Abstract
Assessment of rainfall-induced shallow slope failures is very important to reduce damages of infrastructures and lives of people living close to hazardous areas. Although the rainfall intensity-duration thresholds for initiation of slope failure (ID thresholds) based on the historical slope failure data is commonly used to assess slope failure, critical influence factors triggering shallow slope failures are often disregarded. Three sets of parametric study were therefore performed through finite element model to investigate the effect of saturated permeability of soil, slope angle and antecedent rainfall on instability of shallow slope. It is found that the hydrological mechanisms involving the rainfall induced shallow slope failure are either (1) the rising of water table mode or (2) the rainfall infiltration mode. The hydrological mode during the failure depends on the magnitude of rainfall intensity comparing with the infiltration capacity at soil saturation state. The rate of reduction in safety factor increases with an increasing the intensity of rainfall, only in a range of lower than the infiltration capacity at soil saturated state. As such the saturated permeability of the soil, which is equal to the infiltration capacity at soil saturated state, plays an important role in the shallow slope failure. The saturated permeability was found also to govern a range of applicability of the ID thresholds. If the rainfall intensity is not greater than the infiltration capacity at soil saturated state, the rainfall duration to failure (Trf) can be read from the ID thresholds. Slope angle and antecedent rainfall were found to play role on instability of the shallow slope. They control the initial stability of slope, which results in the different linear relationship of ID thresholds. In addition, the slope angle might accelerate the rate of rain water infiltration, and hence it reflects the slope of the ID thresholds
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References
Aleotti P (2004) A warning system for rainfall-induced shallow failures. Eng Geol 73(3–4):247–265
Bishop AW, Blight GE (1963) Some aspects of effective stress in saturated and partly saturated soils. Géotechnique 13(2):177–197
Bordoni M, Meisina C, Valentino R, Bittelli M, Chersich S (2015) Site-specific to local-scale shallow landslides triggering zones assessment using TRIGRS. Nat Hazards Earth Syst Sci 15(5):1025–1050
Brand EW (1984) State-of-the-art report of landslides in Southeast Asian. In: 4th international symposium on landslides, Toronto, Canada, vol 1, pp 377–384
Caine N (1980) The rainfall intensity-duration control of shallow landslides and debris flows. Geogr Ann Ser A-physical Geogr 62:23–27
Chien YC, Tien CC, Fan CY, Wen CY, Chun CT (2005) Rainfall duration and debrisflow initiated studies for real-time monitoring. Environ Geol 47:715–724
Corominas J (2000) Landslides and climate. Keynote lecture. In: Bromhead E, Dixon N, Ibsen ML (eds) Proceedings 8th international symposium on landslides, AA Balkema, Cardiff, vol 4, pp 1–33
Crosta GB, Frattini P (2001) Rainfall thresholds for triggering soil slips and debris flow. In: Mugnai A, Guzzetti F, Roth G (eds) Proceedings 2nd EGS Plinius conference on mediterranean storms, Siena, pp 463–487
Dahal RK, Hasegawa S, Nonomura A, Yamanaka M, Masuda T, Nishino K (2008) Failure characteristics of rainfall-induced shallow landslides in granitic terrains of Shikoku Island of Japan. Environ Geol 56(7):1295–1310
Godt JW, McKenna JP (2008) Numerical modeling of rainfall thresholds for shallow landsliding in the Seattle, Washington, area. Rev Eng Geol 20:121–136
Guzzetti F, Peruccacci S, Rossi M, Stark CP (2007) Rainfall thresholds for the initiation of landslides in central and southern Europe. Meteorol Atmos Phys 98:239–267
Hamdhan IN, Schweiger HF (2013) Finite element method-based analysis of an unsaturated soil slope subjected to rainfall infiltration. Int J Geomech 13(5):653–658
Jotisankasa A, Mairaing W (2010) Suction-monitored direct shear testing of residual soils from landslide-prone areas. J Geotech Geoenvironmental Eng 136(3):533–537
Jotisankasa A, Vathananukij H (2008) Investigation of soil moisture characteristics of landslide-prone slopes in Thailand. In: Proceeding of international conference on management of landslide Hazard in the Asia-Pacific Region, Sendai Japan, pp 1–12
Keefer DK, Wilson RC, Mark RK, Brabb EE, Brown WM-I, Ellen SD, Harp EL, Wieczorek GF, Alger CS, Zatkin RS (1987) Real-time landslide warning during heavy rainfall. Science 238:921–925
Mualem Y (1976) A new model predicting the hydraulic conductivity of unsaturated porous media. Water Resour Res 12:513–522
Oh S, Lu N (2015) Slope stability analysis under unsaturated conditions: case studies of rainfall-induced failure of cut slopes. Eng Geol 184:96–103
Rahardjo H, Li XW, Toll DG, Leong EC (2001) The effect of antecedent rainfall on slope stability. Geotech Geol Eng 19:371–399
Rahardjo H, Ong TH, Rezaur RB, Leong EC (2007) Factors controlling instability of homogeneous soil slopes under rainfall. J Geotech Geoenvironmental Eng 133(12):1532–1543
Rahardjo H, Nio AS, Leong EC, Song NY (2010) Effects of groundwater table position and soil properties on stability of slope during rainfall. J Geotech Geoenvironmental Eng 136(11):1555–1564
Rahimi A, Rahardjo H, Leong E-C (2010) Effect of hydraulic properties of soil on rainfall-induced slope failure. Eng Geol 114(3–4):135–143
Rahimi A, Rahardjo H, Leong EC (2011) Effect of antecedent rainfall patterns on rainfall-induced slope failure. J Geotech Geoenvironmental Eng 137(5):483–491
Sirangelo B, Braca G (2004) Identification of hazard conditions for mudflow occurrence by hydrological model. Application of FLaIR model to Sarno warning system. Eng Geol 73:267–276
Sirangelo B, Versace P, De Luca DL (2007) Rainfall nowcasting by at site stochastic model PRAISE. Hydrol Earth Syst Sci 11:1341–1351
van Genuchten MT (1980) A closed-form equation for predicting the hydraulic conductivity of unsaturated soil. Soil Sci Soc Am J 44:615–628
Versace P, Sirangelo B, Capparelli G (2003) Forewarning model of landslides triggered by rainfall. 3rd international conference on debris-flow hazards mitigation: mechanics, prediction and assessment, Davos, Switzerland, vol 2, pp 1233–1244
Vieira BC, Fernandes NF, Filho OA (2010) Shallow landslide prediction in the Serra do Mar, São Paulo, Brazil. Nat Hazards Earth Syst Sci 10(9):1829–1837
Wilson RC, Mark RK, Barbato G (1993) Operation of a real-time warning system for debris flows in the San Francisco Bay area, California. International conference hydraulics division, ASCE 2, pp 1908–1913
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Teerametatiparat, T., Chinkulkijniwat, A., Yubonchit, S. (2017). Influences of Rainfall on Shallow Slope Failures. In: Mikoš, M., Casagli, N., Yin, Y., Sassa, K. (eds) Advancing Culture of Living with Landslides. WLF 2017. Springer, Cham. https://doi.org/10.1007/978-3-319-53485-5_22
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