Nash, D. J., Ciborowski, J. T. R., Darvill, T., Pearson, M. P., Ullyott, J. S., Damaschke, M., Evans, J. A., Goderis, S., Greaney, S., Huggett, J. M., Ixer, R. A., Pirrie, D., Power, M. R., Salge, T. and Wilkinson, N., 2021. Petrological and geochemical characterisation of the sarsen stones at Stonehenge. PLoS ONE, 16 (8), e0254760.
Full text available as:
|
PDF (OPEN ACCESS ARTICLE)
Petrological and geochemical characterisation of the sarsen stones at Stonehenge.pdf - Published Version Available under License Creative Commons Attribution. 10MB | |
Copyright to original material in this document is with the original owner(s). Access to this content through BURO is granted on condition that you use it only for research, scholarly or other non-commercial purposes. If you wish to use it for any other purposes, you must contact BU via BURO@bournemouth.ac.uk. Any third party copyright material in this document remains the property of its respective owner(s). BU grants no licence for further use of that third party material. |
DOI: 10.1371/journal.pone.0254760
Abstract
Little is known of the properties of the sarsen stones (or silcretes) that comprise the main architecture of Stonehenge. The only studies of rock struck from the monument date from the 19th century, while 20th century investigations have focussed on excavated debris without demonstrating a link to specific megaliths. Here, we present the first comprehensive analysis of sarsen samples taken directly from a Stonehenge megalith (Stone 58, in the centrally placed trilithon horseshoe). We apply state-of-the-art petrographic, mineralogical and geochemical techniques to two cores drilled from the stone during conservation work in 1958. Petrographic analyses demonstrate that Stone 58 is a highly indurated, grain-supported, structureless and texturally mature groundwater silcrete, comprising fine-to-medium grained quartz sand cemented by optically-continuous syntaxial quartz overgrowths. In addition to detrital quartz, trace quantities of silica-rich rock fragments, Fe-oxides/hydroxides and other minerals are present. Cathodoluminescence analyses show that the quartz cement developed as an initial <10 μm thick zone of non-luminescing quartz followed by ~16 separate quartz cement growth zones. Late-stage Fe-oxides/hydroxides and Ti-oxides line and/or infill some pores. Automated mineralogical analyses indicate that the sarsen preserves 7.2 to 9.2 area % porosity as a moderately-connected intergranular network. Geochemical data show that the sarsen is chemically pure, comprising 99.7 wt. % SiO2. The major and trace element chemistry is highly consistent within the stone, with the only magnitude variations being observed in Fe content. Non-quartz accessory minerals within the silcrete host sediments impart a trace element signature distinct from standard sedimentary and other crustal materials. 143Nd/144Nd isotope analyses suggest that these host sediments were likely derived from eroded Mesozoic rocks, and that these Mesozoic rocks incorporated much older Mesoproterozoic material. The chemistry of Stone 58 has been identified recently as representative of 50 of the 52 remaining sarsens at Stonehenge. These results are therefore representative of the main stone type used to build what is arguably the most important Late Neolithic monument in Europe.
Item Type: | Article |
---|---|
ISSN: | 1932-6203 |
Uncontrolled Keywords: | Automation; Calibration; England; Geologic Sediments; Hyperspectral Imaging; Image Processing, Computer-Assisted; Isotopes; Minerals; Optical Imaging; Spectrometry, X-Ray Emission; Spectrophotometry, Atomic; Tomography, X-Ray Computed; Trace Elements |
Group: | Faculty of Science & Technology |
ID Code: | 38075 |
Deposited By: | Symplectic RT2 |
Deposited On: | 03 Feb 2023 12:59 |
Last Modified: | 03 Feb 2023 12:59 |
Downloads
Downloads per month over past year
Repository Staff Only - |