Hostname: page-component-cd9895bd7-gbm5v Total loading time: 0 Render date: 2024-12-24T02:01:06.607Z Has data issue: false hasContentIssue false

Explosive volcanism on Santorini, Greece

Published online by Cambridge University Press:  01 May 2009

T. H. Druitt
Affiliation:
Department of Geology, University of Wales, P.O. Box 914, Cardiff CF1 3YE, U.K.
R. A. Mellors
Affiliation:
Department of Earth Sciences, University of Cambridge, Cambridge CB2 3EQ, U.K..
D. M. Pyle
Affiliation:
Department of Earth Sciences, University of Cambridge, Cambridge CB2 3EQ, U.K..
R. S. J. Sparks
Affiliation:
Department of Earth Sciences, University of Cambridge, Cambridge CB2 3EQ, U.K..

Abstrct

Santorini volcanic field has had 12 major (1–10 km3 or more of magma), and numerous minor, explosive eruptions over the last ~ 200 ka. Deposits from these eruptions (Thera Pyroclastic Formation) are well exposed in caldera-wall successions up to 200 m thick. Each of the major eruptions began with a pumice-fall phase, and most culminated with emplacement of pyroclastic flows. Pyroclastic flows of at least six eruptions deposited proximal lag deposits exposed widely in the caldera wall. The lag deposits include coarse-grained lithic breccias (andesitic to rhyodacitic eruptions) and spatter agglomerates (andesitic eruptions only). Facies associations between lithic breccia, spatter agglomerate, and ignimbrite from the same eruption can be very complex. For some eruptions, lag deposits provide the only evidence for pyroclastic flows, because most of the ignimbrite is buried on the lower flanks of Santorini or under the sea. At least eight eruptions tapped compositionally heterogeneous magma chambers, producing deposits with a range of zoning patterns and compositional gaps. Three eruptions display a silicic–silicic + mafic–silicic zoning not previously reported. Four eruptions vented large volumes of dacitic or rhyodacitic pumice, and may account for 90% or more of all silicic magma discharged from Santorini. The Thera Pyroclastic Formation and coeval lavas record two major mafic-to-silicic cycles of Santorini volcanism. Each cycle commenced with explosive eruptions of andesite or dacite, accompanied by construction of composite shields and stratocones, and culminated in a pair of major dacitic or rhyodacitic eruptions. Sequences of scoria and ash deposits occur between most of the twelve major members and record repeated stratocone or shield construction following a large explosive eruption.

Volcanism at Santorini has focussed on a deep NE–SW basement fracture, which has acted as a pathway for magma ascent. At least four major explosive eruptions began at a vent complex on this fracture. Composite volcanoes constructed north of the fracture were dissected by at least three caldera-collapse events associated with the pyroclastic eruptions. Southern Santorini consists of pryoclastic ejecta draped over a pre-volcanic island and a ridge of early- to mid-Pleistocene volcanics. The southern half of the present-day caldera basin is a long-lived, essentially non-volcanic, depression, defined by topographic highs to the south and east, but deepened by subsidence associated with the main northern caldera complex, and is probably not a separate caldera.

Type
Articles
Copyright
Copyright © Cambridge University Press 1989

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Bacon, C. R. 1986. Magmatic inclusions in silicic and intermediate volcanic rocks. Journal of Geophysical Research 91, 6091–112.CrossRefGoogle Scholar
Barton, M. & Huijsmans, J. P. P. 1986. Post-caldera dacites from the Santorini volcanic complex, Aegean Sea, Greece: an example of the eruption of lavas of near-constant compositions over a 2,200 year period. Contributions to Mineralogy and Petrology 94, 472–95.CrossRefGoogle Scholar
Barton, M., Salters, V. J. M. & Huijsmans, J. P. P. 1983. Sr-isotope and trace element evidence for the role of continental crust in calc-alkaline volcanism on Santorini and Milos, Aegean Sea, Greece. Earth and Planetary Science Letters 63, 273–91.CrossRefGoogle Scholar
Betancourt, P. P. 1988. Dating the Aegean late Bronze Age with radiocarbon. Archaeometry 29, 45–9.CrossRefGoogle Scholar
Blake, S. & Ivey, G. N. 1986. Magma-mixing and the dynamics of withdrawal from stratified reservoirs. Journal of Volcanology and Geothermal Research 27, 153–78.CrossRefGoogle Scholar
Bond, A. & Sparks, R. S. J. 1976. The Minoan eruption of Santorini, Greece. Journal of the Geological Society of London 132, 116.CrossRefGoogle Scholar
Crisp, J. A. 1984. Rates of magma emplacement and volcanic output. Journal of Volcanology and Geothermal Research 20, 177211.Google Scholar
De Silva, S. L. 1989. The origin and significance of crystalrich inclusions in pumices from two Chilean ignimbrites. Geological Magazine 126, 159–75.CrossRefGoogle Scholar
Druitt, T. H. 1985. Vent evolution and lag breccia formation during the Cape Riva eruption of Santorini, Greece. Journal of Geology 93, 439–54.CrossRefGoogle Scholar
Druitt, T. H. & Sparks, R. S. J. 1982. A proximal ignimbrite breccia facies on Santorini, Greece. Journal of Volcanology and Geothermal Research 13, 147–71.CrossRefGoogle Scholar
Druitt, T. H. & Sparks, R. S. J. 1984. On the formation of calderas during ignimbrite eruptions. Nature 310, 679–81.Google Scholar
Eichelberger, J. C. 1980. Vesiculation of mafic magma during replenishment of silicic magma reservoirs. Nature 288, 446–50.CrossRefGoogle Scholar
Federman, A. N. & Carey, S. 1980. Electron microprobe correlation of tephras from eastern Mediterranean abyssal sediments and the island of Santorini. Quaternary Research 13, 160–71.CrossRefGoogle Scholar
Ferrara, G., Fytikas, N., Giuliani, O. & Marinelli, G. 1980. Age of the formation of the Aegean active volcanic arc. In Thera and the Aegean World II (ed. Doumas, C.), pp. 3741. London: Thera and the Aegean World.Google Scholar
Fisher, R. V. 1977. Erosion by volcanic base-surge density currents: U-shaped channels. Geological Society of American Bulletin 88, 1287–97.2.0.CO;2>CrossRefGoogle Scholar
Fouque, F. 1879. Santorin et ses eruptions. Paris: Masson et Cie, 440 pp.Google Scholar
Freundt, A. & Tait, S. R. 1986. The entrainment of highviscosity magma into low-viscosity magma in eruption conduits. Bulletin of Volcanology 48, 325–39.CrossRefGoogle Scholar
Friedrich, W. L., Pichler, H. & Kussmaul, S. 1977. Quaternary pyroclastics from Santorini/Greece and their significance for the Mediterranean palaeoclimate. Bulletin of the Geological Society of Denmark 26, 2739.CrossRefGoogle Scholar
Georgalas, G. C. 1962. Catalogue of the active volcanoes of the world, including solfatara fields. Part XII. Rome: International Association of Volcanology, 40 pp.Google Scholar
Gunther, D. & Pichler, H. 1973. Die obere und untere Bimsstein-Folge auf Santorin. Neues Jahrbuch fur Geologie und Palaeontologie Monatshefte 7, 394415.Google Scholar
Heiken, G. & McCoy, F. W. 1984. Caldera development during the Minoan eruption, Thera, Cyclades, Greece. Journal of Geophysical Research 89, 8441–62.CrossRefGoogle Scholar
Hildreth, W. 1981. Gradients in silicic magma chambers: implications for lithospheric magmatism. Journal of Geophysical Research 86, 10153–92.CrossRefGoogle Scholar
Huijsmans, J. P. P. 1985. Calc-alkaline lavas from the volcanic complex of Santorini, Aegean Sea, Greece. Geologica Ultraiectina 41, 316 pp.Google Scholar
Keller, J., Ryan, W. B. F., Ninkovich, D. & Altherr, R. 1978. Explosive volcanic activity in the Mediterranean over the past 200000 yr as recorded in deep-sea sediments. Geological Society of America Bulletin 89, 591604.2.0.CO;2>CrossRefGoogle Scholar
Kobayashi, T. 1988. Volcanic ash deposits formed by the intermittent eruption of the active volcano Sakurajima. Journal of the Institute of Earth Sciences, Faculty of Science, Kagoshima University, 112.Google Scholar
le Pichon, X. & Angelier, J. 1979. The Hellenic are and trench system: a key to the neotectonic evolution of the eastern Mediterranean area. Tectonophysics 60, 142.Google Scholar
le Pichon, X., Angelier, J., Aubouin, J., Lyberis, N., Monti, S., Renard, V., Got, H., Hsu, K., Mart, Y., Mascle, J., Matthews, D., Mitropoulos, D., Tsoflias, P. & Chronis, G. 1979. From subduction to transform motion: a seabeam survey of the Hellenic trench system. Earth and Planetary Science Letters 44, 441–50.CrossRefGoogle Scholar
Makris, J. 1978. The crust and upper mantle of the Aegean region from deep seismic soundings. Tectonophysics 46, 269–84.CrossRefGoogle Scholar
Mann, A. C. 1983. Trace element geochemistry of high alumina basalt-andesite-dacite-rhyodacite lavas of the Main Volcanic Series of Santorini Volcano, Greece. Contributions to Mineralogy and Petrology 84, 4357.CrossRefGoogle Scholar
McClelland, E. & Druitt, T. H. 1988. Palaeomagnetic estimates of emplacement temperatures of pyroclastic deposits on Santorini, Greece. Bulletin of Volcanology (in press).Google Scholar
Nicholls, I. A. 1971. Petrology of Santorini Volcano, Cyclades, Greece. Journal of Petrology 12, 67119.Google Scholar
Papazachos, B. C. & Comninakis, P. E. 1971. Geophysical and tectonic features of the Aegean arc. Journal of Geophysical Research 76, 8517–33.Google Scholar
Pichler, H. 1963. Ignimbrite auf Santorin. Annales Géologiques des Pays Helleniques 14, 408–35.Google Scholar
Pichler, H. & Friedrich, W. L. 1976. Radiocarbon dates of Santorini volcanics. Nature 262, 373–4.CrossRefGoogle Scholar
Pichler, H. & Friedrich, W. L. 1980. Mechanism of the Minoan eruption of Santorini. In Thera and the Aegean World II (ed. Doumas, C.), pp. 1530. London: Thera and the Aegean World.Google Scholar
Pichler, H. & Kussmaul, S. 1972. The calc-alkaline volcanic rocks of the Santorini group (Aegean Sea, Greece). Neues Jahrbuch fur Mineralogie Abhandlungen 116, 268307.Google Scholar
Pichler, H. & Kussmaul, S. 1980. Comments on the geological map of the Santorini islands. In Thera and the Aegean World II (ed. Doumas, C.), pp. 413–27. London: Thera and the Aegean World.Google Scholar
Puchelt, H. 1978. Evolution of the volcanic rocks of Santorini. In Thera and the Aegean World I (ed. Doumas, C.), pp. 131–46. London: Thera and the Aegean World.Google Scholar
Pyle, D. M. 1989. Volume of the Minoan tephra. In Thera and the Aegean World III (ed. Doumas, C.). London: Thera and the Aegean World, (in press).Google Scholar
Pyle, D. M., Ivanovich, M. & Sparks, R. S. J. 1988. Magma-cumulate mixing identified by U–Th disequilibrium dating. Nature 331, 157–9.Google Scholar
Reck, H. 1936. Santorin: Der Werdegang eines Inselvulkans und sein Ausbruch 1925–1928, 3 vols. Berlin: D. Reimer.Google Scholar
Seward, D., Wagner, G. A. & Pichler, H. 1980. Fission track ages of Santorini volcanics (Greece). In Thera and the Aegean World II (ed. Doumas, C.), pp. 101–8. London: Thera and the Aegean World.Google Scholar
Smith, R. L. 1979. Ash-flow magmatism. Geological Society of America Special Paper no. 180, 527.CrossRefGoogle Scholar
Sparks, R. S. J. & Huang, T. C. 1980. The volcanological significance of deep-sea ash layers associated with ignimbrites. Geological Magazine 117, 425–36.Google Scholar
Sparks, R. S. J. & Marshall, L. A. 1986. Thermal and mechanical constraints on mixing between mafic and silicic magmas. Journal of Volcanology and Geothermal Research 29, 99124.Google Scholar
Sparks, R. S. J. & Wright, J. V. 1979. Welded air-fall tuffs. Geological Society of America Bulletin 180, 155–66.Google Scholar
Thunnel, R. C., Williams, D., Federman, A. & Sparks, R. S. J. 1977. Late Quaternary tephra chronology of eastern Mediterranean sediments. Geological Society of America Abstracts with Programs 9, 1200.Google Scholar
Walker, G. P. L. 1985. Origin of coarse lithic breccias near ignimbrite source vents. Journal of Volcanology and Geothermal Research 25, 157–71.CrossRefGoogle Scholar
Walker, G. P. L. & Skelhorn, R. R. 1966. Some associations of acid and basic igneous rocks. Earth Science Reviews 2, 93109.Google Scholar
Walker, G. P. L., Wilson, C. J. N. & Froggatt, P. C. 1981. An ignimbrite veneer deposit: the trail marker of the pyroclastic flow. Journal of Volcanology and Geothermal Research 9, 409–21.Google Scholar
Watkins, N. D., Sparks, R. S. J., Sigurdsson, H., Huang, T. C., Federman, A., Carey, S. & Ninkovich, D. 1978. Volume and extent of the Minoan tephra from Santorini Volcano: new evidence from deep-sea sediment cores. Nature 271, 122–6.CrossRefGoogle Scholar
Wilson, L., Sparks, R. S. J. & Walker, G. P. L. 1980. Explosive volcanic eruptions. IV. The control of magma properties and conduit geometry on eruption column behaviour. Geophysical Journal of the Royal Astronomical Society 63, 117–48.CrossRefGoogle Scholar
Wright, J. V. & Walker, G. P. L. 1977. The ignimbrite source problem: Significance of a co-ignimbrite lag-fall deposit. Geology 5, 729–32.Google Scholar