Origins of Carbon in Potsherds

Martine Gabasio; Jacques Evin; Gaston Bernard Arnal; Philippe Andrieux

doi:10.1017/S0033822200007931

Abstract

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The general reliability of 14C dating in archaeology induced us to try to extend the method to other datable materials that may be uncovered, even those which have till now been neglected or considered unreliable. Improvements in AMS techniques will also help us date very small samples or those with low carbon content. For these reasons we have undertaken a systematic study of the application of 14C dating to potsherds which are usually abundant in prehistoric sites and often more representative of human activity than other materials such as charcoal (Evin, 1983).

References

Arnal, G B, 1976, La céramique néolithique dans le Haut-Languedoc, in Mémoire du Centre de Recherche Archéologique du Haut-Languedoc: CNRS.Google Scholar

De Atley, S P, 1980, Radiocarbon dating of ceramic materials: Progress and prospects in Stuiver, M and Kra, R S, eds, Internatl ¹⁴C conf, 10th, Proc: Radiocarbon, v 22 no 3, p 987–993.Google Scholar

Engstrand, L G, 1965, Stockolm natural radiocarbon measurements VI: Radiocarbon v 7, p 257–290.CrossRef Google Scholar

Evin, J, 1983, Materials of terrestrial origin used for radiocarbon dating—Les matériaux d'origine terrestre utilisés pour les datations par le radiocarbone: PACT, v 8, p 235–290.Google Scholar

Evin, J, 1985, Réflexion sur les premiers essais de datation par le radiocarbone de tessons de poteries enfumées, in Archéologie africaine et sciences de la nature appliquées à l'archéologie: Actes symposium internatl, 1st, Bordeaux, Sept 1983, ACCT-CNRS-CRIAA.Google Scholar

Evin, J, Thévenot, J P and Gabasio, M, 1985, Les datations radiocarbone du site de Chassey, in Colloque néolithique de Lons-le-Saunier: Colloque internatl sur le néolithique, Lons-le-Saunier, France, Oct 1985.Google Scholar

Gilet-Blein, N, Marien, G and Evin, J, 1980, Unreliability of ¹⁴C dates from organic matter of soils, in Stuiver, M and Kra, R S, eds, Internatl ¹⁴C conf, 10th, Proc: Radiocarbon v 22 no. 3, p 919–929.Google Scholar

Stuckenrath, R, 1963, University of Pennsylvania radiocarbon dates VI: Radiocarbon, v 5, p 82–103.CrossRef Google Scholar

Tauber, H, 1968, Copenhagen radiocarbon dates IX: Radiocarbon, v 10, no. 2, p 295–327.CrossRef Google Scholar

Vogel, J C and Waterbolk, H T, 1963, Groningen radiocarbon dates IV: Radiocarbon, v 5, p 163–202.CrossRef Google Scholar

Vogel, J C and Waterbolk, H T, 1967, Groningen radiocarbon dates VII: Radiocarbon, v 9, p 107–155.CrossRef Google Scholar

Crossref Citations

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Hester, James J. 1987. The Significance of Accelerator Dating in Archaeological Method and Theory. Journal of Field Archaeology, Vol. 14, Issue. 4, p. 445.

Johnson, Jessica S. Clark, Jeff Miller-Antonio, Sari Robins, Don Schiffer, Michael B. and Skibo, James M. 1988. Effects of firing temperature on the fate of naturally occurring organic matter in clays. Journal of Archaeological Science, Vol. 15, Issue. 4, p. 403.

Geyh, Mebus A. and Schleicher, Helmut 1990. Absolute Age Determination. p. 381.

Heron, C. Evershed, R.P. and Goad, L.J. 1991. Effects of migration of soil lipids on organic residues associated with buried potsherds. Journal of Archaeological Science, Vol. 18, Issue. 6, p. 641.

Hedges, R. E. M. Tiemei, Chen and Housley, R. A. 1992. Results and Methods in the Radiocarbon Dating of Pottery. Radiocarbon, Vol. 34, Issue. 3, p. 906.

Stäuble, Harald 1995. Radiocarbon Dates of the Earliest Neolithic in Central Europe. Radiocarbon, Vol. 37, Issue. 2, p. 227.

Delqué Količ, Emmanuelle 1995. Direct Radiocarbon Dating of Pottery: Selective Heat Treatment to Retrieve Smoke-Derived Carbon. Radiocarbon, Vol. 37, Issue. 2, p. 275.

Gomes, Denise C and Vega, Oscar 1999. Dating Organic Temper of Ceramics By Ams: Sample Preparation and Carbon Evaluation. Radiocarbon, Vol. 41, Issue. 3, p. 315.

Nakamura, Toshio Taniguchi, Yasuhiro Tsuji, Sei'ichiro and Oda, Hirotaka 2001. Radiocarbon Dating of Charred Residues on the Earliest Pottery in Japan. Radiocarbon, Vol. 43, Issue. 2B, p. 1129.

Yoshida, Kunio Ohmichi, Juntaro Kinose, Masanori Iijima, Hiroko Oono, Ayako Abe, Naohiro Miyazaki, Yumiko and Matsuzaki, Hiroyuki 2004. The application of 14C dating to potsherds of the Jomon period. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms, Vol. 223-224, Issue. , p. 716.

Berstan, R. Stott, A.W. Minnitt, S. Ramsey, C. Bronk Hedges, R.E.M. and Evershed, R.P. 2008. Direct dating of pottery from its organic residues: new precision using compound-specific carbon isotopes. Antiquity, Vol. 82, Issue. 317, p. 702.

Peacock, Evan and Feathers, James K. 2009. Accelerator Mass Spectrometry Radiocarbon Dating of Temper in Shell-Tempered Ceramics: Test Cases from Mississippi, Southeastern United States. American Antiquity, Vol. 74, Issue. 2, p. 351.

Hatté, Christine Saliège, Jean-François Senasson, Delphine and Bocoum, Hamady 2010. Cultural and trade practices in Sincu Bara (Senegal): a multi-proxy investigation. Journal of Archaeological Science, Vol. 37, Issue. 3, p. 561.

Messili, Lamia Saliège, Jean-François Broutin, Jean Messager, Erwan Hatté, Christine and Zazzo, Antoine 2013. Direct14C Dating of Early and Mid-Holocene Saharan Pottery. Radiocarbon, Vol. 55, Issue. 3, p. 1391.

Karmanov, Victor N Zaretskaya, Natalia E and Volokitin, Alexander V 2014. Another Way of Early Pottery Distribution in Eastern Europe? Case Study of the Pezmog 4 Site, European Far Northeast. Radiocarbon, Vol. 56, Issue. 2, p. 733.

Gilmore, Zackary I. 2015. Direct radiocarbon dating of Spanish moss (Tillandsia usneoides) from early fiber-tempered pottery in the southeastern U.S.. Journal of Archaeological Science, Vol. 58, Issue. , p. 1.

Roffet-Salque, Mélanie Dunne, Julie Altoft, David T. Casanova, Emmanuelle Cramp, Lucy J.E. Smyth, Jessica Whelton, Helen L. and Evershed, Richard P. 2017. From the inside out: Upscaling organic residue analyses of archaeological ceramics. Journal of Archaeological Science: Reports, Vol. 16, Issue. , p. 627.

Chiriu, Daniele Ricci, Pier Carlo Scattini, Maddalena Polcaro, Andrea D’Andrea, Marta Richard, Suzanne Qader, Abdulqader Abdullah and Carbonaro, Carlo Maria 2018. Portable NIR Raman microspectroscopy investigation on Early Bronze IV pottery (2500–1950 BCE) from Khirbat Iskandar, Jordan. Vibrational Spectroscopy, Vol. 97, Issue. , p. 8.

Casanova, Emmanuelle Knowles, Timothy D. J. Bayliss, Alex Dunne, Julie Barański, Marek Z. Denaire, Anthony Lefranc, Philippe di Lernia, Savino Roffet-Salque, Mélanie Smyth, Jessica Barclay, Alistair Gillard, Toby Claßen, Erich Coles, Bryony Ilett, Michael Jeunesse, Christian Krueger, Marta Marciniak, Arkadiusz Minnitt, Steve Rotunno, Rocco van de Velde, Pieter van Wijk, Ivo Cotton, Jonathan Daykin, Andy and Evershed, Richard P. 2020. Accurate compound-specific 14C dating of archaeological pottery vessels. Nature, Vol. 580, Issue. 7804, p. 506.

Woolsey, Cora A 2020. A Direct-Dated Ceramic AMS Sequence from the Gaspereau Lake Reservoir Site Complex, Maine–Maritimes Region, Northeastern North America. Radiocarbon, Vol. 62, Issue. 2, p. 419.

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Origins of Carbon in Potsherds

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