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.
The sedimentology and tsunamigenic potential of the Byron submarine landslide off New South Wales, Australia
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Published:June 11, 2020
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CiteCitation
Kendall C. Mollison, Hannah E. Power, Samantha L. Clarke, Alan T. Baxter, Emily M. Lane, Thomas C. T. Hubble, 2020. "The sedimentology and tsunamigenic potential of the Byron submarine landslide off New South Wales, Australia", 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
Extensive evidence for submarine landslide failure is found along the east Australian continental margin. This paper assesses the sedimentological properties and models the failure event that created the Byron landslide scar, located on the SE Australian continental margin, c. 34 km off the coast of Byron Bay, New South Wales. Sedimentological analyses and dating (radiocarbon and biostratigraphic) were conducted on three gravity cores collected from within the Byron landslide scar. A paraconformity, identified in one of the three cores by a distinct colour change, was found to represent a distinct radiocarbon age gap of at least 25 ka and probably represents the detachment surface of the slide plane. The core-derived sediment properties for the Byron landslide scar were used to inform hydrodynamic modelling using the freely available numerical modelling software, Basilisk. Model results highlight the important role of sediment rheology on the tsunamigenic potential of the slide and on the resulting inundation along the east Australian coastline, therefore providing a greater understanding of the modern hazard posed by comparable future submarine landslide events for the east Australian coastline.
- Australasia
- Australia
- bathymetry
- biostratigraphy
- C-14
- carbon
- Cenozoic
- computer programs
- continental margin
- cores
- data processing
- depositional environment
- failures
- geologic hazards
- hydrodynamics
- isotopes
- landslides
- mass movements
- natural hazards
- New South Wales Australia
- numerical models
- Quaternary
- radioactive isotopes
- rheology
- sedimentation
- sediments
- shorelines
- slumping
- tsunamis
- Byron Bay
- Basilisk model