STUDY ON THE DISTRIBUTION PATTERN OF EARTHQUAKE- TRIGGERED LANDSLIDES BASED ON SEISMIC LANDSLIDE SUSCEPTIBILITY ANALYSIS: A CASE STUDY OF LANDSLIDES TRIGGERED BY THE MS6.5 LUDIAN EARTHQUAKE IN 2014

doi:10.3969/j.issn.0253-4967.2018.05.012

Abstract

Abstract: On August 3, 2014, an M_W6.5 earthquake occurred in Ludian County, Yunnan Province, which triggered significant landslides and caused serious ground damages and casualties. Compared with the existing events of earthquake-triggered landslides, the spatial distribution of co-seismic landslides during the Ludian earthquake showed a special pattern. The relationship between the co-seismic landslides and the epicenter or the known faults is not obvious, and the maximum landslide density doesn't appear in the area near the epicenter. Peak ground acceleration (PGA), which usually is used to judge the limit boundary of co-seismic landslide distribution, cannot explain this distribution pattern. Instead of correlating geological and topographic factors with the co-seismic landslide distribution pattern, this study focuses on analyzing the influence of seismic landslide susceptibility on the co-seismic distribution. Seismic landslide susceptibility comes from a calculation of critical acceleration values using a simplified Newmark block model analysis and represents slope stability under seismic loading. Both DEM (SRTM 90m)and geological map (1 ︰ 200^￣^￣000)are used as inputs to calculate critical acceleration values. Results show that the most susceptible slopes with the smallest critical accelerations are generally concentrated along the banks of rivers. The stable slopes, which have the larger critical accelerations and are comparably stable, are in the places adjacent to the epicenter. Comparison of the distribution of slope stability and the real landslides triggered by the 2014 M_W6.1 Ludian earthquake shows a good spatial correlation, meaning seismic landslide susceptibility controls the co-seismic landslide distributions to a certain degree. Moreover, our study provides a plausible explanation on the special distribution pattern of Ludian earthquake triggered landslides. Also the paper discusses the advantages of using the seismic landslide susceptibility as a basic map, which will offer an additional tool that can be used to assist in post-disaster response activities as well as seismic landslides hazards zonation.

Key words: earthquake-triggered landslide, Newmark model, seismic landslide susceptibility, the Ludian earthquake

摘要： 2014年8月3日发生于云南省东北部鲁甸县的M_S6.5地震触发了显著的同震滑坡并造成了严重地面破坏和人员伤亡。与已有地震诱发滑坡事件相比，鲁甸地震同震滑坡的空间分布较为特殊：与震中和已知断裂的关系都不明显，滑坡密度最大的区域并不在震中附近区域，且通常用于判断滑坡空间分布范围的地震动峰值加速度（PGA）也不能解释这样的分布格局。与以往研究地震滑坡与地质构造、地形地貌等影响因素相互间的关系不同，文中着重讨论地震滑坡敏感性对地震滑坡的控制作用。基于Newmark刚体滑块模型，文中计算了鲁甸地震滑坡影响区的坡体临界加速度值，并用来衡量地震滑坡敏感性程度：临界加速度值小，表明地震滑坡敏感性程度高，滑坡需要的外力较小，坡体在地震动作用下容易失稳；反之，坡体就越稳定。结果表明，鲁甸震区地震滑坡敏感性程度较高的地区主要沿牛栏江及其支流沙坝河、龙泉河两岸分布，震中及其北部地区的地震滑坡敏感性程度较低。对比研究区坡体地震滑坡敏感性分布与实际滑坡分布，可以看出二者之间具有较高的一致性：地震滑坡敏感性程度较高的区域往往是发生大量滑坡的地区。进一步，文中讨论了根据地震滑坡敏感性判断同震滑坡格局的优势，认为地震滑坡敏感性对同震滑坡的分布起到了控制作用；同时，区域性地震滑坡敏感性的研究不仅有助于理解同震滑坡分布格局，还可以为震源构造的研究提供依据，并且可以作为震后滑坡快速评估及地震滑坡危险性区划的基础。

关键词: 地震滑坡, Newmark刚体滑块模型, 地震滑坡敏感性, 鲁甸地震

CLC Number:

P315.2

CHEN Xiao-li, ZHANG Ling, WANG Ming-ming. STUDY ON THE DISTRIBUTION PATTERN OF EARTHQUAKE- TRIGGERED LANDSLIDES BASED ON SEISMIC LANDSLIDE SUSCEPTIBILITY ANALYSIS: A CASE STUDY OF LANDSLIDES TRIGGERED BY THE M_S6.5 LUDIAN EARTHQUAKE IN 2014[J]. SEISMOLOGY AND GEOLOGY, 2018, 40(5): 1129-1139.

陈晓利, 张凌, 王明明. 基于地震滑坡敏感性分析的同震滑坡分布格局——以2014年M_S6.5鲁甸地震诱发滑坡为例[J]. 地震地质, 2018, 40(5): 1129-1139.

References

陈晓利, 惠红军, 赵永红. 2014. 断裂性质与滑坡分布的关系:以汶川地震中的大型滑坡为例［J］. 地震地质, 36(2):358-367. doi:10.3969/j.issn.0253-4967.2014.02.007.
CHEN Xiao-li, HUI Hong-jun, ZHAO Yong-hong. 2014. Study on the fault mechanics influences on the landslides distribution:A case study from the Wenchuan earthquake［J］. Seismology and Geology, 36(2):358-367(in Chinese).
房立华, 吴建平, 王未来, 等. 2014. 云南鲁甸M_S6.5地震余震重定位及其发震构造［J］. 地震地质, 36(4):1173-1185. doi:10.3969j.issn.0253-4967.2014.04.019.
FANG Li-hua, WU Jian-ping, WANG Wei-lai, et al. 2014. Relocation of the aftershock sequence of the M_S6.5 Ludian earthquake and its seismogenic structure［J］. Seismology and Geology, 36(4):1171-1185(in Chinese).
黄润秋, 李为乐. 2008. "5·12"汶川大地震触发地质灾害的发育规律研究［J］. 岩石力学与工程学报, 27(12):2585-2592.
HUANG Run-qiu, LI Wei-le. 2008. A study on the development and distribution rules of geohazards triggered by "5·12" Wenchuan earthquake［J］. Chinese Journal of Rock Mechanics and Engineering, 27(12):2585-2592(in Chinese).
国家技术监督局, 中华人民共和国建设部. 1995. 中华人民共和国国家标准:工程岩体分级标准(GB 50218-94)［S］. 北京:中国计划出版社。
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［S］. China Planning Press, Beijing(in Chinese).
王未来, 吴建平, 房立华, 等. 2014. 2014年云南鲁甸M_S6.5地震序列的双差定位［J］. 地球物理学报, 57(9):3042-3051.
WANG Wei-lai, WU Jian-ping, FANG Li-hua, et al. 2014. Double difference location of the Ludian M_S6.5 earthquake sequences in Yunnan Province in 2014［J］. Chinese Journal of Geophysics, 57(9):3042-3051(in Chinese).
许冲, 徐锡伟, 于贵华. 2012. 玉树地震滑坡分布调查及其特征与形成机制［J］. 地震地质, 34(1):47-62. doi:10.3969/j.issn.0253-4967.2012.01.006.
XU Chong, XU Xi-we, YU Gui-hua. 2012. Study on the characteristics, mechanism, and spatial distribution of Yushu earthquake triggered landslides［J］. Seismology and Geology, 34(1):47-62(in Chinese).
徐锡伟, 江国焰, 于贵华, 等. 2014. 鲁甸6.5级地震发震断层判定及其构造属性讨论［J］. 地球物理学报, 57(9):3060-3068.
XU Xi-wei, JIANG Guo-yan, YU Gui-hua, et al. 2014. Discussion on seismogenic fault of the Ludian M_S6.5 earthquake and its tectonic attribution［J］. Chinese Journal of Geophysics, 57(9):3060-3068(in Chinese).
张勇, 陈运泰, 许力生, 等. 2015. 2014年云南鲁甸M_W6.1地震:一次共轭破裂地震［J］. 地球物理学报, 58(1):153-162.
ZHANG Yong, CHEN Yun-tai, XU Li-sheng, et al. 2015. The 2014 M_W6.1 Ludian, Yunnan, earthquake:A complex conjugated rupture earthquake［J］. Chinese Journal of Geophysics, 58(1):153-162(in Chinese).
中国地质调查局. 2001. 云南省区域地震图(1:200 000)［CM］. 北京:地质出版社.
China Geological Survey(CGS). 2001. Regional Geological Map of Yunnan Province(1:200 000)［CM］. Geological Publishing House, Beijing(in Chinese).
周庆, 吴果. 2015. 鲁甸6.5级地震崩滑地质灾害分布与成因探讨［J］. 地震地质, 37(1):269-278. doi:10.3969/j.issn.0253-4967.2015.01.21.
ZHOU Qing, WU Guo. 2015. Seismic landslides and seismogenic structure of the 2014 Ludian M_S6.5 earthquake［J］. Seismology and Geology, 37(1):269-278(in Chinese).
Chang Z F, Chen X L, An X W, et al. 2016. Contributing factors to the failure of an unusually large landslide triggered by the 2014 Ludian, Yunnan, China, M_S=6.5 earthquake［J］. Natural Hazards & Earth System Sciences, 16(2):497-507.
Chen X L, Zhou Q, Liu C G. 2015. Distribution pattern of coseismic landslides triggered by the 2014 Ludian, Yunnan, China M_W6.1 earthquake:Special controlling conditions of local topography［J］. Landslides. 12(6):1159-1168.
Dai F C, Xu C, Yao X, et al. 2011. Spatial distribution of landslides triggered by the 2008 M_S8.0 Wenchuan earthquake, China［J］. Journal of Asian Earth Sciences, 40:883-895.
Dreyfus D, Rathje E M, Jibson R W. 2013. The influence of different simplified sliding-block models and input parameters on regional predictions of seismic landslides triggered by the Northridge earthquake［J］. Engineering Geology, 163:41-54.
Gallen S F, Clark M K, Godt J W, et al. 2016. Application and evaluation of a rapid response earthquake-triggered landslide model to the 25 April 2015 M_W7.8 Gorkha earthquake, Nepal［J/OL］. Tectonophysics. http://dx.doi.org/10.1016/j.tecto.2016.10.031
Harp E L, JibsonR W. 1996. Landslides triggered by the 1994 Northridge, California, earthquake［J］. Bulletin of the Seismological Society of America, 86(1B):319-332.
Jibson R W, Harp E L. 2016. Ground motions at the outermost limits of seismically triggered landslides［J］. Bulletin of the Seismological Society of America, 106(2):708-719. doi:10.1785/0120150141.
Jibson R W, Harp E L, Michael J A. 2000. A method for producing digital probabilistic seismic landslide hazard maps［J］. Engineering Geology, 58(3-4):271-289.
Jibson R W, Harp E L, Schulz W, et al., 2006. Large rock avalanches triggered by the M7.9 Denali Fault, Alaska, earthquake of 3 November 2002［J］. Engineering Geology, 83(1):144-160.
Jibson R W, Harp E L, Schulz W, et al. 2004. Landslides triggered by the 2002 M7.9 Denali Fault, Alaska, earthquake and the inferred nature of the strong shaking［J］. Earthquake Spectra. 20:669-691.
Kargel J S, Leonard G J, Shugar D H, et al. 2016. Geomorphic and geologic controls of geohazards induced by Nepal's 2015 Gorkha earthquake［J］. Science, 351.
Keefer D K. 1984. Landslides caused by earthquakes［J］. Geological Society of America Bulletin, 95:406-421.
Keefer D K. 2002. Investigating landslides caused by earthquake:A historical review［J］. Surveys in Geophysics, 23:473-510.
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［J］. Engineering Geology, 71(1-2):79-95.
Meunier P, Hovius N, Haines J A. 2007. Regional patterns of earthquake-triggered landslides and their relation to ground motion［J］. Geophysical Research Letters, 34(20):L20408. doi:10.1029/2007GL031337.
Newmark N M. 1965. Effects of earthquakes on dams and embankments［J］. Geotechnique, 15:139-160.
Qi S W, Xu Q, Lan H X, et al. 2010. Spatial distribution analysis of landslides triggered by 2008.5.12 Wenchuan earthquake, China［J］. Engineering Geology, 116:95-108.
Sato H P, Hasegawa H, Fujiwara S, et al. 2007. Interpretation of landslide distribution triggered by the 2005 Northern Pakistan earthquake using SPOT 5 imagery［J］. Landslides, 4(2):113-122.
Shinoda M, Miyata Y. 2017. Regional landslide susceptibility following the Mid NⅡGATA prefecture earthquake in 2004 with Newmark's sliding block analysis［J］. Landslides, 14(6):1887-1899. doi:10.1007/s10346-017-0833-8.
Su L J, Hu K H, Zhang W F, et al. 2017a. Characteristics and triggering mechanism of Xinmo landslide on 24 June 2017 in Sichuan, China［J］. Journal of Mountain Science, 14(9):1689-1700.
Su L J, Xu X Q, Genge X Y, et al. 2017b. An integrated approach for investigating hydrogeological characteristics of a debris landslide in the Wenchuan earthquake area［J］. Engineering Geology, 219:52-63.
Wang W N, Wu H L, Nakamura H, et al. 2003. Mass movements caused by recent tectonic activity:The 1999 Chi-chi earthquake in central Taiwan［J］. Island Arc, 12(4):325-334.
Wieczorek G F, Wilson R C, Harp E L. 1985. Map showing slope stability during earthquakes in San Mateo County California［CM］. US Geological Survey Miscellaneous Investigations Map I-1257-E, scale 1:62 500.
Xu C, Xu X W, Yao X, et al. 2013. Three(nearly)complete inventories of landslides triggered by the May 12, 2008 Wenchuan M_W7.9 earthquake of China and their spatial distribution statistical analysis［J］. Landslides, 11(3):441-461. doi 10.100 7/s10346-013-0404-6.
Yin Y P, Wang F W, Sun P. 2009. Landslide hazards triggered by the 2008 Wenchuan earthquake, Sichuan, China［J］. Landslides, 6(2):139-152.

[1]	WEI Yan-kun, CHEN Xiao-li. APPLICABILITY OF DIFFERENT SEISMIC LANDSLIDE RISK ASSESSMENT METHODS: A CASE STUDY OF MADUO M_S7.4 EARTHQUAKE [J]. SEISMOLOGY AND GEOLOGY, 2022, 44(3): 590-603.
[2]	LAN Jian, CHEN Xiao-li. EVOLUTION CHARACTERISTICS OF LANDSLIDES TRIGGERED BY 2008 M_S8.0 WENCHUAN EARTHQUAKE IN YINGXIU AREA [J]. SEISMOLOGY AND GEOLOGY, 2020, 42(1): 125-146.
[3]	MA Si-yuan, XU Chong, WANG Tao, LIU Jia-mei. APPLICATION OF TWO SIMPLIFIED NEWMARK MODELS TO THE ASSESSMENT OF LANDSLIDES TRIGGERED BY THE 2008 WENCHUAN EARTHQUAKE [J]. SEISMOLOGY AND GEOLOGY, 2019, 41(3): 774-788.
[4]	CHEN Xiao-li, HUI Hong-jun, ZHAO Yong-hong. STUDY ON THE FAULT MECHANICS INFLUENCES ON THE LANDSLIDES DISTRIBUTION：A CASE STUDY FROM THE WENCHUAN EARTHQUAKE [J]. SEISMOLOGY AND GEOLOGY, 2014, 36(2): 358-367.