Quantitative analysis of a footwall-scarp degradation complex and syn-rift stratigraphic architecture, Exmouth Plateau, NW Shelf, offshore Australia

Barrett, Bonita J.; Hodgson, David M.; Jackson, Christopher; Lloyd, Christopher; Casagrande, Junia; Collier, Richard

doi:10.31223/osf.io/h9bf3

Cited by 4 publications

(38 citation statements)

References 78 publications

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“…Previous studies have addressed the effect of early‐stage relay ramps in syn‐rift settings on subaqueous sediment gravity flows (Anderson et al, 2000; Athmer & Luthi, 2011; Barrett et al, 2020; Bruhn & Vagel, 2005; Fugelli & Olsen, 2007; Ge et al, 2018; Soreghan et al, 1999). Early‐stage relay ramps are observed to direct sediment down the ramp most effectively when there were pre‐existing channels present on the ramp, the ramp had a landward tilt, or the direction of flow was oblique to the ramp orientation (as opposed to perpendicular; Ge et al, 2018).…”

Section: Discussionmentioning

confidence: 99%

“…Bell et al, 2018; Covault & Romans, 2009; Cullen et al, 2020; Cunha et al, 2017; Gervais et al, 2004; Lomas & Joseph, 2004; Prather et al, 1998; Tagliaferri et al, 2018; Winker, 1996). In complex settings, such as relay‐ramps, structure has the potential to greatly influence sediment transport mechanisms and routing pathways ( sensu Anderson et al, 2000; Athmer & Luthi, 2011; Barrett et al, 2020; Bruhn & Vagle, 2005; Serck & Braathen, 2019).…”

Section: Discussionmentioning

confidence: 99%

“…Fault relay ramps are important sediment delivery points along rift margins and often serve as persistent flow pathways in deepwater sedimentary basins (Athmer & Luthi, 2011; Bruhn & Vagle, 2005; Crossley, 1984; Gawthorpe & Hurst, 1993; Jackson & Leeder, 1994; Wells et al, 1999; Young et al, 2000; and references therein; Barret et al, 2020; Elliott et al, 2017; Hemelsdaël & Ford, 2016; Henstra et al, 2016; Serck & Braathen, 2019; Zhang & Scholz, 2015). Relay structures initially comprise a tilted or deformed volume of rock (the ramp) that forms between two overlapping, en‐echelon normal faults of comparable dips.…”

Section: Introductionmentioning

confidence: 99%

“…In the sub‐aqueous setting (marine or lacustrine), the effect of relay ramps on sub‐aqueous sediment gravity flows has been studied using numerical modelling techniques (Athmer et al, 2010; Athmer & Luthi, 2011; Carmona et al, 2016; Ge et al, 2018; Zhang et al, 2020), through the analysis of seismic data (Barret et al, 2020; Bruhn & Vagle, 2005; Fugelli & Olsen, 2007; Gawthorpe & Hurst, 1993; Serck & Braathen, 2019; Soreghan et al, 1999), and in outcrop (Henstra et al, 2016). Previous studies have focused on understanding syn‐rift subaqueous gravity flows in early‐stage relay ramp configurations (Athmer et al, 2010; Athmer & Luthi, 2011; Bruhn & Vagle, 2005; Fugelli & Olsen, 2007; Gawthorpe & Hurst, 1993; Kim & Paola, 2007) and suggest that the structural influence may have limited effect on syn‐rift sub‐aqueous gravity flow and deposition.…”

Section: Introductionmentioning

confidence: 99%

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The effect of breached relay ramp structures on deep‐lacustrine sedimentary systems

2022

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Fault relay ramps are important sediment delivery points along rift margins and often provide persistent flow pathways in deepwater sedimentary basins. They form as tilted rock volumes between en-echelon fault segments, which become modified through progressive deformation, and may develop through-going faults that 'breach' the relay ramp. It is well established that hinterland drainage (fluvial/alluvial systems) is greatly affected by the presence of relay ramps at basin margins. However, the impact on deepwater (deep-marine/lacustrine) subaqueous sediment gravity flow processes, particularly by breached relay ramps, is less well documented. To better evaluate the complex geology of breached relay settings, this study examines a suite of high-quality subsurface data from the Early Cretaceous deep-lacustrine North Falkland Basin (NFB). The Isobel Embayment breached relay-ramp, an ideal example, formed during the syn-rift and was later covered by a thick transitional and early post-rift succession. Major transitional and early post-rift fan systems are observed to have consistently entered the basin at the breached relay location, directed through a significant palaeo-bathymetric low associated with the lower, abandoned ramp of the structure. More minor systems also entered the basin across the structure-bounding fault to the north. Reactivation of basin-bounding faults is shown by the introduction of new point sources along its extent. This study shows the prolonged influence of marginlocated relay ramps on sedimentary systems from syn-rift, transitional and into the early post-rift phase. It suggests that these structures can become reactivated during post-rift times, providing continued control on deposition and sourcing of overlying sedimentary systems. Importantly, breached relays exert control on fan distribution, characterised by laterally extensive lobes sourced by widespread feeder systems, and hanging walls settings by small-scale lobes, with small, often line-sourced feeders. Further characterising the likely sandstone distribution in these structurally complex settings is important as these systems often form attractive hydrocarbon reservoirs. EAGE PLENDERLEITH et al.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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The effect of breached relay ramp structures on deep‐lacustrine sedimentary systems

2022

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“…Given the scale of the system, the above detail is unlikely to be imaged in the subsurface by standard seismic exploration methods (e.g. Barrett et al ., 2020).…”

Section: Sedimentologymentioning

confidence: 99%

Cool deltas: Sedimentological, geomorphological and geophysical characterization of ice‐contact deltas and implications for their reservoir properties (Salpausselkä, Finland)

et al. 2021

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Sediments deposited by glacial meltwaters (for example, ice-contact delta deposits) form permeable packages in the subsurface that can act as reservoirs for both water and hydrocarbons. They are also an important source of aggregate for the construction industry. As reservoirs they are challenging to characterize in terms of their structure, flow and storage properties due to their complex depositional history. In this study, ice-contact deltas of Salpausselkä I and II end moraines in Southern Finland are studied using a combination of geomorphological mapping, sedimentological studies and near surface geophysical methods. Sedimentary logs from isolated outcrops were correlated to ground penetrating radar (GPR) profiles to unravel the internal structure and depositional history of these ice-contact deltas. Subsequently, electrical resistivity tomography (ERT) and gravity data were analysed to estimate the depth to bedrock and to model porosity distribution within the sediments. Results of the study suggest that the delta deposits have a broad range of porosities (10 to 42%) with lowest values found in the bottomset beds. The most variable porosities are in the subaqueous ice-contact-fan zone, and consistently high porosities occur in delta foreset/topset facies. Detailed sedimentary logging linked to the GPR data shows heterogeneities such as mud drapes on foresets and kettle holes which are below the resolution of ERT and gravity methods but significantly affect reservoir properties of the deltas. Moreover, oscillation of the ice-margin may have introduced larger heterogeneities (for example, buried ice marginal ridges, or eskers) into the sedimentary sequence which are atypical for other Gilbert-type deltas. Finally, subglacially sculpted, highly variable bedrock topography exerts a major control on sediment distribution within the delta making reservoir volume and quality less predictable. This work has implications for present-day freshwater aquifers and low enthalpy geothermal energy in southern Finland and other deglaciated regions, as well as hydrocarbon exploration of analogous deposits in the subsurface from Pleistocene and pre-Pleistocene glaciogenic sequences.

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The evolution of catchment‐depositional system relationships on the dip slopes of intra‐rift basement highs: An example from the Frøya High, Mid‐Norwegian rifted margin

et al. 2023

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Basement highs form one of many potential sediment source areas during the evolution of continental rifts and rifted margins and add to the topographic complexity typical of active rifts. Footwall basement highs acting as a source area to sedimentary systems in the hangingwall of major faults has been documented in many systems worldwide. However, the back-tilted footwall dip slopes of such highs have received comparatively little attention. Here we investigate a subsurface case study from the Norwegian continental shelf, where catchments and shallow marine syn-rift sedimentary systems on a dip slope are preserved due to early transgression of an intra-rift high. At the onset of Late Jurassic rifting, the Frøya High emerged as a prominent, N-S trending, 25 km wide basement high tilted towards the east in response to several kilometers of displacement along the Klakk Fault Complex, a major normal fault zone at the Frøya High's western edge. Using well-calibrated 3D seismic reflection data, we observe a series of conspicuous Upper Jurassic wedges along the eastern edge of the Frøya High along the margin of the Froan Basin. Internally, these wedges show sigmoidal geometries marking topand foresets of clinoform packages with a maximum thickness of ca. 200 meters with foresets between 30 -200 m high, dipping ca. 10 degrees towards the east, south east and north east. We interpret these wedges to represent a series of eastward prograding deltas positioned along a constructional shoreline, connected to E-W trending valleys and river catchments updip. The deltas show strong progradation, interpreted to reflect the impact of continued uplift of their catchments. prior to abrupt termination of sediment supply from drainage capture by footwall scarp drainages. The presence of a connected, largely constructional shoreline has implications for Late Jurassic sediment distribution around the Frøya High, providing primary sedimentary input for longshore driven sedimentary systems in the Draugen Ridge to the north. Comparisons with other syn-rift dip slope systems highlights a broadly similar evolution but shows a distinct lack of the protracted backstepping observed in other dip slope systems. We postulate that different structural configurations of dip slope systems, being footwall uplift, Preprint / Henstra et al. 2023 / The evolution of catchment-depositional system relationships on the dip slopes of intra-rift basement highs 2 or hangingwall subsidence driven, may drive the strongly progradational character of the deltaic systems on the Frøya High. The Frøya High example highlights the need to constrain primary sediment input points to aid interpretation of volumetrically significant, but short-lived and subtle depositional systems, especially within complex, tectonically active settings.

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Quantitative analysis of a footwall-scarp degradation complex and syn-rift stratigraphic architecture, Exmouth Plateau, NW Shelf, offshore Australia

Cited by 4 publications

References 78 publications

The effect of breached relay ramp structures on deep‐lacustrine sedimentary systems

The effect of breached relay ramp structures on deep‐lacustrine sedimentary systems

Cool deltas: Sedimentological, geomorphological and geophysical characterization of ice‐contact deltas and implications for their reservoir properties (Salpausselkä, Finland)

The evolution of catchment‐depositional system relationships on the dip slopes of intra‐rift basement highs: An example from the Frøya High, Mid‐Norwegian rifted margin

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