WEBVTT 00:00:06.876 --> 00:00:12.132 In February of 1942, Mexican farmer Dionisio Pulido 00:00:12.132 --> 00:00:15.962 thought he heard thunder coming from his cornfield. 00:00:15.962 --> 00:00:19.740 However, the sound wasn’t coming from the sky. 00:00:19.740 --> 00:00:25.440 The source was a large, smoking crack emitting gas and ejecting rocks. 00:00:25.440 --> 00:00:29.560 This fissure would come to be known as the volcano Paricutin, 00:00:29.560 --> 00:00:36.706 and over the next 9 years, its lava and ash would cover over 200 square km. 00:00:36.706 --> 00:00:39.056 But where did this new volcano come from, 00:00:39.056 --> 00:00:43.160 and what triggered its unpredictable eruption? NOTE Paragraph 00:00:43.160 --> 00:00:46.690 The story of any volcano begins with magma. 00:00:46.690 --> 00:00:50.820 Often, this molten rock forms in areas where ocean water 00:00:50.820 --> 00:00:56.094 is able to slip into the Earth’s mantle and lower the layer’s melting point. 00:00:56.094 --> 00:01:00.114 The resulting magma typically remains under the Earth’s surface 00:01:00.114 --> 00:01:04.226 thanks to the delicate balance of three geological factors. 00:01:04.226 --> 00:01:06.859 The first is lithostatic pressure. 00:01:06.859 --> 00:01:11.780 This is the weight of the Earth’s crust pushing down on the magma below. 00:01:11.780 --> 00:01:16.570 Magma pushes back with the second factor, magmastatic pressure. 00:01:16.570 --> 00:01:20.500 The battle between these forces strains the third factor: 00:01:20.500 --> 00:01:23.696 the rock strength of the Earth’s crust. 00:01:23.696 --> 00:01:26.846 Usually, the rock is strong enough and heavy enough 00:01:26.846 --> 00:01:28.916 to keep the magma in place. 00:01:28.916 --> 00:01:34.701 But when this equilibrium is thrown off, the consequences can be explosive. NOTE Paragraph 00:01:34.701 --> 00:01:37.421 One of the most common causes of an eruption 00:01:37.421 --> 00:01:40.320 is an increase in magmastatic pressure. 00:01:40.320 --> 00:01:43.590 Magma contains various elements and compounds, 00:01:43.590 --> 00:01:46.740 many of which are dissolved in the molten rock. 00:01:46.740 --> 00:01:53.067 At high enough concentrations, compounds like water or sulfur no longer dissolve, 00:01:53.067 --> 00:01:56.887 and instead form high-pressure gas bubbles. 00:01:56.887 --> 00:01:59.122 When these bubbles reach the surface, 00:01:59.122 --> 00:02:02.320 they can burst with the force of a gunshot. 00:02:02.320 --> 00:02:05.950 And when millions of bubbles explode simultaneously, 00:02:05.950 --> 00:02:10.200 the energy can send plumes of ash into the stratosphere. 00:02:10.200 --> 00:02:15.495 But before they pop, they act like bubbles of C02 in a shaken soda. 00:02:15.495 --> 00:02:18.355 Their presence lowers the magma’s density, 00:02:18.355 --> 00:02:23.098 and increases the buoyant force pushing upward through the crust. 00:02:23.098 --> 00:02:28.191 Many geologists believe this process was behind the Paricutin eruption 00:02:28.191 --> 00:02:30.011 in Mexico. NOTE Paragraph 00:02:30.011 --> 00:02:33.518 There are two known natural causes for these buoyant bubbles. 00:02:33.518 --> 00:02:36.688 Sometimes, new magma from deeper underground 00:02:36.688 --> 00:02:40.658 brings additional gassy compounds into the mix. 00:02:40.658 --> 00:02:44.806 But bubbles can also form when magma begins to cool. 00:02:44.806 --> 00:02:50.149 In its molten state, magma is a mixture of dissolved gases and melted minerals. 00:02:50.149 --> 00:02:55.621 As the molten rock hardens, some of those minerals solidify into crystals. 00:02:55.621 --> 00:02:59.621 This process doesn’t incorporate many of the dissolved gasses, 00:02:59.621 --> 00:03:02.912 resulting in a higher concentration of the compounds 00:03:02.912 --> 00:03:06.362 that form explosive bubbles. NOTE Paragraph 00:03:06.362 --> 00:03:10.332 Not all eruptions are due to rising magmastatic pressure— 00:03:10.332 --> 00:03:15.062 sometimes the weight of the rock above can become dangerously low. 00:03:15.062 --> 00:03:20.231 Landslides can remove massive quantities of rock from atop a magma chamber, 00:03:20.231 --> 00:03:25.201 dropping the lithostatic pressure and instantly triggering an eruption. 00:03:25.201 --> 00:03:27.921 This process is known as “unloading” 00:03:27.921 --> 00:03:30.822 and it’s been responsible for numerous eruptions, 00:03:30.822 --> 00:03:35.544 including the sudden explosion of Mount St. Helens in 1980. 00:03:35.544 --> 00:03:39.114 But unloading can also happen over longer periods of time 00:03:39.114 --> 00:03:41.762 due to erosion or melting glaciers. 00:03:41.762 --> 00:03:45.232 In fact, many geologists are worried that glacial melt 00:03:45.232 --> 00:03:49.722 caused by climate change could increase volcanic activity. NOTE Paragraph 00:03:49.722 --> 00:03:54.295 Finally, eruptions can occur when the rock layer is no longer strong enough 00:03:54.295 --> 00:03:56.735 to hold back the magma below. 00:03:56.735 --> 00:03:59.942 Acidic gases and heat escaping from magma 00:03:59.942 --> 00:04:04.568 can corrode rock through a process called hydrothermal alteration, 00:04:04.568 --> 00:04:08.448 gradually turning hard stone into soft clay. 00:04:08.448 --> 00:04:12.088 The rock layer could also be weakened by tectonic activity. 00:04:12.088 --> 00:04:16.777 Earthquakes can create fissures allowing magma to escape to the surface, 00:04:16.777 --> 00:04:19.789 and the Earth’s crust can be stretched thin 00:04:19.789 --> 00:04:23.267 as continental plates shift away from each other. NOTE Paragraph 00:04:23.267 --> 00:04:26.217 Unfortunately, knowing what causes eruptions 00:04:26.217 --> 00:04:28.617 doesn’t make them easy to predict. 00:04:28.617 --> 00:04:31.837 While scientists can roughly determine the strength and weight 00:04:31.837 --> 00:04:33.227 of the Earth’s crust, 00:04:33.227 --> 00:04:37.007 the depth and heat of magma chambers makes measuring changes 00:04:37.007 --> 00:04:40.387 in magmastatic pressure very difficult. 00:04:40.387 --> 00:04:44.297 But volcanologists are constantly exploring new technology 00:04:44.297 --> 00:04:46.844 to conquer this rocky terrain. 00:04:46.844 --> 00:04:49.749 Advances in thermal imaging have allowed scientists 00:04:49.749 --> 00:04:52.409 to detect subterranean hotspots. 00:04:52.409 --> 00:04:55.839 Spectrometers can analyze gases escaping magma. 00:04:55.839 --> 00:05:02.103 And lasers can precisely track the impact of rising magma on a volcano’s shape. 00:05:02.103 --> 00:05:06.595 Hopefully, these tools will help us better understand these volatile vents 00:05:06.595 --> 00:05:08.801 and their explosive eruptions.