Abstract
An extensive dataset of shallow sediment cores is used here to describe one of the World's most voluminous and extensive submarine gravity flows. The Bed 5 event, dated at ~60 ka, originated on the upper slope offshore Atlantic Morocco, in the vicinity of Agadir Canyon. The volume of initial failure was ~130 km3 of sediment, and the failure appeared to rapidly disintegrate into a highly mobile turbidity current. Widespread substrate erosion beneath the flow occurred up to 550 km from the interpreted source, and is estimated to have added a further 30 km3 of sediment. The flow spread upon exiting Agadir Canyon, with deposition occurring across both the Agadir Basin and Seine Abyssal Plain. Evidence for flow transformations and linked turbidite-debrite development can be found in both basins, and there are also indications for sediment bypass and fluid mud behaviour. A portion of the flow subsequently spilled out of the western Agadir Basin, and passed through the Madeira Channels prior to deposition on the enclosed Madeira Abyssal Plain at 5,400 m water depth. The total run-out distance along the flow pathway is about 2,000 km, with only about half of the pathway confined to canyon or channel environments. Our results show that large-volume submarine landslides can rapidly disintegrate into far-traveling fluid turbidity currents, and that deposi-tional processes within such flows may be complex and spatially variable
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Acknowledgments
We would like to thank the large number of scientists and ship staff who have assisted with data collection on research cruises to the Moroccan Turbidite System. In particular, RBW (as Chief Scientist) would like to acknowledge the contribution of the deep-water coring team on the two most recent cruises, CD166 and JC027. Research cruise CD166 was funded by NERC and several companies involved in the UK-TAPS (Turbidite Architecture and Process Studies) Agadir Project consortium, including BHP Billiton, ConocoPhillips, ExxonMobil, Norsk Hydro and Shell. Research cruise JC027 was funded through the NERC Oceans 2025 strategic research programme. We are also grateful to Michael Frenz, Esther Sumner, Sünje Dallmeier-Tiessen, Gayle Hough and Andrey Akhmetzhanov for their significant contributions towards sedi-mentological and geophysical data collection and processing. Reviewers Mark Deptuck and David Hodgson are thanked for their constructive comments that helped improve the paper.
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Wynn, R.B., Talling, P.J., Masson, D.G., Stevenson, C.J., Cronin, B.T., Bas, T.P.L. (2010). Investigating the Timing, Processes and Deposits of One of the World's Largest Submarine Gravity Flows: The ‘Bed 5 Event’ Off Northwest Africa. In: Mosher, D.C., et al. Submarine Mass Movements and Their Consequences. Advances in Natural and Technological Hazards Research, vol 28. Springer, Dordrecht. https://doi.org/10.1007/978-90-481-3071-9_38
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DOI: https://doi.org/10.1007/978-90-481-3071-9_38
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