Hostname: page-component-78c5997874-mlc7c Total loading time: 0 Render date: 2024-11-09T08:40:42.044Z Has data issue: false hasContentIssue false
  • English
  • Français

New AMS dates from Upper Palaeolithic Kastritsa

Published online by Cambridge University Press:  18 February 2014

N. Galanidou  and
P.C. Tzedakis
N. Galanidou
Affiliation:
Department of History & Archaeology, University of Crete, Rethymno, 74 100, [email protected]
P.C. Tzedakis
Affiliation:
School of Geography, University of Leeds, Leeds LS2 9JT, UK
Get access Rights & Permissions [Opens in a new window]

Extract

Thirty-four years ago there appeared in the Proceedings of the Prehistoric Society the third and final paper in a series reporting the research of Eric Higgs and his colleagues into the climate, environment, and Stone Age record of north-west Greece (Higgs et al. 1967). This paper discussed two limestone rockshelters, Kastritsa and Asprochaliko, comparatively in what is now a classic example of site catchment analysis. Kastritsa, in the Pamvotis lake basin, and Asprochaliko, some 35 km away in the Louros river valley (Fig. 1), were destined to become famous, not only for being amongst the first sites in Greece to yield stratified Palaeolithic deposits, but also for the methodological and interpretative issues raised by their archaeological records. The ideas presented in the 1967 paper aroused considerable debate and controversy regarding when and during which seasons the sites were used and whether they were complementary parts of the region's Upper Palaeolithic settlement system (Higgs et al. 1967; Bailey et al. 1983; Bailey 1997a; Green 1997). The essential assumption underlying Higgs' original hypothesis was that some of the strata recovered from these sites were contemporaneous. In recent years the upper part of Kastritsa (strata 1 & 3) has also been considered to be partly coeval with two of the rockshelters in the Voidomatis river valley, namely Klithi and Megalakkos (Fig. 1).

Résumé

Cette étude examine les implications des dates au radiocarbone AMS obtenues récemment à Kastritsa et qui repoussent d'environ 2000 ans en arrière les premières et dernières occupations par rapport aux déterminations antérieures. Selon ces nouvelles dates, l'utilisation humaine du site de Kastritsa ne s'est pas prolongée pendant la dernière glaciation (vers 15 000–10 000) comme on l'avait pensé jusqu'à présent. Cette découverte a eu pour résultat la révision de notre conception de l'occupation du site d'Epire au Paléolithique supérieur.

Zusammenfassung

Dieser Artikel diskutiert die Auswirkungen von AMS Radiocarbon Daten, die man jetzt für Kastritsa erhalten hat, und die die früheste Belegung ca. 2000 Jahre vor die bisherigen Feststellungen datieren. Nach den neuen Daten erstreckte sich die menschliche Benutzung von Kastritsa nicht, wie bisher angenommen, in das Spätglazial hinein (c. 15,000–10,000). Als ein Ergebnis daraus werden die Vorstellungen von der jungpaläolithischen Siedlung von Epirus korrigiert.

Resúmen

Este trabajo analiza las implicaciones de dataciones al carbono-14 tipo AMS recientemente obtenidas del yacimiento de Kastritsa que atrasan el comienzo y fin de la ocupación más de 2000 años de lo previamente establecido. De acuerdo con estas nuevas fechas, la ocupación humana de Kastritsa no continuó en el periodo tardo glacial (ca. 15,000–10,000) como se había supuesto previamente. Esto ha resultado en una revisión de nuestras ideas sobre el asentamiento en la zona del Epirus en el Paleolítico Superior.

Type
Shorter Contributions
Information
Proceedings of the Prehistoric Society , Volume 67 , 2001 , pp. 271 - 278
Copyright
Copyright © The Prehistoric Society 2001

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

BIBLIOGRAPHY

Adam, E. 1997. The Upper Palaeolithic stone industries of Epirus in their regional setting. In Bailey, et al. (eds) 1997, 136–47Google Scholar
Bailey, 1997a. History, aims and structure of investigations. In Bailey, (ed.) 1997c, 326Google Scholar
Bailey, G.N., 1997b. Klithi: a synthesis. In Bailey, (ed.) 1997c, 655–77Google Scholar
Bailey, G.N. (ed.). 1997c. Klithi: Archaeology of a Late Glacial Landscape in Epirus (Northwest Greece). (2 vols). Cambridge: McDonald Institute for Archaeological ResearchGoogle Scholar
Bailey, G.N. 1999. The Palaeolithic archaeology and palaeogeography of Epirus. In Bailey, et al. (eds) 1999, 157–69Google Scholar
Bailey, G.N., Carter, P.L., Gamble, C.S. & Higgs, H.P. 1983. Asprochaliko and Kastritsa: further investigations of Palaeolithic settlement and economy in Epirus (North-West Greece). Proceedings of the Prehistoric Society 49, 1542CrossRefGoogle Scholar
Bailey, G.N., Gamble, C.S., Higgs, H.P., Roubet, C., Webley, D.P., Gowlett, J.A.J., Sturdy, D.A. & Turner, C. 1986. Dating results from Palaeolithic sites and environments in Epirus (North-west Greece). In Gowlett, J.A.J. & Hedges, R.E.M (eds), Archaeological Results from Accelerator Dating, 99107. Oxford: Oxford University Committee for Archaeology Monograph 11Google Scholar
Bailey, G.N., Adam, E., Panagopoulou, E., Perlès, C. & Zachos, K. (eds), 1999. The Palaeolithic of Greece and Adjacent Areas. London: British School at Athens Studies 3Google Scholar
Bottema, S. 1974. Late Quaternary Vegetation History of Northwestern Greece. Unpublished Ph.D Thesis, Rijksuniversiteit te GroningenGoogle Scholar
Digerfeldt, G., Olson, S. & Sandgren, P. 2000. Reconstruction of lake-level changes in lake Xinias, central Greece, during the last 40,000 years. Palaeogeography, Palaeoclimatology, Palaeoecology 158, 6582CrossRefGoogle Scholar
Frogley, M.R. 1997. The Biostratigraphy, Palaeoecology and Geochemistry of a Long Lacustrine Sequence from NW Greece. Unpublished Ph.D. Thesis, Department of Zoology, University of CambridgeGoogle Scholar
Galanidou, N. 1997. Lithic refitting and site structure at Kastritsa. In Bailey, (ed.) 1997c, 497520Google Scholar
Galanidou, N. 1999. Regional settlement and intra-site spatial patterns in Upper Palaeolithic Epirus. In Bailey, et al. (eds) 1997, 148–58Google Scholar
Galanidou, N. 2000. Biographies of lithic artefacts from the Upper Palaeolithic Kastritsa. Annual of the British School at Athens 95, 119CrossRefGoogle Scholar
Galanidou, N., Tzedakis, P.C., Lawson, I.T. & Frogley, M.R. 2000. A revised chronological and palaeoenvironmental framework for the Kastritsa rockshelter, northwest Greece. Antiquity 74, 349–55CrossRefGoogle Scholar
Gowlett, J., Hedges, R. & Housley, R. 1997. Klithi: the AMS radiocarbon dating programme for the site and its environs. In Bailey, (ed.) 1997c, 2740Google Scholar
Green, S., 1997. Interweaving landscapes: the relevance of ethnographic data on rural groups in Epirus for Palaeolithic research. In Bailey, (ed.) 1997c, 637–52Google Scholar
Harrison, S.P. & Digerfeldt, G. 1993. European lakes as palaeoehydrological and palaeoclimatic indicators. Quaternary Science Reviews 12, 233–48CrossRefGoogle Scholar
Higgs, E.S., Vita-Finzi, C., Harris, D.R. & Fagg, A.E. 1967. The climate, environment and industries of Stone Age Greece: part III. Proceedings of the Prehistoric Society 33 129CrossRefGoogle Scholar
Huxtable, J., Gowlett, J.A.J., Bailey, G.N., Carter, P.L. & Papakonstantinou, V. 1992. Thermoluminescence dates and a new analysis of the Early Mousterian from Asprochaliko. Current Anthropology 33(1), 109–14CrossRefGoogle Scholar
King, G.C.P. & Bailey, G.N. 1985. The palaeoenvironment of some archaeological sites in Greece: the influence of accumulated uplift in a seismically active region. Proceedings of the Prehistoric Society 51, 273–83CrossRefGoogle Scholar
Kotjabopoulou, E., Panagopoulou, E. & Adam, E. 1999. The Boila rockshelter: further evidence of human activity in the Voidomatis gorge. In Bailey, et al. (eds) 1999, 197210Google Scholar
Martinson, D.G, Pisias, N.G., Hays, J.D., Imbrie, J., Moore, T.C. Jr & Shackleton, N.J. 1987. Age dating and the orbital theory of ice ages: development of a highresolution 0 to 300,000–year chronostratigraphy. Quaternary Research 27, 129CrossRefGoogle Scholar
Prentice, I.C., Guiot, J. & Harrison, S.P. 1992. Mediterranean vegetation, lake levels and palaeoclimate at the Last Glacial Maximum. Nature 360, 658–60CrossRefGoogle Scholar
Sinclair, A. 1997. Lithic and faunal assemblages from Megalakkos: some problems in the interpretation of small sites. In Bailey, (ed.) 1997c, 415–26Google Scholar
Tzedakis, PC. 1994. Vegetation change through glacialinterglacial cycles: a long pollen sequence perspective. Philosophical Transactions of the Royal Society B345, 403–32Google Scholar