Integrated geophysical, sedimentological and geotechnical investigation of submarine landslides in the Gulf of Lions (Western Mediterranean)

Shray Badhani,Antonio Cattaneo,Florent Colin,Bernard Dennielou,Laurence Droz,Marina Rabineau,Stefano Collico,Sebastien Garziglia,Roger Urgeles,Estelle Leroux

doi:10.1144/sp500-2019-175

Abstract

AbstractThe Gulf of Lions presents recurring mass-transport deposits (MTDs) within the Plio-Quaternary sediments, suggesting a long history of mass movements. The two large, surficial MTDs are located on the eastern and western levee of the Rhone canyon over an area exceeding 6000 km2 and volumes exceeding 100 km3. Both MTDs were emplaced 21 ka ago (peak of the Last Glacial Maximum), suggesting a common trigger. Here, we present a multidisciplinary high-resolution geophysical, sedimentological and in-situ geotechnical study of the source and deposit areas of both MTDs to characterize distinct expressions of sediment deformation as well as their spatial and chronological distributions. We show the internal structure of mass movements and resulting MTDs with unprecedented details that were previously represented in the conventional seismic data as transparent and chaotic facies. The combination of multidisciplinary approaches shows new insights into the nature of basal surfaces of the slope failures. In particular, we show that the basal surfaces of the failures consist of clay-rich material contrasting with the overlying turbiditic deposits, suggesting that a strong lithological heterogeneity exists within the strata. We suggest that this change in lithology between clay-rich sediments and turbiditic sequences most likely controls the localization of weak layers and landslide basal surfaces.

Highlights

ObjectivesThe overarching aim of this study is to analyse for the first time a suite of multidisciplinary dataset to better understand the distribution and characters of seafloor instabilities in the Gulf of Lions (GoL)
The slope is mainly characterised by three types of geomorphologic features: 1) sinuous elongated valleys that incise the seafloor down to several hundred meters interpreted as submarine canyons, 2) irregular, arcuate, curved breaks in the bathymetry interpreted as submarine landslide
R Based on our observation, we suggest that the chaotic reflections in the mass-transport deposits (MTDs) (e.g. Figs. 3, C 6b, c) and transparent reflections in the debris flow deposits (e.g. Rhone Western MTD S (RWMTD); Figs. 3, 6a) are S generated due to lack of resolution of the conventional seismic data, which is not able to U resolve scattered blocks embedded within the transported mass

Summary

Objectives

The overarching aim of this study is to analyse for the first time a suite of multidisciplinary dataset to better understand the distribution and characters of seafloor instabilities in the GoL

Methods

Results

Conclusion