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Volcanoes Volcanoes form from sources of magma inside the earth. The main sources of magma are: - Subduction at convergent plate boundaries. - Sea floor spreading at divergent plate boundaries. - Hot spots. Location of Volcanic Activity Active volcanoes are located in one of three plate tectonic settings: 1. Subduction zones at convergent plate boundaries, where the plate sinking into the mantle melts and creates magma. 2. Rifting and sea floor spreading at divergent plate boundaries, where the separation of the plates corresponds to magma rising up from the mantle. 3. Hot spots: places where tectonic plates move over stationary point sources of magma from the mantle. Map of the world’s active volcanoes, showing that the majority of active volcanoes (about 66%) occur in the Pacific Ring of Fire. Volcanic Features Volcanoes take several different forms, or shapes. The five most common are: - shield volcanoes - stratovolcanoes - calderas - lava domes - cinder cones Shield volcanoes are very large, with gently sloping sides and a convex shape. They form from relatively quiet eruptions of magma. Shield volcanoes are found at oceanic hot spots (like the Hawaiian Islands) and places where mid-ocean ridges stick up above sea level (the country of Iceland). The Big Island of Hawaii, the largest volcano on earth, is an active shield volcano. The magma erupting in Hawaii doesn’t obey road signs, but these eruptions are fairly gentle and quiet. They may cause property damage, but rarely fatalities. Stratovolcanoes are high and steep-sided. Unlike shield volcanoes, they form from violent eruptions of magma. Stratovolcanoes are found at almost all convergent plate boundaries, where subduction makes viscous and gas-rich magma. Volcanic Explosivity The violence of a volcano’s eruption is expressed by the Volcanic Explosivity Index (VEI). Values for the VEI range from 0 to 8, and are based on three criteria: • the volume of material (lava and particles) erupted • the height of the eruption column • how long the eruption lasts The larger the VEI value, the larger the eruption. The violence and explosiveness of a volcanic eruption depends on: The amount of time since the last eruption, The magma’s viscosity The magma’s gas content. The longer a volcano has been dormant, the more violently it may erupt in the future. Viscosity is a measure of how easily a liquid will flow. Magma with just a little bit of gas in it flows out of a volcano as relatively quiet lava. Magma with a lot of gas will blow the volcano apart violently. The higher the gas content, the more violent the eruption. Viscosity and gas content of magma depend on where on a tectonic plate the volcano is located: Divergent boundaries (mid-ocean ridges) and hot spots both have magmas from the upper mantle. This magma is called MAFIC MAGMA and it is generally gentle. In contrast, the magma at convergent boundaries comes from melting of subducted oceanic plates. This magma is called FELSIC MAGMA. This magma has a lot of gas and water in it. Felsic magma often erupts with great violence (the eruptions have high VEI). The world’s most dangerous volcanoes are those at convergent plate boundaries! VOLCANIC HAZARDS Be careful where you park your car in Hawaii! VOLCANIC HAZARDS Stratovolcanoes have the worst volcanic hazards. The only significant hazard associated with shield volcanoes is destruction by flowing lava, and occasionally gas emissions. The Main Volcanic HAZARDS Pyroclastic flows -Lahars -Lava flows -Ash falls -Gases -Tsunamis By far the two most dangerous hazards in terms of loss of life are pyroclastic flows and lahars. Pyroclastic flows are fluid mixtures of hot rock particles and hot gas that are denser than air. They boil out from the top of the volcano and travel at great speed down the flanks. Pyroclastic flows can attain speeds of over 100 miles per hour, and can travel for 10’s of miles across the countryside, burning, burying and suffocating everything in their path. The eruption of Mount Saint Helens in 1980 produced a devastating pyroclastic flow, seen here blasting out to the left (north). The eruption was so violent that the entire top of the mountain was blown off. This flow killed people within several miles of the mountain. The Mount Saint Helens pyroclastic flow knocked down vast acres of forest, stripping the bark entirely off trees. Many of the trees you see here were 2 or more feet in diameter. They were broken like you would break a toothpick. Before After Just to put the size of the Mount Saint Helens eruption in perspective, this figure compares the size of that eruption (as measured by the volume of ejected material) to some bigger ones in the past. Notice how small Mt. St. Helens was compared to the others!! Lahars are fast-moving mud flows. Two things together make a lahar: Thick, loose deposits of volcanic ash and water. The water can come in several ways: - A major rainstorm dumps water on the volcano. - An eruption melts large amounts of snow and ice on the flanks of the volcano. Lahars are more dangerous than pyroclastic flows because they are more common, and they can occur at any time (not just during an eruption). Omaya Sanchez - Lahar Victim - 13 years old © Frank Fournier Lava flows burn and destroy whatever they overrun. This hazard relates mostly to property damage, not fatalities. Lava flows are not life threatening if you keep your distance! Ash falls can cover vast areas of landscape. The ash is like a very fine power. It causes problems for breathing and operation of engines. When wetted by rain the ash creates messy, muddy conditions and potential landslides. The photo shows an interesting problem caused by the weight of ash on the tail of a DC-10. Gases emitted during volcanic eruptions may be toxic and/or corrosive. However the most common hazardous gas is CO2, which is neither toxic nor corrosive. When present in large quantities, CO2 can cause suffocation by driving away oxygen! Lake Nyos / Cameroon Deadliest Volcanic Eruptions Deaths Volcano When Major Cause of Death 92,000 Tambora, Indonesia 1815 Starvation 36,417 Krakatau, Indonesia 1883 Tsunami 29,025 Mt. Pelee, Martinique 1902 Ash flows 25,000 Ruiz, Colombia 1985 Mudflows 14,300 Unzen, Japan 1792 Volcano collapse, tsunami 9,350 Laki, Iceland 1783 Starvation 5,110 Kelut, Indonesia 1919 Mudflows 4,011 Galunggung, Indonesia 1882 Mudflows 3,500 Vesuvius, Italy 1631 Mudflows, lava flows 3,360 Vesuvius, Italy 79 Ash flows and falls 2,957 Papandayan, Indonesia 1772 Ash flows 2,942 Lamington, Papua N.G. 1951 Ash flows 2,000 El Chichon, Mexico 1982 Ash flows 1,680 Soufriere, St Vincent 1902 Ash flows 1,475 Oshima, Japan 1741 Tsunami 1,377 Asama, Japan 1783 Ash flows, mudflows 1,335 Taal, Philippines 1911 Ash flows 1,200 Mayon, Philippines 1814 Mudflows 1,184 Agung, Indonesia 1963 Ash flows 1,000 Cotopaxi, Ecuador 1877 Mudflows 800 Pinatubo, Philippines 1991 Roof collapses and disease 700 Komagatake, Japan 1640 Tsunami 700 Ruiz, Colombia 1845 Mudflows 500 Hibok-Hibok, Philippines 1951 Ash flows 1000s Santorini, Greece 1650 BC Ash flows, tsunami? Pahoehoe lava flow from Kilauea destroying houses Pyroclastic Flows Pyroclastic flows descend the south-eastern flank of Mayon Volcano, Philippines during its 1984 eruption. Photograph by C.G. Newhall Photocredit USGS http://www.usgs.gov/ Hawai’I Volcano National Park http://www.nps.gov/havo/ Content: Margaret Egger http://www.miracosta.edu/home/MEggers/