CHARACTERISTICS OF GEOLOGICAL HAZARDS IN THE EPICENTER OF THE JIASHI MW6.0 EARTHQUAKE ON JANUARY 19, 2020

doi:10.3969/j.issn.0253-4967.2021.02.010

Abstract

Abstract: On January 19, 2020, an M_W6.0 earthquake occurred in Xikeer town, Xinjiang, northwest China. This earthquake was another strong earthquake event that occurred on the Kepingtage fold-and-thrust belt(FTB)after the 2003 Bachu-Jiashi M_W6.3 earthquake. The Kepingtage FTB is bounded by the southern Tian Shan area to the north and the Tarim Basin to the south. The Kepingtage FTB is ~300km long from east to west and 60~140km wide from north to south. It is composed of a series of monoclinal or anticlinal mountains(fold-and-thrust)with a near east-west direction and parallel distribution. Combined with the focal mechanism, seismic reflection profiles, and interferometric synthetic aperture radar coseismic deformation, we can reveal the seismogenic structure of this earthquake. The Jiashi event was mainly of a horizontal compression movement; the slip distribution was concentrated at a depth of 4~6km, and the fault-slip angle was~15°. Our results show that the seismogenic structure of the Jiashi event is the Keping thrust fault at the leading edge of the Kepingtage FTB. We carried out detailed field surveys, measurements, and drone aerial photography of the earthquake area after the earthquake. In the magistoseismic area(Ⅷ degrees), a lot of seismic geological disasters were found, including ground fissures, sand liquefaction, and collapse. This paper summarizes and describes the characteristics of geological hazards from four observation points. In observation point 1, a large area of ground fissures were developed in the area of Xikeer overpass. According to the statistics of ground fissures of this area, the dominant direction of the ground fissures is NEE, the south-north extrusion uplift is 0.1~0.15m, and the horizontal displacement is 0.05~0.1m. In observation point 2, the earthquake caused serious damage to the Xikeer dam, creating the tensile fissures at the dam crest, with a maximum depth of 4m and a maximum length of 900m. In observation point 3, a series of ground fissures were observed parallel to the road in the west of Xikeer town, and the length of ground fissures is~500m. A large area of sand liquefaction developed along the ground fissures, and the liquefied material was gray brown argillaceous silty. In observation point 4, a series of large and huge fresh rock collapses developed in the Shankou gully north of the epicenter. The largest single collapse is 50~100m³, and the largest collapse range is about 200~300m². According to the field investigation and dynamic calculation results, the maximum horizontal deformation is 29.8cm, located downstream of the dam crest. The horizontal deformation upstream of the dam crest is 22.35cm. Because of the sand liquefaction that occurred behind the dam, local settling of the foundation behind the dam also occurred. The horizontal deformation upstream and downstream of the dam crest are inconsistent, which produced the longitudinal fissures on the dam crest. We collected a large amount of strong-motion earthquakes data from the 2020 Jiashi earthquake. By combining the fault strike and upper and lower wall effects, the PGAs of the foreshock, main shock, and aftershocks were fitted, and isoseismal lines were generated. The Xikeer dam is located at the region where the vibration intensity of the Jiashi event was the highest. The effects of the aftershocks were also superimposed mainly in this area. Notably, sand liquefaction and most of the fissures were caused by the main shock, while the aftershocks(M_S>4.0)exacerbated this damage. However, in this study, we could only determine the extent of the damage caused by the main shock, because our detailed field investigation and drilling were conducted in April 2020, after the main shock and aftershocks.

Key words: The 2020 M_W6.0 Jiashi earthquake, seismic geological hazard, distribution characteristics, superposition effect

摘要： 2020年1月19日新疆伽师M_W6.0地震发生在南天山柯坪塔格前陆冲断带前缘的柯坪逆断裂(KPT)上, 是该区域自2003年巴楚-伽师M_W6.3地震后发生的最大地震。震后对震区进行了详细的实地调查、测量和无人机航拍, 在极震区(Ⅷ度区)内发现了大量地震地质灾害, 主要包括地裂缝、砂土液化和崩塌等。文中对震区的4个观察点进行了总结, 并描述了地质灾害的特征: 1)在西克尔互通立交(观察点1)区域内发育了大量纵横交错的地裂缝, 对这部分地裂缝进行统计发现, 其优势走向为NEE, SN向挤压抬升量为0.1~0.15m, 水平位错量为0.05~0.1m; 2)地震对西克尔大坝(观察点2)造成了严重的破坏, 在坝顶形成最大深度为4m、长约900m的拉张性地裂缝, 坝后也出现一系列砂土液化, 喷砂锥的最大直径达3m; 3)西克尔库勒镇以西(观察点3), 路面上发育了多段与公路平行、长约500m的地裂缝, 同时沿地裂缝出现大面积砂土液化, 液化物质为灰褐色泥质粉砂; 4)震中北部山口沟(观察点4)沿线发育了一系列大型、巨型的新鲜岩质崩塌, 最大单体崩塌物的体积为50~100m³, 最大崩塌倒石堆的范围为200~300m²。综合分析上述资料发现, 由于观察点4位于KPT上盘, 在震后未能及时对该观察点进行调查, 导致2020年1月19日伽师M_W6.0地震北部的烈度影响范围被低估, 尤其是Ⅷ度圈。结合现场调查和数值模拟分析西克尔大坝的破坏机理, 认为坝后的砂土液化导致坝基出现不均匀沉降, 使得坝前坡和坝后坡出现了不等的水平位移(坝前坡为22.35cm, 坝后坡为29.8cm), 导致大坝向下游方向旋转, 故在坝顶形成了拉张性的贯通地裂缝。

关键词: 2020年伽师地震, 地震地质灾害, 分布特征, 叠加效应

CLC Number:

P315.2

YAO Yuan, LI Tao, LIU Qi, DI Ning. CHARACTERISTICS OF GEOLOGICAL HAZARDS IN THE EPICENTER OF THE JIASHI M_W6.0 EARTHQUAKE ON JANUARY 19, 2020[J]. SEISMOLOGY AND GEOLOGY, 2021, 43(2): 410-429.

姚远, 李涛, 刘奇, 邸宁. 2020年1月19日新疆伽师M_W6.0地震震中区地质灾害特点[J]. 地震地质, 2021, 43(2): 410-429.

References

[1] 陈杰, 尹金辉, 曲国胜, 等. 2000. 塔里木盆地西缘西域组的底界、时代、成因与变形过程的初步研究[J]. 地震地质, 22(S1): 104—116.
CHEN Jie, YIN Jin-hui, QU Guo-sheng, et al. 2000. Timing, lower boundary, genesis, and deformation of Xiyu Formation around the western margins of the Tarim Basin[J]. Seismology and Geology, 22(S1): 104—l16(in Chinese).
[2] 邓起东, 冯先岳, 张培震, 等. 2000. 天山活动构造 [M]. 北京: 地震出版社.
DENG Qi-dong, FENG Xian-yue, ZHANG Pei-zhen, et al. 2000. Active Tectonics in the Tianshan [M]. Seismological Press, Beijing(in Chinese).
[3] 高国英, 戈澍谟, 韩月鹏, 等. 1997. 1996年3月19日新疆阿图什6.9级地震震源破裂特征的研究[J]. 地震, 17(3): 290—296.
GAO Guo-ying, GE Shu-mo, HAN Yue-peng, et al. 1997. The characteristics of rupture process of Xinjiang Atushi earthquake(M_S=6.9), 19 March 1996[J]. Earthquake, 17(3): 290—296(in Chinese).
[4] 郭飙, 刘启元, 陈九辉, 等. 2002. 新疆伽师强震区余震序列的地震台阵定位[J]. 地震地质, 24(2): 199—207.
GUO Biao, LIU Qi-yuan, CHEN Jiu-hui, et al. 2002. Relocation of earthquake sequences using joint hypocenter determination method: Portable seismic array study in Jiashi region, Xinjiang[J]. Seismology and Geology, 24(2): 199—207(in Chinese).
[5] 何仲太, 马保起, 李玉森, 等. 2012. 汶川地震地表破裂带宽度与断层上盘效应[J]. 北京大学学报(自然科学版), 48(6): 886—894.
HE Zhong-tai, MA Bao-qi, LI Yu-sen, et al. 2012. Width and hanging wall effect of surface rupture caused by Wenchuan earthquake[J]. Acta Scientiarum Naturalium Universitatis Pekinensis, 48(6): 886—894(in Chinese).
[6] 赖院根, 刘启元, 陈九辉, 等. 2002. 新疆伽师强震群区的横波分裂与应力场特征[J]. 地球物理学报, 45(1): 83—93.
LAI Yuan-gen, LIU Qi-yuan, CHEN Jiu-hui, et al. 2002. Features of the S-wave splitting and stress field in the Xinjiang Jiashi strong earthquake region[J]. Chinese Journal of Geophysics, 45(1): 83—92(in Chinese).
[7] 李成龙, 张国宏, 单新建, 等. 2020. 2020年1月19日新疆伽师县M_S6.4地震InSAR同震形变场与断层滑动分布反演[J/OL]. 地球物理学进展. kns.cnki.netkcmsdetail/11.2982.P.20200608.1616.178.html.
LI Cheng-long, ZHANG Gou-hong, SHAN Xin-jian, et al. 2020. Coseismic deformation and slip distribution of the M_S6.4 Jiashi, Xinjiang earthquake revealed by Sentinel-1A SAR imagery[J/OL]. Progress in Geophysics. kns.cnki.netkcmsdetail/11.2982.P.20200608.1616.178.html(in Chinese).
[8] 李杰. 2012. 天山及邻区现今地震构造环境与强震危险性的GPS研究 [D]. 武汉: 中国地质大学.
LI Jie. 2012. Kinematics of present-day deformation of the Tien Shan and adjacent regions with GPS geodesy: Implications for active tectonics and seismic hazards [D]. Chinese University of Geosciences, Wuhan(in Chinese).
[9] 李松林, 张先康, Mooney W D, 等. 2002. 伽师地震区地壳细结构及发震断层的初步研究[J]. 地球物理学报, 45(1): 76—82.
LI Song-lin, ZHANG Xian-kang, Mooney W D, et al. 2002. A preliminary study on fine structures of Jiashi earthquake region and earthquake generating fault[J]. Chinese Journal of Geophysics, 45(1): 76—82(in Chinese).
[10] 李文倩, 朱浩清, 何金刚. 2020. 2020年1月19日新疆伽师6.4级地震强震动记录特征初步分析[J]. 内陆地震, 34(1): 63—69.
LI Wen-qian, ZHU Hao-qing, HE Jin-gang. 2020. The characteristics of strong motion records of Xinjiang Jiashi M_S6.4 earthquake on January 19, 2020[J]. Inland Earthquake, 34(1): 63—69(in Chinese).
[11] 刘启元, 陈九辉, 李顺成, 等. 2000. 新疆伽师强震群区三维地壳上地幔S波速度结构及其地震成因的探讨[J]. 地球物理学报, 43(3): 356—365.
LIU Qi-yuan, CHEN Jiu-hui, LI Shun-cheng, et al. 2000. Passive seismic experiment in Xinjiang Jiashi strong earthquake region and discussion on its seismic genesis[J]. Chinese Journal of Geophysics, 43(3): 356—365(in Chinese).
[12] 潘素珍, 张先康, 杨卓欣, 等. 2004. 利用反演方法确定新疆伽师地震的定位[J]. 地震地质, 26(1): 153—160.
PAN Su-zhen, ZHANG Xian-kang, YANG Zhuo-xin, et al. 2004. Precise locating of Jiashi, Xinjiang earthquake by using inversion method[J]. Seismology and Geology, 26(1): 153—160(in Chinese).
[13] 彭磊. 2011. 汶川地震上盘效应的研究 [D]. 哈尔滨: 中国地震局工程力学研究所.
PENG Lei. 2011. Study on the hanging wall effect in the Wenchuan earthquake [D]. Institute of Engineering Mechanics, China Earthquake Administration(in Chinese).
[14] 沈军, 陈建波, 王翠, 等. 2006. 2003年2月24日新疆巴楚-伽师6.8级地震发震构造[J]. 地震地质, 28(2): 205—212.
SHEN Jun, CHEN Jian-bo, WANG Cui, et al. 2006. The seismogenic tectonics of the M_S6.8 Bachu-Jiashi, Xinjiang earthquake on Feb. 24, 2003[J]. Seismology and Geology, 28(2): 205-212(in Chinese).
[15] 温少妍, 李成龙, 李金. 2020. 2020年1月19日新疆伽师M_S6.4地震InSAR同震形变场特征及发震构造初步探讨[J]. 内陆地震, 34(1): 4—12.
WEN Shao-yan, LI Cheng-long, LI Jin. 2020. InSAR coseismic displacement derived from Sentinel-1 data and seismogenic fault for the 2020 M_S6.4 Jiashi earthquake[J]. Inland Earthquake, 34(1): 4—12(in Chinese).
[16] 许冲, 戴福初, 陈剑, 等. 2009. 汶川M_S8.0地震重灾区次生地质灾害遥感精细解译[J]. 遥感学报, 13(4): 745—762.
XU Chong, DAI Fu-chu, CHEN Jian, et al. 2009. Identification and analysis of secondary geological hazards triggered by a magnitude 8.0 Wenchuan earthquake[J]. Journal of Remote Sensing, 13(4): 745—762(in Chinese).
[17] 许冲, 戴福初, 徐锡伟. 2010. 汶川地震滑坡灾害研究综述[J]. 地质论评, 56(6): 860—874.
XU Chong, DAI Fu-chu, XU Xi-wei. 2010. Wenchuan earthquake-induced landslides: An overview[J]. Geological Review, 56(6): 860—874(in Chinese).
[18] 杨晓平, 冉勇康, 宋方敏, 等. 2006. 西南天山柯坪逆冲推覆构造带的地壳缩短分析[J]. 地震地质, 28(2): 194—204.
YANG Xiao-ping, RAN Yong-kang, SONG Fang-min, et al. 2006. The analysis for crust shortening of Kalpin thrust tectonic zone, south-western Tianshan, Xinjiang, China[J]. Seismology and Geology, 28(2): 194—204(in Chinese).
[19] 姚远, 陈杰, 李涛, 等. 2018. 2016年11月25日新疆阿克陶M_W6.6地震宏观震中与地质灾害[J]. 地震地质, 40(2): 426—439.
YAO Yuan, CHEN Jie, LI Tao, et al. 2018. Geological hazard characteristics and macroscopic epicenter of November 25, 2016, Arketao, Xinjiang, M_W6.6 earthquake[J]. Seismology and Geology, 40(2): 426—439(in Chinese).
[20] 殷跃平. 2008. 汶川八级地震地质灾害研究[J]. 工程地质学报, 16(4): 433—444.
YIN Yue-ping. 2008. Researches on the geo-hazards triggered by Wenchuan earthquake, Sichuan[J]. Journal of Engineering Geology, 16(4): 433—444(in Chinese).
[21] 殷跃平, 张永双, 马寅生, 等. 2010. 青海玉树M_S7.1地震地质灾害主要特征[J]. 工程地质学报, 18(3): 289—296.
YIN Yue-ping, ZHANG Yong-shuang, MA Yin-sheng, et al. 2010. Research on major characteristics of geohazards induced by the Yushu M_S7.1 earthquake[J]. Journal of Engineering Geology, 18(3): 289—296(in Chinese).
[22] 袁晓铭, 曹振中, 孙锐, 等. 2009. 汶川8.0级地震液化特征初步研究[J]. 岩石力学与工程学报, 28(6): 1288—1296.
YUAN Xiao-ming, CAO Zhen-zhong, SUN Rui, et al. 2009. Preliminary research on liquefaction characteristics of Wenchuan 8.0 earthquake[J]. Chinese Journal of Rock Mechanics and Engineering, 28(6): 1288—1296(in Chinese).
[23] 张培震, 邓起东, 杨晓平, 等. 1996. 天山的晚新生代构造变形及其地球动力学问题[J]. 中国地震, 12(2): 127—140.
ZHANG Pei-zhen, DENG Qi-dong, YANG Xiao-ping, et al. 1996. Late Cenozoic tectonic deformation and mechanism along the Tianshan Mountains, northwestern China[J]. Earthquake Research in China, 12(2): 127—140(in Chinese).
[24] 张先康, 赵金仁, 张成科, 等. 2002. 帕米尔东北侧地壳结构研究[J]. 地球物理学报, 45(5): 665—671.
ZHANG Xian-kang, ZHAO Jin-ren, ZHANG Cheng-ke, et al. 2002. Crustal structure at the northeast side of the Pamirs[J]. Chinese Journal of Geophysics, 45(5): 665—671(in Chinese).
[25] 赵翠萍. 2006. 1997—2003年新疆伽师震源区特征的地震学方法研究 [D]. 北京: 中国地震局地球物理研究所.
ZHAO Cui-ping. 2006. Seismological studies on the characteristics of Jiashi source region from 1997 to 2003 [D]. Institute of Geophysics, China Earthquake Administration, Beijing(in Chinese).
[26] 周仕勇, 许忠淮, 陈晓非. 2001. 伽师强震群震源特征及震源机制力学成因分析[J]. 地球物理学报, 44(5): 654—662.
ZHOU Shi-yong, XU Zhong-huai, CHEN Xiao-fei. 2001. Analysis on the source characteristics of the 1997 Jiashi swarm, western China[J]. Chinese Journal of Geophysics, 44(5): 654—662(in Chinese).
[27] Abdrakhmatov K Y, Aldazhanov A S. 1996. Relative recent construction of the Tienshan inferred from GPS measurements of present-day crust deformation[J]. Nature, 384:450—453.
[28] Allen M B, Vincent S J, Wheeler P J. 1999. Late Cenozoic tectonics of the Kepingtage thrust zone: Interactions of the Tien Shan and Tarim Basin, Northwest China[J]. Tectonics, 18(4): 639—654.
[29] Avouac J P, Tapponier P, Bai M X, et al. 1993. Active thrusting and folding along the northern Tienshan and late Cenozoic rotation of the Tarim relative to Dzungaria and Kazakhstan[J]. Journal of Geophysical Research, 98(B4): 6755—6804.
[30] Burchfiel B C, Brown E T, Deng Q D, et al. 1999. Crustal shortening on the margins of the Tien Shan, Xinjiang, China[J]. International Geology Review, 41(8): 665—700.
[31] Chen G, Jin D, Mao J, et al. 2014. Seismic damage and behavior analysis of earth dams during the 2008 Wenchuan earthquake, China[J]. Engineering Geology, 180: 99—129.
[32] Heermance R V, Chen J, Burbank D W, et al. 2008. Temporal constraints and pulsed Late Cenozoic deformation during the structural disruption of the active Kashi foreland, northwest China[J]. Tectonics, 27(6): 1—27.
[33] Hendrix M S, Dumitru T A, Graham S A. 1994. Late Oligocene-early Miocene unroofing in the Chinese Tian Shan: An early effect of the India-Asia collision[J]. Geology, 22(6): 487—490.
[34] Iwasaki T. 1986. Soil liquefaction studies in Japan: State-of-the-art[J]. Soil Dynamics and Earthquake Engineering, 5(1): 2—68.
[35] Krinitzsky E L, Hynes M E. 2002. The Bhuj, India, earthquake: Lessons learned for earthquake safety of dams on alluvium[J]. Engineering Geology, 66(3-4): 163—196.
[36] Li A, Ran Y, Gomez F, et al. 2020. Segmentation of the Kepingtage thrust fault based on paleo-earthquake ruptures, southwestern Tianshan, China[J]. Natural Hazards, 103(4): 1—22.
[37] Lin M L, Liao H J, Ueng T S. 1999. A study on the geotechnical-related damages in the Chi-Chi earthquake[J]. Civil and Hydraulic Engineering, 26(3): 60—71.
[38] Raghvendra S, Debasis R, Sudhri K J. 2005. Analysis of earth dams affected by the 2001 Bhuj earthquake[J]. Engineering Geology, 80(3-4): 282—291.
[39] Seed B. 1968. Landslides during earthquakes due to soil liquefaction[J]. Journal of the Soil Mechanics & Foundations Division, 94(5): 1053—1122.
[40] Thompson J A, Burbank D W, Li T, et al. 2015. Late Miocene northward propagation of the northeast Pamir thrust system, northwest China[J]. Tectonics, 34(3): 510—534, .
[41] Thompson J A, Li T, Bookhagen B, et al. 2018. Dating growth strata and basin fill by combining ²⁶Al/¹⁰Be burial dating and magnetostratigraphy: Constraining active deformation in the Pamir-Tian Shan convergence zone, NW China[J]. Lithosphere, 10(6): 806—828.
[42] Wang C, Dreger D S, Wang C, et al. 2003. Field relations among coseismic ground motion, water level change and liquefaction for the 1999 Chi-Chi(M_W=7.5)earthquake, Taiwan[J]. Geophysical Research Letters, 30(17): HLS1-1—1-4.
[43] Wang Q, Zhang P Z, Freymueller J T, et al. 2000. Present-day crustal deformation in China constrained by global positioning system measurements[J]. Science, 294:574—577.
[44] Yao Y, Chen J, Li T, et al. 2019. Soil liquefaction in seasonally frozen ground during the 2016 M_W6.6 Akto earthquake[J]. Soil Dynamics and Earthquake Engineering, 117:138—148.
[45] Yao Y, Wen S Y, Li T, et al. 2020. The 2020 M_W6.0 Jiashi earthquake: A fold earthquake event in the southern Tian Shan, Northwest China[J]. Seismological Research Letters, 92(6): 859—869.
[46] Yin A, Nie S, Craig P, et al. 1998. Late Cenozoic tectonic evolution of the southern Chinese Tian Shan[J]. Tectonics, 17(1): 1—27.