Litcius/Paper detail

First source-to-sink monitoring shows dense head controls sediment flux and runout in turbidity currents

Ed Pope, Matthieu Cartigny, Michael Clare, Peter J. Talling, Gwyn Lintern, Age Vellinga, Sophie Hage, Sanem Açıkalın, Lewis Bailey, Natasha Chapplow, Ye Chen, Joris T. Eggenhuisen, Alison Hendry, Catharina Heerema, Maarten Heijnen, Stephen M. Hubbard, James E. Hunt, Claire McGhee, Daniel R. Parsons, Stephen M. Simmons, Cooper Stacey, Daniela Vendettuoli

2022Science Advances54 citationsDOIOpen Access PDF

Abstract

Until recently, despite being one of the most important sediment transport phenomena on Earth, few direct measurements of turbidity currents existed. Consequently, their structure and evolution were poorly understood, particularly whether they are dense or dilute. Here, we analyze the largest number of turbidity currents monitored to date from source to sink. We show sediment transport and internal flow characteristic evolution as they runout. Observed frontal regions (heads) are fast (>1.5 m/s), thin (<10 m), dense (depth averaged concentrations up to 38% vol ), strongly stratified, and dominated by grain-to-grain interactions, or slower (<1 m/s), dilute (<0.01% vol ), and well mixed with turbulence supporting sediment. Between these end-members, a transitional flow head exists. Flow bodies are typically thick, slow, dilute, and well mixed. Flows with dense heads stretch and bulk up with dense heads transporting up to 1000 times more sediment than the dilute body. Dense heads can therefore control turbidity current sediment transport and runout into the deep sea.

Topics & Concepts

Turbidity currentSink (geography)SedimentTurbidityGeologySediment transportTurbulenceTurbiditeGeomorphologyGrain sizeHydrology (agriculture)MechanicsGeotechnical engineeringOceanographySedimentary depositional environmentPhysicsStructural basinGeographyCartographyGeological formations and processesCoastal wetland ecosystem dynamicsGeology and Paleoclimatology Research