Hybrid turbidite-drift channel complexes: an integrated multiscale model
Hybrid turbidite-drift channel complexes: an integrated multiscale model
The interaction of deep-marine bottom currents with episodic, unsteady sediment gravity flows affects global sediment transport, forms climate archives, and controls the evolution of continental slopes. Despite their importance, contradictory hypotheses for reconstructing past flow regimes have arisen from a paucity of studies and the lack of direct monitoring of such hybrid systems. Here, we address this controversy by analyzing deposits, high-resolution seafloor data, and near-bed current measurements from two sites where eastward-flowing gravity flows interact(ed) with northward-flowing bottom currents. Extensive seismic and core data from offshore Tanzania reveal a 1650-m-thick asymmetric hybrid channel levee-drift system, deposited over a period of ~20 m.y. (Upper Cretaceous to Paleocene). High-resolution modern seafloor data from offshore Mozambique reveal similar asymmetric channel geometries, which are related to northward-flowing near-bed currents with measured velocities of up to 1.4 m/s. Higher sediment accumulation occurs on the downstream flank of channel margins (with respect to bottom currents), with inhibited deposition or scouring on the upstream flank (where velocities are highest). Toes of the drift deposits, consisting of thick laminated muddy siltstone, which progressively step back into the channel axis over time, result in an interfingering relationship with the sandstone-dominated channel fill. Bottom-current flow directions contrast with those of previous models, which lacked direct current measurements or paleoflow indicators. We finally show how large-scale depositional architecture is built through the temporally variable coupling of these two globally important sediment transport processes. Our findings enable more-robust reconstructions of past oceanic circulation and diagnosis of ancient hybrid turbidite-drift systems.
562-568
Fuhrmann, A.
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Kane, I.a.
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Clare, M.a.
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Ferguson, R.a.
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Schomacker, E.
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Bonamini, E.
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Contreras, F.a.
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June 2020
Fuhrmann, A.
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Kane, I.a.
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Clare, M.a.
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Ferguson, R.a.
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Schomacker, E.
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Bonamini, E.
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Contreras, F.a.
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Fuhrmann, A., Kane, I.a., Clare, M.a., Ferguson, R.a., Schomacker, E., Bonamini, E. and Contreras, F.a.
(2020)
Hybrid turbidite-drift channel complexes: an integrated multiscale model.
Geology, 48 (6), .
(doi:10.1130/G47179.1).
Abstract
The interaction of deep-marine bottom currents with episodic, unsteady sediment gravity flows affects global sediment transport, forms climate archives, and controls the evolution of continental slopes. Despite their importance, contradictory hypotheses for reconstructing past flow regimes have arisen from a paucity of studies and the lack of direct monitoring of such hybrid systems. Here, we address this controversy by analyzing deposits, high-resolution seafloor data, and near-bed current measurements from two sites where eastward-flowing gravity flows interact(ed) with northward-flowing bottom currents. Extensive seismic and core data from offshore Tanzania reveal a 1650-m-thick asymmetric hybrid channel levee-drift system, deposited over a period of ~20 m.y. (Upper Cretaceous to Paleocene). High-resolution modern seafloor data from offshore Mozambique reveal similar asymmetric channel geometries, which are related to northward-flowing near-bed currents with measured velocities of up to 1.4 m/s. Higher sediment accumulation occurs on the downstream flank of channel margins (with respect to bottom currents), with inhibited deposition or scouring on the upstream flank (where velocities are highest). Toes of the drift deposits, consisting of thick laminated muddy siltstone, which progressively step back into the channel axis over time, result in an interfingering relationship with the sandstone-dominated channel fill. Bottom-current flow directions contrast with those of previous models, which lacked direct current measurements or paleoflow indicators. We finally show how large-scale depositional architecture is built through the temporally variable coupling of these two globally important sediment transport processes. Our findings enable more-robust reconstructions of past oceanic circulation and diagnosis of ancient hybrid turbidite-drift systems.
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Accepted/In Press date: 28 January 2020
e-pub ahead of print date: 18 March 2020
Published date: June 2020
Additional Information:
Funding Information:
We thank Michal Janocko for assistance with data analysis, and acknowledge the helpful reviews of F. Gam-beri, F.J. Hernandez-Molina, and G. Shanmugam. We acknowledge funding and data supplied by Equinor ASA, and data from Eni energy company and from ExxonMo-bil. Clare was supported by the Climate Linked Atlantic Sector Science (CLASS) programme (Natural Environment Research Council Grant No. NE/R015953/1).
Publisher Copyright:
© 2020 The Authors. Gold Open Access.
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Local EPrints ID: 439812
URI: http://eprints.soton.ac.uk/id/eprint/439812
ISSN: 0091-7613
PURE UUID: de4d9b78-3543-4bb6-ab8c-0fa571b79596
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Date deposited: 05 May 2020 16:30
Last modified: 16 Mar 2024 07:44
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Contributors
Author:
A. Fuhrmann
Author:
I.a. Kane
Author:
M.a. Clare
Author:
R.a. Ferguson
Author:
E. Schomacker
Author:
E. Bonamini
Author:
F.a. Contreras
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