Which Triggers Produce the Most Erosive, Frequent, and Longest Runout Turbidity Currents on Deltas?

Hizzett, J. L.; Clarke, John E. Hughes; Sumner, Esther J.; Cartigny, Matthieu; Talling, Peter J.; Clare, Michael

doi:10.1002/2017gl075751

Cited by 83 publications

(92 citation statements)

References 34 publications

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“…Considering the predicted sediment budget for the Spanish Flats littoral cell, many transport events likely occurred during the surveyed interval, resulting ultimately in deep incision of a gully at the canyon head and migration of crescent-shaped bedforms characteristic of supercritical flow conditions at the bases of a coarse-grained turbidity currents (Covault et al, 2017;Hage et al, 2018). Due to the canyon's distance from the outlet of a major stream, these events were unlikely to have been triggered by river-generated hyperpycnal currents (Mulder et al, 2003) or plume settling at a river outlet (Hizzett et al, 2018). Instead, wave modeling suggests that a strong longshore current ends abruptly above the canyon head due to canyon-induced sheltering, trapping, and temporarily accumulating sediment in the canyon headwall region.…”

Section: Sediment Transport Into Delgada Canyonmentioning

confidence: 99%

Seeking the Shore: Evidence for Active Submarine Canyon Head Incision Due to Coarse Sediment Supply and Focusing of Wave Energy

Smith

Werner

Buscombe

et al. 2018

Geophysical Research Letters

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Submarine flows carve canyons into continental shelves, yet the conditions and events responsible for canyon incision are incompletely understood. Coarse sediment flux has been shown to promote terrestrial bedrock incision via abrasion in rivers, but similar processes in submarine canyons have yet to be systematically documented. We use repeat bathymetry, provenance analysis, wave modeling, and channel network analysis to show that longshore sheltering and wave focusing by the Delgada submarine canyon induce sediment accumulation and elevated wave shear stresses in its headwall region that frequently mobilize coarse bed material. These mobilizations scour bedrock in the headwall and generate abrasive turbidity currents that work to carve the canyon's active channel into bedrock. These findings highlight an important positive feedback between submarine canyons, waves, and sediment supply and suggest that submarine canyons adjacent to wave‐dominated, coarse sediment‐rich coastlines seek the shoreline through headward incision.

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Section: Sediment Transport Into Delgada Canyonmentioning

confidence: 99%

Seeking the Shore: Evidence for Active Submarine Canyon Head Incision Due to Coarse Sediment Supply and Focusing of Wave Energy

Smith

Werner

Buscombe

et al. 2018

Geophysical Research Letters

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“…(a–c) Mechanisms triggering turbidity currents at river mouths proposed in the literature. Percentage of flows triggered in Squamish by each mechanism are based on Hizzett et al (). References for given examples are 1: Piper & Savoye, ; Mulder et al, .…”

Section: Introductionmentioning

confidence: 99%

Direct Monitoring Reveals Initiation of Turbidity Currents From Extremely Dilute River Plumes

Hage

Cartigny

Sumner

et al. 2019

Geophysical Research Letters

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Rivers (on land) and turbidity currents (in the ocean) are the most important sediment transport processes on Earth. Yet how rivers generate turbidity currents as they enter the coastal ocean remains poorly understood. The current paradigm, based on laboratory experiments, is that turbidity currents are triggered when river plumes exceed a threshold sediment concentration of ~1 kg/m3. Here we present direct observations of an exceptionally dilute river plume, with sediment concentrations 1 order of magnitude below this threshold (0.07 kg/m3), which generated a fast (1.5 m/s), erosive, short‐lived (6 min) turbidity current. However, no turbidity current occurred during subsequent river plumes. We infer that turbidity currents are generated when fine sediment, accumulating in a tidal turbidity maximum, is released during spring tide. This means that very dilute river plumes can generate turbidity currents more frequently and in a wider range of locations than previously thought.

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“…Hizzett et al . () show that these flows generated by settling plume events also tend to coincide with peaks in river discharge.…”

Section: Discussionmentioning

confidence: 87%

“…However, Hizzett et al . () note that the size of the collapse does not necessarily influence the size of the sediment flow generated, with larger delta‐lip collapse (up to 150 000 m 3 ) often having relatively short runout distances. Therefore it is likely that the increased frequency and erosive nature of sediment flows generated by settling of sediment from surface plumes tend to have the greatest influence on channel system morphology within these fjords.…”

Section: Discussionmentioning

confidence: 97%

“…As river discharge increases, the frequency of turbidity current events also increases leading to significantly greater turbidity current activity in Knight and Bute Inlets. These flows, most likely generated by settling plume events, also tend to have the longest runouts and therefore are most important in terms of channel extension (Hizzett et al, ). The increased frequency of erosive, channel‐forming flows in Bute and Knight Inlets leads to the enhanced development of submarine channels.…”

Section: Discussionmentioning

confidence: 99%

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What controls submarine channel development and the morphology of deltas entering deep‐water fjords?

Gales

Talling

Cartigny

et al. 2018

Earth Surf Processes Landf

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River deltas and associated turbidity current systems produce some of the largest and most rapid sediment accumulations on our planet. These systems bury globally significant volumes of organic carbon and determine the runout distance of potentially hazardous sediment flows and the shape of their deposits. Here we seek to understand the main factors that determine the morphology of turbidity current systems linked to deltas in fjords, and why some locations have well developed submarine channels while others do not. Deltas and associated turbidity current systems are analysed initially in five fjord systems from British Columbia in Canada, and then more widely. This provides the basis for a general classification of delta and turbidity current system types, where rivers enter relatively deep (>200 m) water. Fjord‐delta area is found to be strongly bimodal. Avalanching of coarse‐grained bedload delivered by steep mountainous rivers produces small Gilbert‐type fan deltas, whose steep gradient (11°–25°) approaches the sediment's angle of repose. Bigger fjord‐head deltas are associated with much larger and finer‐grained rivers. These deltas have much lower gradients (1.5°–10°) that decrease offshore in a near exponential fashion. The lengths of turbidity current channels are highly variable, even in settings fed by rivers with similar discharges. This may be due to resetting of channel systems by delta‐top channel avulsions or major offshore landslides, as well as the amount and rate of sediment supplied to the delta front by rivers. © 2018 John Wiley & Sons, Ltd.

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Which Triggers Produce the Most Erosive, Frequent, and Longest Runout Turbidity Currents on Deltas?

Cited by 83 publications

References 34 publications

Seeking the Shore: Evidence for Active Submarine Canyon Head Incision Due to Coarse Sediment Supply and Focusing of Wave Energy

Seeking the Shore: Evidence for Active Submarine Canyon Head Incision Due to Coarse Sediment Supply and Focusing of Wave Energy

Direct Monitoring Reveals Initiation of Turbidity Currents From Extremely Dilute River Plumes

What controls submarine channel development and the morphology of deltas entering deep‐water fjords?

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