RELATIONSHIP BETWEEN STRESS INTERACTION AND STRONG EARTHQUAKE ACTIVITY OF JIASHI EARTHQUAKES (MW≥6.0)SINCE 1998

doi:10.3969/j.issn.0253-4967.2021.02.002

Abstract

Abstract: Jiashi seismic region of Xinjiang is located at the junction of South Tianshan, Tarim Basin and Pamir. From January 1997 to March 2003, a series of strong earthquakes occurred in Jiashi area, Xinjiang. In particular, since January 21, 1997, 7 earthquakes with M_S>6 have occurred in the area in just 4 months, which is extremely rare in China and in the world. According to the theory of seismic stress triggering, earthquakes are interrelated with each other. When an earthquake occurs, it will regulate the stress state of its surrounding active faults, thus triggering or inhibiting the seismic risk of surrounding potential faults. Also, the viscoelastic relaxation theory believes that the rheological action of the hot lower crust and mantle will transfer the coseismic stress field changes of the lower crust and upper mantle to the upper crust seismogenic layer in a period ranging from years to hundreds of years after the earthquake. This in turn affects the mechanical properties of the fault.
We invert the focal characteristics of the two Jiashi earthquakes in 1998 and 2003, reconstruct the fault rupture model, and calculate the interaction stress between the two earthquakes and the M_W6.0 earthquake in 2020 based on the viscoelastic relaxation theory to study the triggering relationship among the three earthquakes. We use a viscoelastic layered semi-infinite space model(PSGRN/PSCMP program)to estimate the changes of fault stress caused by coseismic and post seismic deformation. At the same time, we study the influence of different model parameters, including viscosity coefficient, receiving fault parameters and earth medium model parameters, on the calculation results.
The results show that: 1)The 1998 earthquake is a typical sinistral strike-slip earthquake, with fault strike of 57°, dip angle of 81° and the focal depth of 11.5km. The 2003 earthquake is a thrust strike-slip type earthquake with focal depth of 15.2km, the seismogenic fault is a northward low dip angle reverse fault and the main rupture direction of the earthquake is SE, the strike angle is 293° and dip angle is 20°. According to the calculation of fault dip angle, the deepest rupture caused by two seismogenic faults is less than 20km; 2)The 1998 earthquake led to the increase of stress in the western section of the 2003 earthquake fault and the unloading of stress in the eastern section, which increased the stress in the vicinity of the epicenter of the 2003 earthquake by 0.01~1MPa, showing an obvious triggering effect. The first two earthquakes resulted in the increase of stress in the eastern section of the 2020 earthquake fault, but the increase of stress at the epicenter was not more than 0.006MPa, which did not have an obvious triggering effect. This earthquake was mainly caused by other factors, possibly including the tectonic loading or viscoelastic triggering of previous big earthquakes; 3)Considering that there are many factors affecting the distribution of Coulomb stress on the fault, we calculated the stress distribution with different parameters, and the results show that the change of parameters has no obvious effect on the results. In the mutual triggering relationship between the earthquakes, the effect of viscoelastic relaxation after earthquake is not obvious, and the effect of coseismic stress step change is dominant. This may be due to the fact that the fractures caused by the two earthquakes are concentrated in the shallow part, and the coseismic stress in the deep part is relatively small, so the viscoelastic relaxation effect is not obvious. Our stress results are in good agreement with the aftershock distribution obtained by previous relocation methods. The results show that after a long-term stress evolution, the stress loading of the eastern segment of the 2003 earthquake fault is still more than 0.01MPa, so the seismic risk monitoring of this segment should be strengthened. Our results have certain significance for understanding the mechanism and regular pattern of earthquake occurrence in Jiashi area.

Key words: Jiashi earthquake, stress triggering, viscoelastic relaxation

摘要： 新疆伽师地区位于南天山、塔里木盆地和帕米尔3个构造系统的交接部位, 20世纪末—21世纪初该区在短时间内发生了一系列强震。地震应力触发理论认为, 地震之间存在相互联系。文中反演了1998年和2003年2次伽师地震的震源特征, 重建了断层破裂模型; 之后基于黏弹性松弛理论, 计算了2次地震与2020年M_W6.0地震的相互应力作用, 并研究三者之间的触发关系。结果表明, 1998年地震导致2003年地震发震断层西段的应力增加, 东段应力卸载, 使得2003年地震震源处附近的应力增加了0.01~1MPa, 前者对后者具有明显的触发作用; 前2个地震导致2020年地震发震断层东段的应力增加, 但震中位置处增加的应力≤0.006MPa, 不具有明显的触发作用, 2020年地震的发生主要由其他因素导致, 可能为构造运动加载或以前大地震黏弹性触发所致。在相互触发关系中, 震后黏弹性松弛产生的作用不明显, 同震应力阶变的作用占主导地位。文中结果对于认识伽师地区地震的发生机理和规律具有一定的意义。

关键词: 伽师地震, 应力触发, 黏弹性松弛

CLC Number:

P315.72⁺7

ZHOU Yun, PAN Zheng-yang, WANG Wei-min, HE Jian-kun, WANG Xun, LI Guo-hui. RELATIONSHIP BETWEEN STRESS INTERACTION AND STRONG EARTHQUAKE ACTIVITY OF JIASHI EARTHQUAKES (M_W≥6.0)SINCE 1998[J]. SEISMOLOGY AND GEOLOGY, 2021, 43(2): 280-296.

周云, 潘正洋, 王卫民, 何建坤, 王洵, 李国辉. 1998年以来伽师地震(M_W≥6.0)应力相互作用与强震活动的关系[J]. 地震地质, 2021, 43(2): 280-296.

References

[1] 何玉梅, 郑天愉, 单新建. 2001. 1996年3月19日新疆阿图什6.9级地震: 单侧破裂过程[J]. 地球物理学报, 44(4): 510—519.
HE Yu-mei, ZHENG Tian-yu, SHAN Xin-jian. 2001. The 1996 Artux, Xinjiang, earthquake: A unilateral rupture event[J]. Chinese Journal of Geophysics, 44(4): 510—519(in Chinese).
[2] 黄媛, 杨建思, 张天中. 2006. 2003年新疆巴楚-伽师地震序列的双差法重新定位研究[J]. 地球物理学报, 49(1): 162—169.
HUANG Yuan, YANG Jian-si, ZHANG Tian-zhong. 2006. Relocation of the Bachu-Jiashi, Xinjiang earthquake sequence in 2003 using the double-difference location algorithm[J]. Chinese Journal of Geophysics, 49(1): 162—169(in Chinese).
[3] 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. https://kns.cnki.netkcmsdetail/11.2982.P.20200608.1616.178.html.
LI Cheng-long, ZHANG Guo-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. https://kns.cnki.netkcmsdetail/11.2982.P.20200608.1616.178.html(in Chinese).
[4] 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 Xingjiang Jiashi strong earthquake region and discussion on its seismic genesis[J]. Chinese Journal of Geophysics, 43(3): 356—365(in Chinese).
[5] 卢双疆, 何建坤. 2013. 青藏高原—天山大陆内部地壳变形三维数值模拟研究[J]. 地球物理学进展, 28(2): 624—632.
LU Shuang-jiang, HE Jian-kun. 2013. Three-dimensional mechanical modeling of intracontinental deformation around the Tibetan plateau and Tienshan regions[J]. Progress in Geophysics, 28(2): 624—632(in Chinese).
[6] 冉慧敏, 上官文明, 刘东亚. 2020. 2020年1月19日新疆伽师M_S6.4地震及余震序列定位研究[J]. 内陆地震, 34(1): 56—62.
RAN Hui-min, SHANGGUAN Wen-ming, LIU Dong-ya. 2020. Location study of Xinjiang Jiashi M_S6.4 earthquake and aftershocks sequence on January 19th, 2020[J]. Inland Earthquake, 34(1): 56—62(in Chinese).
[7] 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 in Feb. 24, 2003[J]. Seismology and Geology, 28(2): 205—212(in Chinese).
[8] 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 between large earthquakes along the east Kunlun fault system[J]. Chinese Journal of Geophysics, 46(6): 786—795(in Chinese).
[9] 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): 84—97.
SHI Yao-lin, CAO Jian-ling. 2008. Effective viscosity of China continental lithosphere[J]. Earth Science Frontiers, 15(3): 84—97(in Chinese).
[10] 万永革, 沈正康, 盛书中, 等. 2009. 2008年汶川大地震对周围断层的影响[J]. 地震学报, 31(2): 128—139.
WAN Yong-ge, SHEN Zheng-kang, SHENG Shu-zhong, et al. 2009. The influence of 2008 Wenchuan earthquake on surrounding faults[J]. Acta Seismologica Sinica, 31(2): 128—139(in Chinese).
[11] 王琼, 王海涛. 2007. 伽师强震群活动过程应力触发作用研究[J]. 中国地震, 23(1): 35—46.
WANG Qiong, WANG Hai-tao. 2007. Study on stress triggering during activity process of the Jiashi strong earthquake swarm[J]. Earthquake Research in China, 23(1): 35—46(in Chinese).
[12] 王卫民, 赵连锋, 李娟, 等. 2008. 四川汶川8.0级地震震源过程[J]. 地球物理学报, 51(5): 1403—1410.
WANG Wei-min, ZHAO Lian-feng, LI Juan, et al. 2008. Rupture process of the M_S8.0 Wenchuan earthquake of Sichuan, China[J]. Chinese Journal of Geophysics, 51(5): 1403—1410(in Chinese).
[13] 谢小碧, 姚振兴. 1989. 计算分层介质中位错点源静态位移场的广义反射、透射系数矩阵和离散波数方法[J]. 地球物理学报, 32(3): 270—280.
XIE Xiao-bi, YAO Zhen-xing. 1989. A generalized reflection-transmition coefficient matrix method to calculate static displacement field of a stratified half-space by dislocation source[J]. Chinese Journal of Geophysics, 32(3): 270—280(in Chinese).
[14] 徐锡伟, 张先康, 冉勇康, 等. 2006. 南天山地区巴楚-伽师地震(M_S6.8)发震构造初步研究[J]. 地震地质, 28(2): 161—178.
XU Xi-wei, ZHANG Xian-kang, RAN Yong-kang, et al. 2006. The preliminary study on seismotectonics of the 2003 AD Bachu-jiashi earthquake(M_S6.8), southern Tian Shan[J]. Seismology and Geology, 28(2): 161—178(in Chinese).
[15] 尹凤玲, 蒋长胜, 韩立波. 2017. 1833年嵩明8.0级地震对周围断层的影响[J]. 地震地磁观测与研究, 38(3): 67—75.
YIN Feng-ling, JIANG Chang-sheng, HAN Li-bo. 2017. The influence of 1833 Songming M8.0 earthquake on surrounding faults[J]. Seismological and Geomagnetic Observation and Research, 38(3): 67—75(in Chinese).
[16] 张国宏, 单新建, 李卫东. 2008. 汶川M_S8.0地震库仑破裂应力变化及断层危险性初步研究[J]. 地震地质, 30(4): 935—944.
ZHANG Guo-hong, SHAN Xin-jian, LI Wei-dong. 2008. The Coulomb failure stress change associated with the M_S8.0 Wenchuan earthquake and the risk prediction of its surrounding faults[J]. Seismology and Geology, 30(4): 935—944(in Chinese).
[17] 张培震, 邓起东, 张国民, 等. 2003. 中国大陆的强震活动与活动地块[J]. 中国科学(D辑), 33(S1): 12—20.
ZHANG Pei-zhen, DENG Qi-dong, ZHANG Guo-min, et al. 2003. Active tectonic blocks and strong earthquakes in the continent of China[J]. Science in China(Ser D), 33(S1): 12—20(in Chinese).
[18] 张竹琪, 陈永顺, 林间. 2008. 1997年伽师震群中相邻正断层和走滑断层之间相互应力作用[J]. 中国科学(D辑), 38(3): 334—342.
ZHANG Zhu-qi, CHEN Yong-shun, LIN Jian. 2008. Stress interactions between normal faults and adjacent strike-slip faults of 1997 Jiashi earthquake swarm[J]. Science in China(Ser D), 38(3): 334—342(in Chinese).
[19] 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).
[20] 周德敏. 2013. 中西天山现今地壳形变特征及地震危险性分析 [D]. 北京: 中国地震局地质研究所.
ZHOU De-min. 2014. Characteristics of present-day crustal deformation and seismic hazard analysis in the western and central Tian Shan [D]. Institute of Geology, China Earthquake Administration, Beijing(in Chinese).
[21] 周云, 王卫民, 熊林, 等. 2015. 2014年2月12日M_W6.9于田地震震源破裂过程及对周围断层的应力影响[J]. 地球物理学报, 58(1): 184—193.
ZHOU Yun, WANG Wei-min, XIONG Lin, et al. 2015. Rupture process of 12 February 2014, Yutian M_W6.9 earthquake and stress change on nearby faults[J]. Chinese Journal of Geophysics, 58(1): 184—193(in Chinese).
[22] Avouac J P, Tapponnier P, Bai M, et al. 1993. Active thrusting and folding along the northern Tien Shan and late Cenozoic rotation of the Tarim relative to Dzungaria and Kazakhstan[J]. Journal of Geophysical Research: Solid Earth, 98(B4): 6755—6804.
[23] Deng J, Sykes L R. 1997. Stress evolution in southern California and triggering of moderate, small, and microsize earthquakes[J]. Journal of Geophysical Research: Solid Earth, 102(B11): 24411—24435.
[24] Freed A M, Ali S T, Bürgmann R. 2007. Evolution of stress in southern California for the past 200 years from coseismic, postseismic and interseismic stress changes[J]. Geophysical Journal International, 169(3): 1164—1179.
[25] Freed A M, Lin J. 2001. Delayed triggering of the 1999 Hector Mine earthquake by viscoelastic stress transfer[J]. Nature, 411(6834): 180—183.
[26] Harris R A, Simpson R W. 1996. In the shadow of 1857: The effect of the great Ft. Tejon earthquake on subsequent earthquakes in southern California[J]. Geophysical Research Letters, 23(3): 229—232.
[27] King G C P, Stein R S, Lin J. 1994. Static stress changes and the triggering of earthquakes[J]. Bulletin of the Seismological Society of America, 84(3): 935—953.
[28] Lin J, Stein R S. 2004. Stress triggering in thrust and subduction earthquakes and stress interaction between the southern San Andreas and nearby thrust and strike-slip faults[J]. Journal of Geophysical Research: Solid Earth, 109(B2): B02303.
[29] Lorenzo-Martín F, Roth F, Wang R. 2006. Elastic and inelastic triggering of earthquakes in the North Anatolian fault zone[J]. Tectonophysics, 424(3-4): 271—289.
[30] Marsan D, Bean C J. 2003. Seismicity response to stress perturbations, analyzed for a world-wide catalogue[J]. Geophysical Journal International, 154(1): 179—195.
[31] Parsons T, Dreger D. 2000. Static-stress impact of the 1992 Landers earthquake sequence on nucleation and slip at the site of the 1999 M=7.1 Hector Mine earthquake, southern California[J]. Geophysical Research Letters, 27(13): 1949—1952.
[32] Pollitz F. 1992. Postseismic relaxation theory on the spherical earth[J]. Bulletin of the Seismological Society of America, 82(1): 422—453.
[33] 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.
[34] Shan B, Xiong X, Wang R, et al. 2013. Coulomb stress evolution along Xianshuihe-Xiaojiang fault system since 1713 and its interaction with Wenchuan earthquake, May 12, 2008[J]. Earth and Planetary Science Letters, 377-378:199—210.
[35] Tapponnier P, Molnar P. 1977. Active faulting and tectonics in China[J]. Journal of Geophysical Research, 82(20): 2905—2930.
[36] Wang R, Lorenzo-Martín 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 and Geosciences, 32(4): 527—541.