Analysis on the economic mode of the ancestors of Dayindong cave site in Yunnan province by stable isotope

doi:10.16359/j.1000-3193/AAS.2021.0035

Abstract

Abstract:

The origin and dissemination of agriculture is an important innovation in the development of human society. This paper performed carbon and nitrogen stable isotopic analysis on human bones unearthed from the Dayindong cave site in Guangnan county, Wenshan prefecture, Yunnan Province, and explores the diet structure and the subsistence economy of ancient ancestors in Southeast Yunnan from the Neolithic Age to the Bronze Age. The results showed that the δ ¹³C values of the residents at Dayindong Site ranged from -20.2‰ to -17.5‰, mainly C₃ plants, and the δ¹⁵N values ranged from 9.2‰ to 10.7‰, and their trophic levels were high. There are differences in diet between the sexes, men consume more animal protein than women. In terms of the subsistence strategy, the residents of Dayindong cave site mainly engaged in rice agriculture and hunting, and made diversified use of animal resources, possibly supplement food sources through collection, fishing and hunting, and livestock breeding. On this basis, considering that Yunnan is an important channel for the spread of agriculture to the Indo-China Peninsula, the selection of the Neolithic-Bronze Age production strategy in Yunnan was further sorted out. The populations in different areas of the Neolithic Age in Yunnan had different agriculture management strategies. In the Bronze Age, with the introduction of wheat, the selection of agricultural economy became more diversified, and the technology for obtaining animal resources became more mature and diverse. In addition to being affected by natural conditions, different agricultural strategy choices are also the result of cultural interaction with neighboring regions.

Key words: Dayindong cave site, Bones, Stable isotopes, Dietary structure, Subsistence economy

CLC Number:

Q987

ZHAO Dongyue, LÜ Zheng, ZHANG Zetao, LIU Bo, LING Xue, WAN Yang, YANG Fan. Analysis on the economic mode of the ancestors of Dayindong cave site in Yunnan province by stable isotope[J]. Acta Anthropologica Sinica, 2022, 41(02): 295-307.

Figures/Tables 7

References 70

[1]	赵志军. 中国农业起源概述[J]. 遗产与保护研究, 2019, 4(1):1-7
[2]	Chen FH, Dong GH, Zhang DJ, et al. Agriculture facilitated permanent human occupation of the Tibetan Plateau after 3600 B.P.[J]. Science, 2015, 347(6219):248-250 doi: 10.1126/science.1259172 pmid: 25593179
[3]	郭怡. 稳定同位素分析方法在探讨稻粟混作区先民(动物)食物结构中的运用[M]. 杭州: 浙江大学出版社, 2013: 2-9
[4]	He KY, Lu HY, Zhang JP, et al. Prehistoric evolution of the dualistic structure mixed rice and millet farming in China[J]. Holocene, 2017, 27(12):1885-1898 doi: 10.1177/0959683617708455 URL
[5]	李昆声. 云南在亚洲栽培稻起源研究中的地位[J]. 云南社会科学, 1981(1):69-73
[6]	汤圣祥, 闵绍楷, 佐藤洋一郎. 中国粳稻起源的探讨[J]. 中国水稻科学, 1993(03):129-136
[7]	童恩正. 略述东南亚及中国南部农业起源的若干问题——兼谈农业考古研究方法[J]. 农业考古, 1984(2):21-30+82
[8]	黎海明, 左昕昕, 康利宏, 等. 植物大化石和微体化石分析揭示的云贵高原新石器-青铜时代农业发展历程[J]. 中国科学:地球科学, 2016, 46(7):926-938
[9]	张弛, 洪晓纯. 华南和西南地区农业出现的时间及相关问题[J]. 南方文物, 2009(3):70-77
[10]	陈洪波, 韩恩瑞. 试论粟向华南、西南及东南亚地区的传播[J]. 农业考古, 2013(1):13-18
[11]	李小瑞. 云南植物考古现状[J]. 南方文物, 2016(01):166-170
[12]	云南省文物考古考古研究所, 中国社会科学院考古研究所云南工作队, 成都市文物考古研究所, 等. 云南永仁菜园子、磨盘地遗址2001年发掘报告[J]. 考古学报, 2003(02):263-296+325-328
[13]	赵志军. 石佛洞遗址植物遗存分析报告[A].见：云南省文物考古研究所,中国社会科学院考古研究所,成都文物考古研究所,等（编）.耿马石佛洞[C]. 北京: 文物出版社, 2010: 368-373
[14]	金和天, 刘旭, 闵锐, 等. 云南元谋大墩子遗址浮选结果及分析[J]. 江汉考古, 2014(3):109-114
[15]	向安強, 张文绪, 李晓岑, 等. 云南保山昌宁达丙营盘山新石器遗址出土古稻研究[J]. 华夏考古, 2015(1):41-45
[16]	王祁, 蒋志龙, 杨薇, 等. 云南澄江学山遗址植物遗存浮选结果及初步研究[J]. 中国农史, 2019, 38(2):3-11
[17]	李小瑞, 刘旭. 云南江川光坟头遗址植物遗存浮选结果及分析[J]. 农业考古, 2016(3):20-27
[18]	薛轶宁. 云南剑川海门口遗址植物遗存初步研究[D]. 北京:北京大学, 2010
[19]	杨薇, 蒋志龙, 陈雪香. 云南东川玉碑地遗址(2013年度)植物遗存浮选结果及初步分析[J]. 中国农史, 2020, 39(1):3-11
[20]	杨薇. 云南河泊所和玉碑地遗址植物遗存分析[D]. 济南:山东大学, 2016
[21]	张全超. 云南澄江县金莲山墓地出土人骨稳定同位素的初步分析[J]. 考古, 2011(1):30-33
[22]	Ren LL, Li X, Kang LH, et al. Human paleodiet and animal utilization strategies during the Bronze Age in northwest Yunnan Province, southwest China[J]. PloS One, 2017, 12(5):e0177867 doi: 10.1371/journal.pone.0177867 URL
[23]	Zhang XX, Burton J, Jin ZY, et al. Isotope studies of human remains from Mayutian, Yunnan Province, China[J]. Journal of Archaeological Science, 2014, 50(1):414-419 doi: 10.1016/j.jas.2014.08.001 URL
[24]	高玉, 董广辉, 杨晓燕, 等. 史前农业传播:从中国南方到中南半岛[J]. 中国科学:地球科学, 2020, 50(6):723-734
[25]	朱泓. 体质人类学[M]. 北京: 高等教育出版社, 2004: 92-106
[26]	White TD, Folkens PA. The Human Bone Manual[M]. London: Academic Press, 2005: 364-398
[27]	Ambrose SH. Preparation and characterization of bone and tooth collagen for isotopic analysis[J]. Journal of Archaeological Science, 1990, 17(4):431-451 doi: 10.1016/0305-4403(90)90007-R URL
[28]	Ambrose SH, Butler BM, Hanson DB, et al. Stable isotopic analysis of human diet in the Marianas Archipelago, Western Pacific[J]. American Journal of Physical Anthropology, 1997, 104(3):343-361 pmid: 9408540
[29]	Deniro MJ. Postmortem preservation and alteration of in vivo bone collagen isotope ratios in relation to palaeodietary reconstruction[J]. Nature, 1985, 317(6040):806-809 doi: 10.1038/317806a0 URL
[30]	张雪莲. 应用古人骨的元素、同位素分析研究其食物结构[J]. 人类学学报, 2003, 22(1):75-84
[31]	Bocherens H, Fizet M, Mariotti A. Diet, physiology and ecology of fossil mammals as inferred from stable carbon and nitrogen isotope biogeochemistry: implications for Pleistocene bears[J]. Palaeogeography Palaeoclimatology Palaeoecology, 1994, 107(3-4):213-225 doi: 10.1016/0031-0182(94)90095-7 URL
[32]	Sealy JC, Merwe NJVD, Thorp JAL, et al. Nitrogen isotopic ecology in southern Africa: Implications for environmental and dietary tracing[J]. geochimica et cosmochimica acta, 1987, 51(10):2707-2717 doi: 10.1016/0016-7037(87)90151-7 URL
[33]	Huiskes R, Ruimerman R, Lenthe GHV, et al. Effects of Mechanical Forces on Maintenance and Adaptation of Form in Trabecular Bone[J]. Nature, 2000, 405(6787):704-706 doi: 10.1038/35015116 URL
[34]	Adami S, Gatti D, Viapiana O, et al. Physical Activity and Bone Turnover Markers: A Cross-Sectional and a Longitudinal Study[J]. Calcified Tissue International, 2008, 83(6):388-392 doi: 10.1007/s00223-008-9184-8 URL
[35]	Hedges REM, Clement JG, Thomas CDL, et al. Collagen turnover in the adult femoral mid-shaft: Modeled from anthropogenic radiocarbon tracer measurements[J]. American Journal of Physical Anthropology, 2007, 133(2):808-816 doi: 10.1002/(ISSN)1096-8644 URL
[36]	Cox G, Sealy CJ. Investigating Identity and Life Histories: Isotopic Analysis and Historical Documentation of Slave Skeletons Found on the Cape Town Foreshore, South Africa[J]. International Journal of Historical Archaeology, 1997, 1(3):207-224 doi: 10.1023/A:1027349115474 URL
[37]	易冰, 刘祥宇, 原海兵, 等. 四川大邑县高山古城遗址宝墩文化先民牙本质序列的碳氮稳定同位素分析[J]. 四川文物, 2020(1):96-106
[38]	南川雅男, 松井章. 由田螺山遗址出土的人类与动物骨骼胶质炭氮同位素组成推测河姆渡文化的食物资源与家畜利用[A].见：北京大学中国考古学研究中心,浙江省考古研究所（编）.田螺山遗址自然遗存综合研究[C]. 北京: 文物出版社, 2011: 262-269
[39]	胡耀武, 王根富, 崔亚平, 等. 江苏金坛三星村遗址先民的食谱研究[J]. 科学通报, 2007, 52(1):85-88
[40]	吴梦洋, 葛威, 陈兆善. 海洋性聚落先民的食物结构:昙石山遗址新石器时代晚期人骨的碳氮稳定同位素分析[J]. 人类学学报, 2016, 35(2):246-256
[41]	凌雪, 陈靓, 田亚岐, 等. 陕西凤翔孙家南头秦墓出土人骨中C和N同位素分析[J]. 人类学学报, 2010, 29(1):54-61
[42]	张全超, Jacqueline TE, 魏坚等. 内蒙古察右前旗庙子沟遗址新石器时代人骨的稳定同位素分析[J]. 人类学学报, 2010, 29(3):270-275
[43]	张昕煜, 张旭, 索明杰, 等. 东周时期内蒙古中南部人群和文化融合进程中的农业经济——以和林格尔大堡山墓地人骨C、N稳定同位素分析为例[J]. 中国科学:地球科学, 2018, 48(2):200-209
[44]	宫玮. 济南大辛庄、刘家庄商代先民食物结构研究[D]. 济南:山东大学, 2016
[45]	郭怡, 胡耀武, 朱俊英, 等. 青龙泉遗址人和猪骨的C,N稳定同位素分析[J]. 中国科学:地球科学, 2011, 41(1):52-60
[46]	Liu XY, Lightfoot E, O’Connell TC, et al. From necessity to choice: dietary revolutions in west China in the second millennium BC[J]. World Archaeology, 2014, 46(5):661-680 doi: 10.1080/00438243.2014.953706 URL
[47]	吕杰. 滇东南岩溶山区水土资源利用与生态环境耦合协调模拟研究[D]. 昆明:昆明理工大学, 2014
[48]	蓝勇. 中国西南历史气候初步研究[J]. 中国历史地理论丛, 1993 (2):13-39
[49]	Rita DM, Rui M, Chris S, et al. Early agriculture at the crossroads of China and Southeast Asia: Archaeobotanical evidence and radiocarbon dates from Baiyangcun, Yunnan[J]. Journal of Archaeological ence: Reports, 2018, 20:711-721
[50]	王华, 王炜林, 胡松梅. 仰韶时代人类狩猎梅花鹿的策略:以铜川瓦窑沟遗址为案例[J]. 人类学学报, 2014, 33(1):90-100
[51]	董为. 鹿角形态演化综述[A].见：中国古脊椎动物学会.第十一届中国古脊椎动物学学术年会论文集[C]. 中国古脊椎动物学会：中国古生物学会, 2008: 133-150
[52]	张兴永, 邱宣充. 云南麻栗坡县小河洞新石器时代洞穴遗址[J]. 考古, 1983(12):1108-1111
[53]	张兴永. 云南新石器时代的家畜[J]. 农业考古, 1987(1):370-377
[54]	李昆生. 文山岩画[M]. 昆明: 云南人民出版社, 2005: 1-137
[55]	杨帆, 万杨, 胡长城. 云南考古（1979-2009）[M]. 昆明: 云南人出版社, 2010: 278-279
[56]	李昆生. 云南考古学通论[M]. 昆明: 云南大学出版社, 2019: 23-86
[57]	Martelloa RD, Min R, Stevens C, et al. Early agriculture at the crossroads of China and Southeast Asia: Archaeobotanical evidence and radiocarbon dates from Baiyangcun, Yunnan[J]. Journal of Archaeological science: Reports, 2018(20):711-721
[58]	闵锐. 剑川海门口遗址综合研究[J]. 学园, 2013(15):6-9
[59]	刘旭, 戴宗品. 3000 年前的穴居生活:耿马石佛洞遗址[J]. 中国文化遗产, 2008(6):84-87
[60]	王大道. 再论云南新石器时代文化的类型[J]. 西藏考古, 1994 (1):91-108
[61]	云南省文物考古研究所, 大理州文物管理所, 永平县文物管理所. 云南永平新光遗址发掘报告[J]. 考古学报, 2002(2):203-227
[62]	康利宏. 云南元谋磨盘山新石器时代遗址[A].见：国家文物局.2013中国重要考古发现[C]. 北京: 文物出版社, 2014: 30-33
[63]	张根娟. 云南地形、局地气候与农业利用关系初探[J]. 云南地理环境研究, 1993, 5(A9):31-39
[64]	赵琳, 郎南军, 郑科, 等. 云南干热河谷生态环境特性研究[J]. 林业调查规划, 2006(3):117-120
[65]	肖明华. 云南考古述略[J]. 考古, 2001(12):3-15
[66]	云南省文物考古研究所, 玉溪市文物管理所, 澄江县文物管理所, 等. 云南澄江县金莲山墓地2008~2009年发掘简报[J]. 考古, 2011(1):17-30+109+99-103
[67]	云南省博物馆考古发掘工作组. 云南晋宁石寨山古遗址及墓葬[J]. 考古学报, 1956(1):43-63+146-155
[68]	Zhang NM, Dong GH, Yang XY, et al. Diet reconstructed from an analysis of plant microfossils in human dental calculus from the Bronze Age site of Shilinggang, southwestern China[J]. Journal of Archaeological Science, 2017, 83(4):41-48 doi: 10.1016/j.jas.2017.06.010 URL
[69]	杨冬琴, 刘波. 云南全新世气候变化研究综述[J]. 云南地理环境研究, 2011, 23(4):106-111
[70]	崔琳琳, 胡建芳, 王旭. 末次盛冰期以来中国南方C3/C4植被时空演化及影响机制[J]. 中国科学:地球科学, 2019, 49(8):1246-1258

No.	样品Sample	骨骼Bone	性别Gender	死亡年龄 Age(a)	¹⁴C年代(BP cal)	C	N	δ¹³C	δ¹⁵N	C/N
1	2017GDM1	肋骨ribs	女female	34-40	3367-3213	38.2%	14%	-18.9‰	9.6‰	3.2
2	2017GDM2	指骨phalanges	女female?	成年adult	3360-3206	33.1%	12%	-17.5‰	9.2‰	3.2
3	2017GDM3:R1	肋骨ribs	男male	40-45	3346-3165	37.6%	13.8%	-18.4‰	10.3‰	3.2
4	2017GDM3:R2	掌骨metacarpal	?	成年adult	-	43.8%	16%	-18.4‰	9.4‰	3.2
5	2017GDM4	掌骨metacarpal	女female?	成年adult	3446-3326	47.7%	17.6%	-18.6‰	9.4‰	3.2
6	2017GDM5	肋骨ribs	女female?	25±	-	44.6%	16.5%	-18.2‰	10.7‰	3.1
7	2017GDM6:R1	跖骨metatarsal	女female?	成年adult	3360-3206	42.9%	15.6%	-18.8‰	9.6‰	3.2
8	2017GDM6:R2	跖骨metatarsal	?	成年adult	-	41.8%	15.4%	-18.5‰	9.8‰	3.2
9	2017GDM7:R1	跖骨metatarsal	女female?	25±	3407-3320	37.1%	13.6%	-18.6‰	9.4‰	3.2
10	2017GDM7:R2	肋骨ribs	?	成年adult	-	46.1%	16.6%	-20.2‰	9.4‰	3.2
11	2017GDM8:R1	胫骨tibia	?	成年adult	-	44.5%	16.5%	-17.9‰	9.7‰	3.2
12	2017GDM9:R2	跖骨metatarsal	?	?	3376-3226	45.1%	16.6%	-19‰	9.5‰	3.2
13	2017GDM10	指骨phalanges	男male?	35±	3446-3326	43.7%	15.9%	-19.1‰	10.3‰	3.2
14	2017GDM11	髌骨patella	?	成年adult	3400-3240	40.4%	14.6%	-17.6‰	9.5‰	3.2
15	2017GDM12	肋骨ribs	男male	30±	3386-3237	41.5%	15.1%	-18.9‰	9.8‰	3.2
16	2017GDM15	指骨phalanges	男male?	45±	3380-3232	41.6%	15.3%	-18.8‰	9.9‰	3.2
17	2017GD-II	掌骨metacarpal	?	成年adult	3380-3232	43.9%	16.1%	-18.4‰	9.6‰	3.2

No.	样品Sample	骨骼Bone	性别Gender	死亡年龄 Age(a)	¹⁴C年代(BP cal)	C	N	δ¹³C	δ¹⁵N	C/N
1	2017GDM1	肋骨ribs	女female	34-40	3367-3213	38.2%	14%	-18.9‰	9.6‰	3.2
2	2017GDM2	指骨phalanges	女female?	成年adult	3360-3206	33.1%	12%	-17.5‰	9.2‰	3.2
3	2017GDM3:R1	肋骨ribs	男male	40-45	3346-3165	37.6%	13.8%	-18.4‰	10.3‰	3.2
4	2017GDM3:R2	掌骨metacarpal	?	成年adult	-	43.8%	16%	-18.4‰	9.4‰	3.2
5	2017GDM4	掌骨metacarpal	女female?	成年adult	3446-3326	47.7%	17.6%	-18.6‰	9.4‰	3.2
6	2017GDM5	肋骨ribs	女female?	25±	-	44.6%	16.5%	-18.2‰	10.7‰	3.1
7	2017GDM6:R1	跖骨metatarsal	女female?	成年adult	3360-3206	42.9%	15.6%	-18.8‰	9.6‰	3.2
8	2017GDM6:R2	跖骨metatarsal	?	成年adult	-	41.8%	15.4%	-18.5‰	9.8‰	3.2
9	2017GDM7:R1	跖骨metatarsal	女female?	25±	3407-3320	37.1%	13.6%	-18.6‰	9.4‰	3.2
10	2017GDM7:R2	肋骨ribs	?	成年adult	-	46.1%	16.6%	-20.2‰	9.4‰	3.2
11	2017GDM8:R1	胫骨tibia	?	成年adult	-	44.5%	16.5%	-17.9‰	9.7‰	3.2
12	2017GDM9:R2	跖骨metatarsal	?	?	3376-3226	45.1%	16.6%	-19‰	9.5‰	3.2
13	2017GDM10	指骨phalanges	男male?	35±	3446-3326	43.7%	15.9%	-19.1‰	10.3‰	3.2
14	2017GDM11	髌骨patella	?	成年adult	3400-3240	40.4%	14.6%	-17.6‰	9.5‰	3.2
15	2017GDM12	肋骨ribs	男male	30±	3386-3237	41.5%	15.1%	-18.9‰	9.8‰	3.2
16	2017GDM15	指骨phalanges	男male?	45±	3380-3232	41.6%	15.3%	-18.8‰	9.9‰	3.2
17	2017GD-II	掌骨metacarpal	?	成年adult	3380-3232	43.9%	16.1%	-18.4‰	9.6‰	3.2