WEBVTT 00:00:07.525 --> 00:00:09.815 In 132 CE, 00:00:09.815 --> 00:00:12.145 Chinese polymath Zhang Heng 00:00:12.145 --> 00:00:15.585 presented the Han court with his latest invention. 00:00:15.585 --> 00:00:17.675 This large vase, he claimed, 00:00:17.675 --> 00:00:21.325 could tell them whenever an earthquake occurred in their kingdom– 00:00:21.325 --> 00:00:24.595 including the direction they should send aid. 00:00:24.595 --> 00:00:26.505 The court was somewhat skeptical, 00:00:26.505 --> 00:00:31.005 especially when the device triggered on a seemingly quiet afternoon. 00:00:31.005 --> 00:00:34.054 But when messengers came for help days later, 00:00:34.054 --> 00:00:36.614 their doubts turned to gratitude. 00:00:36.614 --> 00:00:41.114 Today, we no longer rely on pots to identify seismic events, 00:00:41.114 --> 00:00:46.150 but earthquakes still offer a unique challenge to those trying to track them. 00:00:46.150 --> 00:00:49.139 So why are earthquakes so hard to anticipate, 00:00:49.139 --> 00:00:52.039 and how could we get better at predicting them? 00:00:52.039 --> 00:00:53.099 To answer that, 00:00:53.099 --> 00:00:57.539 we need to understand some theories behind how earthquakes occur. 00:00:57.539 --> 00:01:01.794 Earth’s crust is made from several vast, jagged slabs of rock 00:01:01.794 --> 00:01:03.749 called tectonic plates, 00:01:03.749 --> 00:01:08.479 each riding on a hot, partially molten layer of Earth’s mantle. 00:01:08.479 --> 00:01:11.289 This causes the plates to spread very slowly, 00:01:11.289 --> 00:01:14.839 at anywhere from 1 to 20 centimeters per year. 00:01:14.839 --> 00:01:17.289 But these tiny movements are powerful enough 00:01:17.289 --> 00:01:20.799 to cause deep cracks in the interacting plates. 00:01:20.799 --> 00:01:22.399 And in unstable zones, 00:01:22.399 --> 00:01:27.219 the intensifying pressure may ultimately trigger an earthquake. 00:01:27.219 --> 00:01:30.249 It’s hard enough to monitor these miniscule movements, 00:01:30.249 --> 00:01:35.589 but the factors that turn shifts into seismic events are far more varied. 00:01:35.589 --> 00:01:38.399 Different fault lines juxtapose different rocks– 00:01:38.399 --> 00:01:42.269 some of which are stronger–or weaker– under pressure. 00:01:42.269 --> 00:01:46.979 Diverse rocks also react differently to friction and high temperatures. 00:01:46.979 --> 00:01:50.431 Some partially melt, and can release lubricating fluids 00:01:50.431 --> 00:01:52.230 made of superheated minerals 00:01:52.230 --> 00:01:54.420 that reduce fault line friction. 00:01:54.420 --> 00:01:56.370 But some are left dry, 00:01:56.370 --> 00:01:59.140 prone to dangerous build-ups of pressure. 00:01:59.140 --> 00:02:03.680 And all these faults are subject to varying gravitational forces, 00:02:03.680 --> 00:02:08.531 as well as the currents of hot rocks moving throughout Earth’s mantle. 00:02:08.531 --> 00:02:11.755 So which of these hidden variables should we be analyzing, 00:02:11.755 --> 00:02:15.955 and how do they fit into our growing prediction toolkit? 00:02:15.955 --> 00:02:19.829 Because some of these forces occur at largely constant rates, 00:02:19.829 --> 00:02:23.159 the behavior of the plates is somewhat cyclical. 00:02:23.159 --> 00:02:27.609 Today, many of our most reliable clues come from long-term forecasting, 00:02:27.609 --> 00:02:31.893 related to when and where earthquakes have previously occurred. 00:02:31.893 --> 00:02:33.573 At the scale of millennia, 00:02:33.573 --> 00:02:37.533 this allows us to make predictions about when highly active faults, 00:02:37.533 --> 00:02:38.873 like the San Andreas, 00:02:38.873 --> 00:02:41.943 are overdue for a massive earthquake. 00:02:41.943 --> 00:02:44.193 But due to the many variables involved, 00:02:44.193 --> 00:02:47.783 this method can only predict very loose timeframes. 00:02:47.783 --> 00:02:49.693 To predict more imminent events, 00:02:49.693 --> 00:02:55.303 researchers have investigated the vibrations Earth elicits before a quake. 00:02:55.303 --> 00:02:57.990 Geologists have long used seismometers 00:02:57.990 --> 00:03:01.920 to track and map these tiny shifts in the earth’s crust. 00:03:01.920 --> 00:03:04.910 And today, most smartphones are also capable 00:03:04.910 --> 00:03:07.670 of recording primary seismic waves. 00:03:07.670 --> 00:03:09.740 With a network of phones around the globe, 00:03:09.740 --> 00:03:12.680 scientists could potentially crowd source a rich, 00:03:12.680 --> 00:03:16.425 detailed warning system that alerts people to incoming quakes. 00:03:16.955 --> 00:03:21.325 Unfortunately, phones might not be able to provide the advance notice needed 00:03:21.325 --> 00:03:23.355 to enact safety protocols. 00:03:23.355 --> 00:03:26.075 But such detailed readings would still be useful 00:03:26.075 --> 00:03:29.425 for prediction tools like NASA’s Quakesim software, 00:03:29.425 --> 00:03:32.255 which can use a rigorous blend of geological data 00:03:32.255 --> 00:03:34.765 to identify regions at risk. 00:03:34.765 --> 00:03:36.765 However, recent studies indicate 00:03:36.765 --> 00:03:41.635 the most telling signs of a quake might be invisible to all these sensors. 00:03:41.635 --> 00:03:43.005 In 2011, 00:03:43.005 --> 00:03:46.265 just before an earthquake struck the east coast of Japan, 00:03:46.265 --> 00:03:50.065 nearby researchers recorded surprisingly high concentrations 00:03:50.065 --> 00:03:54.425 of the radioactive isotope pair radon and thoron. 00:03:54.425 --> 00:03:58.167 As stress builds up in the crust right before an earthquake, 00:03:58.167 --> 00:04:02.407 microfractures allow these gases to escape to the surface. 00:04:02.407 --> 00:04:07.042 These scientists think that if we built a vast network of radon-thoron detectors 00:04:07.042 --> 00:04:08.992 in earthquake-prone areas, 00:04:08.992 --> 00:04:11.522 it could become a promising warning system– 00:04:11.522 --> 00:04:14.532 potentially predicting quakes a week in advance. 00:04:14.532 --> 00:04:15.232 Of course, 00:04:15.232 --> 00:04:17.432 none of these technologies would be as helpful 00:04:17.432 --> 00:04:20.572 as simply looking deep inside the earth itself. 00:04:20.572 --> 00:04:22.242 With a deeper view we might be able 00:04:22.242 --> 00:04:26.852 to track and predict large-scale geological changes in real time, 00:04:26.852 --> 00:04:29.734 possibly saving tens of thousands of lives a year. 00:04:30.034 --> 00:04:30.874 But for now, 00:04:30.874 --> 00:04:35.404 these technologies can help us prepare and respond quickly to areas in need– 00:04:35.404 --> 00:04:39.462 without waiting for directions from a vase.