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- Title
Environmental drivers of paraglacial time duration and intensity for scree slopes dynamics in forested environments.
- Authors
Germain, Daniel; Stabile‐Caillé, Ludwig
- Abstract
The highly fissile lithology of the rockwalls and the diversity of mass‐wasting processes provide a specific character to the active talus slopes of the northern Gaspé Peninsula since deglaciation. At a regional scale, the geology of the rockwalls, the patterns and modalities of deglaciation and the evolution towards a cold temperate morphoclimatic regime in a maritime context still influence the geomorphological dynamics of scree slopes today. At a local scale, the south–north orientation of the main coastal valleys influences insolation and exposure to prevailing winds, which in turn influence the snow cover regime and the occurrence of freeze–thaw cycles. The statistical analyses carried out from the mapping of 43 talus slopes and their geometric variables allowed the identification of significant environmental factors for the characterization of the dominant geomorphic processes: snow avalanches, frost‐coasted clast flows, debris flows and rockfalls. Slope aspect appears to be a key parameter in the nature of the processes acting on the talus slopes. East‐ and north‐facing talus slopes are generally covered by a significant snowpack in winter and the dominant processes are snow avalanches and debris flows. West‐ and south‐facing talus slopes face prevailing winds and insolation and are subject to frost‐coated clast flows, the main driver for forest regression, and rockfalls. However, the evolution of scree slopes in forested environments remains extremely complex due to the multiscale components that affect their evolution in the short, medium and long term.
- Subjects
GASPE Peninsula (Quebec); TALUS (Geology); FORESTED wetlands; ROCKFALL; DEBRIS avalanches; SNOW cover; FREEZE-thaw cycles; GEOLOGY
- Publication
Earth Surface Processes & Landforms, 2023, Vol 48, Issue 6, p1119
- ISSN
0197-9337
- Publication type
Article
- DOI
10.1002/esp.5538