Volume and recurrence of submarine‐fan‐building turbidity currents

Jobe, Zane R.; Howes, Nick; Romans, Brian W.; Covault, Jacob A.

doi:10.1002/dep2.42

Cited by 28 publications

(22 citation statements)

References 99 publications

(216 reference statements)

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“…Repeat bathymetric surveys and direct monitoring provide evidence for multiphase sediment-transport processes in many active unfilled canyons and slope-channel systems (Conway et al, 2012;Gales et al, 2019;Vendettuoli et al, 2019). For example, local deposition of sediment by regular turbidity currents is commonly observed in slope channels but these deposits are eventually flushed downslope during less-frequent, larger-magnitude flow events (Jobe et al, 2018;Paull et al, 2018;Stacey et al, 2019). In some cases, such net-transport conditions can persist for millions of years (e.g., 5 m.y.…”

Section: Implications For Deepwater Sediment Transfer and The Role Ofmentioning

confidence: 99%

“…Our data set sheds light on the fidelity of the stratigraphic record and also provides temporal context for the commonly recognized stratigraphic evolution of submarine channels. Horizontally to vertically aligned channelform stacking patterns are observed globally over a wide range of temporal and spatial scales (spanning distances up to 20 km laterally and >1000 m vertically, over time scales ranging from 10 4 to 10 6 yr; Jobe et al, 2018;Sansom, 2018). Although calculated durations may not be directly applicable to systems of varying longevity, their relative comparison is informative and potentially useful for evaluating the temporal significance of this pattern in other deposits.…”

Section: Implications For the Interpretation Of Submarine Slope-channmentioning

confidence: 99%

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The evolution of submarine slope-channel systems: Timing of incision, bypass, and aggradation in Late Cretaceous Nanaimo Group channel-system strata, British Columbia, Canada

et al. 2019

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Submarine channel systems convey terrestrially derived detritus from shallow-marine environments to some of the largest sediment accumulations on Earth, submarine fans. The stratigraphic record of submarine slope channels includes heterogeneous, composite deposits that provide evidence for erosion, sediment bypass, and deposition. However, the timing and duration of these processes is poorly constrained over geologic time scales. We integrate geochronology with detailed stratigraphic characterization to temporally constrain the stratigraphic evolution recorded by horizontally to vertically aligned channel-fill stacking patterns in a Nanaimo Group channel system exposed on Hornby and Denman Islands, British Columbia, Canada. Twelve detrital zircon samples (n = 300/sample) were used to calculate maximum depositional ages, which identified a new age range for the succession from ca. 79 to 63 Ma. We document five phases of submarine-channel evolution over 16.0 ± 1.7 m.y. including: an initial phase dominated by incision, sediment bypass, and limited deposition (phase 1); followed by increasingly shorter and more rapid phases of deposition on the slope by laterally migrating (phase 2) and aggrading channels (phase 3); a long period of deep incision (phase 4); and a final rapid phase of vertical channel aggradation (phase 5). Our results suggest that ∼60% of the evolutionary history of the submarine channel system is captured in an incomplete, poorly preserved record of incision and sediment bypass, which makes up <20% of outcropping stratigraphy. Our findings are applicable to interpreting submarine channel-system evolution in ancient and modern settings worldwide and fundamentally important to understanding long-term sediment dispersal in the deep sea.

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Section: Implications For Deepwater Sediment Transfer and The Role Ofmentioning

confidence: 99%

Section: Implications For the Interpretation Of Submarine Slope-channmentioning

confidence: 99%

The evolution of submarine slope-channel systems: Timing of incision, bypass, and aggradation in Late Cretaceous Nanaimo Group channel-system strata, British Columbia, Canada

et al. 2019

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“…Calculations of flow volumes and transported grain sizes 18 (including the fraction of clay) requires very detailed dataset collected for this type of purpose, 19 especially in unconfined systems (e.g. Jobe et al, 2018). Finally, these first order controls will be 20 themselves the result of changes in the boundary condition or in the development stage of a 21 turbidite system (e.g.…”

Section: 2mentioning

confidence: 99%

Quantifying tabularity of turbidite beds and its relationship to the inferred degree of basin confinement

Tőkés

Patacci

2018

Marine and Petroleum Geology

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Please cite this article as: Tőkés, L., Patacci, M., Quantifying tabularity of turbidite beds and its relationship to the inferred degree of basin confinement, Marine and Petroleum Geology (2018), Abstract 8 Tabular beds and sheet-like deposits in deep-water systems have been the subject of much 9 research attention; they can form high quality hydrocarbon reservoirs, owing to their excellent 10 lateral continuity and predictable geometry. Additionally, deposit tabularity is a piece of 11 evidence used to infer flow confinement in ancient systems and thus to evaluate the suitability 12 of outcrop datasets as reservoir analogues. However, the quantification of tabularity is rarely 13 attempted and a consistent definition on how to describe it quantitatively is lacking. For this 14 study, published data from eighteen well-constrained ancient turbidite systems in outcrop were 15 analysed. A simple and novel methodology for the quantitative calculation of tabularity along a 16 transect from log panels and photo panels was devised, based on: a) subdividing beds into two 17 groups based on their thickness, b) calculating the percentage of beds continuous across a fixed 18 window (500m) and c) calculating the rate of thinning for the continuous beds within the same 19 window. Calculations obtained from multiple locations within individual systems enable the 20 investigation of proximal to distal, and axial to lateral changes in tabularity to be captured, and 21 therefore permits the evaluation of tabularity in three-dimensions. A comparison between 22 tabularity of the considered systems and their inferred degree of basin confinement shows that 23 in the confined systems >90% of beds are continuous over 500m compared to <40% for the two 24 unconfined systems studied. In addition, different bed types were compared: hybrid event bed 1 thinning rates are shown to be up to three times those of classical turbidites. This methodology 2 provides a new tool to compare tabularity within and between systems quantitatively. It is 3 hoped that the quantitative determination of tabularity will become a common workflow when 4 describing ancient turbidite systems. It is suggested that this approach will enhance the value of 5 outcrop data to inform models capturing the architecture of systems analogous to subsurface 6 hydrocarbon reservoirs. 7

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“…Turbidity currents are driven by gravity acting on this excess density, and contrary to fluvial flows, cannot travel downslope without entrained sediment. Turbidity currents are thought to typically last hours or days, although week-long flows have been documented (Cooper et al, 2013;Azpiroz-Zabala et al, 2017), and occur relatively infrequently in deep-water settings (a few times per year to every few hundred years; Paull et al, 2014;Stevens et al, 2014;Jobe et al, 2018). This contrasts the perennial flows of many fluvial channels, although highly variable discharge in some rivers may result in relatively few flows exhibiting disproportionate control on channel morphology (Wolman and Miller, 1960;Plink-Björklund, 2015).…”

Section: Introductionmentioning

confidence: 99%

Controls on submarine channel-modifying processes identified through morphometric scaling relationships

et al. 2018

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Submarine channels share morphological similarities with rivers, but observations from modern and ancient systems indicate they are formed under processes and controls unique to submarine settings. Morphologic characteristics of channels-e.g., width, depth, slope, and the relationships among them-can constrain interpretations of channel-forming processes. This work uses morphometric scaling relationships extracted from high-resolution seafloor bathymetry to infer connections between morphology and process in submarine channels. Analysis of 36 modern channels in five geographic regions shows that channel widths vary regionally (from <100 m to >10 km wide) but occupy the same range of aspect ratios (~10:1-100:1). This suggests an autogenic control on aspect ratio, perhaps resulting from feedback processes in levee growth and/or bank erosion, and allogenic (e.g., sediment supply, grain size) controls on channel width. Submarine channel aspect ratios tend to decrease with increasing dimensions, while the opposite relationship has been observed for fluvial channels, likely due to opposing relationships between flow discharge and channel distance. Additionally, observation of an apparent lag between channel thalweg and levee responses to gradient changes suggests that thalweg and levee deposition and erosion may be partially decoupled due to the vertical structure of turbidity currents, with thalweg evolution driven by the basal, higher-shear-stress portion of the flow and levee evolution by the dilute upper portion. The data presented here provide a basis for predicting channel metrics in exploration scenarios, in which data coverage may be sparse. This documentation of a diverse suite of channels also captures the range of scales and variability exhibited globally by submarine channel systems, providing context for local studies.

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Volume and recurrence of submarine‐fan‐building turbidity currents

Cited by 28 publications

References 99 publications

The evolution of submarine slope-channel systems: Timing of incision, bypass, and aggradation in Late Cretaceous Nanaimo Group channel-system strata, British Columbia, Canada

The evolution of submarine slope-channel systems: Timing of incision, bypass, and aggradation in Late Cretaceous Nanaimo Group channel-system strata, British Columbia, Canada

Quantifying tabularity of turbidite beds and its relationship to the inferred degree of basin confinement

Controls on submarine channel-modifying processes identified through morphometric scaling relationships

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