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Preconditioning by sediment accumulation can produce powerful turbidity currents without major external triggers

Preconditioning by sediment accumulation can produce powerful turbidity currents without major external triggers
Preconditioning by sediment accumulation can produce powerful turbidity currents without major external triggers
Turbidity currents dominate sediment transfer into the deep ocean, and can damage critical seabed infrastructure. It is commonly inferred that powerful turbidity currents are triggered by major external events, such as storms, river floods, or earthquakes. However, basic models for turbidity current triggering remain poorly tested, with few studies accurately recording precise flow timing. Here, we analyse the most detailed series of measurements yet made of powerful (up to 7.2 m s−1) turbidity currents, within Monterey Canyon, offshore California. During 18-months of instrument deployment, fourteen turbidity currents were directly monitored. No consistent triggering mechanism was observed, though flows did cluster around enhanced seasonal sediment supply. We compare turbidity current timing at Monterey Canyon (a sandy canyon-head fed by longshore drift) to the only other systems where numerous (>10-100) flows have been measured precisely via direct monitoring; the Squamish Delta (a sandy fjord-head delta), and the Congo Canyon (connected to the mud-dominated mouth of the Congo River). A common seasonal pattern emerges, leading to a new model for preconditioning and triggering of turbidity currents initiating through slope failure in areas of sediment accumulation, such as canyon heads or river mouths. In this model, rapid or sustained sediment supply alone can produce elevated pore pressures, which may persist, thereby predisposing slopes to fail. Once preconditioned, a range of minor external perturbations, such as moderate storm-waves, result in local pore pressure variation, and thus become effective triggers. Major external triggers are therefore not always a prerequisite for triggering of powerful turbidity currents.
0012-821X
116845
Bailey, Lewis P.
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Clare, Michael A.
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Rosenberger, Kurt J.
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Cartigny, Matthieu J.b.
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Talling, Peter J.
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Paull, Charles K.
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Gwiazda, Roberto
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Parsons, Daniel R.
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Simmons, Stephen M.
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Xu, Jingping
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Haigh, Ivan D.
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Maier, Katherine L.
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Mcgann, Mary
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Lundsten, Eve
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Monterey CCE Team
Bailey, Lewis P.
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Clare, Michael A.
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Rosenberger, Kurt J.
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Cartigny, Matthieu J.b.
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Talling, Peter J.
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Paull, Charles K.
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Gwiazda, Roberto
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Parsons, Daniel R.
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Simmons, Stephen M.
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Xu, Jingping
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Haigh, Ivan D.
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Maier, Katherine L.
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Mcgann, Mary
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Lundsten, Eve
a4f9b64d-b636-4a2b-8961-e5500417e6fb

Monterey CCE Team (2021) Preconditioning by sediment accumulation can produce powerful turbidity currents without major external triggers. Earth and Planetary Science Letters, 562, 116845. (doi:10.1016/j.epsl.2021.116845).

Record type: Article

Abstract

Turbidity currents dominate sediment transfer into the deep ocean, and can damage critical seabed infrastructure. It is commonly inferred that powerful turbidity currents are triggered by major external events, such as storms, river floods, or earthquakes. However, basic models for turbidity current triggering remain poorly tested, with few studies accurately recording precise flow timing. Here, we analyse the most detailed series of measurements yet made of powerful (up to 7.2 m s−1) turbidity currents, within Monterey Canyon, offshore California. During 18-months of instrument deployment, fourteen turbidity currents were directly monitored. No consistent triggering mechanism was observed, though flows did cluster around enhanced seasonal sediment supply. We compare turbidity current timing at Monterey Canyon (a sandy canyon-head fed by longshore drift) to the only other systems where numerous (>10-100) flows have been measured precisely via direct monitoring; the Squamish Delta (a sandy fjord-head delta), and the Congo Canyon (connected to the mud-dominated mouth of the Congo River). A common seasonal pattern emerges, leading to a new model for preconditioning and triggering of turbidity currents initiating through slope failure in areas of sediment accumulation, such as canyon heads or river mouths. In this model, rapid or sustained sediment supply alone can produce elevated pore pressures, which may persist, thereby predisposing slopes to fail. Once preconditioned, a range of minor external perturbations, such as moderate storm-waves, result in local pore pressure variation, and thus become effective triggers. Major external triggers are therefore not always a prerequisite for triggering of powerful turbidity currents.

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Accepted/In Press date: 17 February 2021
e-pub ahead of print date: 3 March 2021
Published date: 15 May 2021
Learn more about Institute for Life Sciences research Learn more about Ocean and Earth Science research

Identifiers

Local EPrints ID: 468558
URI: http://eprints.soton.ac.uk/id/eprint/468558
DOI: doi:10.1016/j.epsl.2021.116845
ISSN: 0012-821X
PURE UUID: 6cc090d1-5f9d-4d1b-a01d-a1b533f5f679
ORCID for Ivan D. Haigh: ORCID iD orcid.org/0000-0002-9722-3061

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Date deposited: 18 Aug 2022 16:30
Last modified: 17 Mar 2024 03:07

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Contributors

Author: Lewis P. Bailey
Author: Michael A. Clare
Author: Kurt J. Rosenberger
Author: Matthieu J.b. Cartigny
Author: Peter J. Talling
Author: Charles K. Paull
Author: Roberto Gwiazda
Author: Daniel R. Parsons
Author: Stephen M. Simmons
Author: Jingping Xu
Author: Ivan D. Haigh ORCID iD
Author: Katherine L. Maier
Author: Mary Mcgann
Author: Eve Lundsten
Corporate Author: Monterey CCE Team

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