An overview of the Upper Palaeozoic–Mesozoic stratigraphy of the NE Atlantic region

Stoker, Martyn S.; Stewart, Margaret; Shannon, Patrick M.; Bjerager, Morten; Nielsen, Tove; Blischke, Anett; Hjelstuen, Berit Oline; Gaina, Carmen; McDermott, Ken; Ólavsdóttir, Jana

doi:10.1144/sp447.2

Cited by 51 publications

(60 citation statements)

References 154 publications

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“…Devonian -Paleocene multiple rifting events led to the formation of a wide extended area of successive basins and highs confined within the Greenland and Western European Caledonian deformation zone (Fig. 5a) (see also Stoker et al 2016). Four main rifting periods can be identified from sedimentary basins along the NE Atlantic margin: (1) Devonian-Carboniferous; (2) PermianTriassic; (3) Jurassic -Early Cretaceous; and (4) Late Cretaceous -Paleocene (Fig.…”

Section: Break-up and Early Seafloor Spreadingmentioning

confidence: 96%

“…Saunders et al 2007), continental break-up occurred between Greenland and Eurasia before C24 time (c. 55 Ma). To show the pre-break-up configuration of the western Eurasian margin and its conjugate margin, we reconstruct the structural elements (major tectonic boundaries, faults and structural highs: Stoker et al 2016) and simplified inferred sedimentary basin ages at Paleocene -Eocene transition time (Fig. 5a).…”

Section: Break-up and Early Seafloor Spreadingmentioning

confidence: 99%

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Break-up and seafloor spreading domains in the NE Atlantic

Gaina

Nasuti

Kimbell

et al. 2017

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An updated magnetic anomaly grid of the NE Atlantic and an improved database of magnetic anomaly and fracture zone identifications allow the kinematic history of this region to be revisited. At break-up time, continental rupture occurred parallel to the Mesozoic rift axes in the south, but obliquely to the previous rifting trend in the north, probably due to the proximity of the Iceland plume at 57-54 Ma.The new oceanic lithosphere age grid is based on 30 isochrons (C) from C24n old (53.93 Ma) to C1n old (0.78 Ma), and documents ridge reorganizations in the SE Lofoten Basin, the Jan Mayen Fracture Zone region, in Iceland and offshore Faroe Islands. Updated continent -ocean boundaries, including the Jan Mayen microcontinent, and detailed kinematics of the EocenePresent Greenland-Eurasia relative motions are included in this model.Variations in the subduction regime in the NE Pacific could have caused the sudden northwards motion of Greenland and subsequent Eurekan deformation. These events caused seafloor spreading changes in the neighbouring Labrador Sea and a decrease in spreading rates in the NE Atlantic. Boundaries between major oceanic crustal domains were formed when the European Plate changed its absolute motion direction, probably caused by successive adjustments along its southern boundary.

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Section: Break-up and Early Seafloor Spreadingmentioning

confidence: 96%

Section: Break-up and Early Seafloor Spreadingmentioning

confidence: 99%

Break-up and seafloor spreading domains in the NE Atlantic

Gaina

Nasuti

Kimbell

et al. 2017

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“…However, maximum relief in a region is mainly a function of the large-scale tectonic setting. The study area was adjacent to the nonvolcanic rift between Norway and Greenland in the latest Permian and Early Triassic (e.g., Ziegler, 1992;Stoker et al, 2016). In the present, areas close to nonvolcanic rifts such as the Red Sea rift, or the nonvolcanic parts of the East African rift, show a maximum topography close to 3 km due to dynamic rift shoulder uplift (Wernicke, 1985;Daradich et al, 2003).…”

Section: R: Reliefmentioning

confidence: 91%

“…3C; Mørk et al, 1982;Wignall et al, 1998). This was coincident with rifting of the western Norwegian-eastern Greenland margins in the latest Permian and earliest Triassic (Ziegler, 1992;Müller et al, 2005;Faleide et al, 2008;Stoker et al, 2016), and it may possibly be explained by dynamic rift-shoulder uplift (cf. Wernicke, 1985;ten Brink and Stern, 1992;Daradich et al, 2003), which may have led to increased topography, and thus increased erosion rates and sediment supply, and therefore progradation of sedimentary systems.…”

Section: Geological Backgroundmentioning

confidence: 92%

Linking an Early Triassic delta to antecedent topography: Source-to-sink study of the southwestern Barents Sea margin

et al. 2017

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Present-day catchments adjacent to sedimentary basins may preserve geomorphic elements that have been active through long intervals of time. Relicts of ancient catchments in present-day landscapes may be investigated using mass-balance models and can give important information about upland landscape evolution and reservoir distribution in adjacent basins. However, such methods are in their infancy and are often difficult to apply in deep-time settings due to later landscape modification.The southern Barents Sea margin of N Norway and NW Russia is ideal for investigating source-to-sink models, because it has been subject to minor tectonic activity since the Carboniferous, and large parts have eluded significant Quaternary glacial erosion. A zone close to the present-day coast has likely acted as the boundary between basin and catchments since the Carboniferous. Around the Permian-Triassic transition, a large delta system started to prograde from the same area as the present-day largest river in the area, the Tana River, which has long been interpreted to show features indicating that it was developed prior to present-day topography. We performed a source-to-sink study of this ancient system in order to investigate potential linkages between present-day geomorphology and ancient deposits.We investigated the sediment load of the ancient delta using well, core, twodimensional and three-dimensional seismic data, and digital elevation models to investigate the geomorphology of the onshore catchment and surrounding areas. Our results imply that the present-day GSA Bulletin; January/February 2018; v. 130 Tana catchment was formed close to the Permian-Triassic transition, and that the Triassic delta system has much better reservoir properties compared to the rest of Triassic basin infill. This implies that landscapes may indeed preserve catchment geometries for extended periods of time, and it demonstrates that source-to-sink techniques can be instrumental in predicting the extent and quality of subsurface reservoirs.

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“…A major overview of the Late Palaeozoic-Mesozoic stratigraphy of the NE Atlantic region is presented by Stoker et al (2016), who describe the distribution, structural setting, stratigraphy, depositional environment and correlation of these rocks across the conjugate margins and along the axis of the proto-NE Atlantic rift system. The establishment of a regional stratigraphic framework, based on a strong observational record, has provided important new constraints on the timing and nature of sedimentary basin development in the NE Atlantic by challenging the 'classic' view of palinspastic reconstruction in the central part of the proto-NE Atlantic rift system, with implications for the break-up of the Pangaean supercontinent.…”

Section: Stratigraphymentioning

confidence: 99%