Evaluating new fault‐controlled hydrothermal dolomitisation models: insights from the Cambrian Dolomite, Western Canadian Sedimentary Basin

Koeshidayatullah, A., Corlett, H., Stacey, J., Swart, P. K., Boyce, A. , Robertson, H., Whitaker, F. and Hollis, C. (2020) Evaluating new fault‐controlled hydrothermal dolomitisation models: insights from the Cambrian Dolomite, Western Canadian Sedimentary Basin. Sedimentology, 67(6), pp. 2945-2973. (doi: 10.1111/sed.12729)

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Abstract

Fault‐controlled hydrothermal dolomitisation in tectonically complex basins can occur at any depth and from different fluid compositions, including ‘deep‐seated’, ‘crustal’ or ‘basinal’ brines. Nevertheless, many studies have failed to identify the actual source of these fluids, resulting in a gap in our knowledge on the likely source of magnesium of hydrothermal dolomitisation. With development of new concepts in hydrothermal dolomitisation, the study aims in particular to test the hypothesis that dolomitising fluids were sourced from either seawater, ultramafic carbonation or a mixture between the two by utilising the Cambrian Mount Whyte Formation as an example. Here, the large‐scale dolostone bodies are fabric‐destructive with a range of crystal fabrics, including euhedral replacement (RD1) and anhedral replacement (RD2). Since dolomite is cross‐cut by low amplitude stylolites, dolomitisation is interpreted to have occurred shortly after deposition, at a very shallow depth (<1 km). At this time, there would have been sufficient porosity in the mudstones for extensive dolomitisation to occur, and the necessary high heat flows and faulting associated with Cambrian rifting to transfer hot brines into the near surface. While the δ18Owater and 87Sr/86Sr ratios values of RD1 are comparable with Cambrian seawater, RD2 shows higher values in both parameters. Therefore, although aspects of the fluid geochemistry are consistent with dolomitisation from seawater, very high fluid temperature and salinity could be suggestive of mixing with another, hydrothermal fluid. The very hot temperature, positive Eu anomaly, enriched metal concentrations, and cogenetic relation with quartz could indicate that hot brines were at least partially sourced from ultramafic rocks, potentially as a result of interaction between the underlying Proterozoic serpentinites and CO2‐rich fluids. This study highlights that large‐scale hydrothermal dolostone bodies can form at shallow burial depths via mixing during fluid pulses, providing a potential explanation for the mass balance problem often associated with their genesis.

Item Type:Articles
Status:Published
Refereed:Yes
Glasgow Author(s) Enlighten ID:Boyce, Professor Adrian
Authors: Koeshidayatullah, A., Corlett, H., Stacey, J., Swart, P. K., Boyce, A., Robertson, H., Whitaker, F., and Hollis, C.
College/School:College of Science and Engineering > Scottish Universities Environmental Research Centre
Journal Name:Sedimentology
Publisher:Wiley
ISSN:0037-0746
ISSN (Online):1365-3091
Published Online:11 March 2020
Copyright Holders:Copyright © 2020 The Authors
First Published:First published in Sedimentology 67(6): 2945-2973
Publisher Policy:Reproduced under a Creative Commons License

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