Subaqueous Mass Movements and their Consequences: Advances in Process Understanding, Monitoring and Hazard Assessments
This volume focuses on underwater or subaqueous landslides with the overarching goal of understanding how they affect society and the environment. The new research presented here is the result of significant advances made over recent years in directly monitoring submarine landslides, in standardizing global datasets for quantitative analysis, constructing a global database and from leading international research projects. Subaqueous Mass Movements demonstrates the breadth of investigation taking place into subaqueous landslides and shows that, while events like the recent ones in the Indonesian archipelago can be devastating, they are at the smaller end of what the Earth has experienced in the past. Understanding the spectrum of subaqueous landslide processes, and therefore the potential societal impact, requires research across all spatial and temporal scales. This volume delivers a compilation of state-of-the-art papers covering topics from regional landslide databases to advanced techniques for in situ measurements, to numerical modelling of processes and hazards.
A new depositional model for the Tuaheni Landslide Complex, Hikurangi Margin, New Zealand
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Published:June 11, 2020
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CiteCitation
Benjamin Couvin, Aggeliki Georgiopoulou, Joshu J. Mountjoy, Lawrence Amy, Gareth J. Crutchley, Morgane Brunet, Sebastian Cardona, Felix Gross, Christoph Böttner, Sebastian Krastel, Ingo Pecher, 2020. "A new depositional model for the Tuaheni Landslide Complex, Hikurangi Margin, New Zealand", Subaqueous Mass Movements and their Consequences: Advances in Process Understanding, Monitoring and Hazard Assessments, A. Georgiopoulou, L. A. Amy, S. Benetti, J. D. Chaytor, M. A. Clare, D. Gamboa, P. D. W. Haughton, J. Moernaut, J. J. Mountjoy
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Abstract
The Tuaheni Landslide Complex (TLC) is characterized by areas of compression upslope and extension downslope. It has been thought to consist of a stack of two genetically linked landslide units identified from seismic data. We used 3D seismic reflection, bathymetry data and International Ocean Discovery Program Core U1517C (Expedition 372) to understand the internal structures, deformation mechanisms and depositional processes of the TLC deposits. Units II and III of U1517C correspond to the two chaotic units in 3D seismic data. In the core, Unit II shows deformation, whereas Unit III appears more like an in situ sequence. Variance attribute analysis showed that Unit II is split into lobes around a coherent stratified central ridge and is bounded by scarps. By contrast, we found that Unit III is continuous beneath the central ridge and has an upslope geometry, which we interpreted as a channel–levee system. Both units show evidence of lateral spreading due to the presence of the Tuaheni Canyon removing support from the toe. Our results suggest that Units II and III are not genetically linked, are separated substantially in time and had different emplacement mechanisms, but they fail under similar circumstances.
- Australasia
- bathymetry
- channels
- compression
- cores
- deformation
- deposition
- depositional environment
- extension
- facies
- failures
- geologic hazards
- geometry
- geophysical methods
- geophysical profiles
- geophysical surveys
- grain size
- Hikurangi Margin
- International Ocean Discovery Program
- landslides
- levees
- mass movements
- natural hazards
- New Zealand
- North Island
- Pacific Ocean
- reflection methods
- sedimentary rocks
- seismic attributes
- seismic methods
- seismic profiles
- slopes
- slumping
- South Pacific
- Southwest Pacific
- statistical analysis
- stratigraphic units
- surveys
- three-dimensional models
- variance analysis
- West Pacific
- Tuaheni Complex
- Expedition 372
- IODP Site U1517
- Tuaheni Canyon
- Expeditions 372/375