Integrating initial shear modulus (G₀) derived from seismic data with long-term deep-seated inclinometer displacements at selected Polish Outer Carpathian flysch landslides
DOI:
https://doi.org/10.24425/agp.2026.158199Abstract
Landslide investigations have increasingly focused on integrating geotechnical monitoring with geophysical methods to improve the characterisation of internal slope processes and deformation mechanisms. This study presents a combined analysis of long-term deep-seated inclinometer displacements and seismic measurements conducted at selected landslides located in the Polish Outer Carpathian flysch. Two instrumented landslides were investigated using multi-year inclinometer monitoring covering periods of approximately 4–9 years, together with seismic refraction surveys. The initial shear modulus at very small strains (G₀) was derived from shear-wave velocity (Vₛ) and bulk density values calibrated using laboratory measurements, providing a quantitative indicator of subsurface stiffness variability. Vertical distributions of G₀ were compared with cumulative deep-seated displacements recorded by inclinometers, which allowed the identification of kinematic-mechanical deformation zones within the landslide bodies and their relationship to lithological and structural conditions. The results indicate that the integration of geophysical stiffness parameters with long-term inclinometer monitoring enables a more detailed delineation of zones characterised by different deformation behaviour. This approach supports the interpretation of deep-seated landslide structure in flysch terrains and provides a basis for further development of site-specific slope stability assessment and monitoring strategies.
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