Abstract: Understanding the destabilization mechanisms in bedrock and overburden layer slopes influenced by both rainfall and seismic activity is of significant engineering importance. A series of large-scale shaking table model tests was conducted to investigate the instability evolution in bedrock and overburden layer slopes after rainfall and seismic events. This study identifies and assesses degradation modes based on spatial deformation characteristics and slope surface displacement patterns. It integrates soil stress-strain behavior, permeability characteristics, seismic stress distribution, and slope deformation characteristics to explore the deformation mechanisms in bedrock and overburden layer slopes after rainfall and seismic events. The results indicate: (1) During rainfall, saturation significantly increases at the slope crest and toe, leading to notable strength degradation without significant overall deformation. However, during seismic activity, the slope crest initially experiences sliding failure, evolving into multi-stage sliding instability. (2) Macroscopic damage occurs suddenly, and the spatial strain distribution within the slope better identifies the evolution of plastic zone expansion, penetration, and instability. (3) The slope’s instability evolution pattern, analyzed by residual displacement ratios, aligns well with the spatial strain evolution within the soil, showing greater sensitivity in identifying the slope’s damage state compared to cumulative displacement. (4) Changes in moisture content affect soil mechanical properties, and post-rainfall infiltration field distribution affects the slope’s overall mechanical behavior and the transmission and spatial distribution of seismic stress. Soil mechanical properties and dynamic stress spatial characteristics determine the slope’s failure modes.

Key words: bedrock and overburden layer slope, shaking table experiments, rainfall, deformation, spatial characteristics, deterioration mechanism, stability assessment