Abstract
AbstractSediment slumps are known to have generated important tsunamis such as the 1998 Papua New Guinea (PNG) and the 1929 Grand Banks events. Tsunami modellers commonly use solid blocks with short run-out distances to simulate these slumps. While such methods have the obvious advantage of being simple to use, they offer little or no insight into physical processes that drive the events. The importance of rotational slump motion to tsunamigenic potential is demonstrated in this study by employing a viscoplastic landslide model with Herschel–Bulkley rheology. A large number of simulations for different material properties and landslide configurations are carried out to link the slump's deformation, rheology, its translational and rotational kinematics, to its tsunami genesis. The yield strength of the slump is shown to be the primary material property that determines the tsunami genesis. This viscoplastic model is further employed to simulate the 1929 Grand Banks tsunami using updated geological source information. The results of this case study suggest that the viscoplastic model can be used to simulate complex slump-induced tsunami. The simulations of the 1929 Grand Banks event also indicate that a pure slump mechanism is more tsunamigenic than a corresponding translational landslide mechanism.
Highlights
Slumps constitute a subset of landslides that are typically characterized by a rotational impulsive slope failure, a relatively coherent mass displacement, and a short landslide run-out distance
The importance of rotational slump motion to tsunamigenic potential is demonstrated in this study by employing a viscoplastic landslide model with Herschel–Bulkley rheology
The rigid block approach was successful in these studies, because the block could mimic the rotational motion of the slump causing the tsunami genesis in an idealized and simple way, but did not include the updated geological source information from Schulten et al (2019b), which envisaged a slump that partly evacuated the source area
Summary
Slumps constitute a subset of landslides that are typically characterized by a rotational impulsive slope failure, a relatively coherent mass displacement, and a short landslide run-out distance. The rigid block approach was successful in these studies, because the block could mimic the rotational motion of the slump causing the tsunami genesis in an idealized and simple way, but did not include the updated geological source information from Schulten et al (2019b), which envisaged a slump that partly evacuated the source area. This block modelling approach can help to shed light on the slump motion of past events, it has several obvious shortcomings. A detailed study of the event is left for future investigations
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