旧石器遗址出土烧骨的技术分析及其对考古学的启示

doi:10.16359/j.cnki.cn11-1963/q.2019.0022

摘要/Abstract

摘要：

烧骨常见于各类旧石器时代遗址中,作为用火残留物的一类,烧骨对研究人类用火行为有着极为重要的意义,而目前国内针对烧骨的研究工作开展得尚不够深入。本文通过介绍目前烧骨研究领域中若干种主流的分析手段及其在考古学上的应用,以求能进一步完善国内关于旧石器时代人工用火的研究框架,同时希望能对中国古人类用火能力的相关研究提供有益的借鉴。

关键词: 烧骨, 用火残留物, 人类行为, 旧石器时代, 动物考古学

Abstract:

Burned bones are commonly found in Paleolithic sites. As one particular category of fire-use residues, burned bones are significant to a due understanding of the repertoire of hominin behaviors. However, the significance of these objects still remains largely unexplored in Chinese Paleolithic sites. In this paper, we present a review of analytical techniques in observation and quantification of the main features, including colors, fracture patterns, black carbon content, bone histology changes and the crystallinity of hydroxyapatite, of the burned skeletal remains from a variety of contexts. We also mention three types of fire-use behavior that may be related to burnt bones researchs. In this way, we seek to provide a referential framework for future analysis of the burned bones from archaeological sites of China.

Key words: Burned bone, Fire-use residue, Human Behavior, Paleolithic, Zooarchaeology

中图分类号:

K871.1/Q915.86

黄超, 张双权. 旧石器遗址出土烧骨的技术分析及其对考古学的启示[J]. 人类学学报, 2020, 39(02): 249-260.

HUANG Chao, ZHANG Shuangquan. Technological analysis of burned bones and its implications for Paleolithic archaeology[J]. Acta Anthropologica Sinica, 2020, 39(02): 249-260.

参考文献 79

[1]	Pérez L, Sanchis A, Hernández CM , et al. Hearths and bones: An experimental study to explore temporality in archaeological contexts based on taphonomical changes in burnt bones[J]. Journal of Archaeological Science: Reports, 2017,11:287-309 doi: 10.1016/j.jasrep.2016.11.036 URL
[2]	Ellingham STD, Thompson TJU, Islam M , et al. Estimating temperature exposure of burnt bone — A methodological review[J]. Science & Justice, 2015,55(3):181-188 doi: 10.1016/j.scijus.2014.12.002 URL pmid: 25934370
[3]	Thompson TJU . Recent advances in the study of burned bone and their implications for forensic anthropology[J]. Forensic Science International, 2004,146:S203-S205 doi: 10.1016/j.forsciint.2004.09.063 URL pmid: 15639576
[4]	Reidsma FH, van Hoesel A, van Os BJH , et al. Charred bone: Physical and chemical changes during laboratory simulated heating under reducing conditions and its relevance for the study of fire use in archaeology[J]. Journal of Archaeological Science: Reports, 2016,10:282-292 doi: 10.1016/j.jasrep.2016.10.001 URL
[5]	Bonucci E, Graziani G . Comparative thermogravimetric, X-ray and electron microscope investigations of burnt bone from recent, ancient and prehistoric age.[J]. Atti Della Accademia dei Cincei, Scienze Fisiche, Matematiche e Naturali Series. 1975,8(59):517-534
[6]	Correia PMM. Fire Modification of Bone: A Review of the Literature[M]. Forensic Taphonomy: The Post-mortem Fate of Human Remains, Sorg MH, Haglund WD, CRC Press, 1997,668
[7]	李骄勇, 靳万祥, 马伟龙 , 等. 烧骨的研究现状与展望[J].刑事技术, 2009(1):32-35
[8]	Thompson TJU . Heat-induced dimensional changes in bone and their consequences for forensic anthropology[J]. Journal of Forensic Science. 2005,50(5):1008-1015
[9]	Shipman P, Foster G, Schoeninger M . Burnt bones and teeth: an experimental study of color, morphology, crystal structure and shrinkage[J]. Journal of Archaeological Science, 1984,4(11):307-325
[10]	Shahack-Gross R, Bar-Yosef O, Weiner S . Black-Coloured Bones in Hayonim Cave, Israel: Differentiating Between Burning and Oxide Staining[J]. Journal of Archaeological Science, 1997,24(5):439-446 doi: 10.1006/jasc.1996.0128 URL
[11]	Brain CK, Sillen A . Evidence From The Swartkrans Cave For The Earliest Use Of Fire[J]. Nature, 1988,336(6198):464-466 doi: 10.1038/336464a0 URL
[12]	Hackett CJ . Microscopical Focal Destruction(Tunnels) in Exhumed Human Bones[J]. Medicine, Science and the Law, 1981,21(4):243-265 doi: 10.1177/002580248102100403 URL
[13]	Baby R . Hopewell cremation pratices[J]. The Ohin Historical Society. Papers in Archaeology, 1954(1):1-17
[14]	Devlin JB, Herrmann NP. Bone Color as an Interpretive Tool of the Depositional History of Archaeological Cremains[M]. The Analysis of Burned Human Remains, Schmidt CW, Symes SA, London:Academic Press, 2008, 109-128
[15]	Nicholson RA . A Morphological Investigation of Burnt Animal Bone and an Evaluation of its Utility in Archaeology[J]. Journal of Archaeological Science. 1993,20(4):411-428 doi: 10.1006/jasc.1993.1025 URL
[16]	Mckinley JI . The Anglo-Saxon Cemetery at Spong Hill, North Elmham Part VIII: The Cremations. Field Archaeology Division, Norfolk. East Anglian Archaeology Report No. 69[G]. 1994
[17]	徐国昌, 张培华, 任甫 , 等. 基于光学、电子显微镜图像的烧骨组织学变化特征[J]. 解剖学杂志, 2012,35(3):380-383
[18]	Hanson M, Cain CR . Examining histology to identify burned bone[J]. Journal of Archaeological Science, 2007,34(11):1902-1913 doi: 10.1016/j.jas.2007.01.009 URL
[19]	张森水 . 关于西侯度的问题[J].人类学学报, 1998(02):2-14
[20]	Herrmann B . On histological investigations of cremated human remains[J]. Journal of Human Evolution, 1977,6(2):101-103 doi: 10.1016/S0047-2484(77)80112-7 URL
[21]	Oakley KP . Evidence of Fire in South African Cave Deposits[J]. Nature, 1954,174(4423):261-262
[22]	Herrmann NP, Bennett JL . The differentiation of traumatic and heat-related fractures in burned bone[J]. Journal of Forensic Sciences, 1999,44(3):461-469 URL pmid: 10408102
[23]	Rockhold LA. Bones: Bullets, Burns, Bludgeons, Blunders and Why[A]. In Burned bone, Proceedings of the bone trauma workshop: American Academy of Forensic Sciences[C]. Nashvill, 1996: 19-24
[24]	Stiner MC, Kuhn SL, Weiner S , et al. Differential Burning, Recrystallization, and Fragmentation of Archaeological Bone[J]. Journal of Archaeological Science, 1995,22(2):223-237 doi: 10.1006/jasc.1995.0024 URL
[25]	Gonçalves D, Thompson TJU, Cunha E . Implications of heat-induced changes in bone on the interpretation of funerary behaviour and practice[J]. Journal of Archaeological Science, 2011,38(6):1308-1313 doi: 10.1016/j.jas.2011.01.006 URL
[26]	Brain CK . The Occurrence of Burnt Bones at Swartkrans and Their Implications for the Control of Fire by Early Hominids[M]. Swartkrans: A Cave's Chronicle of Early man., Brain CK, Pretoria: Transvaal Museum, 1993, 229-242
[27]	Forbes G . The Effects of Heat on the Histological Structure of Bone[J]. The Police Journal, 1941,14(1):50-60 doi: 10.1177/0032258X4101400108 URL
[28]	曹军骥, 占长林 . 黑碳在全球气候和环境系统中的作用及其在相关研究中的意义[J]. 地球科学与环境学报. 2011(2):177-184
[29]	沈承德, 易惟熙, 杨英 , 等. 周口店猿人遗址样品“元素碳”浓度机器应用于人类用火证据探究的可能性[J]. 科学通报, 2004,49(3):275-278
[30]	周斌, 沈承德, 易惟熙 , 等. 土壤中元素碳的测定与研究[J]. 土壤与环境, 2002(2):133-135
[31]	Binford LR, Stone NM, Aigner JS , et al. Zhoukoudian: A Closer Look[J]. Current Anthropology, 1986,27(5):453-475 doi: 10.1086/203469 URL
[32]	Wu XZ, Weiner S, Xu QQ, et al. Investigating the Possible Use of Fire at Zhoukoudian, China[J]. Science, 1999,283:299
[33]	Weiner S, Xu Q, Goldberg P , et al. Evidence for the use of fire at Zhoukoudian[J]. Science, 1998(281):251-253
[34]	Gao X, Zhang SQ, Zhang Y , et al. Evidence of Hominin Use and Maintenance of Fire at Zhoukoudian[J]. Current Anthropology, 2017,58(S16):S267-S277 doi: 10.1086/692501 URL
[35]	Black D . Evidences of the use of fire by Sinanthropus[J]. Bulletin of the Geological Society of China, 1931,11(2):107-108 doi: 10.1111/j.1755-6724.1932.mp11002002.x URL
[36]	金牛山联合发掘队. 辽宁营口金牛山遗址旧石器文化的研究[J]. 古脊椎动物与古人类, 1978,16(2):129-136
[37]	张森水 . 富林文化[J]. 古脊椎动物与古人类, 1977,15(1):14-27
[38]	吴茂霖, 王令红, 张银运 , 等. 贵州桐梓发现的古人类化石及其文化遗物[J]. 古脊椎动物与古人类, 1975(1):14-23
[39]	Oakley KP . On man's use of fire, with comments on tool-making and hunting[J]. Social life of early man, 1961,31:176-193
[40]	Sillen A, Hoering T . Chemical Characterization of Burnt Bones from Swartkrans[M]. Swartkrans: A Cave's Chronicle of Early man., Brain CK, Pretoria:Transvaal Museum, 1993, 243-249
[41]	胥少汀, 葛宝丰, 徐印坎 . 实用骨科学[M].人民军医出版社, 2012: 19
[42]	Stiner MC, Kuhn SL, Surovell TA , et al. Bone preservation in Hayonim Cave (Israel): a macroscopic and mineralogical study[J]. Journal of Archaeological Science, 2001,28(6):643-659 doi: 10.1006/jasc.2000.0634 URL
[43]	Thompson TJU, Gauthier M, Islam M . The application of a new method of Fourier Transform Infrared Spectroscopy to the analysis of burned bone[J]. Journal of Archaeological Science, 2009,36(3):910-914 doi: 10.1016/j.jas.2008.11.013 URL
[44]	Thompson TJU, Islam M, Piduru K , et al. An investigation into the internal and external variables acting on crystallinity index using Fourier Transform Infrared Spectroscopy on unaltered and burned bone[J]. Palaeogeography, Palaeoclimatology, Palaeoecology, 2011,299(1-2):168-174 doi: 10.1016/j.palaeo.2010.10.044 URL
[45]	Snoeck C, Lee-Thorp JA, Schulting RJ . From bone to ash: Compositional and structural changes in burned modern and archaeological bone[J]. Palaeogeography, Palaeoclimatology, Palaeoecology, 2014,416:55-68 doi: 10.1016/j.palaeo.2014.08.002 URL
[46]	Monge G, Carretero MI, Pozo M , et al. Mineralogical changes in fossil bone from Cueva del Angel, Spain: archaeological implications and occurrence of whitlockite[J]. Journal of Archaeological Science, 2014,46:6-15 doi: 10.1016/j.jas.2014.02.033 URL
[47]	Lebon M, Reiche I, Bahain JJ , et al. New parameters for the characterization of diagenetic alterations and heat-induced changes of fossil bone mineral using Fourier transform infrared spectrometry[J]. Journal of Archaeological Science, 2010,37(9):2265-2276 doi: 10.1016/j.jas.2010.03.024 URL
[48]	Piga G, Malgosa A, Thompson TJU , et al. A new calibration of the XRD technique for the study of archaeological burned human remains[J]. Journal of Archaeological Science, 2008,35(8):2171-2178 doi: 10.1016/j.jas.2008.02.003 URL
[49]	Koon HEC, Nicholson RA, Collins MJ . A practical approach to the identification of low temperature heated bone using TEM[J]. Journal of Archaeological Science, 2003,30(11):1393-1399 doi: 10.1016/S0305-4403(03)00034-7 URL
[50]	Schmahl WW, Kocsis B, Toncala A , et al. The Crystalline State of Archaeological Bone Material[M]. Across the Alps in Prehistory, Al GGE, Springer International Publishing, 2017: 75-104
[51]	Taylor RE, Hare PE, White TD . Geochemical criteria for thermal alteration of bone[J]. Journal of Archaeological Science, 1995,22(1):115-119 doi: 10.1016/S0305-4403(95)80169-3 URL
[52]	Squires KE, Thompson TJU, Islam M , et al. The application of histomorphometry and Fourier Transform Infrared Spectroscopy to the analysis of early Anglo-Saxon burned bone[J]. Journal of Archaeological Science, 2011,38(9):2399-2409 doi: 10.1016/j.jas.2011.04.025 URL
[53]	Sandgathe DM . Identifying and Describing Pattern and Process in the Evolution of Hominin Use of Fire[J]. Current Anthropology, 2017,58(S16):S360-S370 doi: 10.1086/691459 URL
[54]	Goldberg P, Miller CE, Mentzer S M . Recognizing Fire in the Paleolithic Archaeological Record[J]. Current Anthropology, 2017,58(S16):S175-S190 doi: 10.1086/692729 URL
[55]	Alperson-Afil N . Spatial Analysis of Fire: Archaeological Approach to Recognizing Early Fire[J]. Current Anthropology, 2017,58(S16):S258-S266 doi: 10.1086/692721 URL
[56]	Cain CR . Using burned animal bone to look at Middle Stone Age occupation and behavior[J]. Journal of Archaeological Science, 2005,32(6):873-884 doi: 10.1016/j.jas.2005.01.005 URL
[57]	Semaw S, Rogers MJ, Quade J , et al. 2.6-Million-year-old stone tools and associated bones from OGS-6 and OGS-7, Gona, Afar, Ethiopia[J]. Journal of Human Evolution, 2003,45(2):169-177 doi: 10.1016/S0047-2484(03)00093-9 URL pmid: 14529651
[58]	Ferraro JV, Plummer TW, Pobiner BL , et al. Earliest Archaeological Evidence of Persistent Hominin Carnivory[J]. PLoS ONE, 2013,8(4):e62174 doi: 10.1371/journal.pone.0062174 URL pmid: 23637995
[59]	Hlubik S, Berna F, Feibel C , et al. Researching the Nature of Fire at 1.5 Mya on the Site of FxJj20 AB, Koobi Fora, Kenya, Using High-Resolution Spatial Analysis and FTIR Spectrometry[J]. Current Anthropology, 2017,58(S16):S243-S257 doi: 10.1086/692530 URL
[60]	Henry AG . Neanderthal Cooking and the Costs of Fire[J]. Current Anthropology, 2017,58(S16):S329-S336 doi: 10.1086/692095 URL
[61]	Costamagno S, Théry-Parisot I, Castel J , et al. Combustible ou non? Analyse multifactorielle et modèles explicatifs sur des ossements brûlés paléolithiques[M]. Fuel Management during the Palaeolithic and Mesolithic Periods New tools, new interpretations, Théry-Parisot I, Costamagno S, Henry A, England:British Archaeological Reports, 2008, 65-84
[62]	张双权, 张乐, 栗静舒 , 等. 晚更新世晚期中国古人类的广谱适应生存——动物考古学的证据[J]. 中国科学: 地球科学, 2016(8):1024-1036
[63]	Aldeias V . Experimental Approaches to Archaeological Fire Features and Their Behavioral Relevance[J]. Current Anthropology, 2017,58(S16):S191-S205 doi: 10.1086/691210 URL
[64]	Théry-Parisot I, Costamagno S, Brugal J . The use of bone as fuel during the Palaeolithic, experimental study of bone combustible properties[M]. The Zooarchaeology of Fats, Oils, Milk and Dairying, Mulville J, Outram K, Oxbow Books, 2005, 50-59
[65]	Bowler JM, Thorne AG, Polach HA . Pleistocene Man in Australia: Age and Significance of the Mungo Skeleton[J]. Nature, 1972(240):48-50
[66]	Bowler JM, Jones R, Allen H , et al. Pleistocene human remains from Australia: A living site and human cremation from Lake Mungo, western New South Wales[J]. World Archaeology, 1970: 39-60 doi: 10.1080/00438243.1970.9979463 URL pmid: 16468208
[67]	Seitsonen O, Seitsonen S, Broderick LG , et al. Burnt bones by Europe's largest lake: Zooarchaeology of the Stone Age and Early Metal period hunter-gatherers at Lake Ladoga, NW Russia[J]. Journal of Archaeological Science: Reports, 2017,11:131-146 doi: 10.1016/j.jasrep.2016.11.034 URL
[68]	Rhodes SE, Walker MJ, López-Jiménez A , et al. Fire in the Early Palaeolithic: Evidence from burnt small mammal bones at Cueva Negra del Estrecho del Río Quípar, Murcia, Spain[J]. Journal of Archaeological Science: Reports, 2016,9:427-436 doi: 10.1016/j.jasrep.2016.08.006 URL
[69]	Carroll EL, Smith M . Burning questions: Investigations using field experimentation of different patterns of change to bone in accidental vs deliberate burning scenarios[J]. Journal of Archaeological Science: Reports, 2018,20:952-963 doi: 10.1016/j.jasrep.2018.02.001 URL
[70]	Gowlett JAJ, Brink JS, Caris A , et al. Evidence of Burning from Bushfires in Southern and East Africa and Its Relevance to Hominin Evolution[J]. Current Anthropology, 2017,58(S16):S206-S216 doi: 10.1086/692249 URL
[71]	关莹, 高星, 王惠民 , 等. 水洞沟旧石器时代晚期遗址结构的空间利用分析[J]. 科学通报, 2011(33):2797-2803
[72]	Alperson-Afli N, Goren-Inbar N . The Acheulian Site of Gesher Benot Ya'aqov[M]. Volume II ed. Springer, 2010: 19-71
[73]	Wrangham R . Control of Fire in the Paleolithic: Evaluating the Cooking Hypojournal[J]. Current Anthropology, 2017,58(S16):S303-S313 doi: 10.1086/692113 URL
[74]	Monteiro PD, Zapata L, Bicho N . Fuel uses in Cabeço da Amoreira shellmidden: An insight from charcoal analyses[J]. Quaternary International, 2017,431:27-38 doi: 10.1016/j.quaint.2016.01.014 URL
[75]	Allué E, Solé A, Burguet-Coca A . Fuel exploitation among Neanderthals based on the anthracological record from Abric Romaní (Capellades, NE Spain)[J]. Quaternary International, 2017,431:6-15 doi: 10.1016/j.quaint.2015.12.046 URL
[76]	Costa C . The Use of Animal Bone as Fuel in the Third Millennium BC Walled Enclosure of Castanheiro do Vento (Northern Portugal)[J]. International Journal of Osteoarchaeology, 2016,26(5):877-884 doi: 10.1002/oa.v26.5 URL
[77]	Braadbaart F, Poole I, Huisman HDJ , et al. Fuel, Fire and Heat: an experimental approach to highlight the potential of studying ash and char remains from archaeological contexts[J]. Journal of Archaeological Science, 2012,39(4):836-847 doi: 10.1016/j.jas.2011.10.009 URL
[78]	Snoeck C, Schulting RJ, Lee-Thorp JA , et al. Impact of heating conditions on the carbon and oxygen isotope composition of calcined bone[J]. Journal of Archaeological Science, 2016,65:32-43 doi: 10.1016/j.jas.2015.10.013 URL
[79]	Webb H . Cremated Human Remains[M]. London Gateway: Iron Age and Roman salt making in the Thames Estuary. Excavation at Stanford Wharf Nature Reserve, Essex., Biddulph E, Stafford E, Foreman S, et al, Oxford Archaeology, 2012,209