The role of mass‐transport complexes in the initiation and evolution of submarine canyons

Wu, Nan; Nugraha, Harya Dwi; Zhong, Guangfa; Steventon, Michael

doi:10.1111/sed.12987

Cited by 16 publications

(8 citation statements)

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“…From the study of the Mms, we propose a conceptual model for the evolution of a continental margin affected by a large-scale landslide (Fig. 4), where the disruption of submarine slope channel systems over a wide area promotes the development of a major conveyor belt through the formation of topographic lows and confluence zones (see also Wu et al, 2022) that focus the transport of land-derived material and trap sediments carried by bottom currents. During the progressive healing of the landslide topography, which we observe can last for several million years, deposition of sand-prone facies may occur primarily on the upper slope, filling up the accommodation space generated by the landslide (Fig.…”

Section: Discussionmentioning

confidence: 99%

“…Submarine landslides and related mass-transport deposits (MTDs; sensu Weimer, 1990) modify the physiography of continental margins and impact subsequent sediment transport and deposition. Slope failures may capture turbidite channels (Kneller et al, 2016;Qin et al, 2017) and promote the formation of new submarine canyons through retrogressive erosion or by focusing gravity flows (Martínez-Doñate et al, 2021;Wu et al, 2022). The rugose topography of MTDs, generated either by landslide blocks or due to differential compaction (Alves and Cartwright, 2010;Ward et al, 2018), influences the path of subsequent turbidite channels (Bull et al, 2020) and may control the location of channel avulsion (Ortiz-Karpf et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

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Large-scale submarine landslide drives long-lasting regime shift in slope sediment deposition

Stagna

Maselli

Vliet

2023

Geology

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Submarine landslides and associated mass-transport deposits (MTDs) modify the physiography of continental margins and influence the evolution of submarine sediment routing systems. Previous studies highlighted the control of landslides and MTDs on subsequent sedimentary processes and deposits at spatial scales ranging from tens of centimeters to few kilometers, leaving a knowledge gap on how and for how long large-scale submarine landslides (i.e., headscarps wider than 50–100 km) may affect the stratigraphic evolution of continental margins. To fill this gap, we used three-dimensional seismic reflection data tied to an exploration well to investigate the impact of one of the largest submarine landslides discovered on Earth, the Mafia mega-slide (Mms) offshore Tanzania, on slope sediment deposition. Seismic data interpretation indicates that turbidite lobes/lobe complexes and coalescent mixed turbidite-contourite systems formed the pre-Mms stratigraphy between 38 and ca. 21 Ma (age of the Mms), whereas coarser-grained sheet turbidites and debrites accumulated after the Mms for ~15 m.y., primarily on the topographic lows generated by the emplacement of the landslide. We interpret this drastic and long-lasting regime shift in sediment deposition to be driven by the increase in seafloor gradient and the capture and focus of feeding systems within the broad failed area. We propose that the extensive evacuation zones associated with such giant landslides can generate major “conveyor belts”, trapping land-derived material or sediments transported by along-slope processes such as bottom currents. During the progressive healing of the landslide escarpments, which may last for several million years, sand-prone facies are deposited primarily in the upper slope, filling up the accommodation space generated by the landslide, while deeper-water environments likely remain sediment starved or experience accumulation of finer-grained deposits. Our study provides new insights into the long-term response of slope depositional systems to large-scale submarine landslides, with implications for the transfer of coarse-grained sediments that can be applied to continental margins worldwide.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Large-scale submarine landslide drives long-lasting regime shift in slope sediment deposition

Stagna

Maselli

Vliet

2023

Geology

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“…The presence of the stair-stepped scarps in the eastern part indicates that the landslides are initiated on the lower slope and fail retrogressively upwards (i.e. Sawyer et al, 2009;Wu et al, 2022). In the western part, the scattered scarps on the shelf suggest that slope failures dominate the continental shelf area.…”

Section: Discussionmentioning

confidence: 99%

“…In the Southern region, the evenly spaced nature and the absence of onshore fluvial systems indicate the canyoning process in the Southern region is fully marine and is related to alongshore current activities (Krassay et al, 2004;Mitchell et al, 2007b;Wu et al, 2022). Previous studies indicate the initiation and development of the canyons are attributed to the strengthening of the Bass Cascade Current (BCC) since the Pliocene (Mitchell et al, 2007a).…”

Section: Southern and Central Regions: The Supercritical Turbidity Cu...mentioning

confidence: 99%

Complex seabed geomorphology shaped by various oceanographic processes: a case study from the Gippsland Basin, offshore south-eastern Australia

Wu¹,

Niyazi²,

Steventon³

et al. 2023

Preprint

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The Gippsland Basin is located in the south-eastern continental margin of Australia and hosts a variety of important marine resources (i.e. hydrocarbons, offshore wind, biological diversity, and fishing resources). Recent high-resolution seabed mapping reveals a complex seabed morphology in the Gippsland Basin, containing scarps, cyclic steps, channels, canyons, gullies, and giant submarine landslides. However, previous studies have not yet revealed the dominant sedimentary processes behind this morphological complexity. We combine high-resolution multibeam bathymetric and seismic reflection datasets to investigate the dominant sedimentary processes that are active in shaping these complex seabed morphologies. In the northern region of the study area, slope failures are prevalent on the shelf and slope, which are primed by the deposition of contourites generated by the East Australian Current. In the central and southern regions, the Bass Cascade Current can carry large amounts of sediments, scouring the shelf and slope, and can form supercritical turbidity currents that create a variety of erosional seabed morphologies. We suggest that slope gradient variation, oceanography and a variety of sedimentary processes jointly contributed to the seabed morphological complexity in the Gippsland Basin. The high-resolution seabed morphological analysis within this study provides critical geomorphological and geological information for future submarine constructions (i.e. locating potential wind farms and telecommunication cable installations) along with geohazard prediction and mitigation (i.e. knowing the location of past and predicting future giant landslides).

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“…Kneller et al, 2016). Previous studies suggest that relief above MTCs influence sediment transport pathways by diverting subsequent turbidity currents (Hansen et al, 2013;Ortiz-Karpf et al, 2015;Corella et al, 2016;Ward et al, 2018;Wu et al, 2022), or by disrupting the equilibrium condition of subsequent alongshelf transported ocean currents and facilitating their transformation into down-slope transported gravity flows (Wu et al, 2024), or by generating ponded accommodation within which (turbidity current-fed) lobes and contourite channels are deposited (Solheim et al, 2005;Olafiranye et al, 2013;Li et al, 2015;Kneller et al, 2016) (see Appendix-2 for details). However, the way in which pre-existing MTCs control the flow direction, depositional pattern, and stratigraphic architecture of subsequent failures has received less attention.…”

Section: How Do Pre-existing Mtcs Influence Later Slope Failures?mentioning

confidence: 99%

How do ancient mass-transport complexes influence subsequent failure events? A case study from the Kangaroo Syncline, offshore NW Australia

Wu,

Jackson,

Hodgson

et al. 2024

Preprint

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Mass-transport complexes (MTCs) are common features in all continental margins. In some passive margins, accumulations of stacked MTCs indicate repeated slope failure, which raises the question of whether MTC emplacement may influence or even pre-condition, subsequent slope failures. Here, we use 3D seismic reflection data from the Kangaroo Syncline, NW Australia, to investigate how pre-existing MTCs can prime subsequent failure events. We show that: i) lithological heterogeneity present within a sedimentary succession due to MTC emplacement can dictate where subsequent slope failure occurs; ii) relief along the top surface of an MTC controls the transport pathway and stratigraphic architecture of a subsequent MTC; iii) topography created by a buried MTC can enhance the erosive ability of subsequent slope failure events; iv) pre-existing MTCs headwall scarp can drive a cascading effect and influence multiple subsequent slope failures; and v) the thickness distribution pattern of buried MTCs could provide a mechanism for predicting the depocentre of future slope failure events. Buried MTCs have profound effects on the location, nature, geometry, and hazard potential of future slope failures. Therefore, investigating the interaction between multi-stacked MTCs has significant implications for geohazard impact assessment.

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The role of mass‐transport complexes in the initiation and evolution of submarine canyons

Cited by 16 publications

References 100 publications

Large-scale submarine landslide drives long-lasting regime shift in slope sediment deposition

Large-scale submarine landslide drives long-lasting regime shift in slope sediment deposition

Complex seabed geomorphology shaped by various oceanographic processes: a case study from the Gippsland Basin, offshore south-eastern Australia

How do ancient mass-transport complexes influence subsequent failure events? A case study from the Kangaroo Syncline, offshore NW Australia

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