Abstract
Rapid assessment of the distribution of earthquake-triggered landslides is an important component of effective disaster mitigation. The effort should be based on both seismic landslide susceptibility and the ground shaking intensity, which is usually measured by peak ground acceleration (PGA). In this paper, we address this issue by analyzing data from the Mw6.1 2014 Ludian, China earthquake. The Newmark method of rigid-block modeling was applied to calculate the critical acceleration of slopes in the study area, which serve as measurement of slope stability under seismic load. The assessment of earthquake-triggered landslide hazard was conducted by comparing these critical accelerations with the distribution of known PGA values. The study area was classified into zones of five levels of landslide hazard: high, moderate high, moderate, light, and very light. Comparison shows that the resulting landslide hazard zones agree with the actual distribution of earthquake-triggered landslides. Nearly 70% of landslides are located in areas of high and moderately high hazard, which occupy only 17% of the study region. This paper demonstrates that using PGA, combined with the analysis of seismic landslide susceptibility, allows a reliable assessment of earthquake-triggered landslides hazards. This easy-operation map** method is expected to be helpful in emergency preparedness planning, as well as in seismic landslide hazard zoning.
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References
Ambraseys NN, Sarma SK (1967) The response of earth dams to strong earthquakes. Geotechnique 17:181–213
Bandini V, Biondi G, Cascone E, Rampello S (2015) A GLE-based model for seismic displacement analysis of slopes including strength degradation and geometry rearrangement. Soil Dyn Earthq Eng 71:128–142
Biondi G, Condorelli A, Maugeri M, Mussumeci G (2004) Earthquake-triggered landslides hazard in the Catania area. Manag Inf Syst 9:115–130
Bishop AW, Morgenstern N (1960) Stability coefficient for each slopes. Geotechnique 10:129–150
Bommer JJ, Carlos E, Rodríguez CR (2002) Earthquake-induced landslides in Central America. Eng Geol 63:189–220
Cetin KO, Isik N, Unutmaz B (2004) Seismically induced landslide at Degirmendere Nose, Izmit Bay during Kocaeli (Izmit)-Turkey earthquake. Soil Dyn Earthq Eng 24(3):189–197
Chang CJ, Chen WF, Yan JTP (1984) Seismic displacements in slopes by limit analysis. J Geotech Eng 110(7):850–874
Chang ZF, Chen XL, An XW, Cui JW (2016) Contributing factors to the failure of an unusually large landslide triggered by the 2014 Ludian, Yunnan, China, Ms=6.5 earthquake. Nat Hazards Earth Syst Sci 16:497–507
Chen XL, Liu CG, Yu L, Lin CX (2014) Critical acceleration as a criterion in seismic landslide susceptibility assessment. Geomorphology 217:15–22
Chen XL, Zhou Q, Liu CG (2015) Distribution pattern of coseismic landslides triggered by the 2014 Ludian, Yunnan, China Mw6.1 earthquake: special controlling conditions of local topography. Landslides 12(6):1159–1168
China Geological Survey (CGS) (2001) Regional geological map of Sichuan Province (1:200,000), Geological Press, Bei**g
Dai FC, Xu C, Yao X, Xu L, Tu XB, Gong QM (2011) Spatial distribution of landslides triggered by the 2008 Ms 8.0 Wenchuan earthquake. China. J Asian Earth Sci 40(4):883–895
Dreyfus D, Rathje EM, Jibson RW (2013) The influence of different simplified sliding-block models and input parameters on regional predictions of seismic landslides triggered by the Northridge earthquake. Eng Geol 163:41–54
Gallen SF, Clark MK, Godt JW, Roback K, Niemi NA (2016) Application and evaluation of a rapid response earthquake-triggered landslide model to the 25 April 2015 Mw 7.8 Gorkha earthquake, Nepal. Tectonophysics. https://doi.org/10.1016/j.tecto.2016.10.031
General Administration of Quality Supervision, Inspection and Quarantine of the People’s Republic of China, Ministry of construction of the People’s Republic of China (1995) Standard for engineering classification of rock masses. Standards Press of China, Bei**g (in Chinese)
Gorum T, Fan X, van Westen CJ, Huang RQ, Xu Q, Tang C, Wang G (2011) Distribution pattern of earthquake-induced landslides triggered by the 12 May 2008 Wenchuan earthquake. Geomorphology 133(3):152–167
Guo XH, Wei DP, Zhang KL (2013) GPS-constrained estimate method of present-day slip rate along major faults of Sichuan-Yunnan region in China. J UCAS 30(1):74–82 (in Chinese)
Harp EL, Jibson RW (1996) Landslides triggered by the 1994 Northridge, California earthquake. Bull Seismol Soc Am 86(1B):s319–s332
Hermanns RL, Strecker MR (1999) Structural and lithological controls on large Quaternary rock avalanches (sturzstroms) in arid northwestern Argentina. Geol Soc Am Bull 111:934–948
Huang RQ (2015) Understanding the mechanism of large-scale landslides. In: Lollino G et al (eds) Engineering geology for society and territory – vol 2. Springer, Basel
Idriss IM (1985) Evaluating seismic risk in engineering practice. Proc. XI international conference on soil mechanics and foundation engineering, San Francisco. Balkema, Rotterdam, pp 265–320
Jibson RW (2007) Regression models for estimating coseismic landslide displacement. Eng Geol 91:209–218
Jibson RW (2011) Methods for assessing the stability of slopes during earthquakes—a retrospective. Eng Geol 122:43–50
Jibson RW, Harp EL (2012) Extraordinary distance limits of landslides triggered by the 2011 mineral, Virginia, earthquake. Bull Seismol Soc Am 102(6):2368–2377
Jibson RW, Harp EL, Michael JA (2000) A method for producing digital probabilistic seismic landslide. Eng Geol 58:271–289
Jibson RW, Harp EL, Schulz W, Keefer DK (2004) Landslides triggered by the 2002 M-7.9 Denali Fault, Alaska, earthquake and the inferred nature of the strong shaking. Earthq Spectra 20, 669–691
Jibson RW, Harp EL, Schulz W, Keefer DK (2006) Large rock avalanches triggered by the M-7.9 Denali Fault, Alaska, earthquake of 3 November 2002. Eng Geol 83, 144–160
Katz O, Morgan JK, Aharonov E, Dugan B (2014) Controls on the size and geometry of landslides: insights from discrete element numerical simulations. Geomorphology 220:104–113
Keefer DK (1984) Landslides caused by earthquakes. Geol Soc Am Bull 95(4):406–421
Keefer DK, Manson MW (1998) Regional distribution and characteristics of landslides generated by the earthquake. In: Keefer, D.K. (Ed.), The Loma Prieta, California, Earthquake of October 17, 1989 - Landslides. U.S.Geological Survey Professional Paper 1551, pp. C7 - C32
Khazai B, Sitar N (2003) Evaluation of factors controlling earthquake-induced landslides caused by Chi-Chi earthquake and comparison with the Northridge and Loma Prieta events. Eng Geol 71:79–95
Lee HS, Park YJ, Cho TF, You KH (2001) Influence of asperity degradation on the mechanical behavior of rough rock joints under cyclic shear loading. Int J Rock Mech Min Sci 38(7):967–980
Legg M, Slosson J, Eguchi R (1982) Seismic hazard for lifelines vulnerability analyses. Proc. 3rd int. conf. on microzonation, Seattle, Washington
Li XJ, Zhou ZH, Huang M et al (2008) Preliminary analysis of strong-motion recordings from the magnitude 8.0 Wenchuan, China, earthquake of 12 May 2008. Seismol Res Lett 79(6):844–854
Makdisi FI, Seed HB (1979) Simplified procedure for evaluating embankment response. J Geotech Eng Div ASCE 105:1427–1434
Mankelow JM, Murphy W (1993) Using GIS in the probabilistic assessment of earthquake triggered landslide hazards. J Earthq Eng 2(4):593–623
Meunier P, Hovius N, Haines JA (2007) Regional patterns of earthquake-triggered landslides and their relation to ground motion. Geophys Res Lett 34:L20408. https://doi.org/10.1029/2007GL031337
Nakamura S, Wakai A, Umemura J, Sugimoto H, Takeshi T (2014) Earthquake-induced landslides: distribution, motion and mechanisms. Soils Found 54(4):544–559
Newmark NM (1965) Effects of earthquakes on dams and embankments. Geotechnique 15:139–160
Presti LD, Marchetti D, Fontana T (2009) Pseudo-static vs pseudo-dynamic slope stability analysis in seismic areas of the northern Apennines (Italy). Rivista Italiana di Geotecnica 4:13–29
Qi SW, Xu Q, Lan HX, Zhang B, Liu JY (2010) Spatial distribution analysis of landslides triggered by 2008.5.12 Wenchuan earthquake, China. Eng Geol 116:95–108
Rodrígueza CE, Bommerb JJ, Chandlerb RJ (1999) Earthquake-induced landslides: 1980–1997. Soil Dyn Earthq Eng 18:325–346
Sato HP, Hasegawa H, Fujiwara S, Tobita M, Koarai M, Une H, Iwahashi J (2007) Interpretation of landslide distribution triggered by the 2005 Northern Pakistan earthquake using SPOT 5 imagery. Landslides 4(2):113–122
Seed HB (1979) Considerations in the earthquake-resistant design of earth and rockfill dams. Geotechnique 29(3):215–263
Shinoda M, Miyata Y (2017) Regional landslide susceptibility following the Mid Niigata prefecture earthquake in 2004 with Newmarks’S sliding block analysis. Landslides. https://doi.org/10.1007/s10346-017-0833-8
Song FM, Li RC, Xu XW (2002) Preliminary results of the investigation of Paleo-earthquake along the Daliangshan fault zone, Sichuan province, China. Seismol Geol 24(1):27–34 (in Chinese)
Wakai A, Ugai K, Onoue A, Kuroda S, Higuchi K (2010) Numerical modeling of an earthquake-induced landslide considering the strain-softening characteristics at the bedding plane. Soils Found 50(4):533–545
Wang WN, Wu HL, Nakamura H, Wu SC, Ouyang S, Yu MF (2003) Mass movements caused by recent tectonic activity: the 1999 Chi-chi earthquake in central Taiwan. Island Arc 12(4):325–334
Wang HB, Sassa K, Xu WY (2007) Analysis of a spatial distribution of landslides triggered by the 2004 Chuetsu earthquakes of Niigata Prefecture, Japan. Nat Hazards 41:43–60
Wang XY, Nie GZ, Wang S (2011) Ground motion acceleration criterion for judging landslide induced by the 2008 Wenchuan earthquake. Acta Seismol Sin 33(1):82–90
Xu C, Xu XW, Shen LL, Dou S, Wu SE, Tian YY, Li X (2014) Inventoy of landslides triggered by the 2014 Ms6.5 Ludian earthquake and its implication on several earthquake parameters. Seismol Geol 36(4):1186–1203 (in Chinese)
Yin YP, Wang FW, Sun P (2009) Landslide hazards triggered by the 2008 Wenchuan earthquake, Sichuan, China. Landslides 6(2):139–152
Zhang PZ, Deng QD, Zhang GM, Ma J, Gan WJ, Min W, Mao FY, Wang Q (2003) Active tectonic blocks and strong earthquakes in continental China. Sci China (Ser D) 33(Suppl):12–20 (in Chinese)
Acknowledgements
This work was supported by the National Natural Science Foundation of China (Grant No. 41572194) and the Basic Scientific Fund of the Institute of Geology, China Earthquake Administration (Grant No. IGCEA1604). Deep thanks should presented to the editor and reviewers, their constructive suggestions improve the work!
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Chen, X., Liu, C. & Wang, M. A method for quick assessment of earthquake-triggered landslide hazards: a case study of the Mw6.1 2014 Ludian, China earthquake. Bull Eng Geol Environ 78, 2449–2458 (2019). https://doi.org/10.1007/s10064-018-1313-7
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DOI: https://doi.org/10.1007/s10064-018-1313-7