A threshold in submarine channel curvature explains erosion rate and type
A threshold in submarine channel curvature explains erosion rate and type
Submarine channels are conduits for sediment-laden flows called turbidity currents, which play a globally significant role in the offshore transport of sediment and organic carbon and pose a hazard to critical seafloor infrastructure. Time-lapse repeat surveys of active submarine channels have recently shown that upstream-migrating knickpoints can dominate channel evolution. This finding contrasts with many studies of ancient outcrops and subsurface geophysical data that inferred channel bends migrate laterally, as occurs in meandering rivers. Here, we aim to test these two contrasting views by analysing two high-resolution repeat seafloor surveys acquired 13 years apart across the entirety of an active submarine channel in Knight Inlet, British Columbia. We find that two main mechanisms control channel evolution, with the normalised channel radius of curvature (specifically, R* - channel radius of curvature normalised to channel width) explaining which of these mechanisms dominate. Pronounced outer bend migration only occurs at tight bends (R*<1.5). In contrast, at broader bends and straighter sections (R*>1.5), erosion is focused within the channel axis, where upstream-migrating knickpoints dominate. High centrifugal accelerations at tight bends promote super-elevation of flows on the outer channel flank, thus, enhancing outer bend erosion. At R*>1.5, flow is focused within the channel axis, promoting knickpoints that migrate upstream at an order of magnitude faster than the rate of outer bend erosion at tight bends. Despite the dominance of knickpoints in eroding the channel axis, their stratigraphic preservation is very low. In contrast, the lateral migration of channel bends results in much higher preservation via lateral accretion of deposits on the inner bend. We conclude that multiple mechanisms can control evolution at different channel reaches and that the role of knickpoints has been underestimated from past studies that focused on deposits due to their low preservation potential.
Zulkifli, Zaki
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Clare, Michael A.
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Heijnen, Maarten S.
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Talling, Peter J.
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Lintern, D. Gwyn
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Stacey, Cooper
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Cartigny, Matthieu J.B.
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Minshull, Tim
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Marin Moreno, Hector
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Peakall, Jeffrey
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Darby, Steve
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5 September 2024
Zulkifli, Zaki
2acfa116-b74c-4ada-8e34-3bd2308ffc15
Clare, Michael A.
599e2862-baed-4d59-8845-3b8499ca0832
Heijnen, Maarten S.
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Talling, Peter J.
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Lintern, D. Gwyn
41355af9-0e73-4541-a93a-980ae0daa936
Stacey, Cooper
36936140-b618-47d1-9d32-76060722ab05
Cartigny, Matthieu J.B.
bda1b79b-7e11-4790-8238-b86d80a88bb3
Minshull, Tim
bf413fb5-849e-4389-acd7-0cb0d644e6b8
Marin Moreno, Hector
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Peakall, Jeffrey
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Darby, Steve
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Zulkifli, Zaki, Clare, Michael A., Heijnen, Maarten S., Talling, Peter J., Lintern, D. Gwyn, Stacey, Cooper, Cartigny, Matthieu J.B., Minshull, Tim, Marin Moreno, Hector, Peakall, Jeffrey and Darby, Steve
(2024)
A threshold in submarine channel curvature explains erosion rate and type.
Earth and Planetary Science Letters, 646, [118953].
(doi:10.1016/j.epsl.2024.118953).
Abstract
Submarine channels are conduits for sediment-laden flows called turbidity currents, which play a globally significant role in the offshore transport of sediment and organic carbon and pose a hazard to critical seafloor infrastructure. Time-lapse repeat surveys of active submarine channels have recently shown that upstream-migrating knickpoints can dominate channel evolution. This finding contrasts with many studies of ancient outcrops and subsurface geophysical data that inferred channel bends migrate laterally, as occurs in meandering rivers. Here, we aim to test these two contrasting views by analysing two high-resolution repeat seafloor surveys acquired 13 years apart across the entirety of an active submarine channel in Knight Inlet, British Columbia. We find that two main mechanisms control channel evolution, with the normalised channel radius of curvature (specifically, R* - channel radius of curvature normalised to channel width) explaining which of these mechanisms dominate. Pronounced outer bend migration only occurs at tight bends (R*<1.5). In contrast, at broader bends and straighter sections (R*>1.5), erosion is focused within the channel axis, where upstream-migrating knickpoints dominate. High centrifugal accelerations at tight bends promote super-elevation of flows on the outer channel flank, thus, enhancing outer bend erosion. At R*>1.5, flow is focused within the channel axis, promoting knickpoints that migrate upstream at an order of magnitude faster than the rate of outer bend erosion at tight bends. Despite the dominance of knickpoints in eroding the channel axis, their stratigraphic preservation is very low. In contrast, the lateral migration of channel bends results in much higher preservation via lateral accretion of deposits on the inner bend. We conclude that multiple mechanisms can control evolution at different channel reaches and that the role of knickpoints has been underestimated from past studies that focused on deposits due to their low preservation potential.
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Accepted/In Press date: 14 August 2024
Published date: 5 September 2024
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Local EPrints ID: 494083
URI: http://eprints.soton.ac.uk/id/eprint/494083
ISSN: 0012-821X
PURE UUID: 69def8fc-0d74-4865-bb11-4e3545c34904
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Date deposited: 23 Sep 2024 16:41
Last modified: 24 Sep 2024 02:04
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Author:
Michael A. Clare
Author:
Maarten S. Heijnen
Author:
Peter J. Talling
Author:
D. Gwyn Lintern
Author:
Cooper Stacey
Author:
Matthieu J.B. Cartigny
Author:
Hector Marin Moreno
Author:
Jeffrey Peakall
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