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A late pleistocene glacial chronology from the Kitschi-Kurumdu Valley, Tien Shan (Kyrgyzstan), based on 10Be surface exposure dating

Published online by Cambridge University Press:  20 January 2017

Roland Zech
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Abstract

Surface exposure dating has become a helpful tool for establishing numeric glacial chronologies, particularly in arid high-mountain regions where radiocarbon dating is challenging due to limited availability of organic material. This study presents 13 new 10Be surface exposure ages from the Kitschi-Kurumdu Valley in the At Bashi Range, Tien Shan. Three moraines were dated to ~ 15, 21 and > 56 ka, respectively, and corroborate previous findings that glacial extents in the Tien Shan during Marine Oxygen Isotope Stage (MIS) 2 were limited compared to MIS 4. This likely documents increasingly arid conditions in Central Asia during the last glacial cycle. Morphological evidence in the Kitschi-Kurumdu Valley and a detailed review of existing numeric glacial chronologies from the Tien Shan indicate that remnants of the penultimate glaciation (MIS 6) are preserved, whereas evidence for MIS 5 glacier advances remains equivocal. Reviewed and recalculated exposure ages from the Pamir mountains, on the other hand, reveal extensive MIS 5 glacial extents that may indicate increased monsoonal precipitation. The preservation of MIS 3 moraines in the Tien Shan and the southern Pamir does not require any monsoonal influence and can be explained alternatively with increased precipitation via the westerlies.

Keywords

Cosmogenic nuclidesQuaternaryGlaciationPaleoclimateMonsoonCentral Asia
Type
Original Articles
Information
Quaternary Research , Volume 77 , Issue 2 , March 2012 , pp. 281 - 288
Copyright
University of Washington

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References

Abramowski, U. Bergau, A. Seebach, D. Zech, R. Glaser, B. Sosin, P. Kubik, P.W. Zech, W. 2006, Pleistocene glaciations of Central Asia: results from 10Be surface exposure ages of erratic boulders from the Pamir (Tajikistan), and the Alay-Turkestan range (Kyrgyzstan). Quaternary Science Reviews 25, 10801096.Google Scholar
Aizen, V.B. Aizen, E.M. Melack, J.M. 1995, Climate, snow cover, glaciers and runoff in the Tien Shan, central Asia. Water Resources Bulletin 31, 11131129.Google Scholar
Aizen, E.M. Aizen, V.B. Melack, J.M. Nakamura, T. Ohta, T. 2001, Precipitation and atmospheric circulation patterns at mid-latitudes of Asia. International Journal of Climatology 21, 535556.Google Scholar
Balco, G. Stone, J.O. Lifton, N.A. Dunai, T.J. 2008, A complete and easily accessible means of calculating surface exposure ages or erosion rates from 10Be and 26Al measurements. Quaternary Geochronology 3, 174195.Google Scholar
Briner, J.P. Kaufman, D.S. Manley, W.F. Finkel, R.C. Caffee, M.W. 2005, Cosmogenic exposure dating of late Pleistocene moraine stabilization in Alaska. Geological Society of America Bulletin 117, 11081120.Google Scholar
Chlachula, J. 2003, The Siberian loess record and its significance for reconstruction of Pleistocene climate change in north-central Asia. Quaternary Science Reviews 22, 18791906.CrossRefGoogle Scholar
Clark, P.U. Dyke, A.S. Shakun, J.D. Carlson, A.E. Clark, J. Wohlfarth, B. Mitrovica, J.X. Hostetler, S.W. McCabe, A.M. 2009, The Last Glacial Maximum. Science 325, 710714.Google Scholar
Dortch, J.M. Owen, L.A. Caffee, M.W. Brease, P. 2010, Late Quaternary glaciation and equilibrium line altitude variations of the McKinley River region, central Alaska Range. Boreas 39, 233246.Google Scholar
Ehlers, J. Gibbard, P.L. Hughes, P.D. 2011, Quaternary Glaciations—Extent and Chronology, Volume 15: A Closer Look. Elsevier.Google Scholar
Finkel, R.C. Owen, L.A. Barnard, P.L. Caffee, M.W. 2003, Beryllium-10 dating of Mount Everest moraines indicates a strong monsoon influence and glacial synchroneity throughout the Himalaya. Geology 31, 561564.Google Scholar
Frechen, M. Dodonov, A. 1998, Loess chronology of the Middle and Upper Pleisocene in Tadjikistan. Geologische Rundschau 87, 220.Google Scholar
Frechen, M. Zander, A. Zykina, V. Boenigk, W. 2005, The loess record from the section at Kurtak in Middle Siberia. Palaeogeography, Palaeoclimatology, Palaeoecology 228, 228244.Google Scholar
Gillespie, A. Molnar, P. 1995, Asynchronous maximum advances of mountain and continental glaciers. Review of Geophysics 33, 311364.CrossRefGoogle Scholar
Heyman, J. Stroeven, A.P. Harbor, J.M. Caffee, M.W. 2011, Too young or too old: evaluating cosmogenic exposure dating based on an analysis of compiled boulder exposure ages. Earth and Planetary Science Letters 302, 7180.CrossRefGoogle Scholar
Ivy-Ochs, S. 1996, The dating of rock surface using in situ produced 10Be, 26Al and 36Cl, with examples from Antarctica and the Swiss Alps. . Dissertation ETH No. 11763, Zürich, pp. 197 pp.Google Scholar
Kaplan, M.R. Strelin, J.A. Schaefer, J.M. Denton, G.H. Finkel, R.C. Schwartz, R. Putnam, A.E. Vandergoes, M.J. Goehring, B.M. Travis, S.G. 2011, In-situ cosmogenic 10Be production rate at Lago Argentino, Patagonia: implications for late-glacial climate chronology. Earth and Planetary Science Letters 309, 2132.Google Scholar
Kaser, G. 2001, Glacier–climate interaction at low latitudes. Journal of Glaciology 47, 195204.CrossRefGoogle Scholar
Koppes, M. Gillespie, A.R. Burke, R.M. Thompson, S.C. Stone, J. 2008, Late Quaternary glaciation in the Kyrgyz Tien Shan. Quaternary Science Reviews 27, 846866.Google Scholar
Kull, C. Imhof, S. Grosjean, M. Zech, R. Veit, H. 2008, Late Pleistocene glaciation in the Central Andes: temperature versus humidity control—a case study from the eastern Bolivian Andes (17°S) and regional synthesis. Global and Planetary Change 60, 148164.Google Scholar
Lal, D. 1991, Cosmic ray labeling of erosion surfaces: in situ nuclide production rates and erosion models. Earth and Planetary Science Letters 104, 429439.Google Scholar
Lifton, N.A. 2011, Potential resolution of discrepancies between scaling models for in situ cosmogenic nuclide production rates. INQUA meeting, abstract #1554 Bern.Google Scholar
Mix, A.C. Bard, E. Schneider, R. 2001, Environmental processes of the ice age: land, oceans, glaciers (EPILOG). Quaternary Science Reviews 20, 627657.Google Scholar
Narama, C. Kondo, R. Tsukamoto, S. Kajiura, T. Ormukov, C. Abdrakhmatov, K. 2007, OSL dating of glacial deposits during the Last Glacial in the Terskey-Alatoo Range, Kyrgyz Republic. Quaternary Geochronology 2, 249254.Google Scholar
Narama, C. Kondo, R. Tsukamoto, S. Kajiura, T. Duishonakunov, M. Abdrakhmatov, K. 2009, Timing of glacier expansion during the Last Glacial in the inner Tien Shan, Kyrgyz Republic by OSL dating. Quaternary International 199, 147156.Google Scholar
Owen, L.A. Finkel, R.C. Caffee, M.W. Gualtieri, L. 2002, Timing of multiple late Quaternary glaciations in the Hunza Valley, Karakorum Mountains, northern Pakistan: defined by cosmogenic radionuclide dating of moraines. GSA Bulletin 114, 593604.Google Scholar
Owen, L.A. Caffee, M.W. Finkel, R.C. Seong, Y.B. 2008, Quaternary glaciation of the Himalayan–Tibetan orogen. Journal of Quaternary Science 23, 513531.Google Scholar
Putkonen, J. Swanson, T. 2003, Accuracy of cosmogenic ages for moraines. Quarternary Research 59, 255261.Google Scholar
Putnam, A.E. Schaefer, J.M. Barrell, D.J.A. Vandergoes, M. Denton, G.H. Kaplan, M.R. Finkel, R.C. Schwartz, R. Goehring, B.M. Kelley, S.E. 2010, In situ cosmogenic 10Be production-rate calibration from the Southern Alps, New Zealand. Quaternary Geochronology 5, 392409.Google Scholar
Rupper, S. Roe, G. Gillespie, A. 2009, Spatial patterns of Holocene glacier advance and retreat in Central Asia. Quaternary Research 72, 337346.CrossRefGoogle Scholar
Seong, Y.B. Owen, L.A. Yi, C. Finkel, R.C. 2009, Quaternary glaciation of Muztag Ata and Kongur Shan: evidence for glacier response to rapid climate changes throughout the Late Glacial and Holocene in westernmost Tibet. Geological Society of America Bulletin 121, 348365.Google Scholar
Stauch, G. Gualtieri, L. 2008, Late Quaternary glaciations in northeastern Russia. Journal of Quaternary Science 23, 545558.Google Scholar
Stone, J.O. 2000, Air pressure and cosmogenic isotope production. Journal of Geophysical Research 105, 23,753-23,759.CrossRefGoogle Scholar
Svendsen, J.I. Alexanderson, H. Astakhov, V.I. Demidov, I. Dowdeswell, J.A. Funder, S. Gataullin, V. Henriksen, M. Hjort, C. Houmark-Nielsen, M. 2004, Late Quaternary ice sheet history of northern Eurasia. Quaternary Science Reviews 23, 12291271.CrossRefGoogle Scholar
Thackray, G.D. Owen, L.A. Yi, C. 2008, Timing and nature of late Quaternary mountain glaciation. Journal of Quaternary Science 23, 503508.Google Scholar
Zech, R. Glaser, B. Sosin, P. Kubik, P.W. Zech, W. 2005a, Evidence for long-lasting landform surface instability on hummocky moraines in the Pamir Mountains from surface exposure dating. Earth and Planetary Science Letters 237, 453461.Google Scholar
Zech, R. Abramowski, U. Glaser, B. Sosin, P. Kubik, P.W. Zech, W. 2005b, Late Quaternary glacial and climate history of the Pamir Mountains derived from cosmogenic 10Be exposure ages. Quaternary Research 64, 212220.Google Scholar
Zech, R. May, J.-H. Kull, C. Ilgner, J. Kubik, P. Veit, H. 2008, Timing of the late Quaternary glaciation in the Andes from 15 to 40°S. Journal of Quaternary Science 23, 635647.CrossRefGoogle Scholar
Zech, W. Zech, R. Zech, M. Leiber, K. Dippold, M. Frechen, M. Bussert, R. Andreev, A. 2011, Obliquity forcing of Quaternary glaciation and environmental changes in NE Siberia. Quaternary International 234, 133145.CrossRefGoogle Scholar
Zhao, J. Liu, S. He, Y. Song, Y. 2009, Quaternary glacial chronology of the Ateaoyinake River Valley, Tianshan Mountains, China. Geomorphology 103, 276284.Google Scholar
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