par Snoeck, Christophe;Lee-Thorp, Julia;Schulting, Rick;De Jong, Jeroen ;Debouge, Wendy ;Mattielli, Nadine
Référence Rapid communications in mass spectrometry, 29, 1, page (107-114)
Publication Publié, 2015-01-15
Article révisé par les pairs
Résumé : RATIONALEStrontium isotopes (87Sr/86Sr) are used in archaeological and forensic science as markers of residence or mobility because they reflect the local geological substrate. Currently, tooth enamel is considered to be the most reliable tissue, but it rarely survives heating so that in cremations only calcined bone fragments survive. We set out to test the proposition that calcined bone might prove resistant to diagenesis, given its relatively high crystallinity, as the ability to measure in vivo 87Sr/86Sr from calcined bone would greatly extend application to places and periods in which cremation was the dominant mortuary practice, or where unburned bone and enamel do not survive.METHODSTooth enamel and calcined bone samples were exposed to a 87Sr-spiked solution for up to 1 year. Samples were removed after various intervals, and attempts were made to remove the contamination using acetic acid washes and ultrasonication. 87Sr/86Sr was measured before and after pre-treatment on a Nu Plasma multi-collector induced coupled plasma mass spectrometer using NBS987 as a standard.RESULTSThe strontium isotopic ratios of all samples immersed in the spiked solution were strongly modified showing that significant amounts of strontium had been adsorbed or incorporated. After pre-treatment the enamel samples still contained significant amounts of 87Sr-enriched contamination while the calcined bone fragments did not.CONCLUSIONSThe results of the artificial enrichment experiment demonstrate that calcined bone is more resistant to post-mortem exchange than tooth enamel, and that in vivo strontium isotopic ratios are retained in calcined bone. Copyright © 2014 John Wiley & Sons, Ltd.

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