2021
DOI: 10.2110/jsr.2020.77
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Repeated degradation and progradation of a submarine slope over geological timescales

Abstract: Submarine slopes prograde via accretion of sediment to clinoform foresets and degrade in response to channel or canyon incision or to mass-wasting processes. The timescales over which progradation and degradation occur, and the large-scale stratigraphic record of these processes, remain unclear due to poor age constraints in subsurface-based studies and areally limited exposures of exhumed systems. We here integrate 3D seismic reflection and borehole data to study the geometry and origin of ancient slope canyo… Show more

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Cited by 10 publications
(6 citation statements)
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References 80 publications
(74 reference statements)
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“…We have interpreted these valley‐like erosion features as submarine canyons based on the geomorphology, their relationship to other seismic facies and the regional context. The seismic expression of SF4 correlates well with submarine canyon described on the Måløy Slope, northward of the Lomre and Uer Terraces (Jackson et al., 2008, 2019; Sømme et al., 2013). The dendritic plan‐view expression to the E is interpreted as relating to the canyon heads in SF4, hence the terminology of ‘proximal’ submarine canyon.…”
Section: Well‐calibrated Seismic Faciessupporting
confidence: 56%
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“…We have interpreted these valley‐like erosion features as submarine canyons based on the geomorphology, their relationship to other seismic facies and the regional context. The seismic expression of SF4 correlates well with submarine canyon described on the Måløy Slope, northward of the Lomre and Uer Terraces (Jackson et al., 2008, 2019; Sømme et al., 2013). The dendritic plan‐view expression to the E is interpreted as relating to the canyon heads in SF4, hence the terminology of ‘proximal’ submarine canyon.…”
Section: Well‐calibrated Seismic Faciessupporting
confidence: 56%
“…The northern Horda Platform shows first signs of rotation and drainage reversal on the large 6‐ to 15‐km‐wide, E‐dipping fault blocks during SU4 time, with dip‐slope fans overlying the late Oxfordian prograding sequences (Dreyer et al., 2005; Whipp et al., 2014). Canyons 1, 2 and 3 are part of a regional unconformity complex with canyon features extending for more than 150 km along the basin margin to the N, which has been inferred to be caused by basinward tilting of the rift margin due to increased subsidence in the rift axis areas (Jackson et al., 2008, 2019; Koch et al., 2017; Sømme & Jackson, 2013; Sømme et al., 2013), which is likely amplified by high seasonal runoff rates during the humid Kimmeridgian climate (Armstrong et al., 2016). The following subsections will summarize generic observations from the Late Jurassic submarine gravity flow deposits on the Lomre and Uer terraces, with focus on sediment routing and depositional architecture throughout the rift phase.…”
Section: Synthesis Of Tectono‐sedimentary Evolutionmentioning
confidence: 99%
“…The upper sequence boundary (Base Statfjord Gp) marks a turnaround from fining-upwards into coarseningupwards in well-logs (Nystuen et al, 2014) (Figure 5), although it is not particularly pronounced in seismic, and therefore constrained by careful seismic-well-tie. A truncation of the surface in the Smeaheia Fault Block (Figure 8) may be related to a significant unconformity in the greater North Sea, resulting from Middle Jurassic to Early Cretaceous erosion (Goldsmith et al, 2003;Jackson et al, 2008Jackson et al, , 2021Sømme & Jackson, 2013). The Triassic succession is conformably overlain by Lower Jurassic marine mudstone and shale.…”
Section: Upper and Lower Boundariesmentioning
confidence: 99%
“…The thickening direction of multiple fill-and-spill cycles to the NE, together with the persistent migration of the submarine channels and lobes in the same direction, orientated transverse to the stepped slope profile, supports syn-sedimentary lateral tilting. This contrasts with basinward tilting where submarine conduits tend to have fixed positions (e.g., Jackson et al, 2021). Without invoking a lateral tilt, the documented thickening direction and stacking pattern would need to be explained by the turbidite system initiating on the higher part of the steps (SW) and working their way progressively to lower elevations to the NE.…”
Section: Stratigraphic Frameworkmentioning
confidence: 98%
“…In cases where fill-and-spill cycles are vertically stacked, the stratigraphic cyclicity is attributed to the interaction of sediment input and vertical accommodation rejuvenation created by dynamic seafloor deformation induced by fixed structural elements (e.g., Booth et al, 2003;Brooks et al, 2018;Hay, 2012;Spychala et al, 2015). However, accommodation patterns can be spatially variable during the lifespan of a turbidite system, for instance due to basinward tilting (Jackson et al, 2021), lateral tilting (Kane et al, 2010(Kane et al, , 2012 and the emplacement of masstransport complexes (Wu et al, 2020). These factors drive spatially variable topographic configurations and hinder vertical stacking across sediment supply cycles, suggesting that alternative stratigraphic models to the traditional fill-and-spill model need to be developed.…”
Section: Introductionmentioning
confidence: 99%