Three-dimensional modelling of slope stability in heterogeneous montane forest ecosystems

Vegetation can play an important role in stabilizing soil against shallow landslides. Using a three-dimensional (3D) finite element method, we developed a model to study the impact of different management scenarios on slope stability in mountain forests. Ground truth data were obtained from a mixed forest ecosystem situated at an altitude of 1400m a.s.l. in the French Alps. Five scenarios representing the forest at different spatial and temporal stages of management were selected: [A] bare soil, [B] tree island (i.e. tree groups growing in clusters) on bare soil, [C] new gap (i.e. canopy free zones with little understorey) in homogeneous forest, [D] old gap (i.e. canopy free zones with abundant understorey) in homogeneous forest and [E] homogeneous forest. For scenarios [B], [C] and [D], the locations of the vegetated patch along the slope (top, centre and toe) were also tested, to determine if vegetation patterns influenced slope stability. As plant roots play a crucial role in reinforcing soil, we altered the 3D spatial distribution of root density in the model using real data. By calculating the factor of safety (FoS), i.e. a measure of the likelihood that the slope will fail, we show that slope morphology, including angle and soil depth, play an essential role in slope stability. Vegetation also exhibited a positive effect on slope stability, but the efficiency of this effect was significantly influenced by slope morphology and root distribution with regard to soil depth. In particular, if a layer of soil beneath the most superficial rooting zone contained few roots, slope integrity was compromised. Compared to bare soil, the FoS increase due to vegetation was only ≤0.2 (i.e. ≤15%), when deeper soil layers contained few or no roots. However, if the soil profile contained roots throughout, the FoS increase was >25% higher. We highlight the importance of taking into account spatial complexity and refining the output, i.e. FoS, during the modelling of slope stability, which can only be achieved through the use of 3D models.