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Obsidian hydration dating by infrared spectroscopy: method and calibration

Low temperature (90–190 °C) hydrothermal experiments have been conducted on seven obsidians where composition of the glass varies significantly in the concentration of structural water within the unhydrated bulk material. Infrared transmission spectroscopy was used to track the diffusion of molecula...

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Bibliographic Details
Published in:Journal of archaeological science 2011-07, Vol.38 (7), p.1716-1726
Main Authors: Stevenson, Christopher M., Novak, Steven W.
Format: Article
Language:English
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Summary:Low temperature (90–190 °C) hydrothermal experiments have been conducted on seven obsidians where composition of the glass varies significantly in the concentration of structural water within the unhydrated bulk material. Infrared transmission spectroscopy was used to track the diffusion of molecular water into the glass surface as a function of time and temperature. Long-term (60–360 days) hydration sequences at 90 °C show a t 0.6 time dependence for the mass uptake of molecular water that forms the hydration layer. The structural water concentration of the unhydrated bulk obsidian is highly correlated with the pre-exponential and activation energy and may be used to estimate the Arrhenius constants. In addition, secondary ion mass spectrometry (SIMS) hydrogen profiling of Napa Glass Mountain obsidian hydrated at 90 °C reveals that the early stages of diffusion exhibit a dynamic behavior that includes a fluctuating hydrogen concentration and a changing diffusion coefficient that slows with time. ► Water diffusion in obsidian at 90 °C shows a t 0.6 dependence. ► In the early stages of low temperature (90 °C) hydration the concentration of hydrogen in the hydration layer varies with time before approaching a maximum value. ► The Arrhenius constants (pre-exponential, activation energy) may be estimated from the obsidian total structural water content.
ISSN:0305-4403
1095-9238
DOI:10.1016/j.jas.2011.03.003