Book contents
- The High-Mountain CryosphereEnvironmental Changes and Human Risks
- The High-Mountain Cryosphere
- Copyright page
- Contents
- Contributors
- Book part
- 1 Introduction
- Part I Global drivers
- Part II Processes
- Part III Consequences and responses
- 14 The honour of the snow-mountains is the snow
- 15 Ice-clad volcanoes
- 16 Debris-flow activity from high-elevation, periglacial environments
- 17 Contextualizing conflict
- Part IV Conclusions
- Index
- References
15 - Ice-clad volcanoes
from Part III - Consequences and responses
Published online by Cambridge University Press: 05 September 2015
Book contents
- The High-Mountain CryosphereEnvironmental Changes and Human Risks
- The High-Mountain Cryosphere
- Copyright page
- Contents
- Contributors
- Book part
- 1 Introduction
- Part I Global drivers
- Part II Processes
- Part III Consequences and responses
- 14 The honour of the snow-mountains is the snow
- 15 Ice-clad volcanoes
- 16 Debris-flow activity from high-elevation, periglacial environments
- 17 Contextualizing conflict
- Part IV Conclusions
- Index
- References
Summary
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- Type
- Chapter
- Information
- The High-Mountain CryosphereEnvironmental Changes and Human Risks, pp. 272 - 294Publisher: Cambridge University PressPrint publication year: 2015
References
Wolf, T, Geognostische Mitteilungen aus Ecuador; Der Cotopaxi und seine letzte Eruption am 26 Juni 1877. Neues Jahrbuch für Mineralogie, Geologie, und Palaeontologie, 1878 (1878), 113–167. [Authors used unpublished translation to English by Jane Crandell, 1976].Google Scholar
Hall, M, Mothes, P, The rhyolitic–andesitic eruptive history of Cotopaxi volcano, Ecuador. Bulletin of Volcanology, 70 (2008), 675–702.CrossRefGoogle Scholar
Pistolesi, M, Cioni, R, Rosi, M, Cashman, KV, Rossotti, A, Aguilera, E, Evidence for lahar-triggering mechanisms in complex stratigraphic sequences: the post-twelfth century eruptive activity of Cotopaxi volcano, Ecuador. Bulletin of Volcanology, 75 (2013), 698. doi: 10.1007/s00445-013-0698-1.CrossRefGoogle Scholar
Thordarson, T, Larsen, G, Volcanism in Iceland in historical time: volcano types, eruption styles, and eruptive history. Journal of Geodynamics, 43 (2007), 118–152.CrossRefGoogle Scholar
Perret, FA, The Eruption of Mt. Pelée 1929–1932 (Washington, DC: Carnegie Institution of Washington, 1935).Google Scholar
Moore, JG, Base surge in recent volcanic eruptions. Bullein Volcanologique, 30 (1967), 337–363.CrossRefGoogle Scholar
Thórarinsson, S, Course of events. In The Eruption of Hekla 1947–1948, ed. Einarsson, T, Kjartansson, G, Thórarinsson, S (Reykjavík: Visindafélag Islendinga [Societas Scientiarum Islandica], 1976).Google Scholar
Waitt, RB, Pierson, TC, MacLeod, NS, Janda, RJ, Voight, B, Holcomb, RT, Eruption-triggered avalanche, flood, and lahar at Mount St. Helens: effects of winter snowpack. Science, 221 (1983), 1394–1397.CrossRefGoogle ScholarPubMed
Iverson, RM, Debris flows: behavior and hazard assessment. Geology Today, 30, 1 (2014), 15–20.CrossRefGoogle Scholar
Waitt, RB, Swift snowmelt and floods (lahars) caused by great pyroclastic surge at Mount St. Helens, Washington, 18 May 1980. Bulletin of Volcanology, 52 (1989), 138–157.CrossRefGoogle Scholar
Pierson, TC, Janda, RJ, Thouret, J-C, Borrero, CA, Perturbation and melting of snow and ice by the 13 November 1985 eruption of Nevado del Ruiz, Colombia, and consequent mobilization, flow and deposition of lahars. Journal of Volcanology and Geothermal Research, 41 (1990), 17–66.CrossRefGoogle Scholar
Waitt, RB, Gardner, CA, Pierson, TC, Major, JJ, Neal, CA, Unusual ice diamicts emplaced during 15 December 1989 eruption of Redoubt Volcano, Alaska. Journal of Volcanology and Geothermal Research, 62 (1994), 409–428.CrossRefGoogle Scholar
Waythomas, CF, Pierson, TC, Major, JJ, Scott, WE, Voluminous ice-rich and water-rich lahars generated during the 2009 eruption of Redoubt Volcano, Alaska. Journal of Volcanology and Geothermal Research, 239 (2013), 389–413.CrossRefGoogle Scholar
Cronin, SJ, Neall, VE, Lecointre, JA, Palmer, AS, Unusual “snow slurry” lahars from Ruapehu volcano, New Zealand, September 1995. Geology, 24 (1996), 1107–1110.2.3.CO;2>CrossRefGoogle Scholar
Kilgour, G, Manville, V, Della Pasqua, F, Graettinger, A, Hodgson, KA, Jolly, GE, The 25 September eruption of Mount Ruapehu, New Zealand: directed ballistics, surtsean jets, and ice-slurry lahars. Journal of Volcanology and Geothermal Research, 191 (2010), 1–14.CrossRefGoogle Scholar
Major, JJ, Newhall, CG, Snow and ice perturbations during historic volcanic eruptions and the formation of lahars and floods: a global review. Bulletin of Volcanololgy, 52 (1989), 1–27.CrossRefGoogle Scholar
Siebe, C, Abrams, M, Luis Macias, J, Obenholzner, J, Repeated volcanic disasters in prehispanic time at Popocatépetl, central Mexico: past key to the future?. Geology, 24 (1996), 399–402.2.3.CO;2>CrossRefGoogle Scholar
Crandell, DR, Postglacial Lahars from Mount Rainier Volcano, (Washington, DC: US Geological Survey, 1971).Google Scholar
Scott, KM, Magnitude and Frequency of Lahars and Lahar-Runout Flows in the Toutle-Cowlitz River System. (Washington, DC: US Geological Survey, 1989).CrossRefGoogle Scholar
Sisson, TW, Vallance, JW, Frequent eruptions at Mount Rainier over the last 2,600 years. Bulletin of Volcanology, 71 (2009), 595–618.CrossRefGoogle Scholar
Thórarinsson, S, Einarsson, Th, Sigvaldasson, G, Elisson, G, The submarine eruption off the Vestmann Islands 1963–64: a preliminary report. Bulletin Volcanologique, 27 (1964) 435–445.CrossRefGoogle Scholar
Thórarinsson, S, The Öræfajökull Eruption of 1362. Acta Naturalia Islandica, 2 (1958).Google Scholar
Grönvold, K, Jóhannesson, H, Eruption of Grímsvötn 1983. Jökull, 34 (1984), 1–11.CrossRefGoogle Scholar
Björnsson, H, Hydrology of Ice Caps in Volcanic Regions (Reykjavík: Vísingdafélag Íslendinga, 1988).Google Scholar
Siebert, L, Simkin, T, Kimberly, P, Volcanoes of the World (3rd edition) (Berkeley, CA: University of California Press, 2010).Google Scholar
Thórarinsson, S, Some new aspects of the Grímsvötn problem. Journal of Glaciology, 14 (1953), 267–274.CrossRefGoogle Scholar
Björnsson, H, Subglacial lakes and jökulhlaups in Iceland. Global and Planetary Change, 35 (2002), 255–271.CrossRefGoogle Scholar
Guðmundsson, MT, Björnsson, H, Eruptions in Grímsvötn,Vatnajökull, Iceland 1934–1991. Jökull, 41 (1991), 21–45.CrossRefGoogle Scholar
Guðmundsson, MT, Sigmundsson, F, Björnsson, H, Högnadóttir, T, The 1996 eruption at Gjálp, Vatnajökull ice cap, Iceland: efficiency of heat transfer, ice deformation and subglacial water pressure. Bulletin of Volcanology, 66 (2004), 46–65.CrossRefGoogle Scholar
Waitt, RB, Great Holocene floods along Jökulsá á Fjöllum, north Iceland. In Flood and Megaflood Processes, Recent and Ancient Examples, ed. Martini, IP, Baker, VR, Garzón, G. (Oxford, MA: Blackwell Science, 2002), pp. 37–52.CrossRefGoogle Scholar
Larsen, G, Guðmundsson, MT, Björnsson, H, Eight centuries of periodic volcanism at the center of the Iceland hotspot revealed by glacier tephrostratigraphy. Geology, 26 (1998), 943–946.2.3.CO;2>CrossRefGoogle Scholar
Óladóttir, BA, Larsen, G, Sigmarsson, O, Holocene volcanic activity at Grímsvötn, Bárdarbunga and Kverkfjöll subglacial centers beneath Vatnajökull, Iceland. Bulletin of Volcanology, 73 (2011), 1187–1208.CrossRefGoogle Scholar
Thórarinsson, S, The jökulhlaup from the Katla area in 1955 compared with other jökulhlaups in Iceland. Jökull, 7 (1957), 21–25.CrossRefGoogle Scholar
Tómasson, H, The jökulhlaup from Katla in 1918. Annals of Glaciology, 22 (1996), 249–254.CrossRefGoogle Scholar
Jónsson, J, Notes on the Katla volcanoglacial debris flows. Jökull, 32 (1982), 61–68.CrossRefGoogle Scholar
Maizels, J, Lithofacies variations within sandur deposits: the role of runoff regime, flow dynamics, and sediment supply characteristics. Sedimentary Geology, 85 (1993), 299–325.CrossRefGoogle Scholar
Björnsson, H, Pálsson, F, Guðmundsson, MT, Surface and bedrock topography of the Mýrdalsjökull ice cap, Iceland: the Katla caldera sites and routes of jökulhlaups. Jökull, 49 (2001), 29–46.CrossRefGoogle Scholar
Magnússon, E, Guðmundsson, MT, Roberts, MJ, Sigurðsson, G, Hökuldsson, F, Oddson, FB, Ice–volcano interactions during the 2010 Eyjafjallajökull eruption, as revealed by airborne imaging radar. Journal of Geophysical Research, 117 (2012), B07405. doi: 10.1029/2012/JB009250, 2012.CrossRefGoogle Scholar
Smellie, JL, The 1969 subglacial eruption on Deception Island (Antarctica): events and processes during an eruption beneath a thin glacier and implications for volcanic hazards. In Volcano-Ice Interaction on Earth and Mars, ed. Smellie, JL, Chapman, MG (London: Geological Society of London, 2002), pp. 59–79.Google Scholar
Edwards, BR, Gudmundsson, MT, Thordarson, T, et al., Interactions between lava and snow/ice during the 2010 Fimmvorduhals eruption, south-central Iceland. Journal of Geophysical Research, 117 (2012), B04302. doi: 10.1029/2011JB008985.CrossRefGoogle Scholar
Naranjo, JA, Moreno, HR, Laharic debris-flows from Villarica Volcano. Boletín – Servicio Nacional de Geología y Minería, 61 (2004), 28–38.Google Scholar
Moreno, HR, Fuentealba, GC, The May 17–19 1994 Llaima volcano eruption, southern Andes (38°42'S–71°44'W). Andean Geology (Revista geológia de Chile), 21 (1994), 167–171.Google Scholar
Ozerov, AY, Karpov, GA, Droznin, VA, et al., The September 7 – October 2, 1994 eruption of Klyuchevskoi volcano. Kamchatka, Volcanology and Seismology, 18 (1997) 501–516.Google Scholar
Yount, ME, Miller, TP, Emanuel, RP, Wilson, FH, Eruption in the ice-filled caldera of Mount Veniaminof. US Geological Survey Circular, 945 (1985), 58–60.Google Scholar
Belousov, A, Behncke, B, Belousova, M, Generation of pyroclastic flows by explosive interaction of lava flows with ice/water-saturated substrate. Journal of Volcanology and Geothermal Research, 202 (2011), 60–72.CrossRefGoogle Scholar
Edwards, BR, Karson, J, Wysocki, B, Lev, E, Bindeman, I, Kueppers, U, Insights on lava–ice/snow interactions from large-scale basaltic melt experiments. Geology, 41 (2013), 851–854. doi:10.1130/G34305.1.CrossRefGoogle Scholar
Mathews, WH, The Table, a flat-topped volcano in southern British Columbia. American Journal of Science, 249 (1951), 830–841.CrossRefGoogle Scholar
Porter, SC, Pleistocene subglacial eruptions on Mauna Kea. In Volcanism in Hawaii, ed. Decker, RW, Wright, TL, Stauffer, PH (Washington, DC: US Geological Survey, 1987), pp. 587–598.Google Scholar
Lescinsky, DT, Fink, JH, Lava and ice interaction at stratovolcanoes: use of characteristic features to determine past glacial extents and future volcanic hazards. Journal of Geophysical Research, 105 (2000), 23711–23726. doi:10.1029/2000JB900214.CrossRefGoogle Scholar
Mathews, WH, Ice-dammed lavas from Clinker Mountain, southwestern British Columbia. American Journal of Science, 250 (1952), 553–565.CrossRefGoogle Scholar
Jones, JG, Intraglacial volcanoes of the Laugarvatn region, south-west Iceland, I. Quarterly Journal of the Geological Society of London, 124 (1968), 197–211.CrossRefGoogle Scholar
Kokelaar, P, Magma–water interactions in subaqueous and emergent basaltic volcanism. Bulletin of Volcanology, 48 (1986), 275–289.CrossRefGoogle Scholar
Werner, R, Schmincke, H-U, Sigvaldasson, G, A new model for the evolution of table mountains: volcanological and petrological evidence from Herdubreid and Herdubreidatögl volcanoes (Iceland). Geologische Rundschau, 85 (1996), 390–397.CrossRefGoogle Scholar
Edwards, BR, Russell, JK, Simpson, K, Volcanology and petrology of Mathews Tuya, northern British Columbia, Canada: glaciovolcanic constraints on interpretation of the 0.730 Ma Cordilleran paleoclimate. Bulletin of Volcanology, 73 (2011), 479–496.CrossRefGoogle Scholar
Wood, CA, Kienle, J, Volcanoes of North America, United States and Canada (Cambridge: Cambridge University Press, 1990).Google Scholar
Komatsu, G, Arzhannikov, SG, Arzhannikova, AV, Ershov, K, Geomorphology of subglacial volcanoes in the Azas Plateau, the Tuva Republic, Russia. Geomorphology, 88 (2007), 312–328.CrossRefGoogle Scholar
Lisiecki, LE, Raymo, ME, A Pliocene–Pleistocene stack of 57 globally distributed benthic δ18O records. Paleoceanography, 20 (2005). doi: 10.1029/2004PA001071Google Scholar
Hamilton, W, The Hallett Volcanic Province, Antarctica (Washington, DC: US Geological Survey, 1972).CrossRefGoogle Scholar
Smellie, JL, Hole, MJ, Nell, PAR, Late Miocene valley-confined subglacial volcanism in northern Alexander Island, Antarctic Peninsula. Bulletin of Volcanology, 55 (1993), 273–288.CrossRefGoogle Scholar
Smellie, JL, Johnson, JS, McIntosh, WC, et al., Six million years of glacial history recorded in volcanic lithofacies of the James Ross Island Volcanic Group, Antarctic Peninsula. Paleogeography, Paleoclimatology, Paleoecology, 260 (2008), 122–148.CrossRefGoogle Scholar
Kjartansson, G, Geological Map of Iceland, Sheet 5, Central Iceland (scale 1:250,000). (Reykjavík: Museum of Natural History Iceland, 1983).Google Scholar
Jóhannesson, H, Jakobsson, S, Sæmundsson, K, Geological Map of Iceland, Sheet 6, South Iceland (scale 1:250,000). (Reykjavík: Museum of Natural History, 1977).Google Scholar
Jakobsson, SP, Johnson, GI, Intraglacial volcanism in the Western Volcanic Zone, Iceland. Bulletin of Volcanology, 74 (2012), 1141–1160.CrossRefGoogle Scholar
Loughlin, SC, Facies analysis of proximal subglacial and proximal volcaniclastic successions at the Eyjafjalljökull central volcano, southern Iceland. In Volcano–Ice Interaction on Earth and Mars, ed. Smellie, JL, Chapman, MG (London: Geological Society of London, 2002), pp. 149–178.Google Scholar
Smellie, JL, Basaltic subglacial sheet-like sequences: evidence for two types with different implications for the inferred thickness of associated ice. Earth-Science Reviews, 88 (2008), 60–88.CrossRefGoogle Scholar
Huybers, P, Langmuir, C, Feedback between deglaciation, volcanism, and atmospheric CO2. Earth and Planetary Science Letters, 286 (2009), 479–491.CrossRefGoogle Scholar
Schmidt, P, Lund, B, Hieronymus, C, Maclennan, J, Arnadottir, T, Pagli, C, Effects of present-day deglaciation in Iceland on mantle melt production rates. Journal of Geophysical Research – Solid Earth, 118 (2013), 3366–3379.CrossRefGoogle Scholar
Ui, T, Yamamoto, H, Suzuki-Kamata, K, Characterization of debris avalanche deposits in Japan. Journal of Volcanology and Geothermal Research, 29 (1986), 231–243.CrossRefGoogle Scholar
Siebert, L, Glicken, H, Ui, T, Volcanic hazards from Bezymianny- and Bandai-type eruptions. Bulletin of Volcanology, 49 (1987), 435–459.CrossRefGoogle Scholar
Francis, P, Self, S, Collapsing volcanoes. Scientific American, 256 (1986), 90–97.CrossRefGoogle Scholar
Crandell, DR, Gigantic Debris Avalanche of Pleistocene Age from Ancestral Mount Shasta Volcano, California, and Debris-Avalanche Hazards Zonation (Washington, DC: US Geological Survey, 1989).Google Scholar
Paguican, RMR, van Wyk de Vries, B, Lagmay, A, Hummocks: how they form and how they evolve in rockslide-debris avalanches. Landslides, 11 (2014), 67–80.CrossRefGoogle Scholar
Vallance, JW, Scott, KM, The Osceola mudflow from Mount Rainier: sedimentology and hazard implications of a huge clay-rich debris flow. Geological Society of America Bulletin, 109 (1997), 143–163.2.3.CO;2>CrossRefGoogle Scholar
Vallance, JW, Volcanic debris flows. In Debris-Flow Hazards and Related Phenomena, ed. Jakob, M, Hungr, O. (Berlin: Springer-Praxis, 2005), pp. 247–274.CrossRefGoogle Scholar
Reid, ME, Sisson, TW, Brien, DI, Volcano collapse promoted by hydrothermal alteration and edifice shape, Mount Rainier, Washington. Geology, 29 (2001), 779–782.2.0.CO;2>CrossRefGoogle Scholar
Carrasco-Núñez, G, Siebert, L, Díaz-Castellón, R, Vázquez-Selem, L, Capra, L, Evolution and hazards of a long quiescent compound shield-like volcano: Cofre de Perote, eastern trans-Mexican volcanic belt. Journal of Volcanology and Geothermal Research, 197 (2010), 209–224.CrossRefGoogle Scholar
Meier, MF, Glaciers and water supply. Journal of the American Water Works Association, 61 (1969), 8–12.CrossRefGoogle Scholar
Mattson, LE, The influence of a debris cover on the mid-summer discharge of Dome Glacier, Canadian Rocky Mountains. International Association of Hydrological Sciences, 264 (2000), 25–34.Google Scholar
Jackson, KM, Fountain, AG, Spatial and morphological change on Eliot Glacier, Mount Hood, Oregon, USA. Annals of Glaciology 46 (2007), 222–226.CrossRefGoogle Scholar
Ginot, P, Schotterer, U, Stichler, W, Godoi, MM, Francou, B, Schwikowski, M, Influence of the Tungurahua eruption on the ice cores records of Chimborazo, Ecuador. The Cryosphere, 4 (2010), 561–568.CrossRefGoogle Scholar
Frank, D, Meier, MF, Swanson, DA, Assessment of Increased Thermal Activity at Mount Baker, Washington, March 1975 – March 1976 (Washington, DC: US Geological Survey, 1977).CrossRefGoogle Scholar
Imbrie, J, Berger, A, Boyle, EA, et al., On the structure and origin of major cycles, 2: the 100,000-year cycle. Paleoceanography, 8 (1993), 699–735.CrossRefGoogle Scholar
Ruddiman, WF, Plows, Plagues, and Petroleum: How Humans took Control of Nature (Princeton, NJ: Princeton University Press, 2005).Google Scholar
de Silva, SL, Zielinski, GA, Global influence of the AD 1600 eruption of Huaynaputina, Peru. Nature, 393 (1998), 455–458.CrossRefGoogle Scholar
Robock, A, Volcanic eruptions and climate. Reviews of Geophysics, 38 (2000), 191–219.CrossRefGoogle Scholar
Witter, JB, Self, S, The Kuwae (Vanuatu) eruption of AD 1452: potential magnitude and volatile release. Bulletin of Volcanology, 69 (2007), 301–318.CrossRefGoogle Scholar
Miller, GH, Giersdóttir, A, Zhong, Y, et al., Abrupt onset of the Little Ice Age triggered by volcanism and sustained by sea-ice/ocean feedbacks. Geophysical Research Letters, 39, 2 (2012), L02708. doi:10.1029/2011GL050168.CrossRefGoogle Scholar
Dyurgerov, MB, Meier, MF, Twentieth century climate change: evidence from small glaciers. Proceedings of the National Academy of Sciences USA, 97, (2000), 1406–1411.CrossRefGoogle ScholarPubMed
Yamaguchi, S, Naruse, R, Shiraiwa, T, Climate reconstruction since the Little Ice Age by modelling Koryto glacier, Kamchatka Peninsula, Russia. Journal of Glaciology, 54 (2008), 125–130.CrossRefGoogle Scholar
Ward, PD, Under a Green Sky: Global Warming, the Mass Extinctions of the Past and What They Can Tell Us about Our Future (New York: Harper Collins, 2007).Google Scholar
Kargel, J, Leonard, G, Wheate, R, Edwards, B, ASTER and SEM change assessment of changing glaciers near Hoodoo Mountain, British Columbia, Canada. In Global Land Ice Measurements from Space, eds. Kargel, J, Leonard, GJ, Bishop, MP, Kààp, A, Raup, BH (Berlin: Springer-Praxis, 2014) pp. 354–373.CrossRefGoogle Scholar
Sisson, TW, Robinson, JE, Swinney, DD, Whole-edifice ice volume change A.D. 1970 to 2007/2008 at Mount Rainier, Washington, based on LiDAR surveying. Geology, 39 (2011), 639–642.CrossRefGoogle Scholar
O'Connor, JE, Our vanishing glaciers: one hundred years of glacier retreat in the Three Sisters area, Oregon Cascade Range. Oregon Historical Quarterly, 114 (2013), 402–427.CrossRefGoogle Scholar
Granados, HD, The glaciers of Popocatépetl volcano (Mexico): changes and causes. Quaternary International, 43 (1997), 53–60.CrossRefGoogle Scholar
Rivera, A, Bown, F, Mella, R, et al., Ice volumetric changes on active volcanoes in southern Chile. Annals of Glaciology 43 (2006), 111–122.CrossRefGoogle Scholar
Thost, DE, Truffer, M, Glacier recession on Heard Island, southern Indian Ocean. Arctic, Antarctic, and Alpine Research, 40 (2008), 199–214.CrossRefGoogle Scholar
Jordan, E, Ungerechts, L, Caceres, B, Penafiel, A, Francou, B, Estimation by photogrammetry of the glacier recession on the Cotopaxi volcano (Ecuador) between 1956 and 1997. Hydrological Science Journal, 50 (2005), 949–961.Google Scholar
Vuille, M, Francou, B, Wagnon, P, et al., Climate change and tropical Andean glaciers: past, present and future. Earth-Science Reviews, 89 (2008), 79–96, doi:10.1016/j.earscirev.2008.04.002CrossRefGoogle Scholar
Mote, PW, Kaser, G, The shrinking glaciers of Kilimanjaro: can global warming be blamed? American Scientist, 95 (2007), 318–325.CrossRefGoogle Scholar
Thompson, LG, Brecher, HH, Mosley-Thompson, E, Hardy, DR, Mark, BG, Glacier loss on Kilimanjaro continues unabated. Proceedings of the National Academy of Sciences 106 (2009), 19770–19775.CrossRefGoogle ScholarPubMed
Moore, RD, Fleming, SW, Menounos, B, et al., Glacier change in western North America: influences on hydrology, geomorphic hazards and water quality. Hydrological Processes, 23 (2009), 42–61.CrossRefGoogle Scholar
Hildreth, W, Fierstein, J, Eruptive history of Mount Katmai, Alaska. Geosphere, 8 (2012), 1527–1567.CrossRefGoogle Scholar
Schilling, SP, Carrara, PE, Thompson, RA, Iwatsubo, EY, Posteruption glacier development within the crater of Mount St. Helens, Washington, USA. Quaternary Research, 61 (2004), 325–329.CrossRefGoogle Scholar
Walder, JS, Schilling, SP, Vallance, JW, LaHusen, RG, Effects of lava-dome growth on the Crater Glacier of Mount St. Helens, Washington. In A Volcano Rekindled: The Renewed Eruption of Mount St. Helens, 2004–2006, eds. Sherrod, DR, Scott, WE, Stauffer, PH (Washington, DC: US Geological Survey, 2008), pp. 257–276.Google Scholar