Sedimentary processes, provenance, and tectonic control on fluvial sandstone geochemistry during Superior craton stabilization

Haugaard, Rasmus; White, Shawna E.; Jørgensen, Taus R. C.; Frieman, Ben M.; Meek, Dean; Zhou, Xiwen; Mathieu, Lucie; Ayer, J. A.

doi:10.1130/2022.1220(02)

Cited by 5 publications

(2 citation statements)

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“…Whereas many Archean clastic sedimentary basins contain a large amount of graphitic mudstone which, in parts, tend to yield more conductive responses in the MT (e.g., Haugaard et al., 2021a), the basin in this study is primarily dominated by fluvial‐dominated quartz‐rich sandstones and conglomerates with little mudstone lithofacies (Haugaard et al., 2021b). This observation might explain the high resistive nature of this basin.…”

Section: Data Processing Analysismentioning

confidence: 88%

“…Two main clastic sedimentary basins, referred to as the Porcupine type (2690−2685 Ma) and the Timiskaming type (2680−2670 Ma), postdate the volcanic episodes. The latter dominates the central part of the Swayze East and comprises thick successions of conglomerates and sandstones (Haugaard et al., 2021b; MacDonald et al., 2017). The conglomerates consist of poorly sorted, randomly distributed clasts ranging from boulders to cobbles, pebbles, granules and medium‐ to coarse‐grained sand.…”

Section: Geological Settingmentioning

confidence: 99%

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Reflection seismic imaging across a greenstone belt, Abitibi (Ontario), Canada

Cheraghi

Hlousek

Buske

et al. 2022

Geophysical Prospecting

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Established 2D seismic data processing methods such as Kirchhoff pre‐stack time migration and Kirchhoff pre‐stack depth migration function relatively well for regular acquisition geometries and well‐constrained velocity models. Recently developed focusing pre‐stack depth migration methods have the potential to enhance image quality in the case of sparse and non‐regular source–receiver distribution. We have tested the performance of the coherency migration method as one of these focusing migration approaches in comparison to standard dip‐moveout and Kirchhoff pre‐stack time migration techniques by applying them to the Swayze East seismic profile acquired in the Abitibi greenstone belt of Canada. This seismic profile represents a crooked‐line survey that intersects several metal‐bearing deformation zones, providing good target geometries to examine various pre‐stack migration methods. Analysis of the seismic data indicates reflectivity associated with shallowly dipping reflections appears relatively well preserved over the entire 0–6 km offset range for the frequency range between 20 to 90 Hz. Although most reflections are visible already in either the dip‐moveout or the Kirchhoff pre‐stack time migration results, the coherency migration method delivers the most improved image showing all reflective structures inferred for this area. The comparisons suggest the coherency migration method can be considered as superior in terms of resulting seismic image quality compared with conventional approaches for this type of crooked‐line seismic survey in such a complex geological setting.

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Section: Data Processing Analysismentioning

confidence: 88%

Section: Geological Settingmentioning

confidence: 99%