Lessons learned from monitoring of turbidity currents and guidance for future platform designs

Michael Clare; D. Gwyn Lintern; Kurt J. Rosenberger; John Hughes Clarke; Charles K. Paull; Roberto Gwiazda; Matthieu J.B. Cartigny; Peter J. Talling; Daniel Perara; Jingping Xu; Daniel Parsons; Ricardo Silva Jacinto; Ronan Apprioual

doi:10.1144/SP500-2019-173

Lessons learned from monitoring of turbidity currents and guidance for future platform designs

Special Publications

By: Michael Clare, D. Gwyn Lintern, Kurt J. Rosenberger, John Hughes Clarke, Charles K. Paull, Roberto Gwiazda, Matthieu J.B. Cartigny, Peter J. Talling, Daniel Perara, Jingping Xu, Daniel Parsons, Ricardo Silva Jacinto, and Ronan Apprioual

https://doi.org/10.1144/SP500-2019-173

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Abstract

Turbidity currents transport globally significant volumes of sediment and organic carbon into the deep-sea and pose a hazard to critical infrastructure. Despite advances in technology, their powerful nature often damages expensive instruments placed in their path. These challenges mean that turbidity currents have only been measured in a few locations worldwide, in relatively shallow water depths (<<2 km). Here, we share lessons from recent field deployments about how to design the platforms on which instruments are deployed. First, we show how monitoring platforms have been affected by turbidity currents including instability, displacement, tumbling and damage. Second, we relate these issues to specifics of the platform design, such as exposure of large surface area instruments within a flow and inadequate anchoring or seafloor support. Third, we provide recommended improvements to improve design by simplifying mooring configurations, minimising surface area, and enhancing seafloor stability. Finally we highlight novel multi-point moorings that avoid interaction between the instruments and the flow, and flow-resilient seafloor platforms with innovative engineering design features, such as ejectable feet and ballast. Our experience will provide guidance for future deployments, so that more detailed insights can be provided into turbidity current behaviour, and in a wider range of settings.

Additional publication details
Publication type	Article
Publication Subtype	Journal Article
Title	Lessons learned from monitoring of turbidity currents and guidance for future platform designs
Series title	Special Publications
DOI	10.1144/SP500-2019-173
Volume	500
Year Published	2020
Language	English
Publisher	The Geological Society of London
Contributing office(s)	Pacific Coastal and Marine Science Center
Description	30 p.
First page	605
Last page	634
Google Analytic Metrics	Metrics page