玛多MS7.4 地震对周边断层的应力影响分析

doi:10.3969/j.issn.0253-4967.2021.05.001

摘要/Abstract

摘要：

2021年5月22日青海玛多 M_S7.4 地震的发震断层并不是传统意义上的巴颜喀拉块体北边界, 而是发生在巴颜喀拉块体内部一条与东昆仑断裂带主断裂近平行的次级断层上, 针对玛多地震对周边断层尤其是巴颜喀拉块体主边界造成的应力影响亟需开展研究工作。文中利用中国大陆岩石圈统一地震速度模型USTClitho1.0结果完成了研究区的岩石圈结构分层设置, 结合InSAR形变场及余震精定位结果反演得到玛多地震的同震滑动模型, 通过考虑更符合岩石圈实际变形过程的Burgers流变模型, 利用PSGRN/PSCMP程序计算得到玛多地震引起的震源区及周边断层的同震及震后黏弹性库仑应力变化。研究结果表明, 玛多 M_S7.4 地震震源区同震库仑应力加载区除沿发震断层破裂面分布外, 在发震断层的西端、东端分别有3处库仑应力变化正值区, 其中西端朝向发震断层的NW方向, 东端存在2处库仑应力加载区, 分别朝向发震断层的北部以及东部区域, 周边断层同震库仑应力变化正值段的分布与震源区库仑应力加载区的分布较为一致; 玛多地震引起的东昆仑断裂带近震源区段、昆中断裂东段、甘德南缘断裂西北段、五道梁-长沙贡玛断裂中段的同震库仑应力变化均>0.01MPa, 且震后岩石圈黏弹性松弛作用使得上述断层的黏弹性库仑应力进一步增加, 未来应重点关注上述断层段的地震危险性。

关键词: 玛多7.4级地震, Burgers流变模型, 同震库仑应力, 黏弹性库仑应力

Abstract:

The seismogenic fault of the Maduo M_S7.4 earthquake in Qinghai Province on May 22, 2021 is not on the conventionally north boundary of the Bayan Har Block, but a secondary fault named Kunlunshankou-Jiangcuo Fault inside the Bayan Har Block which is nearly parallel to the East Kunlun Fault, with a distance of about 70km. As a result, the study on the stress effect of the Maduo earthquake on surrounding faults is urgent, especially on the main boundary faults of the Bayan Har Block, such as the East Kunlun Fault. In this paper, the lithospheric structure of the study area is stratified by using the USTClitho1.0 results of the unified seismic velocity model of the lithosphere in Chinese mainland. The co-seismic slip model of the Maduo earthquake is inversed by the results of InSAR deformation field and precise aftershock location. The model reveals that the coseismic slip of this earthquake is mainly sinistral strike-slip, the fault strike is 276 degrees, the dip angle is 80 degrees, the average rake angle is 4 degrees, the maximum slip is about 5.1m, and the main slip area is mainly concentrated on the depth of 0~15km. By considering the Burgers rheological model which is more consistent with the actual deformation process of lithosphere, the paper calculates the co-seismic Coulomb stresses and viscoelastic Coulomb stresses in the source area and peripheral faults induced by the Maduo earthquake by using PSGRN/PSCMP program.
The results show that, besides the fracture surface of the seismogenic fault, there are three positive co-seismic Coulomb stress change areas on the west and east ends of the seismogenic fault, of which the stress loading area on the west end is oriented toward the northwest of the seismogenic fault, and the other two stress loading areas on the east end are toward the north and east of the seismogenic fault. The positive section of co-seismic Coulomb stress change of the peripheral faults is consistent with the distribution of the source area. The co-seismic Coulomb stress change induced by Maduo earthquake is bigger than 0.01MPa on the near source section of East Kunlun Fault, the east section of Kunzhong Fault, the northwest segment of Gande-Nanyuan Fault and the middle segment of Wudaoliang-Changshagongma Fault. The maximum co-seismic Coulomb stress changes at the depth of 12.5km reach 0.165MPa, 0.022MPa, 0.102MPa and 0.012MPa, respectively, which proves that the Maduo M_S7.4 earthquake has a strong seismic triggering effect on the above faults. By comparison, the impact of Maduo M_S7.4 on co-seismic Coulomb stress change is also positive in the middle section of Longriba Fault, the south section of Xianshuihe Fault and the north section of Longmenshan Fault, but the magnitude is relatively smaller(less than 0.01MPa), in which the co-seismic Coulomb stress change in the middle section of Longriba Fault increases by thousands of Pa, while the co-seismic Coulomb stress change in the south section of Xianshuihe Fault and the north section of Longmenshan Fault increases by only tens to hundreds of Pa.
For the fault sections with co-seismic Coulomb stress change bigger than 0.01MPa mentioned above, their viscoelastic Coulomb stress changes during 50 years are calculated. The results show that the viscoelastic relaxation of lithosphere after the Maduo earthquake further increases the viscoelastic Coulomb stress changes on the above faults, especially the East Kunlun Fault, where the cumulative Coulomb stress will be increased by 0.038MPa after 50 years. The seismic triggering effect of Maduo earthquake on the above faults will continue to increase over time and more attention should be paid to the seismic risk of the above faults in the future.

Key words: Maduo M_S7.4 earthquake, Burgers rheological model, co-seismic Coulomb stress, viscoelastic Coulomb stress

中图分类号:

P315.2

岳冲, 屈春燕, 牛安福, 赵德政, 赵静, 余怀忠, 王亚丽. 玛多M_S7.4 地震对周边断层的应力影响分析[J]. 地震地质, 2021, 43(5): 1041-1059.

YUE Chong, QU Chun-yan, NIU An-fu, ZHAO De-zheng, ZHAO Jing, YU Huai-zhong, WANG Ya-li. ANALYSIS OF STRESS INFLUENCE OF QINGHAI MADUO M_S7.4 EARTHQUAKE ON SURROUNDING FAULTS[J]. SEISMOLOGY AND EGOLOGY, 2021, 43(5): 1041-1059.

图/表 8

参考文献 55

[1]	程佳, 姚生海, 刘杰, 等. 2018. 2017年九寨沟地震所受历史地震黏弹性库仑应力作用及其后续对周边断层地震危险性的影响[J]. 地球物理学报, 61(5): 2133-2151.
	CHENG Jia, YAO Sheng-hai, LIU Jie, et al. 2018. Viscoelastic Coulomb stress of historical earthquakes on the 2017 Jiuzhaigou earthquake and the subsequent influence on the seismic hazards of adjacent faults[J]. Chinese Journal of Geophysics, 61(5): 2133-2151. (in Chinese)
[2]	邓起东, 程绍平, 马冀, 等. 2014. 青藏高原地震活动特征及当前地震活动形势[J]. 地球物理学报, 57(7): 2025-2042. doi: 10.6038/cjg20140701. DOI
	DENG Qi-dong, CHENG Shao-ping, MA Ji, et al. 2014. Seismic activities and earthquake potential in the Tibetan plateau[J]. Chinese Journal of Geophysics, 57(7): 2025-2042. (in Chinese)
[3]	邓起东, 高翔, 陈桂华, 等. 2010. 青藏高原昆仑-汶川地震系列与巴颜喀喇断块的最新活动[J]. 地学前缘, 17(5): 163-178.
	DENG Qi-dong, GAO Xiang, CHEN Gui-hua, et al. 2010. Recent tectonic activity of Bayankala fault-block and the Kunlun-Wenchuan earthquake series of the Tibetan plateau[J]. Earth Science Frontiers, 17(5): 163-178. (in Chinese)
[4]	国家地震局震害防御司. 1995. 中国历史强震目录 [Z]. 北京: 地震出版社.
	Department of Seismic Hazard Prevention, China Earthquake Administration. 1995. The Catalogue of Chinese Historical Strong Earthquakes [Z]. Seismological Press, Beijing. (in Chinese)
[5]	华俊, 赵德政, 单新建, 等. 2021. 2021年青海玛多 M_W7.3 地震InSAR的同震形变场、断层滑动分布及其对周边区域的应力扰动[J]. 地震地质, 43(3): 677-691. doi: 10.3969/j.issn.0253-4967.2021.03.013. DOI
	HUA Jun, ZHAO De-zheng, SHAN Xin-jian, et al. 2021. Coseismic deformation field, slip distribution and Coulomb stress disturbance of the 2021 M_W7.3 Maduo earthquake using Sentinel-1 InSAR observations[J]. Seismology and Geology, 43(3): 677-691. (in Chinese)
[6]	雷兴林, 马胜利, 苏金蓉, 等. 2013. 汶川地震后中下地壳及上地幔的黏弹性效应引起的应力变化与芦山地震的发生机制[J]. 地震地质, 35(2): 411-422. doi: 10.3969/j.issn.0253-4967.2013.02.019. DOI
	LEI Xing-lin, MA Sheng-li, SU Jin-rong, et al. 2013. Inelastic triggering of the 2013 M_W6.6 Lushan earthquake by the 2008 M_W7.9 Wenchuan earthquake[J]. Seismology and Geology, 35(2): 411-422. (in Chinese)
[7]	梁明剑, 杨耀, 杜方, 等. 2020. 青海达日断裂中段晚第四纪活动性与1947年M7¾地震地表破裂带再研究[J]. 地震地质, 42(3): 703-714. doi: 10.3969/j.issn.0253-4967.2020.03.011. DOI
	LIANG Ming-jian, YANG Yao, DU Fang, et al. 2020. Late Quaternary activity of the central segment of the Dari Fault and restudy of the surface rupture zone of the 1947 M7¾ Dari earthquake, Qinghai Province[J]. Seismology and Geology, 42(3): 703-714. (in Chinese)
[8]	马保起, 苏刚, 侯治华, 等. 2005. 利用岷江阶地的变形估算龙门山断裂带中段晚第四纪滑动速率[J]. 地震地质, 27(2): 234-242.
	MA Bao-qi, SU Gang, HOU Zhi-hua, et al. 2005. Late Quaternary slip rate in the central part of the Longmenshan fault zone from terrace deformation along the Minjiang River[J]. Seismology and Geology, 27(2): 234-242. (in Chinese)
[9]	任金卫, 王敏. 2005. GPS观测的2001年昆仑山口西 M_S8.1 地震地壳变形[J]. 第四纪研究, 25(1): 34-44.
	REN Jin-wei, WANG Min. 2005. GPS measured crustal deformation of the M_S8.1 Kunlun earthquake on November 14th 2001 in Qinghai-Xizang plateau[J]. Quaternary Sciences, 25(1): 34-44. (in Chinese)
[10]	任俊杰, 徐锡伟, 张世民, 等. 2017. 东昆仑断裂带东端的构造转换与2017年九寨沟 M_S7.0 地震孕震机制[J]. 地球物理学报, 60(10): 4027-4045.
	REN Jun-jie, XU Xi-wei, ZHANG Shi-min, et al. 2017. Tectonic transformation at the eastern termination of the eastern Kunlun fault zone and seismogenic mechanism of the 8 August 2017 Jiuzhaigou M_S70 earthquake[J]. Chinese Journal of Geophysics, 60(10): 4027-4045. (in Chinese)
[11]	任天翔, 程惠红, 张贝, 等. 2018. 2001年昆仑山口西 M_S8.1 地震对周围断层的应力影响数值分析[J]. 地球物理学报, 61(12): 4838-4850.
	REN Tian-xiang, CHENG Hui-hong, ZHANG Bei, et al. 2018. Numerical study on the co-seismic stress changes of surrounding faults due to the M_S8.1 earthquake, 2001, Kokoxili earthquake[J]. Chinese Journal of Geophysics, 61(12): 4838-4850. (in Chinese)
[12]	邵志刚, 傅容珊, 薛霆虓, 等. 2008. 震后短期和长期形变模拟: 以1960年智利 M_W9.5 地震为例[J]. 地震学报, 30(4): 405-415.
	SHAO Zhi-gang, FU Rong-shan, XUE Ting-xiao, et al. 2008. Modeling transient and long-term postseismic deformation: A case study of 1960 M_W9.5 Chile earthquake[J]. Acta Seismologica Sinica, 30(4): 405-415. (in Chinese)
[13]	沈正康, 万永革, 甘卫军, 等. 2003. 东昆仑活动断裂带大地震之间的黏弹性应力触发研究[J]. 地球物理学报, 46(6): 786-795.
	SHEN Zheng-kang, WAN Yong-ge, GAN Wei-jun, et al. 2003. Viscoelastic triggering among lager earthquakes along the east Kunlun fault system[J]. Chinese Journal of Geophysics, 46(6): 786-795. (in Chinese)
[14]	石耀霖, 曹建玲. 2008. 中国大陆岩石圈等效黏滞系数的计算和讨论[J]. 地学前缘, 15(3): 82-95.
	SHI Yao-lin, CAO Jian-ling. 2008. Effective viscosity of China continental lithosphere[J]. Earth Science Frontiers, 15(3): 82-95. (in Chinese) DOI URL
[15]	石耀霖, 曹建玲. 2010. 库仑应力计算及应用过程中若干问题的讨论: 以汶川地震为例[J]. 地球物理学报, 53(1): 102-110.
	SHI Yao-lin, CAO Jian-ling. 2010. Some aspects in static stress change calculation: Case study on Wenchuan earthquake[J]. Chinese Journal of Geophysics, 53(1): 102-110. (in Chinese)
[16]	万永革, 沈正康, 曾跃华, 等. 2007. 青藏高原东北部的库仑应力积累演化对大地震发生的影响[J]. 地震学报, 29(2): 115-129.
	WAN Yong-ge, SHEN Zheng-kang, ZENG Yue-hua, et al. 2007. Evolution of cumulative Coulomb failure stress in northeastern Qinghai-Xizang(Tibetan)plateau and its effect on large earthquake occurrence[J]. Acta Seismologica Sinica, 29(2): 115-129. (in Chinese)
[17]	闻学泽. 2000. 四川西部鲜水河-安宁河-则木河断裂带的地震破裂分段特征[J]. 地震地质, 22(3): 239-249.
	WEN Xue-ze. 2000. Character of rupture segmentation of the Xianshuihe-Anninghe-Zemuhe fault zone, western Sichuan[J]. Seismology and Geology, 22(3): 239-249. (in Chinese)
[18]	闻学泽, 杜方, 张培震, 等. 2011. 巴颜喀拉块体北和东边界大地震序列的关联性与2008年汶川地震[J]. 地球物理学报, 54(3): 706-716.
	WEN Xue-ze, DU Fang, ZHANG Pei-zhen, et al. 2011. Correlation of major earthquake sequences on the northern and eastern boundaries of the Bayan Har block, and its relation to the 2008 Wenchuan earthquake[J]. Chinese Journal of Geophysics, 54(3): 706-716. (in Chinese)
[19]	解朝娣, 朱元清, 雷兴林, 等. 2010. M_S8.0 汶川地震产生的应力变化空间分布及其对地震活动性的影响[J]. 中国科学(D辑), 40(6): 688-698.
	XIE Zhao-di, ZHU Yuan-qing, LEI Xing-lin, et al. 2010. Pattern of stress change and its effect on seismicity rate caused by M_S8.0 Wenchuan earthquake[J]. Science of China(Ser D), 40(6): 688-698. (in Chinese)
[20]	熊仁伟, 任金卫, 张军龙, 等. 2010. 玛多-甘德断裂甘德段晚第四纪活动特征[J]. 地震, 30(4): 65-73.
	XIONG Ren-wei, REN Jin-wei, ZHANG Jun-long, et al. 2010. Late Quaternary active characteristics of the Gande segment in the Maduo-Gande fault zone[J]. Earthquake, 30(4): 65-73. (in Chinese)
[21]	熊维, 谭凯, 刘刚, 等. 2015. 2015年尼泊尔 M_W7.9 地震对青藏高原活动断裂同震、震后应力影响[J]. 地球物理学报, 58(11): 4305-4316.
	XIONG Wei, TAN Kai, LIU Gang, et al. 2015. Coseismic and postseismic Coulomb stress changes on the surrounding major faults caused by the 2015 Nepal M_W7.9 earthquake[J]. Chinese Journal of Geophysics, 58(11): 4305-4316. (in Chinese)
[22]	易桂喜, 龙锋, 梁明剑, 等. 2017. 2017年8月8日九寨沟M7.0地震及余震震源机制解与发震构造分析[J]. 地球物理学报, 60(10): 4083-4097.
	YI Gui-xi, LONG Feng, LIANG Ming-jian, et al. 2017. Focal mechanism solution and seismogenic structure of the 8 August 2017 M70 Jiuzhaigou earthquake and its aftershocks, northern Sichuan[J]. Chinese Journal of Geophysics, 60(10): 4083-4097. (in Chinese)
[23]	詹艳, 梁明剑, 孙翔宇, 等. 2021. 2021年5月22日青海玛多 M_S7.4 地震深部环境及发震构造模式[J]. 地球物理学报, 64(7): 2232-2252.
	ZHAN Yan, LIANG Ming-jian, SUN Xiang-yu, et al. 2021. Deep structure and seismogenic pattern of the 2021.5.22 Maduo(Qinghai) M_S7.4 earthquake[J]. Chinese Journal of Geophysics, 64(7): 2232-2252. (in Chinese)
[24]	郑文俊, 袁道阳, 何文贵, 等. 2013. 甘肃东南地区构造活动与2013年岷县-漳县 M_S6.6 地震孕震机制[J]. 地球物理学报, 56(12): 4058-4071.
	ZHENG Wen-jun, YUAN Dao-yang, HE Wen-gui, et al. 2013. Geometric pattern and active tectonics in southeastern Gansu Province: Discussion on seismogenic mechanism of the Minxian-Zhangxian M_S6.6 earthquake on July 22, 2013[J]. Chinese Journal of Geophysics, 56(12): 4058-4071. (in Chinese)
[25]	中国地震局震害防御司. 1999. 中国近代地震目录(公元1912-1990年)[Z]. 北京: 中国科学技术出版社.
	Department of Seismic Hazard Prevention, China Earthquake Administration. 1999. Catalogue of Recent Chinese Earthquakes(1912-1990, M_S≥4.7)[Z]. China Science and Technology Press, Beijing. (in Chinese)
[26]	Ali S T, Freed A M, Calais E, et al. 2008. Coulomb stress evolution in northeastern Caribbean over the past 250 years due to coseismic, postseismic and interseismic deformation[J]. Geophysical Journal International, 174(3): 904-918. DOI URL
[27]	Allen C R, Luo Z L, Qian H, et al. 1991. Field study of a highly active fault zone: The Xianshuihe Fault of southwestern China[J]. Geological Society of America Bulletin, 103(9): 1178-1199. DOI URL
[28]	Cattin R, Avouac J P. 2000. Modeling mountain building and the seismic cycle in the Himalaya of Nepal[J]. Journal of Geophysical Research: Solid Earth, 105(B6): 13389-13407.
[29]	Cotton F, Coutant O. 1997. Dynamic stress variations due to shear faults in a plane-layered medium[J]. Geophysical Journal International, 128(3): 676-688. DOI URL
[30]	Diao F Q, Xiong X, Wang R J. 2010. Mechanisms of transient postseismic deformation following the 2001 M_W7.8 Kunlun(China)earthquake[J]. Pure and Applied Geophysics, 168(5): 767-779. doi: 10.1007/s00024-010-0154-5. DOI URL
[31]	Freed A M. 2005. Earthquake triggering by static, dynamic, and postseismic stress transfer[J]. Annual Review of Earth and Planetary Sciences, 33(1): 335-367. DOI URL
[32]	Freed A M, Lin J. 1998. Time-dependent changes in failure stress following thrust earthquakes[J]. Journal of Geophysical Research: Solid Earth, 103(B10): 24393-24409.
[33]	Freed A M, Lin J. 2001. Delayed triggering of the 1999 Hector Mine earthquake by viscoelastic stress transfer[J]. Nature, 411(6834): 180-183. DOI URL
[34]	Gan W J, Zhang P Z, Shen Z K, et al. 2007. Present-day crustal motion within the Tibetan plateau inferred from GPS measurements[J]. Journal of Geophysical Research: Solid Earth, 112(B8): B08416.
[35]	Hetland E A, Hager B H. 2006. The effects of rheological layering on post-seismic deformation[J]. Geophysical Journal International, 166(1): 277-292. DOI URL
[36]	Hilley G E, Bürgmann R, Zhang P Z, et al. 2005. Bayesian inference of plastosphere viscosities near the Kunlun Fault, northern Tibet[J]. Geophysical Research Letters, 32(1): L01302.
[37]	Huang J, Zhao D. 2006. High-resolution mantle tomography of China and surrounding regions[J]. Journal of Geophysical Research: Solid Earth, 111(B9): B09305.
[38]	Johnson K M, Hilley G E, Burgmann R. 2007. Influence of lithosphere viscosity structure on estimates of fault slip rate in the Mojave region of the San Andreas fault system[J]. Journal of Geophysical Research: Solid Earth, 112(B7): B07408.
[39]	Kilb D. 2003. A strong correlation between induced peak dynamic Coulomb stress change from the 1992 M 7.3 Landers, California, earthquake and the hypocenter of the 1999 M 7.1 Hector Mine, California, earthquake[J]. Journal of Geophysical Research: Solid Earth, 108(B1): ESE3-1-ESE3-7.
[40]	Kirby E, Harkins N, Wang E, et al. 2007. Slip rate gradients along the eastern Kunlun Fault[J]. Tectonics, 26(2): p. TC2010.1-TC2010.16.
[41]	Kirby E, Whipple K X, Burchfiel B C, et al. 2000. Neotectonics of the Min Shan, China: Implications for mechanisms driving Quaternary deformation along the eastern margin of the Tibetan plateau[J]. Geological Society of America Bulletin, 112(3): 375-393. DOI URL
[42]	Lay T, Wallace T C. 1995. Modern Global Seismology[M]. Academic Press.
[43]	Liu Q Y, van der Hilst R D, Li Y, et al. 2014. Eastward expansion of the Tibetan plateau by crustal flow and strain partitioning across faults[J]. Nature Geoscience, 7(5): 361-365. doi: 10.1038/ngeo2130. DOI URL
[44]	Okada Y. 1985. Surface deformation due to shear and tensile faults in a half space[J]. Bulletin of the Seismological Society of America, 75(4): 1135-1154. DOI URL
[45]	Ren J J, Xu X W, Yeats R S, et al. 2013a. Millennial slip rates of the Tazang Fault, the eastern termination of Kunlun Fault: Implications for strain partitioning in eastern Tibet[J]. Tectonophysics, 608(1): 1180-1200. doi: 10.1016/j.tecto.2013.06.026. DOI URL
[46]	Ren J J, Xu X W, Yeats R S, et al. 2013b. Holocene paleoearthquakes of the Maoergai Fault, eastern Tibet[J]. Tectonophysics, 590(1): 121-135. doi: 10.1016/j.tecto.2013.01.017. DOI URL
[47]	Ren J J, Xu X W, Yeats R S, et al. 2013c. Latest Quaternary paleoseismology and slip rates of the Longriba fault zone, eastern Tibet: Implications for fault behavior and strain partitioning[J]. Tectonics, 32(2): 216-238. doi: 10.1002/tect.20029. DOI URL
[48]	Ryder I, Bürgmann R, Pollitz F. 2011. Lower crustal relaxation beneath the Tibetan plateau and Qaidam Basin following the 2001 Kokoxili earthquake[J]. Geophysical Journal International, 187(2): 613-630. doi: 10.1111/j.1365-246x.2011.05179.x. DOI URL
[49]	Wang R J, Lorenzo-Martin F, Roth F. 2006. PSGRN/PSCMP: A new code for calculating co- and post-seismic deformation, geoid and gravity changes based on the viscoelastic-gravitational dislocation theory[J]. Computers & Geosciences, 32(4): 527-541. DOI URL
[50]	Wang R, Motagh M R, Walter T R. 2008. Inversion of slip distribution from co-seismic deformation data by a sensitivity based iterative fitting method[C]. EGU General Assembly, Vienna, Austria, 10: EGU2008-A-07971.
[51]	Xin H L, Zhang H J, Min K, et al. 2018. High-resolution lithospheric velocity structure of continental China by double-difference seismic travel-time tomography[J]. Seismological Research Letters, 90(1): 229-241. doi: 10.1785/0220180209. DOI URL
[52]	Yao H J, Beghein C, van der Hilst R D. 2018. Surface wave array tomography in SE Tibet from ambient seismic noise and two-station analysis-Ⅱ. Crustal and upper-mantle structure[J]. Geophysical Journal International, 173(1): 205-219. DOI URL
[53]	Yao H J, van der Hilst R D, de Hoop M V. 2006. Surface-wave array tomography in SE Tibet from ambient seismic noise and two-station analysis-Ⅰ. Phase velocity maps[J]. Geophysical Journal International, 166(2): 732-744. DOI URL
[54]	Zhang H P, Liu S F, Yang N, et al. 2006. Geomorphic characteristics of the Minjiang drainage basin(eastern Tibetan plateau)and its tectonic implications: New insights from a digital elevation model study[J]. Island Arc, 15(2): 239-250. DOI URL
[55]	Zhang Z J, Yuan X H, Chen Y, et al. 2010. Seismic signature of the collision between the east Tibetan escape flow and the Sichuan Basin[J]. Earth and Planetary Science Letters, 292(3-4): 254-264. doi: 10.1016/j.pngl.2010.01.046. DOI URL

序号	深度/km	V_P/km·s^-1	V_S/km·s^-1	ρ/kg·m^-3	η_k/Pa·s	η_m/Pa·s
1	0	4.50	2.60	2 600	1.00×10²¹	1.00×10²²
2	5	5.60	3.30	2 600	1.00×10²¹	1.00×10²²
3	5	5.60	3.30	2 700	1.00×10²¹	1.00×10²²
4	10	6.05	3.55	2 700	1.00×10²¹	1.00×10²²
5	10	6.05	3.55	2 850	1.00×10²¹	1.00×10²²
6	15	6.05	3.60	2 850	1.00×10²¹	1.00×10²²
7	15	6.05	3.60	2 850	1.00×10²¹	1.00×10²²
8	20	5.75	3.40	2 850	1.00×10²¹	1.00×10²²
9	20	5.75	3.40	2 850	2.00×10¹⁹	2.00×10²⁰
10	30	5.75	3.40	2 850	2.00×10¹⁹	2.00×10²⁰
11	30	5.75	3.40	3 000	6.30×10¹⁸	6.30×10¹⁹
12	40	6.10	3.55	3 000	6.30×10¹⁸	6.30×10¹⁹
13	40	6.10	3.55	3 000	6.30×10¹⁸	6.30×10¹⁹
14	50	6.10	3.55	3 000	6.30×10¹⁸	6.30×10¹⁹
15	50	6.10	3.55	3 100	6.30×10¹⁸	6.30×10¹⁹
16	60	7.10	4.05	3 100	6.30×10¹⁸	6.30×10¹⁹
17	60	7.10	4.05	3 100	6.30×10¹⁸	6.30×10¹⁹
18	80	8.00	4.35	3 100	1.00×10²⁰	1.00×10²¹
19	80	8.00	4.35	3 320	1.00×10²⁰	1.00×10²¹
20	100	7.95	4.35	3 320	1.00×10²⁰	1.00×10²¹

序号	深度/km	V_P/km·s^-1	V_S/km·s^-1	ρ/kg·m^-3	η_k/Pa·s	η_m/Pa·s
1	0	4.50	2.60	2 600	1.00×10²¹	1.00×10²²
2	5	5.60	3.30	2 600	1.00×10²¹	1.00×10²²
3	5	5.60	3.30	2 700	1.00×10²¹	1.00×10²²
4	10	6.05	3.55	2 700	1.00×10²¹	1.00×10²²
5	10	6.05	3.55	2 850	1.00×10²¹	1.00×10²²
6	15	6.05	3.60	2 850	1.00×10²¹	1.00×10²²
7	15	6.05	3.60	2 850	1.00×10²¹	1.00×10²²
8	20	5.75	3.40	2 850	1.00×10²¹	1.00×10²²
9	20	5.75	3.40	2 850	2.00×10¹⁹	2.00×10²⁰
10	30	5.75	3.40	2 850	2.00×10¹⁹	2.00×10²⁰
11	30	5.75	3.40	3 000	6.30×10¹⁸	6.30×10¹⁹
12	40	6.10	3.55	3 000	6.30×10¹⁸	6.30×10¹⁹
13	40	6.10	3.55	3 000	6.30×10¹⁸	6.30×10¹⁹
14	50	6.10	3.55	3 000	6.30×10¹⁸	6.30×10¹⁹
15	50	6.10	3.55	3 100	6.30×10¹⁸	6.30×10¹⁹
16	60	7.10	4.05	3 100	6.30×10¹⁸	6.30×10¹⁹
17	60	7.10	4.05	3 100	6.30×10¹⁸	6.30×10¹⁹
18	80	8.00	4.35	3 100	1.00×10²⁰	1.00×10²¹
19	80	8.00	4.35	3 320	1.00×10²⁰	1.00×10²¹
20	100	7.95	4.35	3 320	1.00×10²⁰	1.00×10²¹

断层名称		活动时代	断层性质	走向/(°)	倾角/(°)	滑动角/(°)
甘德南缘断裂(GDN-F)		更新世	左旋走滑	280~310	86	9
玉科断裂(YK-F)		更新世	左旋走滑	285~315	86	9
达日断裂(DR-F)		全新世	左旋走滑	275~315	81	5
巴颜喀拉主峰断裂(BRKL-F)		更新世	左旋走滑	300~325	72	-3
五道梁-长沙贡玛断裂(WDL-F)		更新世	左旋走滑	280~320	73	-4
鲜水河断裂(XSH-F)	北段XSH1	全新世	左旋走滑	310~325	73	-4
	中段XSH2	全新世	左旋走滑	315~335	86	11
	南段XSH3	全新世	左旋走滑	305~335	85	-1
龙日坝断裂(LRB-F)	北段LRB1	全新世	左旋走滑	165~180	75	0
	中段LRQ	全新世	逆冲兼走滑	220~340	75	135
	南段LRB2	全新世	逆冲兼走滑	220~340	75	135
毛尔盖断裂(MEG-F)		全新世	逆冲	200~235	60	90
抚边河断裂(FBH-F)		更新世	左旋走滑	295~325	71	12
龙门山断裂(LMS-F)	北段LMS1	全新世	右旋走滑	215~235	84	178
	中段LMS2	全新世	逆冲	220~235	68	63
	南段LMS3	全新世	逆冲	195~235	74	99
虎牙断裂(HY-F)	北段HY1	全新世	左旋走滑	150	65	40
	中段HY2	全新世	逆冲	155~175	60	90
	南段HY3	全新世	左旋走滑	165	65	40
树正断裂(SZ-F)		全新世	左旋走滑	148	79	-8
岷江断裂(MJ-F)	北段MJ1	全新世	逆冲兼走滑	1~15	65	45
	中段MJ2	全新世	逆冲兼走滑	160~180	75	45
	南段MJ3	全新世	逆冲兼走滑	179	70	45
塔藏断裂(TZ-F)	西段TZ1	全新世	左旋走滑	300~320	70	0
	中段TZ2	全新世	逆冲兼走滑	280~305	70	45
	东段TZ3	全新世	逆冲兼走滑	100~120	55	45
雪山梁子断裂(XS-F)		全新世	逆冲	265~285	65	90
东昆仑断裂(DKL-F)	西段	全新世	左旋走滑	275~290	61	-12
	东段	全新世	左旋走滑	275~320	83	-20
昆中断裂(KZ-F)		更新世	左旋走滑	265~295	88	29
柴达木南缘隐伏断裂(CDM-F)		更新世	逆冲	80~115	33	123
中铁断裂(ZT-F)		更新世	左旋走滑	265~300	61	-12
玛曲断裂(MQ-F)		全新世	逆冲兼走滑	290	80	45
白龙江断裂(BLJ-F)		全新世	逆冲兼走滑	290	75	45
光盖山断裂(GGS-F)		更新世	左旋走滑	110	81	-14
哈南-稻畦子断裂(HN-F)		全新世	左旋走滑	70	90	0
文县断裂(WX-F)		全新世	逆冲	75	60	90
青川断裂(QC-F)		更新世	右旋走滑	245	70	180
略阳-勉县断裂(LY-F)		更新世	右旋走滑	245	70	180
康县-勉略断裂(KX-F)		更新世	左旋走滑	280	75	20
临潭-宕昌断裂(LT-F)		更新世	逆冲	320	60	90
礼县-罗家堡断裂(LX-F)		更新世	左旋走滑	65	70	0
西秦岭北缘(XQL-F)		全新世	逆冲兼走滑	275	65	45
庄浪河断裂(ZLH-F)		更新世	逆冲	150~170	60	80
倒淌河-临夏断裂(DTH-F)		更新世	逆冲	290~300	78	102
日月山断裂(RYS-F)		全新世	右旋走滑	135~155	80	180
拉脊山断裂(LJS-F)		更新世	逆断	270~330	50	90
鄂拉山断裂(ELS-F)		全新世	右旋走滑	300~340	80	-170
马衔山断裂(MXS-F)		更新世	逆冲兼走滑	295~310	80	45

断层名称		活动时代	断层性质	走向/(°)	倾角/(°)	滑动角/(°)
甘德南缘断裂(GDN-F)		更新世	左旋走滑	280~310	86	9
玉科断裂(YK-F)		更新世	左旋走滑	285~315	86	9
达日断裂(DR-F)		全新世	左旋走滑	275~315	81	5
巴颜喀拉主峰断裂(BRKL-F)		更新世	左旋走滑	300~325	72	-3
五道梁-长沙贡玛断裂(WDL-F)		更新世	左旋走滑	280~320	73	-4
鲜水河断裂(XSH-F)	北段XSH1	全新世	左旋走滑	310~325	73	-4
	中段XSH2	全新世	左旋走滑	315~335	86	11
	南段XSH3	全新世	左旋走滑	305~335	85	-1
龙日坝断裂(LRB-F)	北段LRB1	全新世	左旋走滑	165~180	75	0
	中段LRQ	全新世	逆冲兼走滑	220~340	75	135
	南段LRB2	全新世	逆冲兼走滑	220~340	75	135
毛尔盖断裂(MEG-F)		全新世	逆冲	200~235	60	90
抚边河断裂(FBH-F)		更新世	左旋走滑	295~325	71	12
龙门山断裂(LMS-F)	北段LMS1	全新世	右旋走滑	215~235	84	178
	中段LMS2	全新世	逆冲	220~235	68	63
	南段LMS3	全新世	逆冲	195~235	74	99
虎牙断裂(HY-F)	北段HY1	全新世	左旋走滑	150	65	40
	中段HY2	全新世	逆冲	155~175	60	90
	南段HY3	全新世	左旋走滑	165	65	40
树正断裂(SZ-F)		全新世	左旋走滑	148	79	-8
岷江断裂(MJ-F)	北段MJ1	全新世	逆冲兼走滑	1~15	65	45
	中段MJ2	全新世	逆冲兼走滑	160~180	75	45
	南段MJ3	全新世	逆冲兼走滑	179	70	45
塔藏断裂(TZ-F)	西段TZ1	全新世	左旋走滑	300~320	70	0
	中段TZ2	全新世	逆冲兼走滑	280~305	70	45
	东段TZ3	全新世	逆冲兼走滑	100~120	55	45
雪山梁子断裂(XS-F)		全新世	逆冲	265~285	65	90
东昆仑断裂(DKL-F)	西段	全新世	左旋走滑	275~290	61	-12
	东段	全新世	左旋走滑	275~320	83	-20
昆中断裂(KZ-F)		更新世	左旋走滑	265~295	88	29
柴达木南缘隐伏断裂(CDM-F)		更新世	逆冲	80~115	33	123
中铁断裂(ZT-F)		更新世	左旋走滑	265~300	61	-12
玛曲断裂(MQ-F)		全新世	逆冲兼走滑	290	80	45
白龙江断裂(BLJ-F)		全新世	逆冲兼走滑	290	75	45
光盖山断裂(GGS-F)		更新世	左旋走滑	110	81	-14
哈南-稻畦子断裂(HN-F)		全新世	左旋走滑	70	90	0
文县断裂(WX-F)		全新世	逆冲	75	60	90
青川断裂(QC-F)		更新世	右旋走滑	245	70	180
略阳-勉县断裂(LY-F)		更新世	右旋走滑	245	70	180
康县-勉略断裂(KX-F)		更新世	左旋走滑	280	75	20
临潭-宕昌断裂(LT-F)		更新世	逆冲	320	60	90
礼县-罗家堡断裂(LX-F)		更新世	左旋走滑	65	70	0
西秦岭北缘(XQL-F)		全新世	逆冲兼走滑	275	65	45
庄浪河断裂(ZLH-F)		更新世	逆冲	150~170	60	80
倒淌河-临夏断裂(DTH-F)		更新世	逆冲	290~300	78	102
日月山断裂(RYS-F)		全新世	右旋走滑	135~155	80	180
拉脊山断裂(LJS-F)		更新世	逆断	270~330	50	90
鄂拉山断裂(ELS-F)		全新世	右旋走滑	300~340	80	-170
马衔山断裂(MXS-F)		更新世	逆冲兼走滑	295~310	80	45