Abstract
AbstractLandslides are common disturbances in forests around the world, and a major threat to human life and property. Landslides are likely to become more common in many areas as storms intensify. Forest vegetation can improve hillslope stability via long, deep rooting across and through failure planes. In the U.S. Rocky Mountains, landslides are infrequent but widespread when they do occur. They are also extremely understudied, with little known about the basic vegetation recovery processes and rates of establishment which restabilize hills. This study presents the first evaluation of post‐landslide vegetation recovery on forested landslides in the southern Rocky Mountains. Six years after a major landslide event, the surveyed sites have very little regeneration in initiation zones, even when controlling for soil coverage. Soils are shallower and less nitrogen rich in initiation zones as well. Rooting depth was similar between functional groups regardless of position on the slide, but deep‐rooting trees are much less common in initiation zones. A lack of post‐disturbance tree regeneration in these lower elevation, warm/dry settings, common across a variety of disturbance types, suggests that complete tree restabilization of these hillslopes is likely to be a slow or non‐existent, especially as the climate warms. Replacement by grasses would protect against shallow instabilities but not the deeper mass movement events which threaten life and property.
Highlights
Disturbances are ubiquitous in the world’s forests (Hansen et al 2013)
Within landscapes exposed to landslides, >50% can be impacted in any given event (Walker and Shiels 2012)
We investigated post-landslide forest recovery in a dry montane system
Summary
Disturbances are ubiquitous in the world’s forests (Hansen et al 2013). Agents such as wildfires, windstorms, and landslides regularly cause widespread mortality, with their relative importance depending on biome, location, topographic setting, human exposure, and site history. In steep forested terrain, mass movements (landslides, debris flows) are not uncommon over long timescales (Walker and Shiels 2012). Landslides and debris flows (hereafter denoted as “slides”) occur wherever soil overlays steep topography such that triggering events, such as heavy rainstorms, can reduce factor resisting gravity, like soil cohesion and friction with the underlying bedrock. Within landscapes exposed to landslides, >50% can be impacted in any given event (Walker and Shiels 2012)
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