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| New Progress in Dating of Quaternary Sediments |
| YUAN Lu-lu1, WANG Ming-qi1, HU Jia-le2 |
1. School of Earth Sciences and Resources, China University of Geosciences, Beijing 100083, China;
2. School of Energy Resources, China University of Geosciences, Beijing 100083, China |
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Abstract The Quaternary was an important period in the geological evolution history because it is closely related to the human beings. Therefore, highly reliable and precise Quaternary dating is required. Quaternary sediments change overtime in lithology and composition, and may have obvious changes of space in structure and thickness because of different sedimentary conditions and sediment types and geneses, which make it more difficult to determine the accurate ages of Quaternary sediments. This paper presents the new progress in Quaternary dating, such as K/Ar and 40Ar/39Ar dating, tektite dating, uranium dating, Amino acid racemization dating, cosmogenic nuclide dating, and electron spin resonance dating, as well as the dating range and objects of the related methods. Furthermore, the present problems and strategies for improvement of Quaternary sediment dating methods are introduced. However, to improve the reliability and accuracy of dating, not only geological experience, but also correct dating methods are required for comparative dating. With more attention paid to recreation of the Quaternary environment and its relationship with global climate changes, the dating methods for Quaternary sediments should be helpful in investigations of global climatic changes and environment evolution in the future.
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Received: 01 September 2014
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[1] Hedberg H D. International Stratigraphic Guide[M]. London: John Wiley, 1976.
[2] Shoemaker E M, Uhlherr H R. Stratigraphic significance of australites in the Port Campbell Embayment, Victoria[J]. Meteoritics and Planetary Science, 1999, 34: 369-384.
[3] Hou Y, Potts R, Yuan B, et al. Mid-Pleistocene Acheulean-like stone technology of the Bose Basin, South China[J]. Science, 2000, 287: 1622-1626.
[4] 李永飞, 卞雄飞, 郜晓勇, 等. 大兴安岭北段龙江盆地中生代火山岩激光全熔40Ar/39Ar测年[J]. 地质通报, 2013, 32: 1212-1223.
[5] Wang Y, Zhou S.40Ar/39Ar dating constraints on the high-angle normal faulting along the southern segment of the Tan-Lu fault system: An implication for the onset of eastern China rift-systems[J]. Journal of Asian Earth Sciences, 2009, 34: 51-60.
[6] 王勇生,朱光. 40Ar/39Ar测年中的冷却年龄和变形年龄[J].地质通报,2005, 24(3): 285-290.
[7] 张兆峰,彭子成,贺剑锋,等. 热电离质谱铀系定年测定过程中需考虑的因素[J]. 质谱学报, 2001, 22(3): 1-7.
[8] 王华,殷建军,俞建国,等.α铀系测年对洞穴碳酸盐沉积物中碎屑岩物质影响的祛除研究[J]. 地球学报, 2012,33(6): 936-940.
[9] 余涛,姜涛. 光释光测年技术在海洋沉积物研究中的应用现状与展望[J].地质科技情报,2014, 33(2): 38-44.
[10]Kars R H, Busschers F S, Wallinga J, et al. Validating post IR-IRSL dating on K-feldspars through comparison with quartz OSL ages[J]. Quaternary Geochronology, 2012, 12: 74-86.
[11]Edward J, Rhodes. Optically stimulated luminescence dating of sediments over the past 200,000 years[J]. Annual Review of Earth and Planetary Sciences, 2011, 39: 461-488.
[12]赵瑞欣, 周保, 李滨. 黄河上游龙羊峡至积石峡段巨型滑坡OSL测年[J]. 地质通报, 2013, 32(12): 1943-1951.
[13]王奎,陈建芳,金海燕,等. 楚科奇海——加拿大海盆表层沉积物中的氨基酸[J]. 沉积学报, 2008, 26(4): 661-669.
[14]王丽玲,杨群慧,付少英,等. 南太平洋东劳扩张中心表层沉积物氨基酸组成所揭示的生物地球化学意义[J].地球化学, 2012, 41(1): 23-34.
[15]Beerten K, Stesmans A. ESR dating of sedimentary quartz: Possibilities and limitations of the signal-grain approach[J]. Quaternary Geochronology, 2007, 2: 373-380.
[16]Tissoux H, Toyoda S, Falgueres C, et al. ESR dating of sedimentary quartz from two Pleistonce deposits using Al and Ti-center[J]. Geochronometria, 2008, 30: 23-31.
[17]Liu C R, Yin G M, Gao L, et al. ESR dating of Pleistoncene archaeological localities of the Nihewan Basin, North China-Preliminary results[J]. Quaternary Geochronology, 2010, 5: 385-390.
[18]Akear N, Ivy-Ochs S, Alfimov V, et al. First results on determination of cosmogenic 36Cl in limestone from the Yenicekale Complex in the Hittite capital of Hattusha[J]. Quaternary Geochronology, 2009, 4(6): 533-540.
[19]Shen G J, Gao X. Age of Zhoukoudian Homo erectus determined with 26Al/10Be burial dating[J]. Nature, 2009, 458: 198-200.
[20]Balco G, Shuster D L. Production rate of cosmogenic 21Ne in quartz estimated from 10Be, 26Al, and 21Ne concentrations in slowly eroding Antarctic bedrock surface[J]. Earth and Planetary Science Letters, 2009, 281(1/2):48-58.
[21]Gosse J C, Phillips F M. Terrestrial insitu cosmogenic nuclide: theory and application[J]. Quaternary Science Reviews, 2001, 20: 1475-1560. |
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2014, Vol. 1 
