Abstract
the single ignimbrite cooling unit E (average thickness, 28 m; volume, ca. 30 km3) forms the uppermost member of the Miocene Upper Mogán Formation on Gran Canaria. It is strongly chemically zoned from basal, first-erupted comendite (peralkaline rhyolite) to late-erupted trachyte, and, apart from an upper trachytic zone, it is densely welded. E was emplaced onto a surface inclined ca. 2–5° from the source caldera. Detailed mapping of key sections, up to 300 m long, exposed in barranco walls, ca. 10 km from the caldera margin, reveals structures that are interpreted to have been produced by rheomorphic deformation of the ignimbrite along shear zones. The shear zones formed within the lower-viscosity comenditic tuff. Extensional structures include mega-boudinage and ‘decapitated sequences’ and compression resulted in sequence repitition by overthrusting. Mechanisms traditionally thought to be important during rheomorphic deformation of welded tuffs (compaction, lateral creep, folding, vertical density-driven diapirism) cannot account for these features, which reflect lateral (post-compactional) rheomorphic movement locally in excess of 800 m. We suggest the following sequence of events: emplacement of the several flow units; compaction, with little lateral movement; rheomorphic deformation. During and after compaction, layers of secondary porosity developed within the comenditic tuff, possibly where upward escape of gas was prevented by overlying, relatively impermeable layers of densely compacted ignimbrite. These structurally weak layers of high porosity subsequently acted as shear zones.
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References
Allen JRL (1982) Sedimentary Structures, their Character and Physical Basis II. Elsevier, Amsterdam, pp 1–163
Blake S (1981) Eruptions from zoned magma chambers. J Geol Soc London 138:281–287
Bogaard vd P, Schmincke HU, Freundt A, Hall CM, York D (1988) Eruption ages and magma supply rates during the Miocene evolution of Gran Canaria. Naturwissenschaften 75:616–617
Branney MJ, Kokelaar BP, McConnell BJ (1992) The Bad Step Tuff: a lava-like ignimbrite in a calc-alkaline piecemeal caldera, English Lake District. Bull Volcanol 54:187–199
Chapin CE, Lowell GR (1979) Primary and secondary flow structures in ash-flow tuffs of the Gribbles Run palaeovalley, central Colorado. Geol Soc Am Spec Pap 180:137–154
Collinson JD, Thompson DB (1982) Sedimentary Structures. George Allen & Unwin, London, pp 1–207
Crisp JA (1984) The Mogan and Fataga Formations of Gran Canaria (Canary Islands): geochemistry, petrology, and compositional zonation of the pyroclastic and lava flows; intensive thermodynamic variables within the magma chamber; and the depositional history of pyroclastic flow E/ET. Ph.D. thesis, Princeton Univ, pp 1–304
Crisp JA, Spera FJ (1987) Pyroclastic flows and lavas of the Mogan and Fataga formations, Tejeda Volcano, Gran Canaria, Canary Islands: mineral chemistry, intensive parameters, and magma chamber evolution. Contrib Mineral Petrol 96:503–518
Curtis GH (1968) The stratigraphy of the ejecta from the 1912 eruption of Mount Katmai and Novarupta, Alaska. Geol Soc Am Mem 116:153–210
Freundt A, Schmincke H-U (1992) Mixing of rhyolite, trachyte and basalt magma erupted from a vertically and laterally zoned reservoir, composite flow P1, Gran Canaria. Contrib Mineral Petrol 112:1–19
Griggs RF (1922) The Valley of Ten Thousand Smokes (Alaska). Nat Geog Soc Washington DC, pp 1–340
Hargrove HR, Sheridan MF (1984) Welded tuffs deformed into megarheomorphic folds during collapse of the McDermitt caldera, Nevada-Oregon. J Geophys Res 89:8629–8638
Henry CD, Price JG, Parker DF, Wolff JA (1989) Mid-Tertiary silicic alkalic magmatism of Trans-Pecos Texas: theomorphic tuffs and extensive silicic lavas. New Mexico Bur Mines Min Res Mem 46:231–274
Kobberger G, Schmincke HU (1990) Deformation history of rheomorphic ignimbrite D (Gran Canaria): the role of shear zones. Abstracts, IAVCEI International Volcanological Congress, Mainz
Leat PT (1985) Interaction of a rheomorphic peralkaline ash-flow tuff and underlying deposits, Menengai volcano, Kenya. J Volcanol Geothermal Res 26:131–145
Leat PT, Schmincke HU (1990) Emplacement of strongly welded ignimbrite E, Mogan Formation, Gran Canaria. Abstracts, IAVCEI International Volcanological Congress, Mainz
McKenzie DP (1987) The compaction of igneous and sedimentary rocks. J Geol Soc London 144:299–307
Miller TF (1990) A numerical model of volatile behavior in nonwelded cooling pyroclastic deposits. J Geophys Res 95:19349–19364
Noble DC (1968) Laminar viscous flowage structures in ash-flow tuffs from Gran Canaria, Canary Islands: a discussion. J Geol 76:721–723
Ragan DM, Sheridan MF (1972) Compaction of the Bishop Tuff, California. Geol Soc Am Bull 83:95–106
Reedman AJ, Howells MF, Orton G, Campbell SDG (1987) The Pitts Head Tuff Formation: a subaerial to submarine welded ash-flow tuff of Ordovician age, North Wales. Geol Mag 124:427–439
Riehle JR (1973) Calculated compaction profiles of rhyolitic ashflow tuffs. Geol Soc Am Bull 84:2193–2216
Schmincke HU (1967) Cone sheet swarm, resurgence of Tejeda caldera, and the early geologic history of Gran Canaria. Bull Volcanol 31:153–162
Schmincke HU (1968) Faulting versus erosion and the reconstruction of the mid-Miocene shield volcano of Gran Canaria. Geol Mitt 8:23–50
Schmincke HU (1969a) Petrologie der phonolithischen bis rhyolithischen Vulkanite auf Gran Canaria, Kanarische Inseln. Habilitationsschrift, Ruprecht-Karl-Universität. Heidelberg, pp 1–151
Schmincke HU (1969b) Ignimbrite sequence on Gran Canaria. Bull Volcanol 33:1199–1219
Schmincke HU (1974) Volcanological aspects of peralkaline silicic welded ash-flow tuffs. Bull Volcanol 38:594–636
Schmincke HU (1976) The geology of the Canary Islands. In: Kunkel G (ed) Biogeography and Ecology of the Canary Islands. Dr W Junk BV Publishers, The Hague, pp 67–184
Schmincke HU (1990) Geological field guide, Gran Canaria, 4th edition. Pluto Press, Witten, pp 1–210
Schmincke HU, Swanson DA (1967) Laminar viscous flowage structures in ash-flow tuffs from Gran Canaria, Canary islands. J Geol 75:641–664
Sheridan MF (1970) Fumarolic mounds and ridges of the Bishop Tuff, California, Geol Soc Am Bull 81:851–868
Taylor GA (1958) The 1951 eruption of Mount Lamington, Papua. Aust Bur Miner Resour Geol Geophys Bull 38:1–117
Wilson L, Head JW (1981) Morphology and rheology of pyroclastic flows and their deposits, and guidelines for future observations. In Lipman PW, Mullineaux DR (eds) The 1980 eruptions of Mount St. Helens, Washington. US Geol Surv Prof Pap 1250:513–524
Wolff JA, Wright JV (1981) Rheomorphism of welded tuffs. J Volcanol Geotherm Res 10:13–34
Wright JV (1980) Stratigraphy and geology of the welded air-fall tuffs of Pantelleria, Italy. Geol Rundschau 69:263–291
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Leat, P.T., Schmincke, HU. Large-scale rheomorphic shear deformation in Miocene peralkaline ignimbrite E, Gran Canaria. Bull Volcanol 55, 155–165 (1993). https://doi.org/10.1007/BF00301513
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DOI: https://doi.org/10.1007/BF00301513