An increase in soil pore water pressure is the typical trigger for the majority of landslides caused by rainfall.Atmospheric river storms, common to the west coast of North America during the winter season, can deliver landslide-triggering rainfall resulting in severe impacts to coastal communities.Using a network of hydrologic monitoring stations situated within landslide-prone terrain in the San Francisco Bay area of California (United States), we assess the meteorologic conditions and resulting hydrologic and landslide response resulting from eight consecutive storm events that caused thousands of shallow landslides during the winter of 2022-2023.We find disparate hydrological responses and resultant degrees of observed landsliding ranging from <1 landslide/km 2 to 18 landslides/km 2 at the monitoring sites that reflect the interplay and differences between rainfall delivery, subsurface hydrological characteristics, and geotechnical properties at each site.Antecedent soil moisture from both early season rainfall and the first storm in the sequence played a critical role in setting up some hillslopes for failure.Subsequent storms then generated elevated pore water pressures for several hours with associated landsliding.However, we find that the occurrence of widespread landsliding required not only sufficient pore water pressure magnitude in susceptible hillslopes, but also full and prolonged effective soil saturation throughout hillslope profiles.Landslides may still occur at lower values and durations of effective saturation but are likely to be less extensive regionally.We present these findings within the context of research directions and improvements to landslide early warning systems first suggested by researchers 40 years ago.
Collins et al. (Tue,) studied this question.