STUDY ON THE DISTRIBUTION OF CO-SEISMIC LANDSLIDES AND TERRAIN FEATURES IN THE MS6.5 LUDIAN EARTHQUAKE AFFECTED AREACHEN

doi:10.3969/j.issn.0253-4967.2021.01.003

Abstract

Abstract: The 2014 Ludian, Yunnan M_S6.5 earthquake triggered an unusually large number of co-seismic landslides compared with other events of similar magnitudes in southwestern China. We use landslide-area ratios(LAR)based on a grid(cell size ≈1km²)to delineate the specific distribution of landslides rather than the averaging landslide density that is commonly employed. Results show that the distribution of co-seismic landslides triggered by the 2014 Ludian M_W6.5 earthquake contains LAR values ranging from less than 1.0% to 36.1% with the high values concentrating in river valleys of the study area. Then we examine the correlation between some topographic parameters and the co-seismic landslides in each grid cell and especially focus on the grids with larger LAR(>10%). In addition to examining the correlation between the elevation, local relief and average slope angle(S), we propose a notion of the expected slope degree(ES)to further analyze the correlation between these co-seismic landslides and local topographic features. The expected slope degree can be calculated by dividing the local relief(the difference between the maximum and minimum elevation)by cell length for each grid cell, which is a kind of smooth of the local terrain instead of the average slope. After this procedure, we make a regression analysis on the expected slope degrees and the average slope degrees for all grid cells. Finally, we choose those cells that deviate from the regression line as the unstable units and examine their relation with landslide distribution. Results show that the elevation has a negative relationship with both the average slope degrees and the local relief in the study area, which can be classified as a kind of negative topography implying strong river erosion on the landform. In general, there exists a good positive linear correlation between expected slope degrees and average slope degree for the study area. While larger LAR values(LAR≥10%)lie at the sites that deviate from the regression line, likely representing unstable slopes prone to landsliding. Moreover, it is found that most of these sites with high LAR are just located along river valleys, which permits to predict that mass wasting by future earthquakes or other factors will recur at these places. As a contrast, the analysis results of topographic parameters in the Jiuzhaigou earthquake affected area show different characteristics. Thus, the understanding of the relationship between the geomorphic features and the spatial distribution and scale of landslides is helpful to improve the accuracy of prediction on earthquake-induced landslides and to identify potential large-scale landslides in the early stage.landscape evolution, landslides, adaptive adjustment, expected slope, the Ludian earthquake

摘要： 长期、缓慢的地貌演化具有阶段性的特点, 构造抬升与侵蚀相互作用引起山坡物质运移, 使地貌单元具有向相对稳定状态转变的趋势。滑坡作为山坡物质运移的一种主要方式, 在地貌演化过程中起到了重要作用。 2014年鲁甸M_S6.5地震诱发了异常多的滑坡, 可以看作是该区地貌物质在短时间内发生的集中调整过程。这些滑坡主要沿河流分布, 表明河流侵蚀使河岸地形变陡、强度降低, 形成发生物质运移的有利条件, 从而增强了地震滑坡的易发性。文中以SRTM 30m数字高程模型(DEM)为基础, 通过对鲁甸地震滑坡分布区的网格化划分, 对研究区滑坡分布及其与地形特征的关系进行了定量分析。除计算网格单元内的高程、高差及算数平均坡度外, 还提出期望坡度的计算方法以对网格单元内的地形进行平滑。在此基础上, 对该区域地貌特征参数自相关性进行了分析和比较, 以判断地表物质分布是否均衡并寻找其中的分异性单元(滑坡易发区)。结果表明, 研究区的高程与坡度、地形高差呈负相关, 反映出显著的河流侵蚀效应; 其中地形特征在分析单元的期望坡度与算数平均坡度这2个不同尺度下表现出很高的一致性, 可能代表着研究区地貌在演化中具有的一种动态稳定特征, 而与此特征不符的地貌单元则是可能发生滑坡进行物质调整的区域, 是地貌自适应调整的一种表现。 2014年鲁甸地震触发的大部分规模较大的滑坡发生在期望坡度与平均坡度差异较大的区域, 这些区域大多位于河谷, 显示河流侵蚀及其所造成的地形特征对滑坡易发性的控制作用。基于这样的认识, 认为该区未来的物质运移区域仍然受到河流侵蚀的控制, 滑坡易发性高的位置仍将沿河流分布。作为对比的九寨沟地震震区的地貌参数分析结果则表现出不同的特点, 这种地形地貌分布上的差异性与滑坡空间分布及滑坡规模等之间的关系值得深入探讨。

关键词: 地貌演化, 滑坡, 相关性分析, 期望坡度, 鲁甸地震

CLC Number:

P315.2

Xiao-li, LIU Chun-guo, CHUAN Yi-jian, LAN Jian, WEI Yan-kun. STUDY ON THE DISTRIBUTION OF CO-SEISMIC LANDSLIDES AND TERRAIN FEATURES IN THE M_S6.5 LUDIAN EARTHQUAKE AFFECTED AREACHEN[J]. SEISMOLOGY AND GEOLOGY, 2021, 43(1): 92-104.

陈晓利, 刘春国, 传一健, 兰剑, 魏延坤. 鲁甸地震的滑坡物质运移规律与地形特征[J]. 地震地质, 2021, 43(1): 92-104.

References

[1] 陈晓利, 常祖峰, 王昆. 2015. 云南鲁甸M_S6.5地震红石岩滑坡稳定性的数值模拟[J]. 地震地质, 37(1): 279—290. doi: 10.3969/j.issn.0253-4967.2015.01.02.
CHEN Xiao-li, CHANG Zu-feng, WANG Kun.2015. Numerical simulation study of Hongshiyan landslide triggered by the M_S6.0 Ludian earthquake[J]. Seismology and Geology, 37(1): 279—290(in Chinese).
[2] 祁生文, 许强, 刘春玲, 等. 2009. 汶川地震极重灾区地质背景及次生斜坡灾害空间发育规律[J]. 工程地质学报, 17(1): 39—49.
QI Sheng-wen, XU Qiang, LIU Chun-ling, et al. 2009. Slope instabilities in the severest disaster areas of 5·12 Wenchuan earthquake[J]. Journal of Engineering Geology, 17(1): 39—49(in Chinese).
[3] 王运生, 罗永红, 吉峰, 等. 2008. 汶川大地震山地灾害发育的控制因素分析[J]. 工程地质学报, 16(6): 759—763.
WANG Yun-sheng, LUO Yong-hong, JI Feng, et al. 2008. Analysis of the controlling factors on geo-hazards in mountainous epicenter zones of the Wenchuan earthquake[J]. Journal of Engineering Geology, 16(6): 759—763(in Chinese).
[4] 吴树仁, 王涛, 石玲, 等. 2010. 2008汶川大地震极端滑坡事件初步研究[J]. 工程地质学报, 18(2): 145—159.
WU Shu-ren, WANG Tao, SHI Ling, et al. 2010. Study on catastrophic landslides triggered by 2008 great Wenchuan earthquake, Sichuan, China[J]. Journal of Engineering Geology, 18(2): 145—159(in Chinese).
[5] 许强, 李为乐. 2010. 汶川地震诱发大型滑坡分布规律研究[J]. 工程地质学报, 18(6): 818—826.
XU Qiang, LI Wei-le.2010. Distribution of large scale landslides induced by the Wenchuan earthquake[J]. Journal of Engineering Geology, 18(6): 818—826(in Chinese).
[6] 杨晓平, 王萍, 李晓峰, 等. 2019. 地形坡度和高程变异系数在识别墨脱活动断裂带中的应用[J]. 地震地质, 41(2): 419—435. doi: 10.3969/j.issn.0253-4967.2019.02.010.
YANG Xiao-ping, WANG Ping, LI Xiao-feng, et al. 2019. Application of terrain slope and elevation coefficient of variation in identifying the Motuo active fault zone[J]. Seismology and Geology, 41(2): 419—435(in Chinese).
[7] 张永双, 石菊松, 孙萍, 等. 2009. 汶川地震内外动力耦合及灾害实例[J]. 地质力学学报, 15(2): 131—141.
ZHANG Yong-shuang, SHI Ju-song, SUN Ping, et al. 2009. Coupling between endogenic and exogenic geological processes in the Wenchuan earthquake and example analysis of geo-hazards[J]. Journal of Geomechanics, 15(2): 131—141(in Chinese).
[8] Ashford S A, Sitar N, Lysmer J, et al. 1997. Topographic effects on the seismic response of steep slopes[J]. Bulletin of the Seismological Society of America, 87(3): 701—709.
[9] Blöthe J H, Korup O, Schwanghart W.2015. Large landslides lie low: Excess topography in the Himalaya-Karakoram ranges[J]. Geology, 43:523—526.
[10] 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 and Earth System Sciences, 16:497—507.
[11] Chen X L, Zhou Q, Liu C G.2015. Distribution pattern of co-seismic landslides triggered by the 2014 Ludian, Yunnan, China M_W6.1 earthquake: Special controlling conditions of local topography[J]. Landslides, 12(6): 1159—1168.
[12] Chigira M, Yagi H.2006. Geological and geomorphological characteristics of landslides triggered by the 2004 Mid Niigta prefecture earthquake in Japan[J]. Engineering Geology, 82(4): 202—221.
[13] Fan X M, van Westen C J, Xu Q, et al. 2012. Analysis of landslide dams induced by the 2008 Wenchuan earthquake[J]. Journal of Asian Earth Sciences, 57:25—37.
[14] Hsü K J.1975. Catastrophic debris streams(sturzstroms)generated by rockfalls[J]. Bulletin of the Geological Society of America, 86:129—140.
[15] Hu K, Wu C, Tang J, et al. 2018. New understandings of the June 24th 2017 Xinmo Landslide, Maoxian, Sichuan, China[J]. Landslides, 15(12): 2465—2474.
[16] Huang R Q, Li W L.2009. Analysis of the geo-hazards triggered by the 12 May 2008 Wenchuan earthquake, China[J]. Bulletin of Engineering Geology and the Environment, 68(3): 363—371.
[17] Larsen I J, Montgomery D R, Korup O.2010. Landslide erosion controlled by hillslope material[J]. Nature Geoscience, 3:247—251. doi: 10.1038 /ngeo776.
[18] Liu-Zeng J, Tapponnier P, Gaudemer Y, et al. 2008. Quantifying landscape differences across the Tibetan plateau: Implications for topographic relief evolution[J]. Journal of Geophysical Research, 113:4—18. doi: 10.1029/2007JF000897.
[19] Keefer D K.2002. Investigating landslides caused by earthquakes—A historical review[J]. Surveys in Geophysics, 23(6): 473—510.
[20] Malamud B M, Turcotte D L, Guzzetti F, et al. 2004. Landslides, earthquakes, and erosion[J]. Earth and Planetary Science Letters, 229:45—59.
[21] Meunier P, Hovius N, Haines J A.2008. Topographic site effects and the location of earthquake induced landslides[J]. Earth and Planetary Science Letters, 275:221—232.
[22] Montgomery D R.2001. Slope distributions, threshold hillslopes, and steady-state topography[J]. American Journal of Science, 301(4-5): 432—454.
[23] Montgomery D R, Brandon M T.2002. Topographic controls on erosion rates in tectonically active mountain ranges[J]. Earth and Planetary Science Letters, 21:481—489.
[24] Parker R N, Densmore A L, Rosser N J, et al. 2011. Mass wasting triggered by the 2008 Wenchuan earthquake is greater than orogenic growth[J]. Nature Geoscience, 4:449—452. doi: 10.1038/NGEO1154.
[25] Su L J, Hu K H, Zhang W F, et al. 2017. Characteristics and triggerring mechanism of Xinmo landslide on 24 June 2017 in Sichuan, China[J]. Journal of Mountain Science, 14(9): 1689—1700.
[26] Wang Y S, Zhao B, Li J.2018. Mechanism of the catastrophic June 2017 landslide at Xinmo Village, Songping River, Sichuan Province, China[J]. Landslides, 15:333—345. doi: 10.1007/s10346-017-0927-3.
[27] Yang W T, Wang Y Q, Sun S, et al. 2019. Using Sentinel -2 time series to detect slope movement before the Jinsha River landslide[J]. Landslides, 16:1313—1324.

STUDY ON THE DISTRIBUTION OF CO-SEISMIC LANDSLIDES AND TERRAIN FEATURES IN THE M_S6.5 LUDIAN EARTHQUAKE AFFECTED AREACHEN

鲁甸地震的滑坡物质运移规律与地形特征

RichHTML

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

Comments

[1]	YANG Chen-yi, LI Xiao-ni, FENG Xi-jie, HUANG Yin-di, PEI Gen-di. SHALLOW STRUCTURE AND QUATERNARY ACTIVITY OF THE TAOCHUAN-HUXIAN FAULT, THE SUB-STRAND OF THE NORTHERN QINLING FAULT ZONE [J]. SEISMOLOGY AND GEOLOGY, 2023, 45(2): 464-483.
[2]	LI Yi-shi. RESEARCH ON COMPREHENSIVE STANDARDIZATION FOR SURVEYING AND PROSPECTING OF ACTIVE FAULT [J]. SEISMOLOGY AND GEOLOGY, 2023, 45(2): 455-463.
[3]	ZHANG Ling, MIAO Shu-qing, YANG Xiao-ping. THE ANALYSIS AND IMPLEMENTATION OF THE AUTOMATIC EXTRACTING METHOD FOR ACTIVE THRUST FAULTS IN THE NORTH TIANSHAN MOUNTAINS BASED ON ARCGIS SOFTWARE PLATFORM [J]. SEISMOLOGY AND GEOLOGY, 2023, 45(2): 422-434.
[4]	JIANG Feng-yun, JI Ling-yun, ZHU Liang-yu, LIU Chuan-jin. THE PRESENT CRUSTAL DEFORMATION CHARACTERISTICS OF THE HAIYUAN-LIUPANSHAN FAULT ZONE FROM INSAR AND GPS OBSERVATIONS [J]. SEISMOLOGY AND GEOLOGY, 2023, 45(2): 377-400.
[5]	WANG Liao, XIE Hong, YUAN Dao-yang, LI Zhi-min, XUE Shan-yu, SU Rui-huan, WEN Ya-meng, SU Qi. THE SURFACE RUPTURE CHARACTERISTICS BASED ON THE GF-7 IMAGES INTERPRETATION AND THE FIELD INVESTIGA-TION OF THE 2022 MENYUAN M_S6.9 EARTHQUAKE [J]. SEISMOLOGY AND GEOLOGY, 2023, 45(2): 401-421.
[6]	LIU Qing, LIU Shao, ZHANG Shi-min. PALEOSEISMOLOGIC STUDY ON THE YUEXI FAULT IN THE MIDSECTION OF THE DALIANGSHAN FAULT ZONE SINCE THE LATE QUATERNARY [J]. SEISMOLOGY AND GEOLOGY, 2023, 45(2): 321-337.
[7]	ZHAO Peng, LI Jun-hui, TAO Yue-chao, SHU Peng, FANG Zhen. NEW ACTIVITY PHENOMENA REVEALED BY TRENCH ON THE NORTH SIDE OF NÜSHAN LAKE IN THE TANLU FAULT ZONE AND DISCUSSION [J]. SEISMOLOGY AND GEOLOGY, 2023, 45(2): 338-354.
[8]	ZUO Yu-qi, YANG Hai-bo, YANG Xiao-ping, ZHAN Yan, LI An, SUN Xiang-yu, HU Zong-kai. EVIDENCE OF LATE QUATERNARY TECTONIC ACTIVITY OF THE BEIDA SHAN FAULT, SOUTHERN MARGIN OF THE ALASHAN BLOCK [J]. SEISMOLOGY AND GEOLOGY, 2023, 45(2): 355-376.
[9]	LI Xiao-ni, YANG Chen-yi, LI Gao-yang, FENG Xi-jie, HUANG Yin-di, LI Chen-xia, LI Miao, PEI Gen-di, WANG Wan-he. SHALLOW STRUCTURE AND LATE QUATERNARY ACTIVITIES OF BRANCH FAULTS ON THE NORTHERN SIDE OF THE WEINAN TABLELAND IN THE SOUTHEASTERN MARGIN OF THE WEIHE BASIN [J]. SEISMOLOGY AND GEOLOGY, 2023, 45(2): 484-499.
[10]	LIU Bai-yun, ZHAO Li, LIU Yun-yun, WANG Wen-cai, ZHANG Wei-dong. THE RESEARCH ON RELOCATION AND FAULT PLANE SOLUTION AND GEOMETRIC MEANING OF THE MADUO M7.4 EARTHQUAKE ON 22 MAY 2021 [J]. SEISMOLOGY AND GEOLOGY, 2023, 45(2): 500-516.
[11]	ZHAO De-zheng, QU Chun-yan, ZHANG Gui-fang, GONG Wen-yu, SHAN Xin-jian, ZHU Chuan-hua, ZHANG Guo-hong, SONG Xiao-gang. APPLICATIONS AND ADVANCES FOR THE COSEISMIC DEFORMA-TION OBSERVATIONS, EARTHQUAKE EMERGENCY RESPONSE AND SEISMOGENIC STRUCTURE INVESTIGATION USING INSAR [J]. SEISMOLOGY AND GEOLOGY, 2023, 45(2): 570-592.
[12]	LI An, WAN Bo, WANG Xiao-xian, JI Hao-min, SUO Rui. NEW EVIDENCE OF THE PALEOEARTHQUAKE RUPTURE IN THE NORTH GAIZHOU-ANSHAN SEGMENT OF THE JINZHOU FAULT [J]. SEISMOLOGY AND GEOLOGY, 2023, 45(1): 111-126.
[13]	ZHENG Hai-gang, YAO Da-quan, ZHAO Peng, YANG Yuan-yuan, HUANG Jin-shui. NEW ACTIVITY CHARACTERISTICS IN THE CHISHAN SECTION OF TAN-LU FAULT ZONE IN HOLOCENE [J]. SEISMOLOGY AND GEOLOGY, 2023, 45(1): 127-138.
[14]	TIAN Yi-ming, YANG Zhuo-xin, WANG Zhi-shuo, SHI Jin-hu, ZHANG Yang, TAN Ya-li, ZHANG Jian-zhi, SONG Wei, JI Tong-yu. A PRELIMINARY STUDY OF THE SHALLOW EXPLORATION AND QUATERNARY ACTIVITIES OF THE FENGQIU SEGMENT OF THE XINXIANG-SHANGQIU FAULT [J]. SEISMOLOGY AND GEOLOGY, 2023, 45(1): 139-152.
[15]	YANG Jian-wen, JIN Ming-pei, CHA Wen-jian, ZHANG Tian-ji, YE Beng. CRUSTAL S-WAVE VELOCITY STRUCTURE BENEATH THE XIAO-JIANG FAULT ZONE AND ADJACENT REGIONS REVEALED BY TWO-STEP INVERSION METHOD OF RECEIVER FUNCTIONS [J]. SEISMOLOGY AND GEOLOGY, 2023, 45(1): 190-207.