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Archaeologic Sherd Dating: Comparison of Thermoluminescence Dates with Radiocarbon Dates by Beta Counting and Accelerator Techniques

Published online by Cambridge University Press:  18 July 2016

R A Johnson ,
J J Stipp ,
M A Tamers ,
Georges Bonani ,
Martin Suter  and
Willy Wölfli
R A Johnson
Affiliation:
University of Miami, Miami, Florida
J J Stipp
Affiliation:
University of Miami, Miami, Florida
M A Tamers
Affiliation:
University of Miami, Miami, Florida
Georges Bonani
Affiliation:
Eidgenossische Technische Hochschule, Zurich, Switzerland
Martin Suter
Affiliation:
Eidgenossische Technische Hochschule, Zurich, Switzerland
Willy Wölfli
Affiliation:
Eidgenossische Technische Hochschule, Zurich, Switzerland
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Abstract

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Sherds can be dated by four independent methods: 14C beta counting on associated material, accelerator mass spectrometry on carbon traces on and within the sherd, thermoluminescence studies on minerals within the sherd, and stylistic form. Age analyses of materials and sherds from several sites are shown in this work. Each technique has its own frequently encountered non-laboratory sources of error. A combination of at least two independent techniques is indispensable for the highest level of confidence.

Type
VII. Applications in Archaeology
Information
Radiocarbon , Volume 28 , Issue 2A , 1986 , pp. 719 - 725
Copyright
Copyright © The American Journal of Science 

References

Aitken, M J, Zimmerman, D W and Fleming, S J, 1968, Thermoluminescencent dating of ancient pottery: Nature, v 219, p 442443.Google Scholar
Bill, J, Keller, W A, Erne, R, Bonani, G and Wölfli, W, 1984, C 14 dating of small archaeologic samples: Neolithic to Iron age in the Central Alpine region: Nuclear Instruments & Methods, v 233 (B5), no. 2, p 317320.Google Scholar
Bonani, G, Balzer, R, Hofmann, H J, Morenzoni, E, Nessi, M, Suter, M and Wölfli, W, 1984, Properties of milligram size samples prepared for AMS C-14 dating at ETH: Nuclear Instruments & Methods, v 233 (B5), no. 2, p 284288.Google Scholar
Carr, R and Beriault, J S, 1984, Prehistoric man in south Florida, in Gleason, P, ed, Environments of south Florida present and past, no. 2: Miami Geol Soc, p 114.Google Scholar
De Atley, S, 1980, Radiocarbon dating of ceramic materials: progress and prospects, in Stuiver, M and Kra, RS, eds, Internatl 14C conf, 10th, Proc: Radiocarbon, v 22, no. 3, p 987996.CrossRefGoogle Scholar
Delibrias, G and Evin, J, 1979, La datation par le radiocarbone des sites de Tintan et Chami, Mauritanie: Centre recherche anthropol prehist ethnog Mem, v 28, p 140150.Google Scholar
Druffle, E M and Linick, T W, 1978, Radiocarbon in annual coral rings of Florida: Geophysical Research Letters, v 5, p 913916.CrossRefGoogle Scholar
Doran, G, 1984, Proton induced X-ray emission analysis of prehistoric Florida ceramics: Florida Anthropologist, v 37, no. 3, p 115119.Google Scholar
Evin, J, 1983, Materials of terrestrial origin used for radiocarbon dating, in Symposium on C-14 and archaeology, Groningen, Netherlands, Aug 1981: PACT, v 8—IV. 1, p 235275.Google Scholar
Fleming, S, 1979, Thermoluminescence techniques in archaeology: Oxford, Clarendon Press.Google Scholar
Goggin, J M, 1950, Stratigraphic test in the Everglades National Park: Am Antiquity, v 15, no. 3, p 228246.Google Scholar
Griffin, J W, 1984, Excavations at the Granada Site, vol 1: Archaeology and history of Granada: Tallahassee, Florida Dept of State.Google Scholar
Klein, J, Lerman, J C, Damon, P E and Ralph, E K, 1982, Calibration of radiocarbon dates: tables based on the consensus data of the Workshop on Calibration of the Radiocarbon Time Scale: Radiocarbon, v 24, p 103150.Google Scholar
Polach, H A and Stipp, J J, 1967, Improved synthesis techniques for methane and benzene radiocarbon dating: Jour Applied Radiation Isotopes, v 18, p 359364.Google Scholar
Stuiver, M and Polach, H A, 1977, Discussion: Reporting of 14C data: Radiocarbon, v 19 p 355363.Google Scholar
Suter, M R, Balzer, R, Bonani, G, Hofmann, H, Morenzoni, E, Nessi, M, Wolfli, W, Andrée, M, Beer, J and Oeschger, H, 1984, Precision measurements of C-14 in AMS—some results and prospects: Nuclear Instruments & Methods, v 233 (B5), no. 2, p 117122.Google Scholar
Tamers, M A, 1975, Chemical yield optimization of the benzene synthesis for radiocarbon dating: Jour Applied Radiation Isotopes, v 26, p 676682.Google Scholar
Tauber, H, 1970, Radiocarbon dating of potsherds from Tell Shimshara, in Mortensen, P, ed, Tell Shimshara: Copenhagen.Google Scholar
Taylor, R E and Berger, R, 1968, Radiocarbon dating of the organic portion of ceramic and wattle-and-daub house construction materials of low carbon content: Am Antiquity, v 33, p 363366.Google Scholar
Zimmerman, D W, 1971, Thermoluminescent dating using fine grains from pottery: Archaeometry, v 13, p 29.Google Scholar