Experiments on tsunamis generated by 3D granular landslides

Abstract

Subaerial and submarine landslides can trigger tsunamis with locally high amplitudes and runup, which can cause devastating effects in the near field region such as the 1958 Lituya bay, Alaska, 1998 Papua New Guinea and 2006 Java tsunamis. Tsunami generation by submarine and subaerial landslides were studied in the three dimensional NEES (George E. Brown, Jr. Network for Earthquake Engineering Simulation) tsunami wave basin (TWB) at Oregon State University based on the generalized Froude similarity. A novel pneumatic landslide generator was deployed to control the granular landslide geometry and kinematics. Measurement techniques such as particle image velocimetry (PIV), multiple above and underwater video cameras, multiple acoustic transducer arrays (MTA), as well as resistance wave and runup gauges were applied. The experimental data provided new insights on landslide deformation as it impacts the water surface, penetrates the water and finally deposits on the bottom of the basin. The influence of the landslide volume, shape and the impact speed on the generated tsunami waves were extensively studied. The instantaneous surface velocity fields measured using the PIV gave insight into the kinematics of the landslide and wave generation process. At high impact velocities, flow separation occurred on the slide shoulder resulting in a hydrodynamic impact crater. The measured wave profiles yielded information on the wave propagation and attenuation. The measured wave speed of the leading wave reaches the theoretical solitary wave celerity while the trailing waves are slower in nature. Attenuation functions of the leading wave crest amplitude, the wave length and the time period were obtained to study the wave behavior in the near field and far field regions. The measured wave data serves the validation and advancement of 3-dimensional numerical landslide tsunami and prediction models. © Springer Science + Business Media B.V. 2010.