The radiocarbon dating and authentication of iron artifacts.

The continuing improvements in accelerator mass spectrometry (AMS) dating technology mean that it is possible to work on ever smaller samples, which in turn, make an ever wider range of sample potentially available for dating. This paper discusses some of the difficulties arising with the interpreta...

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Bibliographic Details
Main Authors: Craddock, P T, Wayman, M L, Jull, A J T
Format: Article in Journal/Newspaper
Language:English
Published: Radiocarbon 2002
Subjects:
iron;Churchdown England;Frobisher Bay;Gloucestershire England;Kodlunarn Island;steel;artifacts;accelerator mass spectra;Atlantic Ocean;North Atlantic;England;mass spectra;spectra;archaeology;Great Britain;United Kingdom;Holocene;metals;Europe;Western Europe;Cenozoic;Quaternary;methods;C 14;carbon;isotopes;radioactive isotopes;absolute age
Frobisher Bay
Kodlunarn Island
North Atlantic
Online Access:https://journals.uair.arizona.edu/index.php/radiocarbon/article/view/4071
Description
Summary:The continuing improvements in accelerator mass spectrometry (AMS) dating technology mean that it is possible to work on ever smaller samples, which in turn, make an ever wider range of sample potentially available for dating. This paper discusses some of the difficulties arising with the interpretation of AMS dates obtained from carbon in iron. The overriding problem is that the carbon, now in chemical combination with the iron, could have come from a variety of sources with very different origins. These are now potentially an irresolvable mixture in the iron. For iron made over the last millennium, there are the additional problems associated with the use of both fossil fuel and biomass fuel in different stages of the iron making, leading to great confusion, especially with authenticity studies.

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