How typhoons trigger turbidity currents in submarine canyons. - National Genomics Data Center (CNCB-NGDC)

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How typhoons trigger turbidity currents in submarine canyons.

Octavio E Sequeiros, Michele Bolla Pittaluga, Alessandro Frascati, Carlos Pirmez, Douglas G Masson, Philip Weaver, Alexander R Crosby, Gianluca Lazzaro, Gianluca Botter, Jeffrey G Rimmer

Author Information

Octavio E Sequeiros: Shell Global Solutions International B.V., Lange Kleiweg 40, 2288 GK, Rijswijk, The Netherlands. octavio.e.sequeiros@shell.com. ORCID
Michele Bolla Pittaluga: Shell Global Solutions International B.V., Lange Kleiweg 40, 2288 GK, Rijswijk, The Netherlands.
Alessandro Frascati: Shell Global Solutions International B.V., Grasweg 31, 1031 HW, Amsterdam, The Netherlands.
Carlos Pirmez: Shell Exploration & Production Company, 150 N. Dairy Ashford, 77079, Houston, USA.
Douglas G Masson: Seascape Consultants, Jermyns House, Jermyns Lane, Romsey, SO51 0PE, UK.
Philip Weaver: Seascape Consultants, Jermyns House, Jermyns Lane, Romsey, SO51 0PE, UK.
Alexander R Crosby: Oceanweather Inc., 350 Bedford Street, Suite 404, Stamford, CT 06901, USA.
Gianluca Lazzaro: University of Padova, Department of Civil Architectural and Environmental Engineering. Via Loredan 20, 35131, Padova, Italy.
Gianluca Botter: University of Padova, Department of Civil Architectural and Environmental Engineering. Via Loredan 20, 35131, Padova, Italy.
Jeffrey G Rimmer: Shell Philippines Exploration BV, P.O. Box 171, Ayala Alabang, Muntinlupa City, 1780, Manila, Philippines.

PMID: 31239463 DOI: 10.1038/s41598-019-45615-z

Intense turbidity currents occur in the Malaylay Submarine Canyon off the northern coast of Mindoro Island in the Philippines. They start in very shallow waters at the shelf break and reach deeper waters where a gas pipeline is located. The pipeline was displaced by a turbidity current in 2006 and its rock berm damaged by another 10 years later. Here we propose that they are triggered near the mouth of the Malaylay and Baco rivers by direct sediment resuspension in the shallow shelf and transport to the canyon heads by typhoon-induced waves and currents. We show these rivers are unlikely to generate hyperpycnal flows and trigger turbidity currents by themselves. Characteristic signatures of turbidity currents, in the form of bed shear stress obtained by numerical simulations, match observed erosion/deposition and rock berm damage patterns recorded by repeat bathymetric surveys before and after typhoon Nock-ten in December 2016. Our analysis predicts a larger turbidity current triggered by typhoon Durian in 2006; and reveals the reason for the lack of any significant turbidity current associated with typhoon Melor in December 2015. Key factors to assess turbidity current initiation are typhoon proximity, strength, and synchronicity of typhoon induced waves and currents. Using data from a 66-year hindcast we estimate a ~8-year return period of typhoons with capacity to trigger large turbidity currents.

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Journal Article Research Support, Non-U.S. Gov't