Shortwave infrared hyperspectral imaging as a novel method to elucidate multi-phase dolomitization, recrystallization, and cementation in carbonate sedimentary rocks

McCormick, Cole A.; Corlett, Hilary; Stacey, Jack; Hollis, Cathy; Feng, Jiang; Rivard, Benoît; Omma, Jenny

doi:10.1038/s41598-021-01118-4

Cited by 17 publications

(26 citation statements)

References 58 publications

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“…It is not until later phases of dolomitisation, along N-S faults, that these more characteristic textures are observed and there is a change from replacement of wall rock to cementation of fractures. In this case, a backstepping of the reaction front is less evident that in other studies (McCormick et al, 2021;Stacey et al, 2021), but instead high pressure fluids were focussed along narrow fault splays that appear to derive from the main NW-SE trending crustal lineament. However, the process is somewhat similar; fluid pressures built because matrix permeability had been reduced, forcing fluids to rupture the rock at high pressure, forming saddle dolomite cemented breccias and zebra textures.…”

Section: Discussionmentioning

confidence: 60%

“…It has become clear that there is unlikely to be a common model for all fault‐controlled hydrothermal dolomite bodies, but that fault‐plane convection of sea‐water, fluid convection along basal aquifers and fluid mixing are all likely to be important controls on the localisation of dolomite bodies (Benjakul et al, 2020; Hollis et al, 2017; Koeshiydayatullah et al, 2020; Stacey et al, 2020, 2021). It has also become evident that in many bodies, progressive occlusion of porosity results in the back‐stepping of reaction fronts in time so that fluid flux is constrained to fault planes, where fluid pressures can build (Koeshiydayatullah et al, 2021; McCormick et al, 2021; Stacey et al, 2021). This can lead to the formation of the most characteristic features of HTD; saddle dolomite cemented breccias and zebra dolomite textures.…”

Section: Wider Context and Implicationsmentioning

confidence: 99%

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Mechanisms controlling the localisation of fault‐controlled hydrothermal dolomitisation, Derbyshire Platform, UK

Breislin

Banks

Crowley

et al. 2022

The Depositional Record

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The Derbyshire Platform is a Mississippian aged flat-topped, steep sided platform that forms the westernmost expression of the Derbyshire-East Midlands Platform. On the south-east platform margin, 60 km 2 of Visean limestone has been dolomitised, forming two distinct bodies. One of these bodies forms along a major NW-SE trending basement fault and smaller, associated, N-S trending faults and fractures. This study uses outcrop, petrographic and geochemical analysis to better constrain the timing and mechanism for this fault-controlled dolomitisation. Field relationships demonstrate dolomitisation was multi-phase and initiated after the main phase of matrix pore-occluding calcite cementation on the Derbyshire Platform and terminated prior to the main phase of mineralisation. Fluids are interpreted to have fluxed from adjacent basins, primarily along strike-slip crustal faults that were reactivated during basin inversion at the onset of the Variscan Orogeny. Fluid supply was episodic and progressively confined to fractures as matrix porosity became occluded. The study demonstrates the complex interplay between basin kinematics, host rock permeability and timing of fluid supply through seismic valving along faults that connect the carbonate platform to basin compartments. This ultimately controlled the position of dolomite geobodies along faults and provides a record of fluid flow during the transition from thermal subsidence to post-rift basin inversion. The findings have implications for the exploration of both minerals and hydrocarbon within dolomitised host rocks and can inform studies of fluid transfer and reaction on carbonate platforms within the burial realm.

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Section: Discussionmentioning

confidence: 60%

Section: Wider Context and Implicationsmentioning

confidence: 99%

Mechanisms controlling the localisation of fault‐controlled hydrothermal dolomitisation, Derbyshire Platform, UK

Breislin

Banks

Crowley

et al. 2022

The Depositional Record

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“…Such recrystallization occludes porosity and results in the core of the HTD body being younger than its margins. This phenomenon can be recognized by the spatial distribution of each paragenetic stage in the strata (McCormick et al, 2021), alongside a systematic increase in the dolomitization temperature and δ 18 O fluid values towards the core of the HTD body (Koeshidayatullah et al, 2020). Recrystallization coincides with the shift from zoned, planar‐e dolomite (distal to the fluid source) to unzoned, planar‐s to nonplanar dolomite (proximal to the fluid source).…”

Section: Geological Settingmentioning

confidence: 99%

“…Recrystallization coincides with the shift from zoned, planar‐e dolomite (distal to the fluid source) to unzoned, planar‐s to nonplanar dolomite (proximal to the fluid source). Such relationships have been established at the outcrop scale (Koeshidayatullah et al, 2020; Koeshidayatullah et al, 2021; McCormick et al, 2021; Stacey et al, 2021), but whether they hold true at the basin scale is equivocal. Likewise, the relationship between these dolomitization patterns and the formation of zebra textures, boxwork textures and dolomite breccias has not been investigated.…”

Section: Geological Settingmentioning

confidence: 99%

“…Evidence in support of recrystallization includes (i) the increased crystal size from RD1 to RD2 and (ii) the shift from oscillatory‐zoned, planar‐e dolomite to an unzoned mosaic of planar‐s dolomite (Koeshidayatullah et al, 2020; Stacey et al, 2021). There is a spatial relationship between presence of RD2 and SD within the HTD bodies, which strongly suggests that the fluid flow event(s) that formed SD1 also gave rise to recrystallization of pre‐existing dolomite in the strata (McCormick et al, 2021).…”

Section: Interpretationsmentioning

confidence: 99%

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Basin scale evolution of zebra textures in fault‐controlled, hydrothermal dolomite bodies: Insights from the Western Canadian Sedimentary Basin

et al. 2023

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Structurally controlled dolomitization typically involves the interaction of high‐pressure (P), high‐temperature (T) fluids with the surrounding host rock. Such reactions are often accompanied by cementation and recrystallization, with the resulting hydrothermal dolomite (HTD) bodies including several ‘diagnostic’ rock textures. Zebra textures, associated with boxwork textures and dolomite breccias, are widely considered to reflect these elevated P/T conditions. Although a range of conceptual models have been proposed to explain the genesis of these rock textures, the processes that control their spatial and temporal evolution are still poorly understood. Through the detailed petrographical and geochemical analysis of HTD bodies, hosted in the Middle Cambrian strata in the Western Canadian Sedimentary Basin, this study demonstrates that a single genetic model cannot be applied to all the characteristics of these rock textures. Instead, a wide array of sedimentological, tectonic and metasomatic processes contribute to their formation; each of which is spatially and temporally variable at the basin scale. Distal to the fluid source, dolomitization is largely stratabound, comprising replacement dolomite, bedding‐parallel zebra textures and rare dolomite breccias (non‐stratabound, located only proximal to faults). Dolomitization is increasingly non‐stratabound with proximity to the fluid source, comprising bedding‐inclined zebra textures, boxwork textures and dolomite breccias that have been affected by recrystallization. Petrographical and geochemical evidence suggests that these rock textures were initiated due to dilatational fracturing, brecciation and precipitation of saddle dolomite as a cement, but significant recrystallization occurred during the later stages of dolomitization. These rock textures are closely associated with faults and carbonate‐hosted ore deposits (e.g. magnesite, rare earth element and Mississippi Valley–type mineralization), thus providing invaluable information regarding fluid flux and carbonate metasomatism under elevated P/T conditions.

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Hyperspectral analysis (VNIR-SWIR) applied to the characterization of a dolomitization context: a case study in Rio Bonito Quarry, Brazil

Camargo

Ferreira

Pinto-Coelho

et al. 2023

Carbonates Evaporites

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Shortwave infrared hyperspectral imaging as a novel method to elucidate multi-phase dolomitization, recrystallization, and cementation in carbonate sedimentary rocks

Cited by 17 publications

References 58 publications

Mechanisms controlling the localisation of fault‐controlled hydrothermal dolomitisation, Derbyshire Platform, UK

Mechanisms controlling the localisation of fault‐controlled hydrothermal dolomitisation, Derbyshire Platform, UK

Basin scale evolution of zebra textures in fault‐controlled, hydrothermal dolomite bodies: Insights from the Western Canadian Sedimentary Basin

Hyperspectral analysis (VNIR-SWIR) applied to the characterization of a dolomitization context: a case study in Rio Bonito Quarry, Brazil

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