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Testing the Accuracy of 14C Age Data from Pollen Concentrates in the Yangtze Delta, China

Published online by Cambridge University Press:  26 July 2016

Chunhai Li ,
Yongxiang Li  and
George S Burr
Chunhai Li
Affiliation:
State Key Laboratory of Lake Science and Environment, Nanjing Institute of Geography and Limnology, Chinese Academy of Sciences, 73 East Beijing Road, Nanjing, China
Yongxiang Li
Affiliation:
School of Earth Sciences and Engineering, Nanjing University, Nanjing 210093, China
George S Burr
Affiliation:
NSF-Arizona Accelerator Mass Spectrometry (AMS) Laboratory, University of Arizona, Physics Department, Tucson, Arizona 85721-0081, USA
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Abstract

In order to test the accuracy of accelerator mass spectrometry (AMS) radiocarbon dating of pollen, 8 samples of pollen concentrates and 4 bulk organic samples were collected and analyzed from trench T1041 at the Tianluoshan site, Yuyao city, Zhejiang Province. This site was chosen because a reliable chronology had been previously established there based on radiocarbon dates of plant materials. The pollen concentrate samples were measured using AMS 14C and the 4 bulk organic samples were measured by liquid scintillation counting (LSC). The pollen concentrates and bulk organic samples yield ages that are a few hundred years to thousands of years older than those from plant materials, respectively. Contributions from reworked sediments can explain the older ages for the pollen concentrates and sediment organic dates. This study suggests that caution must be exercised when discussing millennial- or centennial-scale climate events based on chronologies that are controlled by age determinations of pollen concentrates.

Type
Articles
Information
Radiocarbon , Volume 56 , Issue 1 , 2014 , pp. 181 - 187
Copyright
Copyright © 2014 by the Arizona Board of Regents on behalf of the University of Arizona 

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References

Atahan, P, Grice, K, Dodson, J. 2007. Agriculture and environmental change at Qingpu, Yangtze delta region, China: a biomarker, stable isotope and palynological approach. The Holocene 17(4):507–15.CrossRefGoogle Scholar
Atahan, P, Itzstein-Davey, F, Taylor, D, Dodson, J, Qin, J, Zheng, H, Brooks, A. 2008. Holocene-aged sedimentary records of environmental changes and early agriculture in the lower Yangtze, China. Quaternary Science Reviews 27(5–6):556–70.CrossRefGoogle Scholar
Brown, T, Nelson, DE, Matthews, RW, Vogel, JS, Southon, JR. 1989. Radiocarbon dating of pollen by accelerator mass spectrometry. Quaternary Research 32(2):205–12.CrossRefGoogle Scholar
Faegri, K, Iversen, J. 1989. Textbook of Pollen Analysis. Chichester: John Wiley and Sons.Google Scholar
Itzstein-Davey, F, Atahan, P, Dodson, J, Taylor, D, Zheng, H. 2007. Environmental and cultural changes during the terminal Neolithic: Qingpu, Yangtze delta, eastern China. The Holocene 17(7):875–87.CrossRefGoogle Scholar
Kilian, MR, van der Plicht, J, van Geel, B, Goslar, T. 2002. Problematic 14C-AMS dates of pollen concentrates from Lake Gosciaz (Poland). Quaternary International 88:21–6.CrossRefGoogle Scholar
Li, CH, Zheng, YF, Yu, SY, Li, YX, Shen, HD. 2012. Understanding the ecological background of rice agriculture on the Ningshao Plain during the Neolithic Age: pollen evidence from a buried paddy field at the Tianluoshan cultural site. Quaternary Science Reviews 35:131–8.CrossRefGoogle Scholar
Liu, FG, Feng, ZD. 2012. A dramatic climatic transition at ∼4000 cal. yr BP and its cultural responses in Chinese cultural domains. The Holocene 22(10):1181–97.CrossRefGoogle 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
Neulieb, T, Levac, E, Southon, J, Lewis, M, Pendea, IF, Chmura, GL. 2013. Potential pitfalls of pollen dating. Radiocarbon 55(3):1142–55.CrossRefGoogle Scholar
Pimentel, D, Kounang, N. 1998. Ecology of soil erosion in ecosystems. Ecosystems 1(5):416–26.CrossRefGoogle Scholar
Qin, J, Wu, G, Zheng, H, Zhou, Q. 2008. The palynology of the first hard clay layer (late Pleistocene) from the Yangtze delta, China. Review of Palaeobotany and Palynology 149(1–2):6372.CrossRefGoogle Scholar
Regnéll, 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.CrossRefGoogle Scholar
Regnéll, J, Everitt, E. 1996. Preparative centrifugation—a new method for preparing pollen concentrates suitable for radiocarbon dating by AMS. Vegetation History and Archaeobotany 5(3):201–5.CrossRefGoogle Scholar
Richardson, F, Hall, VA. 1994. Pollen concentrate preparation from highly organic Holocene peat and lake deposits for AMS dating. Radiocarbon 36(3):407–12.CrossRefGoogle Scholar
Stanley, DJ, Chen, ZY. 1996. Neolithic settlement distributions as a function of sea level-controlled topography in the Yangtze delta, China. Geology 24(12):1083–6.2.3.CO;2>CrossRefGoogle Scholar
Stanley, DJ, Chen, ZY. 2000. Radiocarbon dates in China's Holocene Yangtze delta: record of sediment storage and reworking, not timing of deposition. Journal of Coastal Research 16(4):1126–32.Google Scholar
Stuiver, M, Reimer, PJ. 1993. Extended 14C data base and revised CALIB 3.0 14C calibration program. Radiocarbon 35(1):215–30.CrossRefGoogle Scholar
Vandergoes, MJ, Prior, CA. 2003. AMS dating of pollen concentrates—a methodological study of Late Quaternary sediments from South Westland, New Zealand. Radiocarbon 45(3):479–91.CrossRefGoogle Scholar
Vasil'chuk, A, Kim, JC, Vasil'chuk, Y. 2005. AMS 14C dating of pollen concentrate from Late Pleistocene ice wedges from the Bison and Seyaha sites in Siberia. Radiocarbon 47(2):243–56.CrossRefGoogle Scholar
Yi, S, Saito, Y, Yang, D-Y. 2006. Palynological evidence for Holocene environmental change in the Changjiang (Yangtze River) Delta, China. Palaeogeography, Palaeoclimatology, Palaeoecology 241(1):103–17.CrossRefGoogle Scholar
Yu, SY, Zhu, C, Song, J, Qu, WZ. 2000. Role of climate in the rise and fall of Neolithic cultures on the Yangtze Delta. Boreas 29(2):157–65.CrossRefGoogle Scholar
Zhang, Q, Zhu, C, Liu, CL, Jiang, T. 2005. Environmental change and its impacts on human settlement in the Yangtze Delta, PR China. Catena 60(3):267–77.CrossRefGoogle Scholar
Zheng, YF, Sun, GP, Qin, L, Li, CH, Wu, XH, Chen, XG. 2009. Rice fields and modes of rice cultivation between 5000 and 2500 BC in east China. Journal of Archaeological Science 36(12):2609–16.Google Scholar
Zheng, YF, Sun, GP, Chen, XG. 2012. Response of rice cultivation to fluctuating sea level during the Mid-Holocene. Chinese Science Bulletin 57(4):370–8.CrossRefGoogle 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.CrossRefGoogle Scholar
Zong, YQ, Innes, JB, Wang, ZH, Chen, ZY. 2011. Mid-Holocene coastal hydrology and salinity changes in the east Taihu area of the lower Yangtze wetlands, China. Quaternary Research 76(1):6982.CrossRefGoogle Scholar