Seabed Seismographs Reveal Duration and Structure of Longest Runout Sediment Flows on Earth

Megan L. Baker; Peter J. Talling; Richard Burnett; Ed L. Pope; Sean C. Ruffell; Morelia Urlaub; Michael A. Clare; Jennifer Jenkins; Michael Dietze; Jeffrey Neasham; Ricardo Silva Jacinto; Sophie Hage; Martin Hasenhündl; Steve M. Simmons; Catharina J. Heerema; Maarten S. Heijnen; Pascal Kunath; Matthieu J. B. Cartigny; Claire McGhee; Daniel R. Parsons

doi:10.1029/2024GL111078

Geophysical Research Letters (Dec 2024)

Seabed Seismographs Reveal Duration and Structure of Longest Runout Sediment Flows on Earth

Megan L. Baker,
Peter J. Talling,
Richard Burnett,
Ed L. Pope,
Sean C. Ruffell,
Morelia Urlaub,
Michael A. Clare,
Jennifer Jenkins,
Michael Dietze,
Jeffrey Neasham,
Ricardo Silva Jacinto,
Sophie Hage,
Martin Hasenhündl,
Steve M. Simmons,
Catharina J. Heerema,
Maarten S. Heijnen,
Pascal Kunath,
Matthieu J. B. Cartigny,
Claire McGhee,
Daniel R. Parsons

Affiliations

Megan L. Baker: Department of Geography Durham University Durham UK
Peter J. Talling: Department of Geography Durham University Durham UK
Richard Burnett: School of Engineering Newcastle University Newcastle Upon Tyne UK
Ed L. Pope: Department of Geography Durham University Durham UK
Sean C. Ruffell: Department of Earth Sciences Durham University Durham UK
Morelia Urlaub: GEOMAR Helmholtz Centre for Ocean Research Kiel Germany
Michael A. Clare: National Oceanography Centre Southampton UK
Jennifer Jenkins: Department of Earth Sciences Durham University Durham UK
Michael Dietze: Department of Geography Georg‐August‐University Göttingen Germany
Jeffrey Neasham: School of Engineering Newcastle University Newcastle Upon Tyne UK
Ricardo Silva Jacinto: Geo‐OceanUnit IFREMER Centre de Brest Plouzané France
Sophie Hage: GEOPS UMR 8148 Université Paris‐Saclay Orsay France
Martin Hasenhündl: Institute of Hydraulic Engineering and Water Resources Management TU Wien Vienna Austria
Steve M. Simmons: Energy and Environment Institute University of Hull Hull UK
Catharina J. Heerema: Department of Earth Sciences Durham University Durham UK
Maarten S. Heijnen: National Oceanography Centre Southampton UK
Pascal Kunath: GEOMAR Helmholtz Centre for Ocean Research Kiel Germany
Matthieu J. B. Cartigny: Department of Geography Durham University Durham UK
Claire McGhee: School of Natural and Environmental Sciences Newcastle University Newcastle UK
Daniel R. Parsons: The Loughborough Centre for Sustainable Transitions: Energy Environment and Resilience Loughborough University Leicestershire UK

DOI: https://doi.org/10.1029/2024GL111078
Journal volume & issue: Vol. 51, no. 23
pp. n/a – n/a

Abstract

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Abstract Turbidity currents carve the deepest canyons on Earth, deposit its largest sediment accumulations, and break seabed telecommunication cables. Powerful canyon‐flushing turbidity currents break sensors placed in their path, making them notoriously challenging to measure, and thus poorly understood. This study provides the first remote measurements of canyon‐flushing flows, using ocean‐bottom seismographs located outside the flow's destructive path, revolutionizing flow monitoring. We recorded the internal dynamics of the longest sediment flows yet monitored on Earth, which traveled >1,000 km down the Congo Canyon‐Channel at 3.7–7.6 m s−1 and lasted >3 weeks. These observations allow us to test fundamental models for turbidity current behavior and reveal that flows contain dense and fast frontal‐zones up to ∼400 km in length. These frontal‐zones developed near‐uniform durations and speeds for hundreds of kilometres despite substantial seabed erosion, enabling flows to rapidly transport prodigious volumes of organic carbon, sediment, and warm water to the deep‐sea.

Published in Geophysical Research Letters

ISSN: 0094-8276 (Print); 1944-8007 (Online)
Publisher: Wiley
Country of publisher: United States
LCC subjects: Science: Physics: Geophysics. Cosmic physics
Website: https://agupubs.onlinelibrary.wiley.com/journal/19448007

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