Hostname: page-component-586b7cd67f-t7fkt Total loading time: 0 Render date: 2024-11-25T06:17:30.395Z Has data issue: false hasContentIssue false

Volcano-stratigraphy of the extension-related silicic volcanism of the Çubukludağ Graben, western Turkey: an example of generation of pyroclastic density currents

Published online by Cambridge University Press:  19 July 2013

ZEKIYE KARACIK*
Affiliation:
Istanbul Technical University, Faculty of Mines, Geology Department, Maslak Istanbul 34469, Turkey
SENGUL C. GENÇ
Affiliation:
Istanbul Technical University, Faculty of Mines, Geology Department, Maslak Istanbul 34469, Turkey
*
*Author for correspondence: [email protected]

Abstract

Western Turkey's extension-related Cumaovası volcanic rocks (Lower Miocene, 17 Ma) are excellent examples of silicic eruptions. The sub-aerial silicic volcanism at Çubukludağ Graben between İzmir and Kuşadası in west–central Anatolia is mainly in the form of rhyolite domes, lava flows and pyroclastic deposits. The initial features of volcanism derived from phreatomagmatic explosive eruptions from silicic magma that came into contact with lake waters during Neogene times. Most of the volcanic succession represents pyroclastic density currents (PDCs), known as the Kuner ignimbrite. The deposits are fine grained and laminated at the base and pass laterally and vertically into deposits displaying well-developed traction structures, soft sediment deformation and/or erosion channels in the NE part of the region. Alternate deposits of massive, diffusely stratified lapilli and ash are the main products of the later explosive stage. Massive lithic breccias forming the top of the sequences are the proximal facies of the PDCs. The lava phase mainly consists of rhyolite extruded as dome and fissure eruptions of lavas, aligned along NE–SW-trending faults as well as from extensional cracks that are nearly perpendicular to the main graben faults. Considering the tectono-stratigraphical aspects and geochemical nature of the study area, we propose that the Cumaovası silicic volcanism was produced by extension-related crustal melting during the Late–Early Miocene period (17 Ma).

Type
Original Articles
Copyright
Copyright © Cambridge University Press 2013 

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

Akartuna, M. 1962. İzmir-Torbalı-Seferihisar-Urla bölgesinin jeolojik etüdü. İstanbul Üniversitesi Fen Fakültesi Monografileri 18, 18.Google Scholar
Başarır, E. & Konuk, Y.T. 1981. Gümüldür yöresinin kristalin temeli ve allokton birimleri. Bulletin of the Geological Society of Turkey 24, 16.Google Scholar
Bluth, J. K. 2004. Syn-erutive incision of Koko Crater, Oahu, Hawaii by condensed steam and hot cohesive debris flows: a re-interpretation of the type locality of “surge-eroded U-shaped channels”. Published thesis, Master of Science. University of Pittsburgh.Google Scholar
Boray, A., Akat, U., Akdeniz, N., Akçören, Z., Çağlayan, A., Günay, E., Korkmazer, B., Öztürk, E.M. & Sav, H. 1973. Menderes Masifinin güney kenarı boyunca bazı önemli sorunlar ve bunların muhtemel çözümleri. Cumhuriyetin 50. Yılı Yerbilimleri Kongresi, Tebliğler, Mineral Research and Exploration Institute of Turkey, Turkey, 1120.Google Scholar
Borsi, S., Ferrara, G., Innocenti, F. & Mazzuoli, R. 1972. Geochronology and petrology of recent volcanics in the Eastern Aegean Sea (West Anatolia and Lesvos Island). Bulletin of Volcanology 36 (3), 473–96.CrossRefGoogle Scholar
Bozkurt, E., Park, G. & Winchester, J.A. 1993. Evidence against the core/cover interpretation of the southern sector of the Menderes massif, west Turkey. Terra Nova 5, 445–51.Google Scholar
Branney, M.J. & Kokelaar, P. 2002. Pyroclastic Density Currents and the Sedimentation of Ignimbrites. Geological Society, London, Memoir 27, pp. 143.Google Scholar
Brooker, M.R., Houghton, B.F., Wilson, C.J.N. & Gamble, J.A. 1993. Pyroclastic phase of a rhyolitic dome-building eruption: Puketarata tuff ring, Taupo Volcanic Zone, New Zealand. Bulletin of Volcanology 55, 395406.Google Scholar
Brown, R.J., Branney, M.J., Maher, C. & Davila-Harris, P. 2010. Origin of accretionary lapilli within ground-hugging density currents: evidence from pyroclastic couplets on Tenerife. GSA Bulletin 122, 305–20.Google Scholar
Brown, R.J., Kokelaar, B.P. & Branney, M.J. 2007. Widespread transport of pyroclastic density current from a large silicic tuff ring: the Glaramara tuff, Scafell caldera, English Lake District, UK. Sedimentology 54, 1163–89.Google Scholar
Cas, R.A.F. & Wright, J.V. 1987. Volcanic Successions Modern and Ancient: A Geological Approach to Processes, Products and Successions. Unwin Hyman, London.Google Scholar
Chough, S. K. & Sohn, Y.K. 1990. Depositional mechanics and sequences of base surges, Songaksan tuff ring, Cheju Island, Korea. Sedimentology 37, 1115–35.Google Scholar
Deering, C.D., Colei, J.W. & Vogeli, T.A. 2008. A rhyolite compositional continuum governed by lower crustal source conditions in theTaupo Volcanic Zone, New Zealand. Journal of Petrology 49 (12), 2245–76.Google Scholar
Drahor, G. & Berge, M.A. 2006. Geophysical investigations of the Seferihisar geothermal area, Western Anatolia, Turkey. Geothermics 35, 302–20.Google Scholar
Ellis, B. & Branney, M.J. 2010. Silicic phreatomagmatism in the Snake River Plain: the Deadeye Member. Bulletin of Volcanology 72, 1241–57.Google Scholar
Erdoğan, B. 1990. İzmir-Ankara zonu'nun, İzmir ile Seferihisar arasındaki bölgede stratigrafik özellikleri ve tektonik evrimi. Türkiye Petrol Jeologları Derneği Bülteni 2 (1), 120.Google Scholar
Eşder, T. & Şimşek, Ş. 1975. Geology of Izmir (Seferihisar) geothermal area, Western Anatolia of Turkey: determination of reservoirs by means of gradient drilling. In: Proceedings of the second UN Symposium on the Development and Use of Geothermal Resources, San Francisco, pp. 349–61.Google Scholar
Fink, J.H. 1983. Structure and emplacement of a rhyolite obsidian flow: Little Glass Mountain, Medicine Lake Highland, Northern California. Geological Society of America Bulletin 94, 362–80.Google Scholar
Fink, J.H. & Anderson, S.W. 2000. Lava domes and coolees. In Encyclopedia of Volcanoes (eds Sigurdsson, H., Houghton, B.F., McNutt, S.R., Rymer, H. & Stix, J.), pp. 307–19. Academic Press, San Diego.Google Scholar
Fisher, R.V. & Schmincke, H.-U. 1984. Pyroclastic Rocks. Springer-Verlag, Berlin, 472 pp.Google Scholar
Francis, P. & Oppenheimer, C. 2004. Volcanoes. Oxford University Press, Oxford.Google Scholar
Genç, Ş.C., Altunkaynak, Ş., Karacık, Z., Yazman, M. & Yılmaz, Y. 2001. The Çubukludağ graben, south of İzmir: its tectonic significance in the Neogene geological evolution of the western Anatolia. Geodinamica Acta 14 (1/3), 4555.Google Scholar
Helvacı, C., Ersoy, E.Y., Sözbilir, H., Erkül, F., Sümer, Ö. & Uzel, B. 2009. Geochemistry and 40Ar/39Ar geochronology of Miocene volcanic rocks from the Karaburun Peninsula: implications for amphibole-bearing lithospheric mantle source, Western Anatolia. Journal of Volcanology and Geothermal Research 185, 181202.Google Scholar
Houghton, B.F., Wilson, C.J.N. & Pyle, D.M. 2000. Pyroclastic fall deposits. In Encyclopedia of Volcanoes (eds Sigurdsson, H., Houghton, B.F., McNutt, S.R., Rymer, H. & Stix, J.), pp. 571–80. Academic Press, San Diego.Google Scholar
Innocenti, F. & Mazzuoli, R. 1972. Petrology of the İzmir-Karaburun volcanic area (West Turkey). Bulletin of Volcanology 36 (1), 88103.Google Scholar
Justet, L. & Spell, T.L. 2001. Effusive eruptions from a large shallow magma chamber: the Bearhead Rhyolite, Jemez Volcanic Field, New Mexico. Journal of Volcanology and Geothermal Research 107, 241–64.Google Scholar
Karacık, Z., Genç, Ş.C., Esenli, F. & Göller, G. 2011. The Gümüldür fire opal: mode of occurrence and mineralogical aspects. Turkish Journal of Earth Sciences 20, 99114.Google Scholar
Karacık, Z., Genç, Ş.C. & Gülmez, F. 2013. Petrochemical features of Miocene volcanism around the Çubukludağ graben and Karaburun peninsula, western Turkey: implications for crustal melting related silicic volcanism. Journal of Asian Earth Sciences 73, 199217.Google Scholar
Konuk, Y.T. 1977. Bornova Flişi'nin yaşı hakkında. Ege Üniversitesi Fen Fakültesi Dergisi B(1), 6573.Google Scholar
Kshirsagar, P.V., Sheth, H.C., Seaman, S.J., Shaikh, B., Mohite, P., Gurav, T. & Chandrasekharam, D. 2012. Spherulites and thundereggs from pitchstones of the Deccan Traps: geology, petrochemistry, and emplacement environments. Bulletin of Volcanology 74, 559–77.Google Scholar
Lofgren, G. 1970. Experimental devitrification rate of rhyolite glass. Geological Society of American Bulletin 81, 553–60.Google Scholar
Lofgren, G. 1971 a. Experimentally produced devitrification textures in natural rhyolite glass. Geological Society of America Bulletin 82, 553–60.Google Scholar
Lofgren, G. 1971 b. Spherulitic textures in glassy and crystalline rocks. Journal of Geophysical Research 76, 5635–48.Google Scholar
Lorenz, V. 1974. Vesiculated tuffs and associated features. Sedimentology 21, 273–91.Google Scholar
Nemeth, K. & White, J.D.L. 2003. Reconstructing eruption processes of a Miocene monogenetic volcanic field from vent remnants: Waipiata Volcanic Field, South Island, New Zealand. Journal of Volcanology and Geothermal Research 124, 121.CrossRefGoogle Scholar
Ocakoğlu, N., Demirbağ, E. & Kuşçu, İ. 2004. Neotectonic structures in the area offshore of Alaçatı, Doğanbey, and Kuşadası (western Turkey): evidence of strike-slip faulting in the Aegean extensional province. Tectonophysics 391, 6783.Google Scholar
Rosi, M. 1992. A model for the formation of vesiculated tuff by the coalescence of accretionary lapilli. Bulletin of Volcanology 54, 429–34.Google Scholar
Schumacher, R. & Schmincke, H.-U. 1995. Models for the origin of accretionary lapilli. Bulletin of Volcanology 56, 626–39.Google Scholar
Self, S. & Sparks, R.S.J. 1978. Characteristics of widespread pyroclastic deposits formed by the interaction of silicic magma and water. Bulletin of Volcanology 41, 196212.Google Scholar
Shaub, B.M. 1979. Genesis of thundereggs, geodes, and agates of igneous origin. Lapidary Journal 32, 2340–66.Google Scholar
Smith, V.C., Shane, P. & Nairn, I.A. 2005. Trends in rhyolite geochemistry, mineralogy, and magma storage during the last 50 kyr at Okataina and Taupo volcanic centres, Taupo Volcanic Zone, New Zealand. Journal of Volcanology and Geothermal Research 148, 372406.Google Scholar
Sohn, Y.K. & Chough, S.K. 1989. Depositional processes of the Suwolbong tuff ring, Cheju Island (Korea). Sedimentology 36, 837–55.Google Scholar
Sohn, Y.K. & Park, K.H. 2005. Composite tuff ring/cone complexes in Jeju Island, Korea: possible consequences of substrate collapse and vent migration. Journal of Volcanology and Geothermal Research 141, 157–75.Google Scholar
Stevenson, R.J., Briggs, R.M. & Hodder, A.P.W. 1994. Physical volcanology and emplacement history of the Ben-Lomond rhyolite lava flow, Taupo Volcanic Center, New-Zealand. New Zealand Journal of Geology and Geophysics 37 (3), 345–58.CrossRefGoogle Scholar
Tait, M.A., Cas, R.A.F. & Viramonte, J.G. 2009. The origin of an unusual tuff ring of perlitic rhyolite pyroclasts: the last explosive phase of the Ramadas Volcanic Centre, Andean Puna, Salta, NW Argentina. Journal of Volcanology and Geothermal Research 183, 116.Google Scholar
Tarcan, G. & Gemici, Ü. 2003. Water geochemistry of the Seferihisar geothermal area, İzmir, Turkey. Journal of Volcanology and Geothermal Research 126, 225–42.Google Scholar
Türkelli, N., Kalafat, D. & Gündoğdu, O. 1995. 6 Kasım 1992 İzmir (Doğanbeyli) depremi saha gözlemleri ve odak mekanizma çözümü. Jeofizik 9–10, 343–8.Google Scholar
Türkelli, N., Kalafat, D. & İnce, Ş. 1990. 6 Kasım 1992 İzmir depremi ve artçı şokları. Deprem Araştırma Bülteni 68, 5895.Google Scholar
Uzel, B. & Sözbilir, H. 2008. A first record of a strike-slip basin in Western Anatolia and its tectonic implication: the Cumaovası Basin. Turkish Journal of Earth Sciences 17, 559–91.Google Scholar
Waitt, R.B. & Dzurisin, D. 1981. Proximal airfall deposits from the May 18 eruption: stratigraphy and field sedimentology. In: The 1980 Eruptions of Mount St Helens, Washington (Lipman, P.W. & Mullineaux, D.R., eds), 601–16. US Geological Survey Professional Paper, 1250.Google Scholar
Wohletz, K.H. & Sheridan, M.F. 1979. A model of pyroclastic surge. In Ash-flow Tuffs (eds C.E. Chapin & W.E. Elston), pp. 177–94. Geological Society of America, Special Paper no. 180.Google Scholar
Yağmurlu, F. 1980. Bornova (İzmir) güneyi fliş topluluklarının jeolojisi. Bulletin of the Geological Society of Turkey 23, 141–52.Google Scholar
Supplementary material: File

Karacik supplementary tifs

Karacik supplementary tifs

Download Karacik supplementary tifs(File)
File 19.1 MB