Book contents
- Volcanotectonics
- Volcanotectonics
- Copyright page
- Contents
- Preface
- Acknowledgements
- 1 Introduction
- 2 Volcanotectonic Structures
- 3 Volcanotectonic Deformation
- 4 Volcanic Earthquakes
- 5 Volcanotectonic Processes
- 6 Formation and Dynamics of Magma Chambers and Reservoirs
- 7 Magma Movement through the Crust: Dike Paths
- 8 Dynamics of Volcanic Eruptions
- 9 Formation and Evolution of Volcanoes
- 10 Understanding Unrest and Forecasting Eruptions
- Book part
- Index
- References
9 - Formation and Evolution of Volcanoes
Published online by Cambridge University Press: 18 April 2020
Book contents
- Volcanotectonics
- Volcanotectonics
- Copyright page
- Contents
- Preface
- Acknowledgements
- 1 Introduction
- 2 Volcanotectonic Structures
- 3 Volcanotectonic Deformation
- 4 Volcanic Earthquakes
- 5 Volcanotectonic Processes
- 6 Formation and Dynamics of Magma Chambers and Reservoirs
- 7 Magma Movement through the Crust: Dike Paths
- 8 Dynamics of Volcanic Eruptions
- 9 Formation and Evolution of Volcanoes
- 10 Understanding Unrest and Forecasting Eruptions
- Book part
- Index
- References
Summary
How are volcanoes born, in which way do they live, and why and when, eventually, do they become extinct? More specifically, why are there any polygenetic central volcanoes at all? Why is the volcanism not simply evenly distributed through the volcanic zone or field? There are certainly volcanic areas where the volcanism is more or less evenly distributed – such as at fast-spreading ridges. But for most other volcanic areas one or more locations within the area dominates the volcanism, resulting in the formation of a specific central volcano. The central volcano erupts much more frequently than its surroundings and, therefore, normally forms an edifice. The edifice is a structure with a certain mechanical strength, most of which derives from the internal structure of the volcano. Later in the evolution of the volcano, it may form a collapse caldera, as well as being subject to lateral collapses, all of which affect its shape. When, eventually, the supply of magma to the volcano is cut off, it becomes extinct, that is, dies.
- Type
- Chapter
- Information
- VolcanotectonicsUnderstanding the Structure, Deformation and Dynamics of Volcanoes, pp. 424 - 471Publisher: Cambridge University PressPrint publication year: 2020
References
References and Suggested Reading
Acocella, V., 2007. Understanding caldera structure and development: an overview of analogue models compared to natural calderas. Earth-Science Reviews, 85, 125–160.CrossRefGoogle Scholar
Acocella, V., Behncke, B., Neri, M., D’Amico, S., 2003. Link between major flank slip and eruptions at Mt. Etna (Italy). Geophysical Research Letters, 30, 2286, doi:10.1029/2003GL018642.CrossRefGoogle Scholar
Acosta, J., Uchupi, E., Munoz, A., et al., 2003. Geologic evolution of the Canarian Islands of Lanzarote, Fuerteventura, Gran Canaria and La Gomera and comparison of landslides at these islands and those at Tenerife, La Palma and El Hierro. Marine Geophysical Research, 24, 1–40.CrossRefGoogle Scholar
Aguirre-Diaz, G., 2008. Types of collapse calderas. Institute of Physics Conference Series: Earth and Environmental Sciences, 3, 012021.Google Scholar
Agustsdottir, T., Woods, J., Greenfield, T., 2016. Strike-slip faulting during the 2014 Bardarbunga–Holuhraun dike intrusion, central Iceland. Geophysical Research Letters, 43, 1495–1503.Google Scholar
Almond, D. C. 1977. The Sabaloka igneous complex, Sudan. Philosophical Transactions of the Royal Society of London, A287, 595–633.Google Scholar
Anderson, E. M., 1936. The dynamics of formation of cone sheets, ring dykes and cauldron subsidences. Proceedings of the Royal Society of Edinburgh, 56, 128–163.Google Scholar
Andrew, R. E. B., Gudmundsson, A., 2008. Volcanoes as elastic inclusions: their effects on the propagation of dykes, volcanic fissures, and volcanic zones in Iceland. Journal of Volcanology and Geothermal Research, 177, 1045–1054.Google Scholar
Apuani, T., Corazzato, C., Cancelli, C., Tibaldi, A., 2005. Stability of a collapsing volcano (Stromboli, Italy): limit equilibrium analysis and numerical modelling. Journal of Volcanology and Geothermal Research, 144, 191–210.Google Scholar
Aramaki, S. 1984. Formation of the Aira caldera, southern Kyushu, ~ 22,000 years ago. Journal of Geophysical Research, 89, 8484–8501.CrossRefGoogle Scholar
Baragar, W. R. A., Lambert, M. B., Baglow, N., Gibson, I. L., 1987. Sheeted dykes of the Troodos Ophiolite, Cyprus. Geological Association of Canada Special Paper, 34, 257–272.Google Scholar
Billings, M. P., 1972. Structural Geology, 3rd edn. Upper Saddle River, NJ: Prentice-Hall.Google Scholar
Bonaccorso, A., Davis, P., 1999. Models of ground deformation from vertical volcanic conduits with application to eruptions of Mount St. Helens and Mount Etna. Journal of Geophysical Research, 104, 10531–10542.Google Scholar
Boudon, G., Le Friant, A., Komorowski, J. C., Deplus, C., Semet, M. P., 2007. Volcano flank instability in the lesser Antilles arc: diversity of scale, processes, and temporal recurrence. Journal of Geophysical Research, 112 (B8), Art. No. B08205.Google Scholar
Branney, M. J. 1995. Downsag and extension at calderas: new perspectives on collapse geometries from ice-melt, mining, and volcanic subsidence. Bulletin of Volcanology, 57, 303–318.Google Scholar
Browning, J., Gudmundsson, A., 2015a. Surface displacements resulting from magma-chamber roof subsidence, with application to the 2014–2015 Bardarbunga–Holuhraun volcanotectonic episode in Iceland. Journal of Volcanology and Geothermal Research, 308, 82–98.Google Scholar
Browning, J., Gudmundsson, A., 2015b. Caldera faults capture and deflect inclined sheets: an alternative mechanism of ring-dike formation. Bulletin of Volcanology, 77, 889, doi:10.1007/s00445-014-0889-4.Google Scholar
Browning, J., Drymoni, K., Gudmundsson, A., 2015. Forecasting magma-chamber rupture at Santorini volcano, Greece. Scientific Reports, 5, doi:10.1038/srep15785.CrossRefGoogle ScholarPubMed
Chaussard, E., Amelung, F., 2014. Regional controls on magma ascent and storage in volcanic arcs. Geochemistry, Geophysics, Geosystems, 15, doi:10.1002/2013GC005216.Google Scholar
Cole, J. W., Milner, D. M., Spinks, K. D. 2005. Calderas and caldera structures: a review. Earth-Science Reviews, 69, 1–26.CrossRefGoogle Scholar
Coleman, R. G., 1977. Ophiolites. Ancient Oceanic Lithosphere? Berlin: Springer Verlag.Google Scholar
Del Potro, R., Hurlimann, M., 2008. Geotechnical classification and characterisation of materials for stability analyses of large volcanic slopes. Engineering Geology, 98, 1–17.CrossRefGoogle Scholar
Dzurisin, D., 2006. Volcano Deformation: New Geodetic Monitoring Techniques. Berlin: Springer Verlag.Google Scholar
Fedotov, S. A., Chirkov, A. M., Gusev, N. A., Kovalev, G. N., Slezin, Yu. B., 1980. The large fissure eruption in the region of Plosky Tolbachik Volcano in Kamchatka, 1975–1976. Bulletin of Volcanology, 43, 47–60.Google Scholar
Filson, J., Simkin, T., Leu, L. 1973. Seismicity of a caldera collapse: Galapagos Islands 1968. Journal of Geophysical Research, 78, 8591–8622.Google Scholar
Foden, J., 1986. The petrology of the Tambora volcano, Indonesia: a model for the 1815 eruption. Journal of Volcanology and Geothermal Research, 27, 1–41.Google Scholar
Francis, P., 1993. Volcanoes: A Planetary Perspective. Oxford: Oxford University Press.Google Scholar
Garcia, M. O., Sherman, S. B., Moore, G. F., et al., 2006. Frequent landslides from Koolau Volcano: results from ODP Hole 1223A. Journal of Volcanology and Geothermal Research, 151, 251–268.Google Scholar
Gertisser, R., Self, S., Thomas, L. E., et al., 2012. Processes and timescales of magma genesis and differentiation leading to the great Tambora eruption in 1815. Journal of Petrology, 53, 271–297.Google Scholar
Geshi, N., Shimano, T., Chiba, T., Nakada, S., 2002. Caldera collapse during the 2000 eruption of Miyakejima volcano, Japan. Bulletin of Volcanology, 64, 55–68.Google Scholar
Geyer, A., Marti, J., 2008. The new worldwide collapse caldera database (CCDB): a tool for studying and understanding caldera processes. Journal of Volcanology and Geothermal Research, 175, 334–354.Google Scholar
Geyer, A., Marti, J., 2014. A short review of our current understanding of the development of ring faults during collapse caldera formation. Frontiers in Earth Science, 2, doi:10.3389/feart.2014.00022.Google Scholar
Gudmundsson, A. 1988. Effect of tensile-stress concentration around magma chambers on intrusion and extrusion frequencies. Journal of Volcanology and Geothermal Research, 35, 179–194.Google Scholar
Gudmundsson, A., 1998. Magma chambers modeled as cavities explain the formation of rift zone central volcanoes and their eruption and intrusion statistics. Journal of Geophysical Research, 103, 7401–7412.Google Scholar
Gudmundsson, A. 2000. Dynamics of volcanic systems in Iceland: example of tectonism and volcanism at juxtaposed hot spot and mid-ocean ridge systems. Annual Review of Earth and Planetary Sciences, 28, 107–140.Google Scholar
Gudmundsson, A., 2006. How local stresses control magma-chamber ruptures, dyke injections, and eruptions in composite volcanoes. Earth-Science Reviews, 79, 1–31.Google Scholar
Gudmundsson, A., 2009. Toughness and failure of volcanic edifices. Tectonophysics, 471, 27–35.CrossRefGoogle Scholar
Gudmundsson, A., 2011a. Rock Fractures in Geological Processes. Cambridge: Cambridge University Press.Google Scholar
Gudmundsson, A., 2011b. Deflection of dykes into sills at discontinuities and magma-chamber formation. Tectonophysics, 500, 50–64.Google Scholar
Gudmundsson, A., 2012. Magma chambers: formation, local stresses, excess pressures, and compartments. Journal of Volcanology and Geothermal Research, 237–238, 19–41.Google Scholar
Gudmundsson, A., 2015. Collapse-driven large eruptions. Journal of Volcanology and Geothermal Research, 304, 1–10Google Scholar
Gudmundsson, A., 2016. The mechanics of large volcanic eruptions. Earth-Science Reviews, 163, 72–93.Google Scholar
Gudmundsson, A., 2017. The Glorious Geology of Iceland’s Golden Circle. Berlin: Springer Verlag.Google Scholar
Gudmundsson, A., Brenner, S. L., 2004. Local stresses, dyke arrest, and surface deformation in volcanic edifices and rift zones. Annals of Geophysics, 47, 1433–1454.Google Scholar
Gudmundsson, A., Brenner, S. L., 2005. On the conditions for sheet injections and eruptions in stratovolcanoes. Bulletin of Volcanology, 67, 768–782.Google Scholar
Gudmundsson, A., Lotveit, I. F., 2012. Sills as fractured hydrocarbon reservoirs: examples and models. In Spence, G. H., Redfern, J., Aguilera, R., et al. (eds.), Advances in the Study of Fractured Reservoirs. Geological Society of London Special Publications, 374. London: Geological Society of London, pp. 251–271.Google Scholar
Gudmundsson, A., Bergerat, F., Angelier, J., Villemin, T. 1992. Extensional tectonics of Southwest Iceland. Bulletin of the Geological Society of France, 163, 561–570.Google Scholar
Gudmundsson, A., Friese, N., Galindo, I., Philipp, S. L., 2008. Dike-induced reverse faulting in a graben. Geology, 36, 123–126.Google Scholar
Humle, G., 1974. The interpretation of lava flow morphology. Geophysical Journal of the Royal Astronomical Society, 39, 361–383.Google Scholar
Hurlimann, A., Marti, J., Ledesma, A., 2004. Morphological and geological aspects related to large slope failures on oceanic islands – the huge La Orotava landslides on Tenerife, Canary Islands. Geomorphology, 62, 143–158.Google Scholar
Johnson, S. E., Schmidth, K. L., Tate, M. C., 2002. Ring complexes in the Peninsular Ranges Batholith, Mexico and the USA: magma plumbing system in the middle and upper crust. Lithos, 61, 187–208.Google Scholar
Kaneko, T., Yasuda, A., Fujii, T., Yoshimoto, M., 2010. Crypto-magma chambers beneath Mt. Fuji. Journal of Volcanology and Geothermal Research, 193, 161–170.CrossRefGoogle Scholar
Kerle, N., de Vries, B. V. W., 2001. The 1998 debris avalanche at Casita volcano, Nicaragua: investigation of structural deformation as the cause of slope instability using remote sensing. Journal of Volcanology and Geothermal Research, 105, 49–63.Google Scholar
Kilburn, C. J., 2000. Lava flows and flow fields. In Sigurdsson, H. (ed.), Encyclopedia of Volcanoes. New York, NY: Academic Press, pp. 291–305.Google Scholar
Lipman, P. W. 1984. The roots of ash flow calderas in western North America: windows into the tops of granitic batholiths. Journal of Geophysical Research, 89, 8801–8841.Google Scholar
Lipman, P. W. 1997. Subsidence of ash-flow calderas: relation to caldera size and magma chamber geometry. Bulletin of Volcanology, 59, 198–218.Google Scholar
Lipman, P. W., Mullineaux, D. R. (eds.), 1981. The 1980 Eruptions of Mount St. Helens, Washington. US Geological Survey Professional Paper, 1250. Denver, CO: US Geological Survey.Google Scholar
Lipman, P. W., Dungan, M. A., Bachmann, O., 1997. Comagmatic granophyric granite in the Fish Canyon Tuff, Colorado: implications for magma-chamber processes during a large ash-flow eruption. Geology, 25, 915–918.Google Scholar
Lippard, S. J., Shelton, A. W., Gass, I. (eds.), 1986. The Ophiolite of Northern Oman. Oxford: Blackwell.Google Scholar
Martì, J., Gudmundsson, A., 2000. The Las Canadas caldera (Tenerife, Canary Islands): an overlapping collapse caldera generated by magma-chamber migration. Journal of Volcanology and Geothermal Research, 103, 161–173.Google Scholar
Marti, J., Ablay, G. J., Redshaw, L. T., Sparks, R. S. J., 1994. Experimental studies of collapse calderas. Journal Geological Society London, 151, 919–929.Google Scholar
Marti, J., Geyer, A., Folch, A., Gottsmann, J., 2008. A review on collapse caldera modelling. In Gottsmann, J. and Marti, J. (eds.), Caldera Volcanism: Analysis, Modelling and Response. Amsterdam: Elsevier, pp. 233–283.Google Scholar
Marti, J., Geyer, A., Folch, A., 2009. A genetic classification of collapse calderas based on field studies, and analogue and theoretical modelling. In Thordarson, T., Self, S. (eds.), Volcanology: The Legacy of GPL Walker. London: IAVCEI-Geological Society of London, pp. 249–266.Google Scholar
Mitchell, N. C., Masson, D. G., Watts, A. B., Gee, M. J. R., Urgeles, R., 2002. The morphology of submarine flanks of volcanic ocean islands – a comparative study of the Canary and Hawaiian hotspot islands. Journal of Volcanology and Geothermal Research, 115, 83–107.CrossRefGoogle Scholar
Moore, J. G., Clague, D. A., Holcomb, R. T., et al., 1989. Prodigious submarine landslides on the Hawaiian Ridge. Journal of Geophysical Research, 94, 17465–17484.Google Scholar
Moore, J. G., Normark, W. R., Holcomb, R. T., 1994. Giant Hawaiian landslides. Annual Review of Earth and Planetary Sciences, 22, 119–144.Google Scholar
Morgan, J. K., Moore, G. F., Clague, D. A., 2003. Slope failure and volcanic spreading along the submarine south flank of Kilauea volcano, Hawaii. Journal of Geophysical Research, 108, 2415, doi.org/10.1029/2003JB002411.CrossRefGoogle Scholar
Nakada, S., Uto, K., Sakuma, S., Eichelberger, J. C., Shimizu, H., 2005. Scientific results of conduit drilling in the Unzen Scientific Drilling Project (USDP). Scientific Drilling, 1, 18–22, doi:10.2204/iodp.sd.1.03.2005.Google Scholar
Newhall, C. G., Dzurisin, D., 1988. Historical Unrest of Large Calderas of the World. Reston, VA: US Geological Survey.Google Scholar
Nicolas, A., 2013. Structures of Ophiolites and Dynamics of Oceanic Lithosphere. Berlin: Springer Verlag.Google Scholar
O’Driscoll, B., Troll, V.R., Reavy, R.J., Turner, P., 2006. The Great Eucrite intrusion of Ardnamurchan, Scotland: reevaluating the ring-dike concept. Geology, 34, 189–192.Google Scholar
Oehler, J. F., de Vries, B. V. W., Labazuy, P., 2005. Landslides and spreading of oceanic hot-spot and arc basaltic edifices on low strength layers (LSLs): an analogue modelling approach. Journal of Volcanology and Geothermal Research, 144, 169–189.Google Scholar
Oehler, J. F., Lenat, J. F., Labzuy, P., 2008. Growth and collapse of the Reunion Island volcanoes. Bulletin of Volcanology, 70, 717–742.Google Scholar
Oftedahl, C. 1953. The igneous rock complex of the Oslo region: XIII. The cauldrons. Skrifter Det Norske Videnskaps-Akademi i Oslo, 3, 1–108.Google Scholar
Pina-Varas, P., Ledo, J., Queralt, P., Marcuello, A., Perez, N., 2018. On the detectability of Teide volcano magma chambers (Tenerife, Canary Islands) with magnetotelluric data. Earth, Planets and Space, 70, doi.org/10.1186/s40623-018–0783-yGoogle Scholar
Pinel, V., Jaupart, C., 2005. Some consequences of volcanic edifice destruction for eruption conditions. Journal of Volcanology and Geothermal Research, 145, 68–80.Google Scholar
Ponomreva, V. V., Melekestev, I. V., Dirksen, O. V., 2006. Sector collapses and large landslides on late Pleistocene–Holocene volcanoes in Kamchatka, Russia. Journal of Volcanology and Geothermal Research, 158, 117–138.Google Scholar
Reid, M. E., 2004. Massive collapse of volcano edifices triggered by hydrothermal pressurization. Geology, 32, 373–376.Google Scholar
Rosi, M., Papale, P., Lupi, L., Stoppato, M., 2003. Volcanoes. Buffalo, NY: Firefly Books.Google Scholar
Rust, D., Behncke, B., Neri, M., Ciocanel, A., 2005. Nested zones of instability in the Mount Etna volcanic edifice, Italy. Journal of Volcanology and Geothermal Research, 144, 137–153.Google Scholar
Segalstad, T. V., 1975. Cauldron subsidences, ring-structures, and major faults in the Skien district, Norway. Norks Geologisk Tidsskrift, 55, 321–333.Google Scholar
Self, S., Rampino, M. R., Newton, M. S., Wolff, J. A., 1984. Volcanological study of the great Tambora eruption of 1815. Geology, 12, 659–663.Google Scholar
Siebert, L., 1984. Large volcanic debris avalanches: characteristics of source areas, deposits and associated eruptions. Journal of Volcanology and Geothermal Research, 22, 163–197.CrossRefGoogle Scholar
Simkin, T., Howard, K.A. 1970. Caldera collapse in the Galapagos Islands, 1968. Science, 169, 429–437.Google Scholar
Spera, F. J., 1980. Thermal evolution of plutons: a parameterized approach. Science, 207, 299–301.Google Scholar
Spera, F. J., 2000. Physical properties of magmas. In Sigurdsson, H. (ed.), Encyclopedia of Volcanoes. New York, NY: Academic Press, pp. 171–190.Google Scholar
Thordarson, T., Hoskuldsson, A., 2008. Postglacial volcanism in Iceland. Jokull, 58, 197–228.Google Scholar
Tibaldi, A., 2001. Multiple sector collapses at Stromboli volcano, Italy: how they work. Bulletin of Volcanology, 63, 112–125.Google Scholar
Tibaldi, A., Bistacchi, A., Pasquare, F. A., Vezzoli, L., 2006. Extensional tectonics and volcano lateral collapses: insights from Ollague volcano (Chile–Bolivia) and analogue modelling. Terra Nova, 18, 282–289.Google Scholar
Tsuchida, E., Yaegashi, A. 1981. Stresses in a thick elastic plate containing a prolate spheroidal cavity subjected to an axisymmetric pressure. Theoretical and Applied Mechanics, 31, 85–96.Google Scholar
Tsuchida, E., Saito, Y., Nakahara, I., Kodama, M., 1982a. Stresses in a semi-infinite elastic body containing a prolate spheroidal cavity subjected to axisymmetric pressure. Japan Society of Mechanical Engineers Bulletin, 25, 891–897.Google Scholar
Tsuchida, E., Saito, Y., Nakahara, I., Kodama, M., 1982b. Stress concentration around a prolate spheroidal cavity in a semi-infinite elastic body under all-around tension. Japan Society of Mechanical Engineers Bulletin, 25, 493–500.Google Scholar
Vinciguerra, S., Elsworth, D., Malone, S., 2005. The 1980 pressure response and flank failure of Mount St. Helens (USA) inferred from seismic scaling exponents. Journal of Volcanology and Geothermal Research, 144, 155–168.Google Scholar
Walter, T. R., Schmincke, H. U., 2002. Rifting, recurrent landsliding and Miocence structural reorganisation on NW-Tenerife (Canary Islands). International Journal of Earth Sciences, 91, 615–628.Google Scholar
Williams, H., McBirney, A. R., Lorenz, V. 1970. An Investigation of Volcanic Depressions. Part I. Calderas. Houston, TX: Manned Spacecraft Center.Google Scholar
Wooller, L., de Vries, B. V. W, Murray, J. B., Rymer, H., Meyer, S., 2004. Volcano spreading controlled by dipping substrata. Geology, 32, 573–576.Google Scholar