Chemical weathering and progressing alteration as possible controlling factors for creeping landslides

Chemical weathering and progressing alteration as possible controlling factors for creeping landslides

Landslides can behave as dynamic processes, which emerge from the complex interplay of tectonics, erosion, weathering and gravitational influences, triggered by various hydrological, mineralogical, biological and geotechnical factors. Integral studies to assess the mechanisms underlying landslide in...

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Bibliographic Details
Published in:The Science of the total environment Vol. 778; p. 146300
Main Authors: Baldermann, Andre, Dietzel, Martin, Reinprecht, Volker
Format: Journal Article
Language:English
Published: Netherlands Elsevier B.V 15-07-2021
Subjects:
Chemical weathering
Hydrochemistry
Landslide
Monitoring
Pelitic sediments
Soil chemistry
Soil chemistry
Landslide
Hydrochemistry
Chemical weathering
Monitoring
Pelitic sediments
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Summary:Landslides can behave as dynamic processes, which emerge from the complex interplay of tectonics, erosion, weathering and gravitational influences, triggered by various hydrological, mineralogical, biological and geotechnical factors. Integral studies to assess the mechanisms underlying landslide initiation and progression are mainly focussed on specific cases with high geohazard potential. The landslide near Stadtschlaining (Austria) represents a key study site to elucidate the impacts of pelitic sediment composition, weathering regime, alteration patterns and hydrochemistry on recurrent damage progression in the local infrastructure. Based on field work, soil-mechanical logging (Atterberg limits, undrained strength, friction angles), water chemistry (ICP-OES, IC, hydrochemical modeling), solid-phase characterization (XRD, XRF, SEM) and sorption experiments we establish a conceptual model for initiating and progressing of landslides: Infiltration of low mineralized meteoric water (EC: <200 μS/cm) in permeable limonitic gravels triggers chemical weathering of greenschist-derived detritus and promotes its transformation into kaolinite and smectite. The clayey strata (>50 wt% of clay minerals) create zones of mechanical and chemical weakness in the underground (~4–6 m below ground level), which are characterized by particle disintegration/delamination, slip bedding and deformations, and development of porous layers depicting water flow paths. Subsequent Na+ exchange for bivalent ions in the smectite interlayer delivered by percolating, highly mineralized water (EC: 1600–5100 μS/cm) is caused by de-icing salt and fertilizer applications during winter and late summer, and yield in i) decohesion and physical breakdown of the particle aggregates and ii) swelling of the clay matrix in early spring and autumn. These processes reduce the shear strength of the pelitic sediments, resulting in failure and initiation of landslides (deformation: ~500 mm within a month) and subsequent steady creeping motion (deformation: ~100 mm in 6 months). Customized engineered solutions to prevent landslides in this area are presented, which can be conveyed to analogous landslide-affected areas worldwide. [Display omitted] •Conceptual model for seasonal variation of landslide movement in pelitic sediments•Strata-bound mineral-fluid interface processes chemically weaken the slide masses.•Clay mineral neo-formation and ion exchange create preferred sliding planes.•Longitudinal drainage system prevents from landslides.
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ISSN:0048-9697
1879-1026
DOI:10.1016/j.scitotenv.2021.146300