Utilization of plant by humans at the Yahuai Cave site in Long’an, Guangxi

doi:10.16359/j.1000-3193/AAS.2025.0037

Abstract

Abstract:

This study systematically investigates the subsistence economy patterns of early human populations in Guangxi and the functional applications of stone tools, with a particular focus on Yahuai Cave in Long’an County. Employing an integrated methodological approach that combines chronological analysis, micro-botanical remains examination, and morphological studies, we conduct comprehensive research on both micro-plant remains and carbonized plant remains retrieved from the site. The AMS ¹⁴C dating results establish a chronological framework for Yahuai Cave, spanning approximately from 43,000 to 4,000 calibrated years before present, which can be clearly divided into four cultural phases.

Our phytolith analysis of stone artifacts provides significant insights into how early humans utilized different types of tools in various periods and their preferential selection of plant resources. Notably, carbonized grape seeds obtained through flotation have been taxonomically identified as Vitis bryoniaefolia, a wild grape species within the Vitis genus. The synthetic analysis of phytolith assemblages from both sediment samples and stone tool surfaces, combined with the study of macro-botanical remains, reveals a clear evolutionary trajectory of plant resource utilization strategies.

During Phases 1~2 (43,000~21,000 BP cal), the inhabitants adopted a diversified subsistence strategy involving both woody plants and Poaceae species. The phytolith record provides substantial evidence of the processing of various plant materials, including potential wild rice varieties, using stone implements. A significant transition in subsistence patterns becomes evident in Phase 3 (17,000~14,000 BP cal) and Phase 4 (4,000 BP cal). Our data indicate a marked shift towards greater reliance on herb species and climbing plant fruits. This change in dietary focus is reflected in both the micro-botanical remains and the functional analysis of stone tools, suggesting an adaptation to changing environmental conditions or the development of more specialized processing techniques.

The discovery of carbonized Vitis bryoniaefolia seeds represents the earliest direct evidence of wild grape utilization in the region, offering new insights into Paleolithic foraging behaviors. Moreover, the phytolith analysis of grinding stones and other processing tools reveals distinct use-wear patterns corresponding to different plant taxa, enabling the reconstruction of ancient food preparation methods.

Our findings make several important contributions to the understanding of pre-agricultural economies in southern China. First, we establish a detailed chronology of plant use patterns from the Late Pleistocene to the Middle Holocene periods. Second, we document the technological evolution of stone tools in relation to changing subsistence needs. Third, we provide a comprehensive record of wild plant exploitation strategies in Guangxi prior to the advent of agriculture. The micro-botanical evidence shows that early inhabitants developed sophisticated knowledge of local flora, selectively utilizing various plant resources according to availability and nutritional value. The presence of both woody plant and grass phytoliths in early phases suggests a broad-spectrum foraging strategy, while the later focus on Poaceae and vine fruits indicates a possible intensification of certain food resources.

This research not only fills critical gaps in our understanding of prehistoric subsistence patterns in subtropical China but also establishes a methodological framework for future studies of early human-plant interactions in similar ecological contexts.

Key words: Archaeology, Yahuai Cave site, phytolith, stone tools, Late Pleistocene

CLC Number:

K871

WANG Jingyi, ZHAO Zhijun, XIE Guangmao, LIN Qiang, WU Yan. Utilization of plant by humans at the Yahuai Cave site in Long’an, Guangxi[J]. Acta Anthropologica Sinica, 2025, 44(03): 488-498.

Figures/Tables 4

Fig.1 Overview of Yahuai Cave site in Long’an, Guangxi A.娅怀洞遗址与周边晚更新世考古遗址分布图Distribution map of Yahuai Cave site and surrounding Late Pleistocene archaeological sites[13,19,30 -32]；B.娅怀洞遗址地层取样示意图Stratigraphic sampling diagram of Yahuai Cave site[10]

Tab.1 AMS14C dating result of the charcoal samples from the Yahuai Cave site

序号Sample code	样品号Lab number	¹⁴C 年代dating(BP)	校正年代Age calibrated (BP cal)
BT1206-5	BA160128	13340±50	16238-15850
BT1206-7	Beta-444301	13500±50	16355-16130
BT1206-8	BA170399	13445±50	16366-15976
BT1106-9	BA170401	20310±70	24618-24120
BT0907-16	Beta-444303	20470±70	24880-24410
BT0908-17	BA170404	21100±100	25693-25189
BT1006-21	Beta-495504	32050±190	36359-35510

Fig.2 Grain size analysis results and phytolith percentage diagram of Yahuai Cave site

Fig.3 Phytolith analysis of stone tools

References 43

[1]	Wang Y. Late Pleistocene human migrations in China[J]. Current Anthropology, 2017, 58(S17): S504-S513
[2]	贾兰坡, 吴汝康. 广西来宾麒麟山人类头骨化石[J]. 古脊椎动物学报, 1959, 1: 19-21
[3]	Shen G, Wang W, Wang Q, et al. U-Series dating of Liujiang hominid site in Guangxi, Southern China[J]. Journal of Human Evolution, 2002, 43(6): 817-829 pmid: 12473485
[4]	Wu L, Xiujie W. Some problems for the Late Pleistocene human cranium found in Liujiang of South China based on morphological analysis[J]. Acta Anthropologica Sinica, 2006, 25(3): 177
[5]	Zhou Y, Jiang Y, Liang G, et al. A technological perspective on the lithic industry of the Bailiandong Cave (36-7 ka) in Guangxi: An effort to redefine the cobble-tool industry in South China[J]. Comptes Rendus Palevol, 2019, 18(8): 1095-1121
[6]	Gorodetskaya O, Hsieh ML, Guo LX, et al. Paleolithic-Neolithic transition and late-to-postglacial climate change in East Asia: A review of archaeological data from karst caves in Southern China[J]. Quaternary International, 2022, 61020-61037
[7]	Zhu S, Li F, Chen X, et al. Subsistence and health in Middle Neolithic (9000-7000 BP) southern China: new evidence from the Dingsishan site[J]. Antiquity, 2021, 95(379): 13-26
[8]	赵志军, 傅宪国, 吕烈丹. 广西邕宁县顶蛳山遗址出土植硅石的分析与研究[J]. 考古, 2005, 11: 76-84+104+102
[9]	Bae CJ, Wang W, Zhao J, et al. Modern human teeth from late Pleistocene Luna cave (Guangxi, China)[J]. Quaternary International, 2014, 354: 169-183
[10]	Wu Y, Xie GM, Mao LM, et al. Phytolith evidence for human-plant subsistence in Yahuai Cave (Guangxi, South China) over the past 30000 years[J]. Science China-Earth Sciences, 2020, 63(11): 1745-1757
[11]	De Chadin T, LICEN F. On the discovery of a Paleolithic industry in Northern China[J]. Bulletin of the Geological Society of China, 1924, 345
[12]	Hung H, Zhang C, Matsumura H, et al. Neolithic transition in Guangxi: a long development of hunting-gathering society in southern China[J]. Bio-anthropological studies of Early Holocene hunter-gatherer sites at Huiyaotian and Liyupo in Guangxi, China, 2017, 20528
[13]	陈伟驹. 岭南地区新石器时代文化的时空框架与生计方式研究[D]. 博士学位毕业论文, 长春: 吉林大学, 2016
[14]	Ma Z, Zhang C, Liu S, et al. Use-wear Traces and Plant Micro-remain Analysis Reveal the Function of Perforated Shells From the Xianrendong and Diaotonghuan Sites in the Middle Reaches of the Yangtze River, China[J]. Journal of Archaeological Science: Reports, 2023, 48: 103852
[15]	Yuan S, Zhou G, Guo Z, et al. ¹⁴C AMS dating the transition from the Paleolithic to the Neolithic in South China[J]. Radiocarbon, 1995, 37(2): 245-249
[16]	Li D, Jiang Y, Ye L, et al. Multiproxy record of climate change during the late quaternary and human adaptive response at the Bailian Cave, Guangxi, South China[J]. Historical Biology, 2022, 1-13
[17]	何乃汉, 黄云忠, 刘文. 柳州市大龙潭鲤鱼嘴新石器时代贝丘遗址[J]. 考古, 1983, 9769-774
[18]	李大伟, 王頠, 胡超涌, 等. 广西陆那洞古人类遗址古环境背景研究[J]. 第四纪研究, 2017, 37(4): 877-884
[19]	杨庆江, 赵克良, 周新郢, 等. 晚更新世-早全新世广西独山洞遗址孢粉记录的植被景观演替[J]. 第四纪研究, 2024, 44(3): 793-804
[20]	Kealhofer L, Torrence R, Fullagar R. Integrating phytoliths within use-wear/residue studies of stone tools[J]. Journal of archaeological Science, 1999, 26(5): 527-546
[21]	Domínguez-Rodrigo M, Serrallonga J, Juan-Tresserras J, et al. Woodworking activities by early humans: a plant residue analysis on Acheulian stone tools from Peninj (Tanzania)[J]. Journal of Human Evolution, 2001, 40(4): 289-299
[22]	Piperno DR. Phytoliths: a comprehensive guide for archaeologists and paleoecologists[M]. New York: Rowman Altamira, 2006
[23]	王永吉, 吕厚远(著). 植物硅酸体研究及应用[M]. 北京: 海洋出版社, 1993
[24]	Wu Y, Li Z, Stidham TA, et al. Phytolith evidence reveals the origin of angiosperm leaf eating habits among ancient Cretaceous birds[J]. The Innovation, 2023, 4(5):100500
[25]	Wu Y, Mao LM, Wang C, et al. Phytolith evidence suggests early domesticated rice since 5600 cal a BP on Hainan Island of South China[J]. Quaternary International, 2016, 426: 120-125
[26]	Zhao Z, Pearsall DM, Benfer Jr RA, et al. Distinguishing rice (Oryza sativa Poaceae) from wild Oryza species through phytolith analysis, II: Finalized method[J]. Economic Botany, 1998, 134-145
[27]	Lu H, Zhang J, Wu N, et al. Phytoliths analysis for the discrimination of foxtail millet (Setaria italica) and common millet (Panicum miliaceum)[J]. PLoS One, 2009, 4(2): e4448
[28]	Pearsall DM, Chandler-Ezell K, Chandler-Ezell A. Maize can still be identified using phytoliths: response to Rovner[J]. Journal of Archaeological Science, 2004, 31(7): 1029-1038
[29]	谢光茂, 林强, 余明辉, 等. 广西隆安娅怀洞遗址发掘报告[J]. 人类学学报, 2025, 44(3):365-388
[30]	漆招进. 桂东北漓江流域的石器时代洞穴遗址及其分期[J]. 农业考古, 2000, 1: 47-54
[31]	陈铁梅, 原思训, 马力. 碳十四年代测定报告(七)[J]. 文物, 1987, 1189-1192
[32]	陈铁梅, 原思训, 王良训, 等. 碳十四年代测定报告(六)[J]. 文物, 1984, 492-496
[33]	赵志军. 植物考古学概述[J]. 农业考古, 1992, 1: 26-31
[34]	赵志军. 植物考古学的田野工作方法:浮选法[J]. 考古, 2004, 3: 80-87+82
[35]	舒军武, 黄小忠, 徐德克, 等. 新版Tilia软件:中文指南和使用技巧[J]. 古生物学报, 2018, 57(2): 260-272
[36]	冉敬, 杜谷, 潘忠习. 沉积物粒度分析方法的比较[J]. 岩矿测试, 2011, 30(6): 669-676
[37]	徐德克, 李泉, 吕厚远. 棕榈科植硅体形态分析及其环境意义[J]. 第四纪研究, 2005, 25(6): 785-792
[38]	中国科学院中国植物志编辑委员会. 中国植物志[M]. 北京: 科学出版社, 1993
[39]	Madella M, Powers-Jones AH, Jones MK. A simple method of extraction of opal phytoliths from sediments using a non-toxic heavy liquid[J]. Journal of Archaeological Science, 1998, 25(8): 801-803
[40]	Madella M, Jones MK, Goldberg P, et al. The exploitation of plant resources by Neanderthals in Amud Cave (Israel): the evidence from phytolith studies[J]. Journal of Archaeological Science, 2002, 29(7): 703-719
[41]	Tsartsidou G, Karkanas P, Marshall G, et al. Palaeoenvironmental reconstruction and flora exploitation at the Palaeolithic cave of Theopetra, central Greece: the evidence from phytolith analysis[J]. Archaeological and Anthropological Sciences, 2015, 7169-7185
[42]	Van Gijn A, Little A. Tools, use-wear and experimentation: extracting plants from stone and bone[J]. Wild Harvest: Plants in the hominin and pre-agrarian human worlds, 2016, 135-153
[43]	Li J, Zhai S, Zhao C. Insights into plant-based food resource harvesting and processing: A microfossil analysis of stone tools at the Xinzhai Site, China[J]. Journal of Archaeological Science: Reports, 2024, 57104635