Luminescence dating of heated quartz extracted from burnt clay and pottery excavated from the Lingjiatan archaeological site, China

IF 2 3区地球科学 Q3 GEOSCIENCES, MULTIDISCIPLINARY

Frontiers in Earth Science Pub Date : 2022-08-04 DOI:10.3389/feart.2022.933342

Chunxin Wang, Xiaolei Zhang, Yunyi Zhang, Youjin Wu, Chang Huang, A. Fan

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引用次数: 3

Abstract

This study utilizes OSL-SAR, TL-SAR, and TL-MAAD methods to date heated quartz extracted from burnt clay and pottery samples from the Lingjiatan archaeological site, China. The OSL components of the heated quartz were determined by deconvoluting the CW-OSL curve, and the Fast Ratio value was used to distinguish whether the initial OSL signal was dominated by the fast component. The results show two types of quartz OSL characteristics in the initial signals: Type I is dominated by the fast component (Fast Ratio values > 10), while Type II is dominated by the medium and slow components (Fast Ratio values < 10). Type I samples show bright OSL signals, and a preheat plateau appears from a relatively low temperature. The recuperation is negligible, and reliable equivalent doses can be obtained using the conventional OSL-SAR measurement conditions. In contrast, the OSL signal of Type II samples is relatively dim, and the preheat plateau appears from a much higher temperature than in Type I samples. The recuperation of Type II samples increases significantly at higher preheat temperatures. Significant De underestimation of Type II samples was observed at lower preheat temperatures. It is noted that the thermal transfer effect can be attenuated by increasing the OSL stimulation temperature. Therefore, a modified OSL-SAR measurement condition, with higher preheat, cut-heat and stimulation temperatures, was used to date Type II samples. The OSL-SAR ages of most of these two types of samples agree well with the independent 14C ages, demonstrating that OSL-SAR can be used to date heated archaeological materials at high firing temperatures (∼900°C). The Lingjiatan archaeological site was determined to be approximately 5.4–5.8 ka BP 2022.

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从中国凌家滩考古遗址出土的烧焦粘土和陶器中提取的加热石英的发光年代测定

本研究利用ls - sar、TL-SAR和TL-MAAD方法测定了中国凌家滩考古遗址燃烧粘土和陶器样品中提取的加热石英的年代。通过对CW-OSL曲线进行反卷积，确定了被加热石英的OSL组分，并利用Fast Ratio值来区分初始OSL信号是否以Fast组分为主。结果表明，初始信号中石英OSL有两种特征:ⅰ型以快组分为主(fast Ratio值为bbb10)，ⅱ型以中、慢组分为主(fast Ratio值< 10)。I型样品显示明亮的OSL信号，并且在相对较低的温度下出现预热平台。在常规的光学光学光谱测量条件下，可获得可靠的等效剂量。相比之下，II型样品的OSL信号相对较暗，并且在比I型样品高得多的温度下出现预热平台。在较高的预热温度下，II型样品的回热显著增加。在较低的预热温度下观察到II型样品的显著De低估。结果表明，提高热释光激发温度可以减弱换热效应。因此，采用改进的ols - sar测量条件，采用更高的预热、切割和刺激温度，对II型样品进行测年。这两种样品的大多数ols - sar年龄与独立的14C年龄吻合得很好，表明ols - sar可以用于在高温(~ 900°C)下加热考古材料的年代测定。凌家滩考古遗址被确定为大约5.4-5.8 ka BP 2022。

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来源期刊

Frontiers in Earth Science Earth and Planetary Sciences-General Earth and Planetary Sciences

CiteScore

3.50

自引率

10.30%

发文量

2076

审稿时长

12 weeks

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