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Population Fluctuation and the Adoption of Food Production in Prehistoric Korea: Using Radiocarbon Dates as a Proxy for Population Change

Published online by Cambridge University Press:  16 November 2017

Yongje Oh ,
Matthew Conte ,
Seungho Kang ,
Jangsuk Kim  and
Jaehoon Hwang
Yongje Oh*
Affiliation:
Department of Archaeology and Art History, Seoul National University, 1 Gwanak-ro, Gwanak-gu, Seoul, 08826, South Korea
Matthew Conte
Affiliation:
Department of Archaeology and Art History, Seoul National University, 1 Gwanak-ro, Gwanak-gu, Seoul, 08826, South Korea
Seungho Kang
Affiliation:
Department of Archaeology and Art History, Seoul National University, 1 Gwanak-ro, Gwanak-gu, Seoul, 08826, South Korea
Jangsuk Kim
Affiliation:
Department of Archaeology and Art History, Seoul National University, 1 Gwanak-ro, Gwanak-gu, Seoul, 08826, South Korea
Jaehoon Hwang
Affiliation:
Department of Archaeology, Chungnam National University, 99 Daehak-ro, Yoosung-gu, Daejeon, 34134, South Korea
*
*Corresponding author. Email: y0y0@snu.ac.kr.
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Abstract

Population growth has been evoked both as a causal factor and consequence of the transition to agriculture. The use of radiocarbon (14C) dates as proxies for population allows for reevaluations of population as a variable in the transition to agriculture. In Korea, numerous rescue excavations during recent decades have offered a wealth of 14C data for this application. A summed probability distribution (SPD) of 14C dates is investigated to reconstruct population trends preceding and following adoptions of food production in prehistoric Korea. Important cultivars were introduced to Korea in two episodes: millets during the Chulmun Period (ca. 6000–1500 BCE) and rice during the Mumun Period (ca. 1500–300 BCE). The SPD suggests that while millet production had little impact on Chulmun populations, a prominent surge in population appears to have followed the introduction of rice. The case in prehistoric Korea demonstrates that the adoption of food production does not lead inevitably towards sustained population growth. Furthermore, the data suggest that the transition towards intensive agriculture need not occur under conditions of population pressure resulting from population growth. Rather, intensive rice farming in prehistoric Korea began during a period of population stagnation.

Keywords

cultivationKoreaprehistoric populationradiocarbon datessummed probability distributiontransition to agriculture
Type
Applications
Information
Radiocarbon , Volume 59 , Special Issue 6: 8th International Symposium, Edinburgh, 27 June – 1 July, 2016 Part 2 of 2 , December 2017 , pp. 1761 - 1770
Copyright
© 2017 by the Arizona Board of Regents on behalf of the University of Arizona 

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Footnotes

Selected Papers from the 8th Radiocarbon & Archaeology Symposium, Edinburgh, UK, 27 June–1 July 2016

References

REFERENCES

Ahn, S-M. 2010. The emergence of rice agriculture in Korea: archaeobotanical perspectives. Archaeological and Anthropological Sciences 2:8998.CrossRefGoogle Scholar
Ahn, S-M. 2013a. Table of excavated plant remains in the Korean Peninsula. In: Ahn S-M, editor. Archaeology of Agriculture. Seoul: Sahoepyongron, p 275302. In Korean.Google Scholar
Ahn, S-M. 2013b. A look at changing cultivar assemblages by period through plant remains. In: Ahn S-M, editor. Archaeology of Agriculture. Seoul: Sahoepyongron, p 69110. In Korean.Google Scholar
Ahn, S-M, Kim, J, Hwang, J. 2015. Sedentism, settlements, and radiocarbon dates of Neolithic Korea. Asian Perspectives 54(1):113143.CrossRefGoogle Scholar
Ammerman, AJ, Cavalli-Sforza, LL. 1971. Measuring the rate of spread of early farming in Europe. Man. 674688.CrossRefGoogle Scholar
Ammerman, AJ, Cavalli-Sforza, LL. 1973. Population model for the diffusion of early farming in Europe. In: Renfrew C, editor. The Explanation of Culture Change: Models In Prehistory. London: Duckworth. p 343357.Google Scholar
Bamforth, DB, Grund, B. 2012. Radiocarbon calibration curves, summed probability distributions, and early Paleoindian population trends in North America. Journal of Archaeological Science 39:17681774.CrossRefGoogle Scholar
Bettinger, RL. 2015. Orderly Anarchy: Sociopolitical Evolution in Aboriginal California. Oakland: University of California Press.Google Scholar
Binford, LR. 1968. Post-Pleistocene adaptations. In: Binford SR, Binford LR, editors. New Perspectives in Archaeology. Chicago: Aldine Publishing Company. p 313342.Google Scholar
Bleed, P, Matsui, A. 2010. Why didn’t agriculture develop in Japan? A consideration of Jomon ecological style, niche construction, and the origins of domestication. Journal of Archaeological Method and Theory 17:356370.CrossRefGoogle Scholar
Bocquet-Appel, J-P. 2011. When the world’s population took off: the springboard of the Neolithic Demographic Transition. Science 333(6042):560561.CrossRefGoogle ScholarPubMed
BocquetAppel, J, Naji, S, Armelagos, G, Maes, K, Chamberlain, A, Eshed, V, Jackes, M, Mosothwane, M, Sullivan, A, Warrick, G. 2006. Testing the hypothesis of a worldwide Neolithic demographic transition: corroboration from American cemeteries. Current Anthropology 47(2):341365.CrossRefGoogle Scholar
Boserup, E. 1965. The Conditions of Agricultural Growth: The Economics of Agrarian Change under Population Pressure. London: Allen & Unwin.Google Scholar
Bronk Ramsey, C. 2009. Bayesian analysis of radiocarbon dates. Radiocarbon 51(1):337360.CrossRefGoogle Scholar
Choy, K, Richards, MP. 2010. Isotopic evidence for diet in the Middle Chulmun Period: a case study from the Tongsamdong shell midden, Korea. Archaeological and Anthropological Sciences 2:110.CrossRefGoogle Scholar
Choy, K, An, D, Richards, MP. 2012. Stable isotopic analysis of human and faunal remains from the Incipient Chulmun (Neolithic) shell midden site of Ando Island, Korea. Journal of Archaeological Science 39:20912097.CrossRefGoogle Scholar
Cohen, MN. 1975. Archaeological evidence for population pressure in pre-agricultural societies. American Antiquity 40:471475.CrossRefGoogle Scholar
Cohen, MN. 1977. Food Crisis in Prehistory: Overpopulation and the Origins of Agriculture. New Haven: Yale University Press.Google Scholar
Cohen, MN. 2009. Introduction: rethinking the origins of agriculture. Current Anthropology 50(5):591595.CrossRefGoogle ScholarPubMed
Collard, M, Edinborough, K, Shennan, S, Thomas, MG. 2010. Radiocarbon evidence indicates that migrants introduced farming to Britain. Journal of Archaeological Science 37:866870.CrossRefGoogle Scholar
Cook, SF, Heizer, RF. 1968. Relationships among houses, settlement areas, and population in Aboriginal California. In: Chang KC, editor. Settlement Archaeology. Palo Alto: National Press. p 79116.Google Scholar
Crawford, GW. 2006. East Asian plant domestication. In: Stark MT, editor. Archaeology of Asia. Oxford: Blackwell Publishing. p 7795.CrossRefGoogle Scholar
Crawford, GW, Lee, G-A. 2003. Agricultural origins in the Korean Peninsula. Antiquity 77(295):8795.CrossRefGoogle Scholar
Crema, E, Habu, J, Kobayashi, K, Madella, M. 2016. Summed probability distribution of 14C dates suggests regional divergences in the population dynamics of the Jomon Period in eastern Japan. PLoS ONE 11(4):118.CrossRefGoogle ScholarPubMed
Habu, J. 2008. Growth and decline in complex hunter-gatherer societies: a case study from the Jomon Period Sannai Maruyama Site, Japan. Antiquity 82:571584.CrossRefGoogle Scholar
Hwang, J. 2014. Early Mumun Period chronology in central-western Korea based on a re-analysis of radiocarbon dates. Journal of the Korean Archaeological Society 92:3679. In Korean.Google Scholar
Hwang, J, Yang, H. 2015. Radiocarbon dating and Early Bronze Age chronology revised. Journal of the Honam Archaeological Society 50:3051. In Korean.Google Scholar
Hwang, J, Kim, J, Lee, Y, Lee, J, Song, A, Kim, J-K, Park, J, Yang, J, Yang, H, Kang, S, Oh, Y, Ahn, S-M, Choi, J, Seong, C, Wright, David K, Choi, S, Hyun, C. 2016. Radiocarbon dating and old wood effect: an experiment and archaeological assessment. Journal of the Korean Ancient Historical Society 92:117149. In Korean.Google Scholar
Kelly, R. 1995. The Foraging Spectrum. Washington, DC: Smithsonian Institution Press.Google Scholar
Kim, J. 2002. An archaeological distinction between migration and diffusion: preliminary models. Journal of Korean Ancient Historical Society 38:126. In Korean.Google Scholar
Kim, J. 2003. Land-use conflict and the rate of transition to agricultural economy: a comparative study of southern Scandinavia and central-western Korea. Journal of Archaeological Method and Theory 10(3):277321.CrossRefGoogle Scholar
Kim, J. 2010. Opportunistic versus target mode: prey choice changes in central-western Korean prehistory. Journal of Anthropological Archaeology 29(1):8093.CrossRefGoogle Scholar
Kim, J. 2014. Interdisciplinary research in archaeology, physics, and statistics for radiocarbon dating. Proceedings of 38th Meeting of Korean Archaeology. The Korean Archaeological Society. In Korean.Google Scholar
Kim, J, Yang, S. 2001. New understandings of the central-western Korean Neolithic chronology and shellmedden exploitation strategy. Journal of Korean Archaeological Society 45(5):44. In Korean.Google Scholar
Kim, M, Shin, H-N, Kim, S, Lim, D-J, Jo, K, Ryu, A, Won, H, Oh, S, Noh, H. 2015. Population and social aggregation in the Neolithic Chulmun villages of Korea. Journal of Anthropological Archaeology 40:160182.CrossRefGoogle Scholar
Kolb, CC, Charlton, TH, DeBoer, W, Fletcher, R, Healy, PF, Janes, RR, Naroll, R, Shea, D. 1985. Demographic estimates in archaeology: contributions from ethnoarchaeology on Mesoamerican peasants [and comments and reply]. Current Anthropology 26(5):581599.CrossRefGoogle Scholar
Korean Archaeological Society. 2010. Lectures on Korean Archaeology. Seoul: Sahoepyongron. In Korean.Google Scholar
Koyama, S. 1992. Prehistoric Japanese Populations: A Subsistence-Demographic Approach. Japanese as a Member of the Asian and Pacific Populations. Kyoto. Japan: International Research Center for Japanese Studies. p 187197.Google Scholar
Kuzmin, YV, Keates, SG. 2005. Dates are not just data: Paleolithic settlement patterns in Siberia derived from radiocarbon records. American Antiquity 70(4):773789.CrossRefGoogle Scholar
Lee, G-A. 2011. The transition from foraging to farming in prehistoric Korea. Current Anthropology 52(S4):S307S329.CrossRefGoogle Scholar
Lee, G-A. 2012. Archaeological perspectives on the origins of Azuki (Vigna angularis). The Holocene 23(3):453459.CrossRefGoogle Scholar
Lee, G-A, Crawford, GW, Liu, L, Sasaki, Y, Chen, X. 2011. Archaeological soybean (Glycine max) in East Asia: does size matter? PLoS ONE 6(11):112.CrossRefGoogle ScholarPubMed
Lee, J-J. 2011. Intensification of millet and rice agriculture in Korea: evidence from stable isotopes. Journal of Korean Ancient Historical Society 73:3166. In Korean.Google Scholar
Lee, Y. 2011. Subsistence type. In: Heritage CIoC, editor. Introduction to Korean Neolithic Culture. Seoul: Seogyeongmunhwasa. In Korean.Google Scholar
Matsui, A, Kanehara, M. 2006. The question of prehistoric plant husbandry during the Jomon Period in Japan. World Archaeology 38(2):259273.CrossRefGoogle Scholar
Naroll, R. 1962. Floor area and settlement population. American Antiquity 27(4):587589.CrossRefGoogle Scholar
Shennan, S, Edinborough, K. 2007. Prehistoric population history: from the Late Glacial to the Late Neolithic in Central and Northern Europe. Journal of Archaeological Science 34:13391345.CrossRefGoogle Scholar
Shennan, S, Downey, SS, Timpson, A, Edinborough, K, Colledge, S, Kerig, T, Manning, K, Thomas, MG. 2013. Regional population collapse followed initial agriculture booms in mid-Holocene Europe. Nature Communications 4:18.CrossRefGoogle ScholarPubMed
Smith, BD. 2001. Low-level food production. Journal of Archaeological Research 9(1):143.CrossRefGoogle Scholar
Tallavaara, M, Pesonen, P, Oinonen, M. 2010. Prehistoric population history in eastern Fenndoscandia. Journal of Archaeological Science 37(2):251260.CrossRefGoogle Scholar
Timpson, A, Colledge, S, Crema, E, Edinborough, K, Kerig, T, Manning, K, Thomas, MG, Shennan, S. 2014. Reconstructing regional population fluctuations in the European Neolithic using radiocarbon dates: a new case-study using an improved method. Journal of Archaeological Science 52:549557.CrossRefGoogle Scholar
Timpson, A, Manning, K, Shennan, S. 2015. Inferential mistakes in population proxies: a response to Torfing’s “Neolithic population and summed probability distribution of 14C-dates”. Journal of Archaeological Science 63:199202.CrossRefGoogle Scholar
Warrick, GA. 1988. Estimating Ontario Iroquoian village duration. Man in the Northeast 36:2160.Google Scholar
Whittle, A, Bayliss, A, Healy, F. 2008. The timing and tempo of change: examples from the fourth millennium cal. BC in southern England. Cambridge Archaeological Journal 18(1):6570.CrossRefGoogle Scholar
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