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PH307 Disasters: Volcanos Dr. Dirk Froebrich. This presentation can be found at: http://astro.kent.ac.uk/~df/teaching/ph307/disasters_volcanos.ppt. Volcanos. Kílauea, Hawai‘i. Mauna Kea, Hawai‘i.
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PH307 Disasters: Volcanos Dr. Dirk Froebrich This presentation can be found at: http://astro.kent.ac.uk/~df/teaching/ph307/disasters_volcanos.ppt
Mauna Kea, Hawai‘i ... The summit appears utterly lifeless except for a few unlucky bugs blown up from below and a few flightless native insects that feed on them. No trees, no plants. Just lifeless void. The mountain last erupted 4500years ago and is considered dormant. (If it erupts when you are up there, please disregard this last statement.) 4205m
Outline causes of volcanism types of volcanos types of eruptions methods of predicting eruptions dangers, effects and how to minimise damage/loss of life Seminar
Volcano Types (by position) mid ocean ridges usually at sea floor, but e.g. Iceland subduction zones e.g. Mt. Etna, the Ring of Fire Hotspots/Plumes e.g. Hawai‘i, Eifel, Auvergne
Volcano Types (by shape) Shield Volcanos - huge quantities of basaltic lava gradually build up wide shield like mountain - hot fluid lava flows - e.g. Hawai‘i
Shield Volcanos Skjaldbreidur Mt. Edziza Olympus Mons (Mars) Mauna Loa
Volcano Types (by shape) Shield Volcanos - huge quantities of basaltic lava gradually build up wide shield like mountain - hot fluid lava flows - e.g. Hawai‘i Strato Volcanos - strata – internally consistent layer of rock - tall conical mountain build up by a sequence of lava flows and ejecta - e.g. Mt. Fuji, Vesuvius, Stromboli, Popocatépetl, Mt. St. Helens
Strato Volcanos Mt. Fuji Stromboli Mt. St. Helens Popocatépetl
Volcano Types (by shape) Shield Volcanos - huge quantities of basaltic lava gradually build up wide shield like mountain - hot fluid lava flows - e.g. Hawai‘i Strato Volcanos - strata – internally consistent layer of rock - tall conical mountain build up by a sequence of lava flows and ejecta - e.g. Mt. Fuji, Vesuvius, Stromboli, Popocatépetl, Mt. St. Helens Cinder Cones - small (30-400m high), build up around vents - can be on flanks of other volcanos or isolated Submarine & Subglacial Volcanos Supervolcanos - large calderas - eruptions on enourmous scales
Supervolcanos Mt. Aso Campi Flegrei Lake Taupo Yellowstone Caldera
Eruption Types Subglacial Strombolian Vulcanian Peléan Hawai‘ian Phreatic Plinian
Subglacial Eruption - under ice or glacier - risk of floods, lahars - rare type (only 5 active) - e.g. Iceland Subglacial eruption: 1 water vapor cloud, 2 lake, 3 ice, 4 pillow lava, 5 magma conduit, 6 magma chamber
Strombolian Eruption - named after Mt. Stromboli - low level eruptions - ejection of cinder and lava bombs between 10 and a few 100m - viscous lava flows - gas bubbles (slugs) rise through magma and burst near the top - slugs form deep (~3km) and are hence difficult to predict - long lasting eruptions (up to decades)
Vulcanian Eruption - named after Vulcano Island - rising magma makes contact with ground or surface water - extreme temperatures result in near instantaneous evaporation to steam explosion - dangers from exploding steam, water, ash, rock, volcanic bombs Vulcanian eruption: 1 Ash plume, 2 Lapilli, 3 Volcanic ash rain, 4 Lava fountain, 5 Volcanic bomb, 6 Lava flow, 7 Sill, 8 Magma conduit, 9 Magma chamber, 0 Dike
Peléan Eruption Mt. Mayon - named after Mt. Pelée - glowing cloud eruption - huge amounts of gas, dust, ash, lava fragments are blown out of a crater - fall back avalanche down with 100mph (pyroclastic flows) Pelean eruption: 1 Ash plume, 2 Volcanic ash rain, 3 Lava dome, 4 Volcanic bomb, 5 Pyroclastic flow, 6 Magma conduit, 7 Magma chamber, 8 Dike
Hawai‘ian Eruption - named after eruptions in Hawai‘i - occur along fissures, (central) vents - gentle, low level eruptions, lava fountains up to 600m high, - low viscosity lava - safest eruptions for tourism Hawaiian eruption: 1 Ash plume, 2 Lava fountain, 3 Crater, 4 Lava lake, 5 Fumaroles, 6 Lava flow, 7 Sill, 8 Magma conduit, 9 Magma chamber, 0 Dike
Phreatic Eruption - steam blast eruption - explosive expanding steam from ground or surface water - only pre-existing solid rock, no new magma is ejected - danger from steam, rock fragments, poisonous gases, asphyxiation - e.g. Mt. St. Helens before big eruption in 1980 Mt. St. Helens
Plinian Eruption - named after eruption of Vesuvius observed by Pliny the Younger - most powerful eruption type - explosive ejection of viscous lava - 10s of miles into the air (stratosphere) - 100s of miles fallout area - pyroclastic flows - large amounts of lava caldera forming - e.g. Krakatoa, St. Helens, Pinatubo Pinatubo
Predictions of Eruptions very difficult complex systems, highly non-linear every volcano is different significant progress in recent decades mostly by continued extensive monitoring can in many cases predict imminent (~days) eruptions combinations of different methods used
Methods for Predictions Seismic (earthquakes, tremors): short-period earthquakes like normal fault generated earthquakes indicate moving lava long-period earthquakes indicate increased gas pressure harmonic tremors indicate magma pushing on overlying rock increasing seismic activity increasing probability of eruption but complex behaviour
Methods for Predictions Gas Emissions: Magma rises gas escapes amount and chemical composition monitored e.g. increase in escaping gas volume observed before Pinatubo eruption e.g. decrease of escaping gas volume sealing of gas passages increase in pressure higher eruption risk
Methods for Predictions Ground deformation: moving magma changes pressure inside the mountain change in the slopes on the outside measured e.g. with tiltmeters (laser) Thermal Monitoring: IR maps to observe changes in surface temperature on-side detectors or satellite based Many major volcanos are monitored extensively to predict eruptions. These are volcanos in populated areas and potentially very dangerous ones (Yellowstone).
Effects/Dangers Local (a few 10s of km‘s): explosions pyroclastic flows lava lahars gases (CO2, H2S, SO2) earthquakes
Effects/Dangers larger scales (10s to 1000s of km‘s): acid rain (covered earlier in course) SO2 H2SO4 tsunamies (covered later in course) ash-fallout global scales: volcanic winter, drop in temperatures due to change in albedo of Earth‘s atmosphere crop failure, hunger, conflicts .....
Effects/Dangers - Examples on average all volcanos on Earth eject 1.3-2.3*1011kg CO2/yr all human emissions add up to about 2.5*1013kg/yr Mt. Pinatubo eruption (15.6.1991) >490 years after last known eruptive activity 2nd largest eruption in 20th century 1013kg of magma ejected up to 34km high 2*1010kg SO2 ejected coincided with typhoon Yunga Lahars ash cloud 125000km2 10 times bigger eruption than Mt.St.Helens on 18.5.1980 ~800 people died, mostly due to roofs collapsing
Effects/Dangers - Examples Supervolcanos: huge off-scale earthquakes tsunamies up to several 1000km3 ejecta! immediate continent scale devastation mass extinction!!! next one due? Yellowstone
Topics to Discuss in Seminar How to prevent danger for a large number of people in the first place? How to react in case of an imminent eruption? don‘t panic How to react in case of an eruption? run