{"id":193,"date":"2020-03-05T17:04:02","date_gmt":"2020-03-05T22:04:02","guid":{"rendered":"https:\/\/pressbooks.bccampus.ca\/earthsystems\/?post_type=chapter&p=193"},"modified":"2020-11-05T15:33:26","modified_gmt":"2020-11-05T20:33:26","slug":"chapter-10","status":"publish","type":"chapter","link":"https:\/\/pressbooks.bccampus.ca\/earthsystems\/chapter\/chapter-10\/","title":{"raw":"Chapter 13","rendered":"Chapter 13"},"content":{"raw":"

Topic 12 \u2013 Recycling Rocks<\/strong><\/span><\/p>\r\n\"This planet is essentially a body of crystallized and uncrystallized igneous material. The final philosophy of earth history will therefore be founded on igneous-rock geology.\" - Reginald Aldworth Daly, 1914.\r\n\r\nVolcanic eruptions are one of the most destructive of all natural hazards. Yet within this destructive potential, we see a significant connection between Earth\u2019s lithosphere and atmosphere. \"AnChemicals are released, ash and dust are dispersed to high levels, sometimes reaching the stratosphere. Perhaps most importantly, new rocks are solidified from liquid rock as its delivered to the surface. Underground, liquid rock is called magma<\/strong> and at the surface it is referred to as [pb_glossary id=\"327\"]lava[\/pb_glossary]<\/strong>. Rocks formed directly from cooled liquid rock are called [pb_glossary id=\"330\"]Igneous[\/pb_glossary]<\/strong><\/em> rocks, and represent a significant portion of the rock cycle. Where these rocks form from rapidly cooling at or near the surface, they are called [pb_glossary id=\"329\"]extrusive[\/pb_glossary]<\/strong> igneous rocks. Where they cool deep underground they are referred to as [pb_glossary id=\"328\"]intrusive[\/pb_glossary]<\/strong> igneous rocks. The slower cooling possible in the underground environment generally allows the mineral crystals within intrusive rocks to grow larger than an extrusive rock with the same mineral content.\r\n\r\n[caption id=\"attachment_195\" align=\"alignleft\" width=\"350\"]\"A How the mineral make up in igneous rocks reflects magma composition[\/caption]\r\n\r\nVolcanic activity occurs when liquid rock makes its way to the Earth\u2019s surface. Much like air masses in the atmosphere, liquid rock moves through Earth\u2019s crust based on density differences with surrounding material. Warmer liquid rock is less dense than the surrounding, cooler crust and as a result tends to rise towards the surface, melting through overlying rocks as it goes. The melting rock mixes with the existing magma and affects the chemistry of the mix, resulting in a unique chemical signature for each centre of volcanic activity. While rising through the lithospheric crust, intense pressure keeps volatile gases dissolved within the magma. When the magma reaches the surface, this pressure is removed and the gases are rapidly released in an explosive eruption. The violence of this explosion is associated with the chemistry of the magma and how easily it flows ([pb_glossary id=\"331\"]viscosity<\/strong>[\/pb_glossary]). Generally, magma with higher [pb_glossary id=\"332\"]silica[\/pb_glossary]<\/strong> content is higher viscosity (high resistance to flow). Magma with lower silica content is lower viscosity (low resistance to flow).\r\n\r\n \r\n\r\n\"A\r\n\r\nAccording to the diagram above, basalt has a low silica content and low viscosity. Basaltic lava is often found in association with volcanic eruptions with low explosivity (effusive eruptions), like those in Hawaii and Iceland. Rhyolite has a high silica content and high viscosity. Rhyolitic rock is often found in incredibly high explosive eruptions like the volcanic centre that underlies Yellowstone volcanic field. In between, andesitic and dacitic volcanoes (like Mount St. Helens in Washington) have explosive behaviour but on a smaller scale.\r\n\r\nMagmatic chemistry affects the type of eruption at a volcanic centre and, as a result, the type of landforms generated:\r\n\r\n\"\"\r\n\r\nThere are many other volcanic landforms that you can explore, and a good summary exists here:\r\n\r\nhttps:\/\/opentextbc.ca\/geology\/chapter\/4-3-types-of-volcanoes\/\r\n\r\nVolcanic activity plays a critical role in the rock cycle, moving magma to the surface where it can solidify and form new rock. It functions in many other critical zone cycles, including mineral cycles like the Phosphorus Cycle, and the Sulphur Cycle, supplying significant nutrients necessary for soil development and plant growth.","rendered":"

Topic 12 \u2013 Recycling Rocks<\/strong><\/span><\/p>\n

“This planet is essentially a body of crystallized and uncrystallized igneous material. The final philosophy of earth history will therefore be founded on igneous-rock geology.” – Reginald Aldworth Daly, 1914.<\/p>\n

Volcanic eruptions are one of the most destructive of all natural hazards. Yet within this destructive potential, we see a significant connection between Earth\u2019s lithosphere and atmosphere. \"AnChemicals are released, ash and dust are dispersed to high levels, sometimes reaching the stratosphere. Perhaps most importantly, new rocks are solidified from liquid rock as its delivered to the surface. Underground, liquid rock is called magma<\/strong> and at the surface it is referred to as lava<\/a><\/strong>. Rocks formed directly from cooled liquid rock are called Igneous<\/a><\/strong><\/em> rocks, and represent a significant portion of the rock cycle. Where these rocks form from rapidly cooling at or near the surface, they are called extrusive<\/a><\/strong> igneous rocks. Where they cool deep underground they are referred to as intrusive<\/a><\/strong> igneous rocks. The slower cooling possible in the underground environment generally allows the mineral crystals within intrusive rocks to grow larger than an extrusive rock with the same mineral content.<\/p>\n

\"A
How the mineral make up in igneous rocks reflects magma composition<\/figcaption><\/figure>\n

Volcanic activity occurs when liquid rock makes its way to the Earth\u2019s surface. Much like air masses in the atmosphere, liquid rock moves through Earth\u2019s crust based on density differences with surrounding material. Warmer liquid rock is less dense than the surrounding, cooler crust and as a result tends to rise towards the surface, melting through overlying rocks as it goes. The melting rock mixes with the existing magma and affects the chemistry of the mix, resulting in a unique chemical signature for each centre of volcanic activity. While rising through the lithospheric crust, intense pressure keeps volatile gases dissolved within the magma. When the magma reaches the surface, this pressure is removed and the gases are rapidly released in an explosive eruption. The violence of this explosion is associated with the chemistry of the magma and how easily it flows (viscosity<\/strong><\/a>). Generally, magma with higher silica<\/a><\/strong> content is higher viscosity (high resistance to flow). Magma with lower silica content is lower viscosity (low resistance to flow).<\/p>\n

 <\/p>\n

\"A<\/p>\n

According to the diagram above, basalt has a low silica content and low viscosity. Basaltic lava is often found in association with volcanic eruptions with low explosivity (effusive eruptions), like those in Hawaii and Iceland. Rhyolite has a high silica content and high viscosity. Rhyolitic rock is often found in incredibly high explosive eruptions like the volcanic centre that underlies Yellowstone volcanic field. In between, andesitic and dacitic volcanoes (like Mount St. Helens in Washington) have explosive behaviour but on a smaller scale.<\/p>\n

Magmatic chemistry affects the type of eruption at a volcanic centre and, as a result, the type of landforms generated:<\/p>\n

\"\"<\/p>\n

There are many other volcanic landforms that you can explore, and a good summary exists here:<\/p>\n

4.3 Types of Volcanoes<\/a><\/p><\/blockquote>\n