Wave Generation by Fluidized Granular Flows: Experimental Insights Into the Maximum Near‐Field Wave Amplitude

Lipiejko, Natalia; Whittaker, Colin; Lane, Emily M.; Power, William

doi:10.1029/2022jc019583

Cited by 4 publications

(1 citation statement)

References 57 publications

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“…The amplitude and consequences of waves generated from subaerial landslides can be extreme: the seismically triggered 1958 Lituya Bay landslide in Alaska generated a tsunami wave with a runup of 524 m, the highest recorded in history (Fritz et al., 2009; Miller, 1960); whereas the 1963 failure at Vajont, Italy generated a wave that overtopped a dam, flooded the valley, and destroyed villages, resulting in the loss of over 2000 lives (Barla & Paronuzzi, 2013; Genevois & Ghirotti, 2005). Waves associated with subaerial landslides have been thoroughly investigated in the laboratory using solid block experiments (e.g., Heller & Spinneken, 2013; Kamphuis & Bowering, 1970; Panizzo et al., 2005), experiments with dry granular landslides (e.g., Huber, 1980; Fritz et al., 2004; Mohammed & Fritz, 2012, Miller et al., 2017), and experiments using flows with greater velocities and distal reach ranging from snow avalanches (e.g., Zitti et al., 2016), saturated flows (e.g., Bullard et al., 2023; de Lange et al., 2020), pyroclastic density currents (e.g., Lipiejko et al., 2023) and finally, to water as a fully fluidized material (e.g., Bullard, Mulligan, Carreira, & Take, 2019; Bullard, Mulligan, & Take, 2019). Through this wide range of experimental data sets, relationships have been derived to predict the maximum wave amplitude formed at impact based on the characteristic properties of the landslide (e.g., Fritz et al., 2004; Heller & Hager, 2010; Mulligan & Take, 2017) and validation exercises have been conducted with numerical simulations aimed to capture landslide momentum transfer, wave propagation, and wave runup (e.g., Mulligan et al., 2020).…”

Section: Introductionmentioning

confidence: 99%

Large‐Scale Physical Modeling of Wave Generation and Runup on Slopes From the Collapse of Partially and Fully Submerged Granular Columns

Treflik‐Body,

Steel,

Take

et al. 2024

JGR Oceans

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Climate change is making coastal regions increasingly vulnerable to hazards, including rapid subaerial and submarine landslides, which can result in catastrophic tsunamis. Due to the complex geomechanics of failure, limited physical modeling studies have been conducted that encompass the entire problem including the triggering of granular landslides, the waves generated by partially and fully submerged mass failures, and the runup of these waves on local and distal slopes. In the present study, for the first time, waves in both the seaward direction (in the direction of failure for both submarine and partially submerged slides) and the landward direction (opposing the direction of failure only for submarine slides) are investigated during morphological evolution of the granular material. A series of large‐scale experiments are conducted under varying levels of submergence in water by releasing columns of gravel‐sized material into a range of different reservoir depths. This is accomplished using a pneumatically actuated vertical lift gate designed specifically for these experiments. The wave amplitudes measured in the seaward direction agree with empirical relationships developed in a previous study using smaller‐scale models, and a new analytical solution relating the column submergence to the trough‐led wave amplitudes in landward direction is presented. These novel predictions of wave amplitude and runup in both the seaward and landward directions indicate strong dependence of the wave behavior on the submergence depth and granular properties, improving our understanding of tsunamis generated by mass failures in coastal regions.

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Section: Introductionmentioning

confidence: 99%

Large‐Scale Physical Modeling of Wave Generation and Runup on Slopes From the Collapse of Partially and Fully Submerged Granular Columns

Treflik‐Body,

Steel,

Take

et al. 2024

JGR Oceans

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A Review of Tsunamis Generated by Volcanoes (TGV) Source Mechanism, Modelling, Monitoring and Warning Systems

Schindelé,

Kong,

Lane

et al. 2024

Pure Appl. Geophys.

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Tsunamis generated by volcanic eruptions have risen to prominence since the December 2018 tsunami generated by the flank collapse of Anak Krakatau during a moderate eruption and then the global tsunami generated by the explosive eruption of the Hunga volcano in the Tongan Archipelago in January 2022. Both events cause fatalities and highlight the lack in tsunami warning systems to detect and warn for tsunamis induced by volcanic mechanisms. Following the Hunga Tonga—Hunga Ha’apai eruption and tsunami, an ad hoc working group on Tsunamis Generated by Volcanoes was formed by the Intergovernmental Oceanographic Commission of UNESCO. Volcanic tsunamis differ from seismic tsunamis in that there are a wide range of source mechanisms that can generate the tsunamis waves and this makes understanding, modelling and monitoring volcanic tsunamis much more difficult than seismic tsunamis. This paper provides a review of both the mechanisms behind volcanic tsunamis and the variety of modelling techniques that can be used to simulate their effects for tsunami hazard assessment and forecasting. It gives an example of a volcanic tsunami risk assessment undertaken for Stromboli, outlines the requirement of volcanic monitoring to warn for tsunami hazard and provides examples of volcanic tsunami warning systems in Italy, the Hawaiian Island (USA), Tonga and Indonesia. The paper finishes by highlighting the need for implementing monitoring and warning systems for volcanic tsunamis for locations with submarine volcanoes or near-shore volcanoes which could potentially generate tsunamis.

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Tsunamis generated by pyroclastic flows: experimental insights into the effect of the bulk flow density

Bougouin,

Paris,

Roche

et al. 2024

Bull Volcanol

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Wave Generation by Fluidized Granular Flows: Experimental Insights Into the Maximum Near‐Field Wave Amplitude

Cited by 4 publications

References 57 publications

Large‐Scale Physical Modeling of Wave Generation and Runup on Slopes From the Collapse of Partially and Fully Submerged Granular Columns

Large‐Scale Physical Modeling of Wave Generation and Runup on Slopes From the Collapse of Partially and Fully Submerged Granular Columns

A Review of Tsunamis Generated by Volcanoes (TGV) Source Mechanism, Modelling, Monitoring and Warning Systems

Tsunamis generated by pyroclastic flows: experimental insights into the effect of the bulk flow density

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