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A Model for Calculating Freshwater Reservoir Offsets on AMS-Dated Charred, Encrusted Cooking Residues Formed from Varying Resources

Published online by Cambridge University Press:  26 July 2016

John P Hart
John P Hart*
Affiliation:
Research and Collections Division, New York State Museum, 3140 Cultural Education Center, Albany, NY 12230, USA. Email: jph_nysm@mail.nyscd.gov
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Abstract

The freshwater reservoir effect (FRE) hypothesis suggests that ancient carbon from aquatic organisms incorporated into AMS-dated charred, encrusted cooking residues on interior pottery walls produces old apparent radiocarbon ages. This hypothesis has been used primarily in northern European final Mesolithic contexts to explain 14C ages on cooking residues that are thought to be too old relative to 14C ages obtained on terrestrial samples, resulting in so-called freshwater reservoir offsets (FROs). More recently, the hypothesis has been cited in interpretations of 14C ages from residues in the North American Plains and elsewhere. This article presents a model using an Excel spreadsheet that allows calculation of FROs with varying inputs of dead carbon and aquatic and terrestrial resources.

Type
Articles
Information
Radiocarbon , Volume 56 , Issue 3 , 2014 , pp. 981 - 989
Copyright
Copyright © 2014 by the Arizona Board of Regents on behalf of the University of Arizona 

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References

Boudin, M, Van Strydonck, M, Crombé, P. 2009. Radiocarbon dating of pottery food crusts: reservoir effect or not? The case of the Swifterbant pottery from Doel “Deurganckdok” (Belgium). In: Crombé, P, Van Strydonck, M, Sergant, J, Bats, M, Boudin, M, editors. Chronology and Evolution within the Mesolithic of North-West Europe. Newcastle-upon-Tyne: Cambridge Scholars Publishing. p 727–45.Google Scholar
Boyd, M, Surette, C. 2010. Northernmost precontact maize in North America. American Antiquity 75(1):117–33.Google Scholar
Brock, F, Higham, T, Ditchfield, P, Bronk Ramsey, C. 2010. Current pretreatment methods for AMS radiocarbon dating at the Oxford Radiocarbon Accelerator Unit (ORAU). Radiocarbon 52(1):103–12.CrossRefGoogle Scholar
Broecker, WS, Walton, A. 1959. The geochemistry of C14 in fresh-water systems. Geochimica et Cosmochimica Acta 16(1):1538.Google Scholar
Caraco, N, Bauer, JE, Cole, JJ, Petsch, S, Raymond, P. 2010. Millennial-aged organic carbon subsidies to a modern river food web. Ecology 91(8):2385–93.CrossRefGoogle ScholarPubMed
Crombé, P, Robinson, E, Van Strydonck, M, Boudin, M. 2013. Radiocarbon dating of Mesolithic open-air sites in the Coversand area of the north-west European plain: problems and prospects. Archaeometry 55(3):545–62.Google Scholar
Deevey, ES Jr, Gross, MS, Hutchinson, GE, Kraybill, HL. 1954. The natural C14 contents of materials from hard-water lakes. Proceedings of the National Academy of Sciences of the USA 40(5):285–8.Google Scholar
Fischer, A, Heinemeier, J. 2003. Freshwater reservoir effect in 14C dates of food residue on pottery. Radiocarbon 45(3):449–66.CrossRefGoogle Scholar
Godwin, H. 1951. Comments on radiocarbon dating for samples from the British Isles. American Journal of Science 249(4):301–7.Google Scholar
Hart, JP, Lovis, WA. 2007. The freshwater reservoir and radiocarbon dates on cooking residues: old apparent ages or a single outlier? Comments on Fischer and Heinemeier (2003). Radiocarbon 49(3):1403–10.Google Scholar
Hart, JP, Lovis, WA. 2014. A re-evaluation of the reliability of AMS dates on pottery food residues from the late prehistoric central Plains of North America: comment on Roper (2013). Radiocarbon 56(1):341–53.CrossRefGoogle Scholar
Hart, JP, Lovis, WA, Schulenberg, JK, Urquhart, GR. 2007a. Paleodietary implications from stable carbon isotope analysis of experimental cooking residues. Journal of Archaeological Science 34(5):804–13.CrossRefGoogle Scholar
Hart, JP, Brumbach, HJ, Lusteck, R. 2007b. Extending the phytolith evidence for early maize (Zea mays ssp. mays) and squash (Cucurbita sp.) in central New York. American Antiquity 72(3):563–83.Google Scholar
Hart, JP, Thompson, RG, Brumbach, HJ. 2003. Phytolith evidence for early maize (Zea mays) in the northern Finger Lakes region of New York. American Antiquity 68(4):619–40.Google Scholar
Hart, JP, Urquhart, GR, Feranec, RS, Lovis, WA. 2009. Non-linear relationship between bulk δ13C and percent maize in carbonized cooking residues and the potential of false negatives in detecting maize. Journal of Archaeological Science 36(10):2206–12.Google Scholar
Hart, JP, Lovis, WA, Urquhart, GR, Reber, EA. 2013. Modeling freshwater reservoir offsets on radiocarbon-dated charred cooking residues. American Antiquity 78(3):536–52.Google Scholar
Hastorf, CA, DeNiro, MJ. 1985. Reconstruction of prehistoric plant production and cooking practices by a new isotopic method. Nature 315(6019):489–91.Google Scholar
Hohman-Caine, CA, Syms, EL. 2012. The Age of Brainerd Ceramics. Report prepared for Minnesota Historical Society Contract No. 4107232. Hackensack, Minnesota: Soils Consulting.Google Scholar
Ishikawa, NF, Hyodo, F, Tayasu, I. 2013. Use of carbon-13 and carbon-14 natural abundances for stream food web studies. Ecological Research 28(5):759–69.Google Scholar
Keaveney, EM, Reimer, PJ. 2012. Understanding the variability in freshwater radiocarbon reservoir offsets: a cautionary tale. Journal of Archaeological Science 39(5):1306–16.Google Scholar
Lovis, WA. 1990. Curatorial considerations for systematic research collections: AMS dating of a curated ceramic assemblage. American Antiquity 55(2):382–7.Google Scholar
Lovis, WA, Urquhart, GR, Raviele, ME, Hart, JP. 2011. Hardwood ash nixtamalization may lead to false negatives for the presence of maize by depleting bulk δ13C in carbonized residues. Journal of Archaeological Science 38(10):2726–30.Google Scholar
Messner, TC, Dickau, R, Harbison, J. 2008. Starch grain analysis: methodology and applications in the Northeast. In: Hart, JP, editor. Current Northeast Paleoethnobotany II. New York State Museum Bulletin 512. Albany: University of the State of New York. p 111–28.Google Scholar
Morton, JD, Schwarcz, H. 2004. Palaeodietary implications from stable isotopic analysis of residues on prehistoric Ontario ceramics. Journal of Archaeological Science 31(5):503–17.Google Scholar
Mullins, HT, Patterson, WP, Teece, MA, Burnett, AW. 2011. Holocene climate and environmental change in central New York (USA). Journal of Paleolimnology 45(2):243–56.Google Scholar
Philippsen, B, Heinemeier, J. 2013. Freshwater reservoir effect variability in northern Germany. Radiocarbon 55(2–3):1085–101.Google Scholar
Philippsen, B, Kjeldsen, H, Hartz, S, Paulsen, H, Clausen, I, Heinemeier, J. 2010. The hardwater effect in AMS 14C dating of food crusts on pottery. Nuclear Instruments and Methods in Physics Research B 268(7):995–8.Google Scholar
Raviele, ME. 2010. Assessing carbonized archaeological cooking residues: evaluation of maize phytolith taphonomy and density through experimental residue analysis [PhD dissertation]. East Lansing: Department of Anthropology, Michigan State University.Google Scholar
Reber, EA, Hart, JP. 2008. Pine resins and pottery sealing: analysis of absorbed and visible pottery residues from central New York State. Archaeometry 50(6):9991117.Google Scholar
Rice, PM. 1987. Pottery Analysis: A Sourcebook. Chicago: University of Chicago Press.Google Scholar
Roper, DC. 2013. Evaluating the reliability of AMS dates on food residue on pottery from the late prehistoric Central Plains of North America. Radiocarbon 55(1):151–62.CrossRefGoogle Scholar
Saul, H, Madella, M, Fischer, A, Glykou, A, Hartz, S, Craig, OE. 2013. Phytoliths in pottery reveal the use of spice in European prehistoric cuisine. PLoS ONE 8(8):e70583, doi:10.1371/journal.pone.0070583.Google Scholar
Skibo, JM. 2013. Understanding Pottery Function. New York: Springer.Google Scholar
Stuiver, M, Reimer, PJ. 1993. Extended 14C data base and revised CALIB 3.0 14C age calibration program. Radiocarbon 35(1):215–30.Google Scholar
Ward, GK, Wilson, SR. 1978. Procedures for comparing and combining radiocarbon age determinations: a critique. Archaeometry 20(1):1931.Google Scholar
Zigah, PK, Minor, EC, Werne, JP. 2012. Radiocarbon and stable-isotope geochemistry of organic and inorganic carbon in Lake Superior. Global Biogeochemical Cycles 26(1):GB1023, doi:10.1029/2011GB004132.Google Scholar