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AMS 14C Dating of Pollen Concentrate from Late Pleistocene ICE Wedges From the Bison and Seyaha Sites in Siberia

Published online by Cambridge University Press:  18 July 2016

Alla Vasil'chuk ,
Jong-Chan Kim  and
Yurij Vasil'chuk
Alla Vasil'chuk
Affiliation:
Departments of Geology and Geography, Lomonosov's Moscow State University, Leninskie Hills, Moscow, Russia, 119992. Email: [email protected]
Jong-Chan Kim
Affiliation:
Department of Physics, Seoul National University, Kwanak-ku, Seoul, 151–742, South Korea. Email: [email protected]
Yurij Vasil'chuk
Affiliation:
Departments of Geology and Geography, Lomonosov's Moscow State University, Leninskie Hills, Moscow, Russia, 119992. Email: [email protected]
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Abstract

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Accelerator mass spectrometry (AMS) radiocarbon dates of pollen concentrate were obtained from multistage syngenetic ice wedges of cross-sections from the Late Pleistocene Bison site, located along the Lower Kolyma River (68°34'N, 158°34'E), from ∼43,600 to ∼26,200 BP, and 3 AMS 14C dates of pollen concentrate in ice wedges from the Seyaha site cross-section, located on the east coast of the Yamal Peninsula (70°10'N, 72°34'E), from ∼22,400 to ∼25,200 BP. Pollen concentrate samples were prepared using a special pretreatment procedure. Pollen and spores from ice-wedge ice signalize a regional pollen rain. Therefore, 14C-dated extracts of pollen and spores from ice-wedge ice enable an adequate reconstruction and chronology of landscape dynamics on a regional scale. The pollen and spores were well preserved despite numerous redepositions in the penecontemporaneous structure in which they were found. Thus, a comparison with dates on other fractions from the same sample is necessary. The youngest date is the most reliable among the intersample AMS 14C dates from the ice and permafrost sediments.

Type
Articles
Information
Radiocarbon , Volume 47 , Issue 2 , 2005 , pp. 243 - 256
Copyright
Copyright © 2005 by the Arizona Board of Regents on behalf of the University of Arizona 

References

Brown, TA, Nelson, DE, Matthews, RW, Vogel, JS, Southon, JR. 1989. Radiocarbon dating of pollen extracted from peat samples by accelerator mass spectrometry. Quaternary Research 32:205–12.Google Scholar
Gillespie, R. 1990. On the use of oxidation for AMS sample preparation. Nuclear Instruments and Methods in Physics Research B 52:345–47.Google Scholar
Kilian, MR, van der Plicht, J, van Geel, B, Goslar, T. 2002. Problematic 14C AMS dates of pollen concentrates from Lake Gos`ciąż (Poland). Quaternary International 88:21–6.Google Scholar
Kim, JC, Lee, CH, Park, JH, Kang, J, Cheoun, MK, Kim, YD, Moon, CB. 2000. A new AMS facility in Korea. Nuclear Instruments and Methods in Physics Research B 172:13–7.Google Scholar
Kretschmer, W, Kerscher, H, Klein, M, Morgenroth, G. 1999. The Erlangen AMS facility: status and applications in archaeology, geology and environmental research. In: Frontiers in Accelerator Mass Spectrometry. Proceedings of the International Workshop. Tsukuba-Sakura, Japan, 6–8 January 1999. p 6274.Google Scholar
Long, A, Davis, OK, de Lanois, JD. 1992. Separation and 14C dating of pure pollen from lake sediments. Radiocarbon 34(3):557–60.Google Scholar
Mensing, SA, Southon, JR. 1999. A simple method to separate pollen for AMS radiocarbon dating and its application to lacustrine and marine sediments. Radiocarbon 41(1):18.CrossRefGoogle Scholar
Nelson, RE, Carter, LD, Robinson, SW. 1988. Anomalous radiocarbon ages from a Holocene detrital organic lens in Alaska and their implications for radiocarbon dating and paleoenvironmental reconstructions in the Arctic. Quaternary Research 29(1):6671.Google Scholar
Olsson, IU. 1974. Some problems in connection with the evaluation of 14C dates. Geologiska Föreningens i Stockholm Förhandlingar 96:311–20.Google Scholar
Olsson, IU. 1991. Accuracy and precision in sediment chronology. Hydrobiologia 214:2534.Google Scholar
Pancost, RD, van Geel, B, Baas, M, Damste, JSS. 2000. δ13C values and radiocarbon dating of microbial biomarkers as traces for carbon recycling in peat deposits. Geology 28(7):663–6.Google Scholar
Regnell, J. 1992. Preparing of pollen concentrate for AMS dating–a methodological study from a hard-water lake in southern Sweden. Boreas 21(4):373–7.Google Scholar
Richardson, F, Hall, V. 1994. Pollen concentrate preparation from highly organic Holocene peat and lake deposits for AMS dating. Radiocarbon 36(3):407–12.Google Scholar
Stuckenrath, R, Miller, GH, Andrews, JT. 1979. Problems of radiocarbon dating Holocene organic-bearing sediments, Cumberland Peninsula, Baffin Island, NWT, Canada. Arctic and Alpine Research 11(1):109–20.Google Scholar
Ukraintseva, W. 1993. Vegetation Cover and Environment of the “Mammoth Epoch” in Siberia. [Agenbroad, LD, Mead, JI, Helvy, RJ, editors]. Hot Springs: The Mammoth Site of Hot Springs, Inc. 309 p.Google Scholar
Vasil'chuk, AC. 2003. Appearance of Heinrich events in 14C-dated pollen and spore diagrams of edoma sediments and ice wedges of Lower Kolyma. Earth Cryosphere 7(4):313. In Russian.Google Scholar
Vasil'chuk, Y. 1992. Oxygen Isotope Composition of Ground Ice (Application to Paleogeocryological Reconstructions). Moscow: Theoretical Problems Department, Russian Academy of Sciences and Lomonosov's Moscow University publication. Volume 1:420 p; Volume 2:264 p. In Russian, with English contents, figure captions, and summary.Google Scholar
Vasil'chuk, Y, Vasil'chuk, AC. 1996. Late Pleistocene oxygen-isotope curves and radiocarbon dating for syngenetic ice-wedges. In: van der Plicht, J, Punning, J-M, editors. Proceedings, 11th International Workshop on Isotope-Geochemical Research in the Baltic Region. Lohusalu, Estonia, 14–16 March 1996. Groningen: Groningen Isotope Centre Publ. p 7796.Google Scholar
Vasil'chuk, AC, Vasil'chuk, Y. 1998a. The application of pollen and spores to determine the origin and formation conditions of ground ice in western Siberia. In: Lewkowicz, AG, Allard, M, editors. Proceedings, 7th International Conference on Permafrost. Yellowknife, Canada, 23–27 June 1998. University Laval, Centre d'etudes nordiques. Collection Nordicana 57:1071–6.Google Scholar
Vasil'chuk, Y, Vasil'chuk, AC. 1998b. A model of thick syngenetic ice-wedge formation. In: 28th International Arctic Workshop. Arctic and Alpine Environments, Past and Present. Abstracts. Boulder: Institute of Arctic and Alpine Research. p 157–9.Google Scholar
Vasil'chuk, Y, van der Plicht, J, Jungner, H, Sonninen, E, Vasil'chuk, AC. 2000. First direct dating of Late Pleistocene ice wedges by AMS. Earth and Planetary Science Letters 179(2):237–42.Google Scholar
Vasil'chuk, Y, Vasil'chuk, AC, Rank, D, Kutschera, W, Kim, J. 2001a. Radiocarbon dating of δ18O-δD plots in Late Pleistocene ice wedges of the Duvanny Yar (Lower Kolyma River, northern Yakutia). Radiocarbon 43(2B):541–53.Google Scholar
Vasil'chuk, Y, Vasil'chuk, AC, van der Plicht, J, Kutschera, W, Rank, D. 2001b. Radiocarbon dating of the Late Pleistocene ice wedges in the Bison section in the lower reaches of the Kolyma River. Doclady Earth Sciences 379(5):589–93.Google Scholar
Vasil'chuk, Y, van der Plicht, J, Kutschera, W, Papesch, W, Rank, D, Vasil'chuk, AC. 2002. AMS dating of the δ18O-δD plots in Bison ice-wedge complex. In: 9th International Conference on Accelerator Mass Spectrometry (AMS-9). Abstracts. Nagoya: Nagoya University. p 228–9.Google Scholar
Vasil'chuk, AC, Kim, J-C, Vasil'chuk, Y. 2003. First radiocarbon dating of pollen and spores from syngenetic ice-wedge ice. In: Phillips, M, Springman, SM, Arenson, LU, editors. Proceedings, 8th International Conference on Permafrost. Zurich, Switzerland, 21–25 July 2003. Volume 2. Rotterdam: AA Balkema Publishers. p 1167–72.Google Scholar
Zhou, W, Donahue, D, Jull, AJT. 1997. Radiocarbon AMS dating of pollen concentrated from eolian sediments: implications for monsoon climate change since the Late Quaternary. Radiocarbon 39(1):1926.Google Scholar
Zimov, SA, Voropaev, YV, Semiletov, IP, Davidov, SP, Prosiannikov, SF, Chapin, FS III, Chapin, MC, Trumbore, S, Tyler, S. 1997. North Siberian lakes: a methane source fueled by Pleistocene carbon. Science 277:800–2.Google Scholar