中国旧石器原料开发策略的研究进展

doi:10.16359/j.1000-3193/AAS.2023.0014

摘要/Abstract

摘要：

石料开发与获取是石器生产操作链的重要环节，也是史前人地关系研究的重要内容，能够反映史前人类的资源开发策略、环境认知与适应能力、移动模式和交流贸易网络等。相比于旧大陆西侧，东亚地区的燧石和黑曜岩等优质石料产地相对稀缺，中国许多旧石器考古遗址的石器原料主要来自遗址周边质量欠佳的脉石英、石英岩和一般燧石等，而相关的旧石器时代石料开发策略系统研究也相对较少。本文对中国目前已开展的旧石器时代石料开发策略研究进行系统梳理分析和总结发现，从旧石器时代早期到晚期末段，中国境内史前人类的石料开发策略存在明显的时空变化，主要体现在石料类型组成、产地选取和开发方式三个方面，可能主要受到史前人类流动性变化、石器技术演变和环境变化等因素的共同影响。综合而言，开展旧石器时代遗址的石料开发策略研究，对于理解中国境内史前人类的行为模式和交流迁徙等有重要意义。

关键词: 旧石器, 石器原料, 开发策略, 影响因素

Abstract:

As an important part of the lithic artifact manufacturing system, lithic raw materials exploitation reflects several attributes of prehistoric humans, including environmental cognition, resource exploitation, mobility patterns, and cultural exchanges. However, there were differences in these attributes between Africa and Western Eurasia: In the former, high-quality flint and obsidian are relatively abundant, whereas in East Asia the Paleolithic hunter-gatherers mainly exploited the locally ubiquitous vein quartz, quartzite, and ordinary chert to produce stone artifacts. This has resulted in a relatively small number of Paleolithic raw materials exploitation studies in East Asia. To better understand what is known about the lithic raw material exploitation strategies of the Paleolithic hunter-gatherers in China, here we review and summarize all previous related studies. We found that from the Lower Paleolithic to Upper Paleolithic periods, raw materials composition, source selection and exploitation methods changed substantially. During the Lower Paleolithic period, hunter-gatherers mainly exploited local vein quartz, quartzite and flint from riverbeds, bedrock outcrops and weathered outcrops near residential or camp sites. The quality of these raw materials was usually unexceptional, and the exploitation distances were generally within 10 km. During the Middle Paleolithic period, lithic raw material types increased in number and they varied between regions. Although the quality of these raw materials was also generally unexceptional, high-quality flint began to appear at some sites, albeit not in dominant proportions. Local procurement within 10 km still dominated during this period, while long-distance procurement occurred occasionally. The hunter-gatherers during this period clearly had an improved ability to recognize and utilize local raw materials, and they relied increasingly on high-quality raw materials. During the Upper Paleolithic period, the types of lithic raw materials increased greatly, and there was a marked decrease in the proportion of vein quartz and quartzite, and a significant increase in the proportion of high-quality raw materials, like flint, chalcedony, siliceous rock and volcanic tuff, and there was also the first appearance of obsidian. Long-distance procurement of high-quality raw materials in northern China became more common, but in southern China local procurement from riverbeds still dominated. The emergence of specialized raw material exploitation and lithic production workshop sites is another distinctive feature of this period. These temporal and spatial changes in Paleolithic raw material exploitation strategies in China were likely the result of multiple factors, including the mobility patterns of hunter-gatherers, advances in stone tool production technologies, and climate changes. In summary, the study of Paleolithic raw material exploitation strategy is critical for understanding human behavior, population interactions and migrations. Therefore, more intensive and systematic studies of Paleolithic raw materials exploitation in China are needed in the future.

Key words: Paleolithic sites, Lithic raw materials, Exploitation strategies, Impact factors

中图分类号:

K871.11

申旭科, 李婷, 张东菊. 中国旧石器原料开发策略的研究进展[J]. 人类学学报, 2023, 42(02): 161-176.

SHEN Xuke, LI Ting, ZHANG Dongju. A review of Paleolithic raw material exploitation studies in China[J]. Acta Anthropologica Sinica, 2023, 42(02): 161-176.

图/表 3

图1 中国开展石料开发策略研究的旧石器时代遗址分布图 LP: 旧石器时代早期Lower Paleolithic sites; MP: 旧石器时代中期Middle Paleolithic sites;UP/Epi-P: 旧石器时代晚期/后旧石器时代Upper Paleolithic / Epipaleolithic sites

Fig.1 Distribution of Paleolithic sites where lithic raw material exploitation study had been carried out in China

图2 中国旧石器时代不同时段遗址开发的代表性原料 a. 旧石器时代早期Lower Paleolithic(LP)：1.上陈遗址的石英岩工具Quartzite tool from Shangchen(SC-K5)[30]；2.周口店第1地点的石英两极石片Quartz bipolar flake from layer 4-5 of Zhoukoudian 1[100]；3-4.小长梁遗址的燧石石片和锥钻Chert flake and borer from Xiaochangliang site[31]。b. 旧石器时代中期Middle Paleolithic(MP)：5.板井子遗址的燧石石锥 Chert awl from Banjingzi site(2015BJ:701)[101]；6.板井子遗址的燧石锯齿刃器Chert denticulate from Banjingzi site(2015BJ:2967) [101]；7.丁村遗址的角页岩石片Hornfels flake from Dingcun site(P1627)[44]；8.灵井遗址的石英锯齿刃器Quartz denticulate from the lower culture layer of Lingjing site[36]；9.乌兰木伦遗址的石英岩石片Quartzite flake from Wulanmulun site(11KW(6)566)[46]；10.观音洞遗址的燧石石片Chert flake from Guanyindong Cave site[102]；11.玉米洞遗址的石灰岩石器Limestone tool from Yumidong site[103]。c. 旧石器时代晚期/后旧石器时代Upper Paleolithic / Epipaleolithic sites(UP/Epi-P)：12.水洞沟第2地点的燧石端刮器Chert endscraper from Shuidonggou 2(SDG2T2-7424)[104]；13.水洞沟第2地点的燧石边刮器Chert sidescraper from Shuidonggou 2(SDG2T2-9037)[104]；14.水洞沟第7地点的硅质白云岩石片Siliceous dolomite flake from Shuidonggou 7(SDG7-6194)[105]；15.西沙河遗址的燧石细石核Chert microblade core from Xishahe site[106]；16. 桦阳遗址的霏细岩细石核Felsite microblade core from Huayang site[80]；17.桃山遗址的凝灰岩两面器Tuff bifacial tool from Taoshan site[79]；18.白佛寺遗址的燧石细石核Chert microblade core from White Buhhda Temple site[26]；19.湖东种羊场遗址的碧玉岩刮削器Jasper scraper from Hudongzhongyangchang site[26]；20.铜线4地点的碧玄岩石片Lydite flake from Bronze Wire Canyon 4[26]；21. 151遗址的燧石细石叶Chert microblade from 151 site[26]；22.和龙大洞遗址的黑曜岩细石核Obsidian microblade core from Helong Dadong site(07DD.C1175)[87]

Fig.2 Artifact photos of representative raw materials exploited in different Paleolithic sites of different periods

图3 中国旧石器时代遗址石料开发策略变化 Ag: 玛瑙agate; Ch: 燧石chert; Cy: 玉髓chalcedony; Do: 硅质白云岩 siliceous dolomite; Ho：角岩 hornfels; Ja: 碧玉 jasper; Li: 硅质灰岩 siliceous limestone; Ob: 黑曜岩 obsidian; Qu: 石英岩 quartzite; Qz: 石英 quartz; Rh: 流纹岩 rhyolite; Sa: 石英砂岩 quartz sandstone; Si: 硅质岩 siliceous rock; Sl: 板岩 slate; Tu: 凝灰岩 tuff; Vo: 火山岩 volcanic rock

Fig.3 The change patterns of lithic raw material exploitation strategies of Paleolithic sites in China

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