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13 - Megaflood sedimentary valley fill: Altai Mountains, Siberia

Published online by Cambridge University Press:  04 May 2010

By
Paul A. Carling ,
I. Peter Martini ,
Jürgen Herget ,
Pavel Borodavko  and
Sergei Parnachov
Edited by
Devon M. Burr ,
Paul A. Carling  and
Victor R. Baker
Devon M. Burr
Affiliation:
University of Tennessee
Paul A. Carling
Affiliation:
University of Southampton
Victor R. Baker
Affiliation:
University of Arizona
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Summary

Summary

During the Quaternary, the Altai Mountains of south-central Siberia sustained ice caps and valley glaciers. Glaciers or ice lobes emanating from plateaux blocked the outlet of the Chuja–Kuray intermontane basins and impounded meltwater to form large ice-dammed lakes up to 600 km3 capacity. On occasion the ice dams failed and the lakes emptied catastrophically. The megafloods that resulted were deep, fast-flowing and heavily charged with sand and gravel, the sediment being sourced from the lake basins and also entrained along the course of the floodways. The floods were confined within mountain valleys of the present-day rivers Chuja and Katun but large quantities of sediment were deposited over a distance of more than 70 km from the dam site in tributary river-mouths, re-entrants in the confining valley walls and on the inside of major valley bends. The main depositional units that resulted are giant bars, which blocked the entrances to tributaries and temporarily impeded normal drainage from the tributaries into the main-stem valley such that minor lakes were impounded within the tributaries behind the bars. Fine sediment from the tributaries accumulated in these lakes as local lacustrine units. Later the bars were breached by the tributary flows and the local lakes were drained. Sections of the giant bar sediments and the local lacustrine units are used to describe the nature of the megaflood valley fill, which was deposited primarily during marine isotope stage 2.

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Information
Megaflooding on Earth and Mars , pp. 243 - 264
Publisher: Cambridge University Press
Print publication year: 2009

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References

Allen, J. R. L. (1981). Sediments and processes on a small alluvial stream-dominated Devonian alluvial fan, Shetland Islands. Sedimentary Geology, 29, p. 31–66.CrossRefGoogle Scholar
Baker, V. R. (1973). Paleohydrology of Catastrophic Pleistocene Flooding in Eastern Washington. Geological Society of America Special Paper, 144.Google Scholar
Baker, V. R. (2002). The study of superfloods. Science, 295, 2379–2380.CrossRefGoogle Scholar
Baker, V. R. and Bunker, R. C. (1985). Cataclysmic late Pleistocene flooding from glacial Lake Missoula: a review. Quaternary Science Reviews, 4, 1–41.CrossRefGoogle Scholar
Baker, V. R., Benito, G. B. and Rudoy, A. N. (1993). Paleohydrology of Late Pleistocene superflooding, Altay Mountains, Siberia. Science, 259, 348–350.CrossRefGoogle ScholarPubMed
Benvenuti, M. and Martini, I. P. (2002). Analysis of terrestrial hyperconcentrated flows and their continental deposits. In Flood and Megaflood Processes and Deposits, eds. Martini, I. P., Baker, V. R. and Garzon, G.. Sedimentology Special Publication32, pp. 167–194.Google Scholar
Blyakharchuk, T., Wright, H. E., Borodavko, P. S., Knaap, W. O. and Ammann, B. (2004). Late Glacial and Holocene vegetational changes on the Ulagan high-mountain plateau, Altai Mountains, southern Siberia. Palaeogeography Palaeoclimatology Paleoecology, 209, 259–279.CrossRefGoogle Scholar
Bretz, J H. (1928). The Channeled Scabland of Eastern Washington. Geographical Review, 18, 446–477.CrossRefGoogle Scholar
Bretz, J H., Smith, H. T. U. and Neff, G. E. (1956). Channeled Scabland of Washington; new data and interpretations. Geological Society of America Bulletin, 67, 957–1049.CrossRefGoogle Scholar
Buslov, M. M., Zykin, V. S., Novikov, I. S. and Delvaux, D. (1999). The Cenozoic history of the Chuja Depression (Gonry Altai): Structures and geodynamics. Geologiya i Geofizika, 40 (12), 1720–1736 (in Russian).Google Scholar
Carling, P. A. (1996). Morphology, sedimentology and palaeohydraulic significance of large gravel dunes, Altai Mountains, Siberia. Sedimentology, 43, 647–564.CrossRefGoogle Scholar
Carling, P. A., Kirkbride, A. D., Parnachov, S., Borodavko, P. S. and Berger, G. B. (2002). Late-glacial catastrophic flooding in the Altai Mountains of south-central Siberia: a synoptic overview and introduction to flood deposit sedimentology. In Flood and Megaflood Processes and Deposits: Recent and Ancient Examples, eds. Martini, I. P., Baker, V. R. and Garzon, G.. Special Publication 32 of the IAS, Oxford: Blackwell Science.Google Scholar
Carling, P., Villanueva, I., Herget, J.et al. (in press). Unsteady 1-D and 2-D hydraulic models with ice-dam break for Quaternary megaflood, Altai Mountains, southern Siberia. Global and Planetary Change, Special Issue.
Cheel, R. J. (1990). Horizontal lamination and the sequence of bed phases and stratification under upper-flow-regime conditions. Sedimentology, 37, 517–529.CrossRefGoogle Scholar
Chikov, B. M., Zinoviev, S. V. and Deyev, E. V. (2008). Mesozoic and Cenozoic collisional structures of the southern Great Altai. Russian Geology and Geophysics, 49, 323–331.CrossRefGoogle Scholar
Fisher, T. G. and Smith, D. G. (1993). Exploration for Pleistocene aggragate resources using process-depositional models in the Fort McMurray region, NE Allberta, Canada. Quaternary International, 20, 71–80.CrossRefGoogle Scholar
Gilliespie, A. R., Burke, R. M., Komatsu, G. and Bayasgalan, A. (2008). Late Pleistocene glaciers in Darhad Basin, northern Mongolia. Quaternary Research, 69, 169–187.CrossRefGoogle Scholar
Haeberli, W. (1983). Frequency and characteristics of glacier floods in the Swiss Alps. Annals of Glaciology, 4, 85–90.CrossRefGoogle Scholar
Herget, J. (2005). Reconstruction of Pleistocene Ice-Dammed Lake Outburst Floods in the Altai Mountains, Siberia. Geological Soceity of America, Special Paper 386.CrossRef
Hiscott, R. N. (1994). Traction-carpet stratification in turbidites: fact or fiction?Journal of Sedimentary Research, A64 (2), 204–208.Google Scholar
Hiscott, R. N. and Middleton, G. V. (1980). Fabric of coarse deep-water sandstones, Tourelle Formation, Quebec, Canada. Journal of Sedimentary Petrology, 50, 703–722.Google Scholar
Jaegar, C. (1980). Rock Mechanics and Engineering, Cambridge: Cambridge University Press.Google Scholar
Kneller, B. (1995). Beyond the turbidite paradigm: physical models for deposition of turbidites and their implications for reservoir prediction. In Characteristics of Deep Marine Clastic Systems, eds. Hartley, A. J. and Prosser, D. J.. Geological Society Special Publication 94, pp. 31–49.Google Scholar
Koppes, M., Gillespie, A. R., Burke, R. M., Thompson, S. C. and Stone, J. (2008). Late Quaternary glaciation in the Kyrgyz Tien Shan. Quaternary Science Reviews, 27, 846–866.CrossRefGoogle Scholar
Lønne, I. (1997). Facies characteristics of proglacial turbiditic sand-lobe at Svalbard. Sedimentary Geology, 109, 13–35.CrossRefGoogle Scholar
Lowe, D. R. (1982). Sediment gravity flows II. Depositional models with special reference to the deposits of high-density turbidity currents. Journal of Sedimentary Petrology, 52, 279–297.Google Scholar
Maizels, J. (1993). Lithofacies variations within sandur deposits: the role of runoff regime, flow dynamics and sediment supply characteristics. Sedimentary Geology, 85, 299–325.CrossRefGoogle Scholar
Moody, U. L. (1988). Late Quaternary stratigraphy of the Channeled Scabland and adjacent areas. Unpublished Ph.D. thesis, University of Idaho, USA.
Morgenstern, N. R. (1963). Stability charts for earth slopes during rapid drawdown. Geotechnique, 13, 121–131.CrossRefGoogle Scholar
Morgenstern, N. R. (1967). Submarine slumping and the initiation of turbidity currents. In Marine Geotechnique, ed. Richards, A. F.. University of Illinois Press, pp. 189–220.Google Scholar
Novikov, I. S. and Parnachev, S. V. (2000). Morphotectonics of late Quaternary lakes in river valleys and intermountain troughs of southwestern Altai. Geologiya I Geofiska, 2, 227–238 (in Russian).Google Scholar
Ota, T., Utsunomiya, A., Uchio, Y.et al. (2007). Geology of the Gorny Altai subduction-accretion complex, southern Siberia: tectonic evolution of an Ediacaran-Cambrian intra-oceanic arc-trench system. Journal of Asian Earth Sciences, doi:10.1016/j.jseaes.2007.03.001.CrossRefGoogle Scholar
Postma, G. (1986). Classification of sediment gravity flow deposits based on flow conditions during sedimentation. Geology, 14, 291–294.2.0.CO;2>CrossRefGoogle Scholar
Postma, G. and Cruickshank, C. (1988). Sedimentology of a late Weichselian to Holocene terraced fan delta, Varangerfjord, northern Norway. In Fan Deltas: Sedimentology and Tectonic Settings, eds. Nemec, W. and Steel, R. J.. Glassgow, London: Blackie and Son, pp. 144–157.Google Scholar
Postma, G., Nemec, W. and Kleinspehn, K. L. (1988). Large floating clasts in turbidites: a mechanism for their emplacement. Sedimentary Geology, 58, 47–61.CrossRefGoogle Scholar
Ragosin, L. A. (1942). Middle Katun valley terrace. In Investigation and Exploration of the Productive Force of Siberia, pp. 36–107. Proceedings of a Scientific Conference, Tomsk University, Tomsk (in Russian).Google Scholar
Reuther, A. U., Herget, J., Ivy-Ochs, S.et al. (2006). Constraining the timing of the most recent cataclysmic flood event from ice-dammed lakes in the Russian Altai Mountains, Siberia, using cosmogenic in situ 10Be. Geology, 34, 913–916.CrossRefGoogle Scholar
Rudoy, A. N. (1988). Regime of glacial-dammed lakes in the intermontane basins of South Siberia. USSR Academy of Sciences Materials of Glaciological Research, 61, 36–42 (in Russian).Google Scholar
Rudoy, A. N. (1990). Ice flow and ice-dammed lakes of the Altai in the Pleistocene. USSR Academy of Sciences Izvestiya, Seriya geograficheskaya, 120, 344–348 (in Russian).Google Scholar
Rudoy, A. N. (1998). Mountain ice-dammed lakes of southern Siberia and their influence on the development and regime of the intracontinental run-off systems of north Asia in Late Pleistocene. In Palaeohydrology and Environmental Change, eds. Beninto, G., Baker, V. R. and Gregory, K. J.. Chichester: John Wiley & Sons, pp. 215–234.Google Scholar
Rudoy, A. N. and Baker, V. R. (1993). Sedimentary effects of cataclysmic late Pleistocene glacial outburst flooding, Altay Mountains, Siberia. Sedimentary Geology, 85, 53–62.CrossRefGoogle Scholar
Rudoy, A. N., Galakov, V. P. and Danilin, A. L. (1989). Reconstruction of glacial drainage of the upper Chuja and the feeding of ice-dammed lakes in the Late Pleistocene. All-Union Geographical Society Proceedings, 121, 236–244 (in Russian).Google Scholar
Russell, A. J. and Knudsen, Ó. (1999). An ice-contact rhythmite (turbidite) succession deposited during the November 1996 catastrophic outburst flood (jökulhlaup), Skeiðarárjökull, Iceland. Sedimentary Geology, 127, 1–10.CrossRefGoogle Scholar
Russell, A. J., Fay, H., Marren, P. M., Tweed, F. S. and Knudsen, Ó. (2005). Icelandic jökulhlaup impacts. In Iceland: Modern Processes and Past Environments, eds. Caseldine, C., Russell, A., Harđardóttir, J. and Knudsen, Ó.. Developments in Quaternary Science, 5, Amsterdam: Elsevier, pp. 153–203.CrossRefGoogle Scholar
Rust, B. R. and Romanelli, R. (1975). Late Quaternary sub-aqueous outwash deposits near Ottawa, Canada. In Glaciofluvial and Glaciolacustrine Sedimentation, eds. Jopling, A. V. and McDonald, B. C.. SEPM Special Publication 23, pp. 177–192.CrossRefGoogle Scholar
Sallenger, A. H. (1979). Inverse grading and hydraulic equivalence in grain-flow deposits. Journal of Sedimentary Petrology, 49, 553–562.Google Scholar
Shanmugan, G. (1996). High-density turbidity currents: are they sandy debris flows?Journal of Sedimentary Research, 66, 2–10.CrossRefGoogle Scholar
Shaw, J. (1977). Sedimentation in an alpine lake during deglaciation; Okanagan Valley, British Columbia, Canada. Geografiska Annaler, 59, 221–240.CrossRefGoogle Scholar
Sheinkman, V. C. (2002). The diagnostic age of glacial sediments of the Altai, tested using sections of the Dead Sea. In Data of Glaciological Studies, Publication 93, Institute of Geography of the Russian Academy of Science, Glaciological Association, pp. 41–55. (In Russian with English summary.)
Smith, G. A. (1993). Missoula flood dynamics and magnitudes inferred from sedimentology of slack-water deposits on the Columbia Plateau, Washington. Geological Society of America Bulletin, 105, 77–100.2.3.CO;2>CrossRefGoogle Scholar
Sohn, Y. K. (1997). On traction-carpet sedimentation. Journal of Sedimentary Research, 67A, 502–509.Google Scholar
Thomas, G. S. P. and Connell, R. J. (1985). Iceberg drop, dump, and grounding structures for Pleistocene glacio-lacustrine sediments. Journal of Sedimentary Research, 55 (2), 243–249.Google Scholar
Todd, S. P. (1989). Stream-driven, high-density gravelly traction carpets: possible deposits in the Trabeg Conglomerate Formation, SW Ireland and some theoretical considerations of their origin. Sedimentology, 36, 513–530.CrossRefGoogle Scholar
Tweed, F. S. and Russell, A. J. (1999). Controls on the formation and sudden drainage of glacier-impounded lakes: implications for jökulhlaup characteristics. Progress in Physical Geography, 23, 79–110.CrossRefGoogle Scholar
Vrolijk, P. J. and Southard, J. B. (1997). Experiments on rapid deposition of sand from high-velocity flows. Geoscience Canada, 24, 45–54.Google Scholar
Waitt, R. B. (1980). About forty last-glacial Lake Missoula jokulhlaups through southern Washington. Journal of Geology, 88, 653–679.CrossRefGoogle Scholar
Zykin, V. S. and Kazanskii, A. Y. (1995). Stratigraphy of Cainozoic (Pre-Quaternary) deposits of the Chuja depression in Gorny Altai. Geologiya I Geofizika, 36 (10), 75–84.Google Scholar

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