Hostname: page-component-8448b6f56d-sxzjt Total loading time: 0 Render date: 2024-04-19T06:38:34.665Z Has data issue: false hasContentIssue false
  • English
  • Français

Climate change, patch choice, and intensification at Pont d'Ambon (Dordogne, France) during the Younger Dryas

Published online by Cambridge University Press:  20 January 2017

Emily Lena Jones
Emily Lena Jones*
Affiliation:
Department of Sociology, Social Work, and Anthropology, Utah State University, Logan, UT 84322-0730, USA
*
Fax: +1 435 797 3943. E-mail address:Emily.Jones@usu.edu
Get access Rights & Permissions [Opens in a new window]

Abstract

This paper considers the impact of the Younger Dryas on the prehistoric inhabitants of Pont d'Ambon, a site in the Dordogne region of southwestern France, through an examination of the zooarchaeological remains from this site. An investigation of patch choice indicates that patch choice evenness declines during the Younger Dryas due to increasing local dominance of the grassland patch. Analyses of demographic composition, cutmark frequency, and marrow processing in the wild European rabbit (Oryctolagus cuniculus) assemblage suggest intensified rabbit use during this period. This study thus supports the hypothesis that changing climate had significant impacts on the prehistoric inhabitants of Pont d'Ambon. However, the traditional climate hypothesis—that changing climate negatively impacted the availability of larger fauna, forcing a switch to smaller, lower-ranked prey items—is not supported here. The inhabitants of Pont d'Ambon seem to have adapted to changing climate by efficiently exploiting the new species available to them, and possibly, during the Younger Dryas, by intensifying their use of one of these new species, the European rabbit.

Keywords

Pleistocene-Holocene transitionYounger DryasZooarchaeologyDordogneDietary changePont d'Ambon
Type
Short Paper
Information
Quaternary Research , Volume 72 , Issue 3 , November 2009 , pp. 371 - 376
Copyright
University of Washington

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Bouzouggar, A., Barton, R., Blockley, S., Bronk-Ramsey, C., Collcutt, S., Gale, R., Higham, T., Humphrey, L., Parfitt, S., Turner, E., and Ward, S. Reevaluating the age of the Iberomaurusian in Morocco. African Archaeological Review 25, (2008). 319.Google Scholar
Broodbank, C. The origins and early development of Mediterranean maritime activity. Journal of Mediterranean Archaeology 19, (2006). 199230.Google Scholar
Broughton, J.M. Declines in mammalian foraging efficiency during the late Holocene, San Francisco Bay, California. Journal of Anthropological Archaeology 13, (1994). 371401.CrossRefGoogle Scholar
Broughton, J.M. Resource depression and intensification during the late Holocene, San Francisco Bay: evidence from the Emeryville shellmound, California. (1999). University of California Press, Berkeley.Google Scholar
Burger, O., Hamilton, M.J., and Walker, R. The prey as patch model: optimal handling of resources with diminishing returns. Journal of Archaeological Science 32, (2005). 11471158.Google Scholar
Cannon, M.D., and Meltzer, D.J. Explaining variability in Early Paleoindian foraging. Quaternary International 191, (2008). 517.Google Scholar
Célérier, G. L'abri sous roche de Pont d'Ambon à Bourdeilles (Dordogne): le milieu biologique. Gallia Préhistoire 36, (1994). 96105.Google Scholar
Célérier, G. L'abri sous-rouche de Pont d'Ambon à Bourdeilles (Dordogne, France): perspective synthétique. Paléo 10, (1998). 233264.Google Scholar
Célérier, G., Guérin, G., Duchadeau-Kervazo, C., Kervazo, B., Gambier, D., LeGall, O., Pannoux, P., Limondin, N., Ozouf, J.-C., and Thiébault, S. L'Abri sous roche de Pont d'Ambon à Bourdeilles (Dordogne). Gallia Préhistoire 36, (1994). 65144.Google Scholar
Célérier, G., and Kervazo, B. L'Abri sous roche de Pont d'Ambon à Bourdeilles (Dordogne): étude géologique du site. Gallia Préhistoire 36, (1994). 7295.CrossRefGoogle Scholar
Cochard, D. (2004). "Les léporidés dans la subsistance paléolithique du Sud de la France.". Unpublished Thèse de doctorat thesis, Université de Bordeaux I, .Google Scholar
Corbet, G.B. Taxonomy and origins. Thompson, H.V., and King, C.M. The European rabbit: the history and biology of a successful colonizer. (1994). Oxford University Press, Oxford. 17.Google Scholar
Delpech, F. La faune du Paléolithique supérieur dans le Sud-Ouest de la France. (1983). Cahier du Quaternaire, Paris.Google Scholar
Delpech, F. Le monde magdalénien d'après le milieu animal. Rigaud, J.-P., Laville, H., and Vandermeersch, B. Le peuplement magdalénien: paléographie physique et humaine: colloque de Chancelade, 10–15 octobre 1988. (1992). CTHS, Paris. 127135.Google Scholar
Delpech, F. Biomasse d'ongulés au Paléolithique et inférences sur la démographie. Paléo 11, (1999). 1942.CrossRefGoogle Scholar
Demars, P.-Y. Altitude des sites suivant le climat au Paléolithique supérieur et au Mésolithique en France. Praehistoria 1, (2000). 4754.Google Scholar
Demars, P.-Y. A la conquête des massifs montagneux: l'occupation de l'espace à la fin de la dernière glaciation et au début du Postglaciare dans le sud de la France. Bulletin Préhistoire du Sud-Ouest 9, (2002). 185190.Google Scholar
Donard, E. (1982). Recherches sur les léporinés quaternaires (Pleistocène moyen et supérieur, Holocène). Unpublished Docteur en géologie du quaternaire et préhistoire thesis, Université de Bordeaux I, .Google Scholar
el Guennouni, K. (2001). Les lapins du Pleistocène Moyen et Supérieur de quelques sites préhistoriques de l'Europe Mediterranéene: Terra Amata, Orgnac 3, Baume Bonne, Grotte du Lazaret, Grotte du Boquete de Zafarraya, Arma Delle Mainie. Étude paleontologique, taphonomique et archéozoologique. Unpublished Thèse de doctorat thesis, Muséum National d'Histoire Naturelle de Paris, Laboratoire de Préhistoire, Institut de Paleontologie Humaine, .Google Scholar
Fauquette, S., Guiot, J., Menut, M., de Beaulieu, J.-L., Reille, M., and Guenet, P. Vegetation and climate since the last interglacial in the Vienne area (France). Global and Planetary Change 20, (1999). 117.Google Scholar
Firestone, R.B., West, A., Kennett, J.P., Becker, L., Bunch, T.E., Revay, Z.S., Schultz, P.H., Belgya, T., Kennett, D.J., Erlandson, J.M., Dickenson, O.J., Goodyear, A.C., Harris, R.S., Howard, G.A., Kloosterman, J.B., Lechler, P., Mayewski, P.A., Montgomery, J., Poreda, R., Darrah, T., Que Hee, S.S., Smith, A.R., Stich, A., Topping, W., Wittke, J.H., and Wolbach, W.S. Evidence for an extraterrestrial impact 12,900 years ago that contributed to the megafaunal extinctions and the Younger Dryas cooling. Proceedings of the National Academy of Sciences of the United States of America 104, (2007). 1601616021.Google Scholar
Grayson, D.K., Delpech, F., Rigaud, J.-P., and Simek, J.F. Explaining the development of dietary dominance by a single ungulate taxon at Grotte XVI, Dordogne, France. Journal of Archaeological Science 28, (2001). 115125.Google Scholar
Guiot, J. Methodology of the last climatic cycle reconstruction in France from pollen data. Palaeogeography, Palaeoclimatology, Palaeoecology 80, (1990). 4969.CrossRefGoogle Scholar
Guiot, J., Pons, J.A., de Beaulieu, J.-L., and Reille, M. A 140,000-year climate reconstruction from two European pollen records. Nature 338, (1989). 309313.Google Scholar
Hockett, B.S., and Bicho, N.F. The rabbits of Picareiro Cave: small mammal hunting during the Late Upper Palaeolithic in the Portuguese Estremadura. Journal of Archaeological Science 27, (2000). 715723.Google Scholar
Hockett, B.S., and Haws, J.A. Nutritional ecology and diachronic trends in Paleolithic diet and health. Evolutionary Anthropology 12, (2003). 211216.Google Scholar
Huntley, B. Europe. Huntley, B., and Webb, I.T. Vegetation History. (1988). Kluwer Academic Press, Dordrecht. 341384.Google ScholarPubMed
Huntley, B. European pollen history: palaeovegetation maps from pollen data—13 000 yr BP to present. Journal of Quaternary Science 5, (1990). 103122.Google Scholar
Jones, E.L. (2004a). Broad spectrum diets and the European rabbit (Oryctolagus cuniculus): Dietary change during the Pleistocene-Holocene transition in the Dordogne, Southwestern France. Unpublished PhD dissertation thesis, University of Washington, .Google Scholar
Jones, E.L. Dietary evenness, prey choice, and human–environment interactions. Journal of Archaeological Science 31, (2004). 307317.Google Scholar
Jones, E.L. Prey choice, mass collecting, and the wild European rabbit (Oryctolagus cuniculus). Journal of Anthropological Archaeology 25, (2006). 275289.Google Scholar
Jones, E.L. Subsistence change, landscape use, and changing site elevation at the Pleistocene–Holocene transition in the Dordogne of Southwestern France. Journal of Archaeological Science 34, (2007). 344353.Google Scholar
LeGall, O. Évolution des pêches de l'Épipaléolithique au Néolithique ancien. Préhistoire Anthropologie Méditeranées 2, (1993). 135142.Google Scholar
LeGall, O., and Pannoux, P. Les poissons de Pont d'Ambon. Gallia Préhistoire 36, (1994). 113126.Google Scholar
Lombardi, L., Fernández, N., Moreno, S., and Villafuerte, R. Habitat-related differences in rabbit (Oryctolagus cuniculus) abundance, distribution, and activity. Journal of Mammalogy 84, (2003). 2636.2.0.CO;2>CrossRefGoogle Scholar
Lupo, K.D. Evolutionary foraging models in zooarchaeological analysis: recent applications and future challenges. Journal of Archaeological Research 15, (2007). 143189.CrossRefGoogle Scholar
Lyman, R.L. Quantitative Paleozoology. (2008). Cambridge University Press, New York.Google Scholar
Magny, M. Éléments pour une histoire du climat entre 13000 et 6000 BP. Bulletin de la Société Préhistorique Française 94, (1997). 161167.Google Scholar
Magurran, A.E. Ecological diversity and its measurement. (1988). Princeton University Press, Princeton, NJ.Google Scholar
Marchandeau, S., Chaval, Y., and Le Goff, E. Prolonged decline in the abundance of wild European rabbits Oryctolagus cuniculus and high immunity level over three years following the arrival of rabbit haemorrhagic disease. Wildlife Biology 6, (2000). 141147.Google Scholar
Nagaoka, L. The effects of resource depression on foraging efficiency, diet breadth, and patch use in southern New Zealand. Journal of Anthropological Archaeology 21, (2002). 419442.Google Scholar
Newby, P., Bradley, J., Spiess, A., Shuman, B., and Leduc, P. A Paleoindian response to Younger Dryas climate change. Quaternary Science Reviews 24, (2005). 141154.Google Scholar
Perez Ripoll, M. Las marcas tafonomicas en huesos de lagomorfos. Estudios Sobre Cuaternario (1993). 227231.Google Scholar
Pike-Tay, A. Red deer hunting in the upper Paleolithic of southwest France: a study in seasonality. (1991). British Archaeological Reports, Oxford.Google Scholar
Ritchie, M.E. Scale-dependent foraging and patch choice in fractal environments. Evolutionary Ecology 12, (1998). 309330.Google Scholar
Rogers, P.M., Arthur, C.P., and Soriguer, R.C. The rabbit in continental Europe. Thompson, H.V., and King, C.M. The European rabbit: the history and biology of a successful colonizer. (1994). Oxford Univ. Press, Oxford. 2263.Google Scholar
Schmitt, D.N. Bone artifacts and human remains. Elston, R.G., and Budy, E.E. The Archaeology of James Creek Shelter. (1990). University of Utah, Anthropological Papers, Salt Lake City. 117127.Google Scholar
Stiner, M.C., and Munro, N.D. Approaches to prehistoric diet breadth, demography, and prey ranking systems in time and space. Journal of Archaeological Method and Theory 9, (2002). 181214.Google Scholar
Straus, L.G. The archaeology of the Pleistocene–Holocene transition in southwest Europe. Straus, L.G., Eriksen, B.V., Erlandson, J.M., and Yesner, D.R. Humans at the End of the Ice Age: the Archaeology of the Pleistocene-Holocene Transition. Interdisciplinary Contributions to Archaeology (1996). Plenum Press, New York. 83100.Google Scholar
Straus, L.G. High resolution archeofaunal records across the Pleistocene Holocene transition on a transect between 43 and 51 degrees north latitude in Western Europe. Driver, J.C. Zooarchaeology of the Pleistocene/Holocene boundary. (1999). Archaeopress, Oxford. 2129.Google Scholar
Straus, L.G. Coming out from the cold: Western Europe in Dryas I and beyond. Peterkin, G.L., and Price, H.A. Regional Approaches to Adaptation in Late Pleistocene Western Europe. BAR international series vol. 896, (2000). Archaeopress, Oxford. 191204.Google Scholar