Prehistoric human activities in Kona basin, northeastern Qinghai Tibet Plateau and their environmental background to Lake Cuona in winter
在暴露于地面的石头制品的密集区域中,布置了五个大小不同(约2×2.3 m)的四方体(T1-T5)。使用技术类型学对石材进行了收集和详细分析。此外,具有1.2的四方体选择×0.5 m的土壤并去除10 cm的表层土壤,以2 cm的间隔通过湿筛筛选这些10–50 cm的土壤样品,并对每层中发现的残留物进行计数,同时十个炉床测量并挖掘了(1-10号)裸露并散布在研究区域地面上的DJCN 3-2-2剖面。该剖面是从该站点东南约2 m处的当地沉积地层收集的。剖面约100厘米厚,根据沉积物的岩性和颜色,确定了两个主要的地层单元。在0至90厘米之间,地层由浅黄色黄土组成,在该处有两个埋藏的富含木炭的文化层。分别为24–28厘米和30–32厘米;而在d的较低层90-100厘米的深处是蓝灰色湖相沉积物。沿断面以2 cm的间隔收集了45个样品,分别用于测量颗粒大小,磁化率,花粉,木炭和真菌孢子;从田间的炉膛和烧过的土壤中,采集了三个木炭样品(DJCN 3-2-2 C1,从美国佛罗里达州迈阿密市Beta Analytic公司进行的AMS14C测年收集了分别来自烧过的土壤(分别为5号和8号炉台)的DJCN 3-2-2 C2和DJCN 3-2-2 C3。 。通过使用Calib REV 7.0.2程序(Stuiver andReimer,1993)的IntCal 13校准曲线(Reimeret等,2013)将AMS14C日期进一步转换为日历年值。青海师范大学自然地理与环境过程。光谱仪(ICP-MS)。未暴露的中间部分用于测量等效剂量(De)。我们还使用自动RisøTL / OSL-DA-20-C / Dreader获得了OSL测量值。实验室辐射使用90Sr / 90Y beta光源。样品制备包括分别用HCl(10%)和H2O2(30%)处理以去除有机物质和碳酸盐。通过湿筛分选择38至63 µm的颗粒,并用H2SiF6处理约2周。用水含量10±5%来计算年龄(Stauch等人,2012)。在青海师范学院青海省自然地理与环境过程重点实验室完成了粒度和磁化率的测定。粒度分析采用标准工艺,包括用HCl处理(10%)和H2O2(10%)分别去除碳酸盐和有机物质,以及用10 mL的10%(NaPO3)6处理分散剂并用超声波清洗机摇动以使颗粒充分分散(Lu and An,1997)。易感性是用英国Bartington生产的MS2双频磁化率仪进行分析。通过计算三个低频磁化率平均值与两个背景值的平均值之差获得低频磁化率值。对真菌孢子,木炭和花粉样品进行氢氟酸(HF)处理处理方法(Faegri和Iversen,1989; Moore等,1991)。将样品分别在10%HCl和10%KOH中煮沸以溶解钙质矿物质和腐殖质组分。然后将样品通过200 µm筛网过筛,并用40%HF处理以消解细小的二氧化硅。接下来,将样品过7 µm筛网以除去粘土大小的颗粒。最后,将样品储存并固定在甘油冻中。在400倍和1000倍的放大倍数下鉴定出花粉和真菌孢子。真菌孢子形态型的鉴定是基于与Van Geel(1978),Van Geel等人的描述和插图的比较。 (1989年,2003年,2011年),记录了每个样品的Van.300花粉和真菌孢子,并表示为总含量的百分比。花粉和真菌最初通过向样品中添加石蒜孢子片(27637±563孢子)来计算孢子浓度值,然后使用Tilia和Tilia-Graph软件制作图表(Grimm,2011年)。对木炭进行了计数,并将其分为两种类型,即20–100 µm和> 100 µm。
该数据集以Excel格式存储,包含了2个工作表,分别是DJCN3-2-2---Pollen,NPP and Charcoal data(原始数据)工作表和DJCN环境指标(粒度、色度、磁化率)年代工作表。其中NPP and Charcoal data(原始数据)工作表中有3个Sheet表分别是Pollen、NPP、Charcoal.Pollen中有Samples Depth/cLycopodium Betula Corylus Picea Pinus Ulmus Alnus(桤木) Juglans(胡桃) Cupressaceae(柏科) Chenopodiaceae Elaeagnaceae Ephdra Tamaricaceae(柽柳科) Fabaceae Rosaceae Nitraria Cyperaceae Artemisia Poaceae Aster-T Taraxacum-T Saussurea-T Ranunculaceae Lamiaceae Thalictrum Apiaceae Polygonum Campanulaceae(桔梗科) Gentianaceae Caprifoliaceae Caryophyllaceae Geraniaceae Thymelaeaceae Brassicaceae(十字花科) Liliaceae Solanaceae(茄科) Primulaceae Polypodiaceae/Pyrrosia(水龙骨科/石韦属) Gleicheniaceae(里白科) Abies(冷杉) Limonium(补血草属) Moraceae/Humulus(桑科/葎草属) Boraginaceae(紫草科) Typhaceae(香蒲科) Euphorbiaceae(大戟科) ongraceae(柳叶榛科) SUM Lt*Pf Lf*g 孢粉浓度的数据。NPP中有Samples Depth/cm、 Lycopodium 、Sordaria-type (HdV-55A)、 Sporormiella-type(HdV-113)、Coniochaeta-type(HdV-172)、 Delitschia spp Glomus cf. fasciculatum Apiosordaria-type(HdV-169) Cercophora-type(HdV-112) Arnium-type(HdV-261,262) Thecaphora ISL-1、 ISL-2 、ISL-4、 ISL-5、 ISL-6、 ISL-7、 ISL-8 、(Savoryella) ISL-9 (Valsaria?) 、ISL-11 、ISL-12 、ISL-13 SUM的数据。Charcoal中有Samples 、Depth/cm、 Lycopodium 、20-100μm、 >100μm 、SUM的数据。DJCN环境指标(粒度、色度、磁化率)年代工作表中的数据是样品名称、深度(cm)、 Age(ka 平均粒径/μm粒度<4μm/%、粒度<4-63μm/%、 粒度>63μm/% 、亮度、 红度、 黄度 、磁化率/(10-8SI)、 <2μm(%)、 2-63μm(%)、 >63μm(%) 、分选 、偏度、 峰度。
候光良. (2021). 青藏高原东北部科纳盆地史前人类活动及其冬给错那湖的环境背景. 时空三极环境大数据平台,
DOI:
10.11888/Paleoenv.tpdc.271272.
CSTR:
18406.11.Paleoenv.tpdc.271272.
[Hou, G. (2021). Prehistoric human activities in Kona basin, northeastern Qinghai Tibet Plateau and their environmental background to Lake Cuona in winter. A Big Earth Data Platform for Three Poles,
DOI:
10.11888/Paleoenv.tpdc.271272.
CSTR:
18406.11.Paleoenv.tpdc.271272.
]
(下载引用:
RIS格式 |
RIS英文格式 |
Bibtex格式 |
Bibtex英文格式
)
使用本数据时必须引用“文章的引用”中列出的文献,并进行数据的引用
1.Aichner, B., Herzschuh, U., Wilkes, H., et al. (2012). Ecological development of Lake Donggi Cona, north-eastern Tibetan Plateau,since the late glacial on basis of organic geochemical proxiesand non-pollen palynomorphs. Palaeogeography, Palaeoclimatology, Palaeoecology, 313(1), 140–149. (查看 )
2.Aldenderfer, M., and Zhang, Y.N. (2004). The prehistory of the Tibetan Plateau to the seventh century A.D., Perspectives and research from China and the west since 1950. Journal of World Prehistory, 18(1), 1–55. (查看 )
3.An, Z.S., Colman, S.M., Zhou, W.J., et al. (2012). Interplay between the Westerlies and Asian monsoon recorded in Lake Qinghai sediments since 32 ka. Scientific Reports 2, 619.Baker AG, Bhagwat SA and Willis KJ (2013) Do dung fungal spores make a good proxy for past distribution of large herbivores. Quaternary Science Reviews, 62, 21–31. (查看 )
4.Baker, A.G., Cornelissen, P., Shonil, A., et al. (2016). Quantification of population sizes of large herbivores and their long-term functional role in ecosystems using dung fungal spores. Methods in Ecology and Evolution, 7(11), 1273–1281. (查看 )
5.Bell, A. (2005). An Illustrated Guide to the Coprophilous Ascomycetes of Australia. Saint Paul, MN, APS Press. Blackford JJ and Innes JB (2006) Linking current environments and processes to fungal spore assemblages, Surface NPM data from woodland environments. Review of Palaeobotany and Palynology, 141, 179–187. (查看 )
6.Brantingham, P.J., Gao, X., Madsen, D.B., et al. (2013). Late occupation of the high-elevation northern Tibetan Plateau based on cosmogenic, luminescence, and radiocarbon ages. Geoarchaeology, 28, 413–431. (查看 )
7.Brantingham, P.J., Gao, X., Olsen, J.W., et al. (2007). A short chronology for the peopling of the Tibetan Plateau. Developments in Quaternary Science, 9(7), 129–150. (查看 )
8.Cao, Y.F., Huang, C.C., Han, J.Q., et al. (2007). Changes of fire environment recorded by charcoal hided in Holocene profiles in the eastern and western Loess Plateau. Geography and GeoInformation Science, 23(1), 92–96. (查看 )
9.Carrancho, A., Villalaín, J.J. (2011). Different mechanisms of magnetisation recorded in experimental fires, Archaeomagnetic implications. Earth and Planetary Science Letters, 312(1–2), 176–187. (查看 )
10.Chen, F.H., Dong, G.H., Zhang, D.J., Liu, X.Y., Jia, X., An, C.B., Ma, M.M., Xie, Y.W., Barton, L., Ren, X.Y., Zhao, Z.J., Wu, X.H., Jones, M.K. (2015). Agriculture facilitated permanent human occupation of the Tibetan Plateau after 3600 B.P. Science, 347( 6219) : 248-250. (查看 )
11.Chen, F.H., Liu, F.W., Zhang, D.J., et al. (2016). The process and driving force for peopling the Tibetan Plateau during prehistoric periods. Chinese Journal of Nature, 38(4), 235–240. (查看 )
12.Chen, F.H., Frido Welker, Chuan-Chou Shen, Shara E. Bailey, Inga Bergmann, Simon Davis, Huan Xia, Hui Wang, Roman Fischer, Sarah E. Freidline, Tsai-Luen Yu, Matthew M. Skinner, Stefanie Stelzer, Guangrong Dong, Qiaomei Fu, Guanghui Dong, Jian Wang, Dongju Zhang & Jean-Jacques Hublin (2019). A late middle pleistocene denisovan mandible from the tibetan plateau. Nature, 569(7756), 409-412. (查看 )
13.Chen, H.H., Ge, S.B., and Li, G.L. (1998). Discuss to the nature of Zongri relic. Archaeology, 19(5), 23–27 (in Chinese). (查看 )
14.Connor, S.E., Thomas, I., & Kvavadze, E.V. (2007). A 5600-yr history of changing vegetation, sea levels and human impacts from the Black Sea coast of Georgia. The Holocene, 17(1), 25–36. (查看 )
15.Cugny, C., Mazier, F., & Galop, D. (2010). Modern and fossil nonpollen palynomorphs from the Basque mountains (westernPyrenees, France), The use of coprophilous fungi to reconstruct pastoral activity. Vegetation History and Archaeobotany, 19, 391–408. (查看 )
16.D’Alpoim Guedes J, Lu, H.L., Li, Y.X., et al. (2014). Moving agriculture onto the Tibetan Plateau, The archaeobotanical evidence.Archaeological and Anthropological Sciences, 6(3), 255–269. (查看 )
17.Dietze, E., Wünnemann, B., Diekmann, B., et al. (2010). Basin morphology and seismic stratigraphy of Lake Donggi Cona,north-eastern Tibetan Plateau, China. Quaternary International, 218(1), 131–142. (查看 )
18.Dong,G.H., Jia,X., An, C.B., Ma, MM.(2012).Mid-Holocene climate change and its effect on prehistoric cultural evolution in eastern Qinghai Province China. Quaternary Research, 77,23-30. (查看 )
19.E, C.Y., Lai, Z.P., Hou, G.L., et al. (2015). Age determination for a Neolithic site in northeastern Qinghai-Tibetan Plateau using acombined luminescence and radiocarbon dating. Quaternary Geochronology, 30(Part. B), 411–415. (查看 )
20.Hou, G.L., Cao, G.C., E, C.Y., et al. (2016). New evidence of human activities at an altitude of 4000 meters area of Qinghai-Tibet Plateau. Acta Geographica Sinica, 71(7), 1231–1240. (查看 )
为尊重知识产权、保障数据作者的权益、扩展数据中心的服务、评估数据的应用潜力,请数据使用者在使用数据所产生的研究成果中(包括公开发表的论文、论著、数据产品和未公开发表的研究报告、数据产品等成果),明确注明数据来源和数据作者。对于转载(二次或多次发布)的数据,作者还须注明原始数据来源。
License:
This work is licensed under an
Attribution 4.0 International (CC BY 4.0)
联系方式
中国科学院西北生态环境资源研究院
0931-4967287
poles@itpcas.ac.cn
关注我们
时空三极环境大数据平台 © 2018-2020 陇ICP备05000491号 | All Rights Reserved
| 
京公网安备11010502040845号
数据中心技术支持: 数云软件
