Development of a universal landslide hazard potential model for mudrock slopes: fuzzy logic and molecular-level modelling approaches

Development of a universal landslide hazard potential model for mudrock slopes: fuzzy logic and molecular-level modelling approaches

The reduction in shear strength due to moisture-induced swelling and the subsequent slaking of mudrocks is one of the leading causes of landslide hazards in mountainous regions. In practice, empirical/semiempirical approaches that have been adopted to identify this hazard are mostly based on macrole...

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Bibliographic Details
Published in:Natural hazards (Dordrecht) Vol. 116; no. 3; pp. 3583 - 3615
Main Authors: ur-Rehman, Habib, Abduljauwad, Sahel N., Naeemuddin, Muhammad
Format: Journal Article
Language:English
Published: Dordrecht Springer Netherlands 01-04-2023
Springer Nature B.V
Subjects:
Cation exchange
Cation exchanging
Cations
Cementation
Civil Engineering
Coupling (molecular)
Earth and Environmental Science
Earth Sciences
Environmental Management
Exchange capacity
Fuzzy logic
Geological hazards
Geophysics/Geodesy
Geotechnical Engineering & Applied Earth Sciences
Hydrogeology
Landslides
Landslides & mudslides
Mechanics
Mineralogy
Modelling
Moisture content
Moisture effects
Molecular dynamics
Monte Carlo simulation
Mountain regions
Natural Hazards
Original Paper
Predictions
Shear strength
Slaking
Slopes
Statistical methods
Swelling
Water content
Mudrocks
Fuzzy logic
Landslide hazard potential
Molecular-level simulations
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Summary:The reduction in shear strength due to moisture-induced swelling and the subsequent slaking of mudrocks is one of the leading causes of landslide hazards in mountainous regions. In practice, empirical/semiempirical approaches that have been adopted to identify this hazard are mostly based on macrolevel factors. However, those do not comprehensively consider the microlevel factors that contribute to the complex swelling/slaking process. Therefore, this study developed a comprehensive fuzzy logic-based model, which includes both the macrolevel landslide contributing factors and the microlevel factors, such as mineralogy, cementation, cation exchange capacity, in situ moisture content, density, and stress state. The model was developed from molecular simulations of swelling, and the subsequent slaking processes were identified using Monte Carlo simulations, molecular mechanics, and molecular dynamics. The results of the microlevel model are incorporated into the fuzzy logic model to create a universal landslide hazard potential model for mudrock slopes. The microlevel behaviour is incorporated in the coupled model via the cohesive energy density parameter for the mudrocks. The final coupled model was verified via the accurate prediction of the landslides and by comparing the predicted terminal water content with the water content of the mudrock samples collected from the actual landslides.
ISSN:0921-030X
1573-0840
DOI:10.1007/s11069-023-05826-0