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1. Harmonic and recorded ground motion simulations of failure in bonded particle models of massive rock slopes:Subtitle

   https://doi.org/10.17603/ds2-p9mf-gc56  

   Arnold, Lorne; Wartman, Joseph; MacLaughlin, Mary (January 2024, Designsafe-CI)

   This study investigates seismically-induced failure mechanisms in massive rock slopes using the bonded particle model. The data from this study can be used to track seismically-induced stresses in steep slope geometries leading up to failure initiation. The data can also be used to study the propagation of damage initiated by these failure mechanisms and track the development of mass movement enabled by the seismically-induced damage. The bonded particle model data includes the motion time-histories of an array of monitoring particles in the slope, the stress tensors of representative volume elements throughout loading, and the full model geometry, which can be used to reproduce the discrete element model. 

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2. The influence of clay content on submarine slope failure: insights from laboratory experiments and numerical models

   https://doi.org/10.1144/SP500-2019-186  

   Silver, M. M.; Dugan, B. (January 2020, Geological Society, London, Special Publications)

   Submarine slope failures pose risks to coastlines because they can damage infrastructure and generate tsunamis. Passive margin slope failures represent the largest mass failures on Earth, yet we know little about their dynamics. While numerous studies characterize the lithology, structure, seismic attributes and geometry of failure deposits, we lack direct observations of failure evolution. Thus, we lack insight into the relationships between initial conditions, slope failure initiation and evolution, and final deposits. To investigate submarine slope failure dynamics in relation to initial conditions and to observe failure processes we performed physical experiments in a benchtop flume and produced numerical models. Submarine slope failures were induced under controlled pore pressure within sand–clay mixtures (0–5 wt% clay). Increased clay content corresponded to increased cohesion and pore pressure required for failure. Subsurface fractures and tensile cracks were only generated in experiments containing clay. Falling head tests showed a log-linear relation between hydraulic conductivity and clay content, which we used in our numerical models. Models of our experiments effectively simulate overpressure (pressure in excess of hydrostatic) and failure potential for (non)cohesive sediment mixtures. Overall our work shows the importance of clay in reducing permeability and increasing cohesion to create different failure modes due to overpressure. 

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3. Coevolution of Rock Slope Instability Damage and Resonance Frequencies From Distinct‐Element Modeling

   https://doi.org/10.1029/2023JF007305  

   Jensen, E. K.; Moore, J. R. (November 2023, Journal of Geophysical Research: Earth Surface)

   Abstract Ambient vibration measurements can detect resonance frequency changes related to rock slope instability damage or boundary condition changes during progressive failure. However, the impact of slope kinematics on resonance changes and the expected form and sensitivity of frequency evolution during destabilization require clarification to improve the implementation of this technique across diverse settings. Since instrumented rock slope failures are rare, numerical modeling is needed to study the anticipated spectral response from in situ monitoring. We used 2D distinct‐element modeling to evaluate the sensitivity and evolution of rock slope resonance behavior for slab toppling, flexural toppling, and planar sliding instabilities during progressive failure. Model simulations revealed that fundamental resonance frequency decreases between 20% and 60% with changes correlated with increasing length of open joints. Changes to higher‐order frequencies associated with landslide sub‐volumes were also detectable for cases with multiple fracture networks. Resonance behavior was most pronounced for failures dominated by steeply dipping open tension cracks, that is, flexural and slab toppling. Additionally, amplification patterns across the slope varied for the flexural toppling and sliding cases, providing potential new information with which to characterize landslide failure mechanisms using ambient vibration array measurements. Our results demonstrate landslide characteristics well‐suited for in situ ambient resonance monitoring and provide new data describing the anticipated changes in resonance frequencies during progressive rock slope failure. 

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4. Moment load impact on resistance of foundation soils to seismic loads

   https://doi.org/10.1016/j.compgeo.2024.106405  

   Kim, Yeon Sam; Michalowski, Radoslaw L (July 2024, Computers and Geotechnics)

   The subject of the influence of the seismic excitation on limit loads of footings is revisited, with emphasis on the moment load. The kinematic approach of limit analysis is employed using two collapse mechanisms allowing footing rotation and one with pure translational kinematics. Two of the mechanisms have novel elements, not presented in earlier literature. The paper is focused on the resistance of the soil weight to activating a mechanism of failure, which can be best cast in terms of the seismic bearing capacity factor Nsγ . Seismic loads from the superstructure are interpreted as those caused by a three-mass model, each mass with its own seismic coefficient. The notion of generalized loads is used to present the yield locus for the footing in terms of the gravity force, horizontal force, and moment. The non-symmetric components of the load are interpreted as seismically activated. The approach yields a strict upper bound to the magnitude of the load vector causing failure. Of the three failure mechanisms considered none yields the best (least) solutions for all combinations of loads. In general, the two mechanisms with footing rotation perform better for large moments, whereas the translational mechanism yields better results when moments are small. However, even in the absence of a moment load, the rotational mechanism can yield better estimates of the limit load when the seismic coefficient is relatively large. 

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5. Post‐Wildfire Stability of Unsaturated Hillslopes Against Rainfall‐Triggered Landslides

   https://doi.org/10.1029/2022EF003213  

   Abdollahi, Masood; Vahedifard, Farshid; Tracy, Fred T. (March 2023, Earth's Future)

   Abstract Wildfire records demonstrate worsening patterns coupled with the spread to higher altitudes in several regions, raising the risk of post‐wildfire ground failures. This study investigates the post‐wildfire stability of unsaturated hillslopes against rainfall‐triggered shallow landslides. We developed a new physics‐based analytical framework incorporating wildfire‐induced changes in soil properties and near‐surface processes affecting the hillslope stability. A coupled hydromechanical infiltration model is integrated into an infinite slope stability analysis to simulate temporal changes in the depth profiles of soil water content, pressure head, and the resulting factor of safety (F.S.) of a vegetated slope. We consider the antecedent conditions of soil and vegetation cover, including the recovery phase after the fire, wildfire‐induced alterations in transpiration, and time‐varying infiltration rates. The model is verified against numerical simulations and employed in parametric studies evaluating the effects of wildfire severity and rainfall intensity‐duration. For the cases examined, it was shown that wildfire could reduce the F.S. of slopes by 25%. As a case study, the model successfully captured shallow rainfall‐triggered landslides that occurred in the Las Lomas watershed in California, USA, in 2019, 3 years after the Fish Fire burned the area. The proposed model uses measurable hillslope and wildfire characteristics and can be employed to evaluate the risk of shallow landslides in wildfire‐prone areas. 

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