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1. Landslide-driven drainage divide migration

   https://doi.org/10.1130/G39916.1  

   Dahlquist, Maxwell P.; West, A. Joshua; Li, Gen (February 2018, Geology)
2. Landslide susceptibility modeling by interpretable neural network

   https://doi.org/10.1038/s43247-023-00806-5  

   Youssef, K.; Shao, K.; Moon, S.; Bouchard, L.-S. (December 2023, Communications Earth & Environment)

   Abstract Landslides are notoriously difficult to predict because numerous spatially and temporally varying factors contribute to slope stability. Artificial neural networks (ANN) have been shown to improve prediction accuracy but are largely uninterpretable. Here we introduce an additive ANN optimization framework to assess landslide susceptibility, as well as dataset division and outcome interpretation techniques. We refer to our approach, which features full interpretability, high accuracy, high generalizability and low model complexity, as superposable neural network (SNN) optimization. We validate our approach by training models on landslide inventories from three different easternmost Himalaya regions. Our SNN outperformed physically-based and statistical models and achieved similar performance to state-of-the-art deep neural networks. The SNN models found the product of slope and precipitation and hillslope aspect to be important primary contributors to high landslide susceptibility, which highlights the importance of strong slope-climate couplings, along with microclimates, on landslide occurrences. 

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3. Topographic stress control on bedrock landslide size

   https://doi.org/10.1038/s41561-021-00739-8  

   Li, Gen K.; Moon, Seulgi (May 2021, Nature Geoscience)

   null (Ed.)
4. Mixed Hydrometeorological Processes Explain Regional Landslide Potential

   https://doi.org/10.1029/2025GL115912  

   Li, Chuxuan; Handwerger, Alexander L; Horton, Daniel E (July 2025, Geophysical Research Letters)

   Abstract During December 2022–January 2023, nine atmospheric rivers (ARs) struck California consecutively, causing catastrophic flooding and 600+ landslides. The extensive footprints of landslide‐triggering storms and their diverse hydrometeorological forcings highlight the urgent need to incorporate regional‐scale hydrometeorology into landslide research. Here, using a meteorologically‐informed hydrologic model, we simulate the time‐evolving water budget during the nine‐AR event and identify hydrometeorological conditions that contributed to widespread landslide occurrences across California. Our analysis reveals that 89% of observed landslides occurred under excessively wet conditions, driven by precipitation exceeding the capacities of infiltration, storage, evapotranspiration, and soil drainage. Using K‐means clustering, we identify three distinct hydrometeorological pathways that increased landslide potential: intense precipitation‐induced runoff (∼32% of reported landslides), rain on pre‐wetted soils (∼53%), and snowmelt and soil ice thawing (∼15%). Our findings highlight the importance of constraining the compounding factors that influence slope stability over spatial scales consistent with landslide‐triggering weather systems. 

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5. Probabilistic seismic source inversion from regional landslide evidence

   https://doi.org/10.1007/s10346-021-01780-9  

   Rasanen, Ryan A.; Maurer, Brett W. (February 2022, Landslides)