Abstract
Field investigations and aerial photography after the earthquake of May 12, 2008 show a large number of geo-hazards in the zone of extreme earthquake effects. In particular, landslides and debris flows, the geo-hazards that most threaten post-disaster reconstruction, are widely distributed. We describe the characteristics of these geo-hazards in Beichuan County using high-resolution remote sensing of landslide distribution, and the relationships between the area and volume of landslides and the peak-discharges of debris flows both pre- and post-earthquake. The results show: 1) The concentration (defined as the number of landslide sources per unit area: Lc) of earthquaketriggered landslides is inversely correlated with distance from the earthquake (D F) fault. The relationship is described by the following equation: Lc = 3.2264exp(−0.0831D F) (R 2 = 0.9246); 2) 87 % of the earthquake-triggered landslides were less than 15×104 m2 in area, and these accounted only for 50% of the total area; 84% of the landslide volumes were less than 60×104 m3, and these accounted only for 50% of the total volume. The probability densities of the area and volume distributions are correlated: landslide abundance increases with landslide area and volume up to maximum values of 5 × 104 m2 and 30 × 104 m3, respectively, and then decreases exponentially. 3) The area (AL) and volume (VL) of earthquake-triggered landslides are correlated as described with the following equation: VL=6.5138AL1.0227 (R 2 = 0.9131); 4) Characteristics of the debris flows changed after the earthquake because of the large amount of landslide material deposited in the gullies. Consequently, debris flow peak-discharge increased following the earthquake as described with the following equation: Vpost = 0.8421Vpre1.0972 (R 2 = 0.9821) (Vpre is the peak discharge of pre-earthquake flows and the Vpost is the peak discharge of post-earthquake flows). We obtained the distribution of the landslides based on the above analyses, as well as the magnitude of both the landslides and the post-earthquake debris flows. The results can be useful for guiding post-disaster reconstruction and recovery efforts, and for the future mitigation of these geo-hazards. However, the equations presented are not recommended for use in site-specific designs. Rather, we recommend their use for mapping regional seismic landslide hazards or for the preliminary, rapid screening of sites.
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References
Crowley, J.K., Hubbard, B.E. and Mars, J.C. 2003. Analysis of potential debris flow source areas on Mount Shasta,California, by using airborne and satellite remote sensing data. Remote Sensing of Environment 87:345–358.
CUI, P., WEI, F.Q., HE, S.M. et al. 2008. Geo-hazards and countermeasures in 5.12 Wenchuan Earthquake area. Bulletin of Chinese Academy of Sciences 23(4):317–323.
CUI, P., CHEN, X.Q., ZHU, Y.Y. et al. 2009a. The Wenchuan Earthquake (May 12, 2008), Sichuan Province, China, and resulting geohazards. Natural Hazards. DOI: 10.1007/s11069-009-9392-1. (In pressing).
CUI, P., ZHU, Y.Y., HAN, Y.S. et al. 2009b. The 12 May Wenchuan earthquake-induced landslide lakes: distribution and preliminary risk evaluation. Landslides 6:209–223. DOI: 10.1007/s10346-009-0160-9.
FEI, X.J. and SU, A.P. 2004. Movement mechanism and disaster control for debris flow. Beijing, China: Press of Univ. Tsinghua.
García-Rodríguez, M.J., Malpica, J.A., Benito, B. et al. 2008. Susceptibility assessment of earthquake-triggered landslides in El Salvador using logistic regression. Geomorphology 95:172–191.
Guzzetti, F., Ardizzone, F., Cardinali, M. et al. 2009. Landslide volumes and landslide mobilization rates in Umbria, central Italy. Earth and Planetary cience Letters 279:222–229.
Guzzetti, F., Ardizzone, F., Cardinali, M. et al. 2008. Distribution of landslides in the Upper Tiber River basin, central Italy. Geomorphology 96:105–122
Guzzetti, F., Reichenbach, P., Cardinali, M. et al. 2005. Probabilistic landslide hazard assessment at the basin scale. Geomorphology 72:272–299
Imaizumi, F., Sidle, R.C. et al. 2007. Linkage of sediment supply and transport processes in Miyagawa Dam catchment, Japan. Journal Geophysical Research 112: F03012. DOI: 10.1029/2006JF000495.
Imaizumi, F., Sidle, R.C. and Kamei, R. 2008. Effects of forest harvesting on the occurrence of landslides and debris flows in steep terrain of central Japan. Earth Surface Processes and Landforms 33:827–840. DOI: 10.1002/esp.1574.
Jibson, R.W., Keefer, D.K. et al. 1989. Statistical analysis of factors affecting landslide distribution in the New Madrid seismic zone, Tennessee and Kentucky. Engineering Geology 27:509–542.
Keefer, D.K. 2000. Statistical analysis of an earthquake-induced landslide distribution -the 1989 Loma Prieta, California event. Engineering Geology 58:231–249.
LAN, H.X., ZHOU, C.H., LEE, C.F. et al. 2003. Rainfall-induced landslide stability analysis in response to transient pore pressure-A case study of natural terrain landslide in Hong Kong. Science in China Series E (supp):52–68.
LIN, C.W., LIU, S.H., LEE, S.Y. et al. 2006. Impacts of the Chi-Chi earthquake on subsequent rainfall-induced landslides in central Taiwan. Engineering Geology 86:87–101.
Malamud, B.D., Turcotte, D.L., Guzzetti, F. et al. 2004. Landslide inventories and their statistical properties. Earth Surface Processes and Landforms 29:687–711.
Mohammad, R.M., Shahryar, S. and Mohammad, K.J. 2006. Landslides triggered by the Avaj, Iran earthquake of June 22, 2002. Engineering Geology 86:166–182.
Reichenbach, P., Galli, M., Cardinali, M. et al. 2005. Geomorphologic mapping to assess landslide risk: concepts, methods and applications in the Umbria Region of central Italy. In: Glade, T., Anderson, M, G. and Crozier, M.J. (eds.), Landslide Risk Assessment John Wiley, Chichester. 429–468.
TANG, C., ZHU, J., LI, W.L. et al. 2009. Rainfall-triggered debris flows following the Wenchuan earthquake. Bulletin of Engineering Geology Environmental 68:187–194.
WU, J.S., TIAN, L.Q. and KANG. Z.C. 1993. Debris flow and its comprehensive mitigation. Beijing, China: Science Press.
XU, X.W., WEN, X.Z., YE, J.Q. et al. 2008. The MS 8.0 Wenchuan earthquake surface ruptures and its seismogenic structure. Seismology and Geology 30(3):597–629.
YOU, Y. and LIU, J.F. 2009. The influence on debris flow prevention in the upriver of Minjiang after Wenchuan Earthquake. Journal of Sichuan University (Engineering Science Edition) (suup) 41:16–22.
ZHUANG, J.Q., CUI, P., GE, Y.G. et al. 2009. Hazard assessment of debris flow valleys along Dujiangyan-Wenchuan highway after 5.12 Wenchuan devastating earthquake. Journal of Sichuan University (Engineering Science Edition) 41:131–139.
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Zhuang, J., Cui, P., Hu, K. et al. Characteristics of earthquake-triggered landslides and post-earthquake debris flows in Beichuan County. J. Mt. Sci. 7, 246–254 (2010). https://doi.org/10.1007/s11629-010-2016-0
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DOI: https://doi.org/10.1007/s11629-010-2016-0