133 which makes them perfect [br]for sports equipment, 0:01:13.133,0:01:14.258 like tennis racquets, 0:01:14.258,0:01:15.320 golf clubs, 0:01:15.320,0:01:16.700 and skis. 0:01:16.700,0:01:18.219 They're resistant to corrosion, 0:01:18.219,0:01:22.375 and can be cast into complex shapes[br]with mirror-like surfaces 0:01:22.375,0:01:24.499 in a single molding step. 0:01:24.499,0:01:26.812 Despite their strength [br]at room temperature, 0:01:26.812,0:01:29.202 if you go up a few hundred [br]degrees Celsius, 0:01:29.202,0:01:31.062 they soften significantly, 0:01:31.062,0:01:34.474 and can be deformed into[br]any shape you like. 0:01:34.474,0:01:35.832 Cool them back down, 0:01:35.832,0:01:38.278 and they regain the strength. 0:01:38.278,0:01:41.206 So where do all of these wondrous[br]attributes come from? 0:01:41.206,0:01:45.519 In essence, they have to do with[br]metallic glass' unique atomic structure. 0:01:45.519,0:01:48.154 Most metals are crystalline as solids. 0:01:48.154,0:01:52.278 That means that if you zoomed in[br]close enough to see the individual atoms, 0:01:52.278,0:01:56.304 they'd be neatly lined up[br]in an orderly, repeating pattern 0:01:56.304,0:01:58.587 that extends throughout [br]the whole material. 0:01:58.587,0:01:59.871 Ice is crystalline, 0:01:59.871,0:02:01.124 and so are diamonds, 0:02:01.124,0:02:02.219 and salt. 0:02:02.219,0:02:04.603 If you heat these materials up enough[br]and melt them, 0:02:04.603,0:02:07.985 the atoms can jiggle freely[br]and move randomly, 0:02:07.985,0:02:09.590 but when you cool them back down, 0:02:09.590,0:02:11.427 the atoms reorganize themselves, 0:02:11.427,0:02:13.841 reestablishing the crystal. 0:02:13.841,0:02:17.219 But what if you could cool [br]a molten metal so fast 0:02:17.219,0:02:20.055 that the atoms couldn't [br]find their places again, 0:02:20.055,0:02:21.914 so that the material was solid, 0:02:21.914,0:02:26.356 but with the chaotic, amorphous internal[br]structure of a liquid? 0:02:26.356,0:02:28.096 That's metallic glass. 0:02:28.096,0:02:31.579 This structure has the added benefit[br]of lacking the grain boundaries 0:02:31.579,0:02:33.472 that most metals have. 0:02:33.472,0:02:36.884 Those are weak spots where the material[br]is more susceptible to scratches 0:02:36.884,0:02:38.783 or corrosion. 0:02:38.783,0:02:43.394 The first metallic glass was made[br]in 1960 from gold and silicon. 0:02:43.394,0:02:44.837 It wasn't easy to make. 0:02:44.837,0:02:47.505 Because metal atoms [br]crystallize so rapidly, 0:02:47.505,0:02:51.405 scientists had to cool the alloy down[br]incredibly fast, 0:02:51.405,0:02:54.527 a million degrees Kelvin per second, 0:02:54.527,0:02:57.456 by shooting tiny droplets[br]at cold copper plates, 0:02:57.456,0:03:00.317 or spinning ultrathin ribbons. 0:03:00.317,0:03:05.440 At that time, metallic glasses could[br]only be tens or hundreds of microns thick, 0:03:05.440,0:03:08.657 which was too thin [br]for most practical applications. 0:03:08.657,0:03:10.715 But since then, [br]scientists have figured out 0:03:10.715,0:03:14.318 that if you blend several metals[br]that mix with each other freely, 0:03:14.318,0:03:16.899 but can't easily crystallize together, 0:03:16.899,0:03:19.701 usually because they have very different[br]atomic sizes, 0:03:19.701,0:03:22.945 the mixture crystallizes much more slowly. 0:03:22.945,0:03:26.034 That means you don't have to cool[br]it down as fast, 0:03:26.034,0:03:27.616 so the material can be thicker, 0:03:27.616,0:03:30.092 centimeters instead of micrometers. 0:03:30.092,0:03:34.375 These materials are called bulk[br]metallic glasses, or BMGs. 0:03:34.375,0:03:37.042 Now there are hundreds of different BMGs, 0:03:37.042,0:03:40.109 so why aren't all of our bridges[br]and cars made out of them? 0:03:40.109,0:03:44.349 Many of the BMGs currently available[br]are made from expensive metals, 0:03:44.349,0:03:46.537 like palladium and zirconium, 0:03:46.537,0:03:48.022 and they have to be really pure 0:03:48.022,0:03:51.374 because any impurities [br]can cause crystallization. 0:03:51.374,0:03:56.386 So a BMG skyscraper or space shuttle[br]would be astronomically expensive. 0:03:56.386,0:03:57.776 And despite their strength, 0:03:57.776,0:04:02.089 they're not yet tough enough[br]for load-bearing applications. 0:04:02.089,0:04:05.082 When the stresses get high,[br]they can fracture without warning, 0:04:05.082,0:04:08.206 which isn't ideal for, say, a bridge. 0:04:08.206,0:04:12.065 But when engineers figure out[br]how to make BMGs from cheaper metals, 0:04:12.065,0:04:14.058 and how to make them even tougher, 0:04:14.058,0:04:15.736 for these super materials, 0:04:15.736,0:04:17.309 the sky's the limit.