STUDY OF CRUSTAL TOMOGRAPHY AND PRECISE EARTHQUAKE LOCATION IN YANGBI AREA, YUNNAN PROVINCE

doi:10.3969/j.issn.0253-4967.2021.04.008

Abstract

Abstract:

The occurrence of strong earthquake is closely related to the distribution of crustal velocity anomalies. Some studies have shown that strong earthquakes occur in the transition zone between high-velocity anomalies and low-velocity anomalies in the middle and upper crust or inside the low-velocity anomaly zone. Thus, high-resolution imaging of the velocity structure in the seismic source area and accurate earthquake location can assist the evaluation of seismogenic settings of strong earthquakes. On May 21, 2021, an M_S6.4 earthquake occurred in Yangbi, Yunnan with casualties and property losses. The epicenter region of the Yangbi earthquake is in the western Yunnan area of the Sichuan-Yunnan block, which is located on the southeastern edge of the Qinghai-Tibet Plateau and characterized with intensive tectonic activity. Previous studies in this area are mostly on regional scales, and lacking on the three-dimensional fine crustal velocity structure in the Yangbi earthquakes area. To investigate the seismogenic environment and source characteristics of the 2021 Yangbi M_S6.4 sequence in Yunnan, we used the P-wave and S-wave arrival data of 12 652 earthquakes recorded by both the Yunnan regional digital network and the mobile observation arrays over a 10-year period(May 1, 2011, to May 31, 2021) and obtained the average V_P/V_S ratio of 1.79 via fitting the P-wave and S-wave arrival-time curves with the Wadati method. The magnitude ranges from M_S0.0 to M_S6.4, and the original focal depth ranges from 0 to 35km. To ensure the reliability of the calculation results, at least 4 stations records are required, and the maximum station azimuth gap allowed is 120°. Furthermore, the event-station distance is restricted to 400km and only earthquakes with travel time residuals<0.5s are retained. Our final velocity model is further refined via gridding(i.e., nodes)with an optimal horizontal grid of 0.25°×0.25° and a range between 0~65km vertically. A checkerboard test is also conduced to validate our inversion results. The test results showed that the recovery degree is high except for the depths of 0 and 65km, which were impacted by the uneven seismic distribution and rays. The high degree of recovery of 5~45km suggests high-resolution and robust imaging at these depths. Finally, the double-difference tomography method(TomoDD)was used to invert the three-dimensional P-wave and S-wave velocity structures in the Yangbi and its surrounding areas(24.5°~26.5°N, 99°~101°E). According to the result of precise location, the M_S6.4 main shock is located at 99.89°E, 25.70°N with a focal depth of 7.9km. The Yangbi M_S6.4 earthquake sequence is mainly distributed along the NW direction. Least-squares fitting prefers a~20km long axis with a strike of 312°, and the hypocenter depths are 5~20km. In general, the studied sequence is shallow and located within the upper crust, consistent with the depth distribution characteristics of historical earthquakes in this area. According to the spatio-temporal evolution characteristics of the aftershock sequence, the aftershocks of the M_S6.4 earthquake mainly spread unilaterally toward SE direction. Thus, we speculate that the overall medium in the NW of the mainshock is rigid and hinders aftershocks evolution. On the north side of the M_S6.4 mainshock epicenter, a group of earthquakes spread along the NNE direction and extended to the Weixi-Qiaohou Fault that hosted the M_S4.1 earthquake on May 27, 2021. Considering the geological and structural background, we believe this earthquake occurred on a parallel but unmapped fault on the SE side of the Weixi-Qiaohou Fault. In contrast, the earthquakes spreading in the NNE direction on the north side of the main shock maybe occurred on an unknown fault in the NNE direction. Therefore, the two faults form a conjugate structure. From the imaging results, the upper crustal velocity structure in the study area is consistent with the geological structure changes and the active faults, where the velocities are low. At 0km depth, the extremely low P-wave and S-wave velocities may reflect impacts from surface sediments. A velocity contrast is observed at a depth of 5km near the mainshock. In addition, a high-velocity anomaly was observed to the southeast side of the mainshock at 10-km depth, with a length of about 0.6°(EW)and a width of about 0.2°(SN). Within the depth range of 10~20km, the distribution of earthquakes near the mainshock shows a clear strip-like distribution, delineating the geometry of the fault. The velocity structure and seismic relocation results at 10-km depth suggest that majority of the events locate around the high-velocity anomaly on the west side of the Weixi-Qiaohou Fault. From the AA' profile, both P- and S-wave velocities suggest high-velocity anomalies in the SE direction of the mainshock. Combining with the distribution characteristics of aftershocks, the non-uniform variations of velocity structure are probably the major factor controlling the distribution of aftershocks, leading to the aftershock distribution extending along the SE direction.

Key words: Weixi-Qiaohou Fault, double difference tomography, earthquake locating, velocity structure

摘要：

为考察2021年云南漾濞M_S6.4地震序列的孕震环境和序列活动特征, 文中使用云南区域数字台网和部分野外流动观测台阵观测的2011年5月1日-2021年5月31日的P波和S波震相到时数据, 利用双差层析成像方法(TomoDD)获得了漾濞M_S6.4地震序列周边地区的P波和S波三维速度结构、地震序列重新定位结果。结果显示, 漾濞M_S6.4地震序列主要沿NW向呈条带状展布, 展布区域长轴长约20km, 震源深度为5~20km。 M_S6.4地震的余震主要沿SE向单侧扩展。发震断层为维西-乔后断裂SE侧的一条近平行的未探明断裂, 而主震震中N侧分布的1组NNE向展布的地震则表明可能还存在1条NNE向的未探明断裂, 两者共同组成1组共轭断裂。

关键词: 维西-乔后断层, 双差层析成像, 地震定位, 速度结构

CLC Number:

P315.2

YIN Xin-xin, JIANG Chang-sheng, CAI Run, GUO Xiang-yun, JIANG Cong, WANG Zu-dong, ZOU Xiao-bo. STUDY OF CRUSTAL TOMOGRAPHY AND PRECISE EARTHQUAKE LOCATION IN YANGBI AREA, YUNNAN PROVINCE[J]. SEISMOLOGY AND EGOLOGY, 2021, 43(4): 864-880.

尹欣欣, 蒋长胜, 蔡润, 郭祥云, 姜丛, 王祖东, 邹小波. 云南漾濞地区地壳层析成像与地震精定位[J]. 地震地质, 2021, 43(4): 864-880.

Figures/Tables 12

Fig. 1 Geological tectonic setting and historical big earthquakes of the research area.

Fig. 2 Epicenter distribution from the seismic data used in this paper.

Fig. 3 Grid and seismic ray distribution map used in this paper.

Table1 Initial 1D P-wave velocity model

深度/km	V_P/km·s^-1	V_P/V_S
-5	3.00	1.79
0	4.88
5	5.81
10	6.09
15	6.18
25	6.60
35	6.93
45	7.70
65	8.12

Fig. 4 P- and S-wave arrival times.

Fig. 5 The resolution of checkerboard test of P-waves at different depths.

Fig. 6 The resolution of checkerboard test of S-waves at different depths.

Fig. 7 Tomography results of P-wave velocity at different depths.

Fig. 8 Tomography results of S-wave velocity at different depths.

Fig. 9 Temporal and spatial distribution of precisely relocated earthquakes of Yangbi earthquake sequence.

Fig. 10 Spatial and temporal extension of the Yangbi earthquake sequence along AA'.

Fig. 11 P- and S-wave velocity structures on three vertical profiles.

References 38

[1]	蔡锁章, 杨明, 雷英杰. 2016. 数值计算方法(第2版)[M]. 北京: 国防工业出版社.
	CAI Suo-zhang, YANG Ming, LEI Ying-jie. 2016. Numerical Methods(Second Edition)[M]. National Defense Industry Press, Beijing. (in Chinese)
[2]	曹颖, 黄江培, 钱佳威, 等. 2021. 利用时移层析成像方法揭示与2014年云南鲁甸M_S6.5地震有关的P波速度变化[J]. 地球物理学报, 64(5): 1569-1584.
	CAO Ying, HUANG Jiang-pei, QIAN Jia-wei, et al. 2021. Application of time-lapse seismic tomography based on double-difference tomography to reveal P wave velocity changes related to the 2014 Ludian M_S6.5 earthquake[J]. Chinese Journal of Geophysics, 64(5): 1569-1584. (in Chinese)
[3]	常祖峰, 常昊, 臧阳, 等. 2016. 维西-乔后断裂新活动特征及其与红河断裂的关系[J]. 地质力学学报, 22(3): 517-530.
	CHANG Zu-feng, CHANG Hao, ZANG Yang, et al. 2016. New activity characteristics of Weixi-Qiaohou Fault and its relationship with Honghe Fault[J]. Acta Geomechanica Sinica, 22(3): 517-530. (in Chinese)
[4]	贾佳. 2020. 洱源地区地壳三维P波速度精细结构研究[D]. 北京: 中国地震局地球物理研究所.
	JIA Jia. 2020. 3D P-wave velocity structure of crust in the Eryuan area[D]. Institute of Geophysics, China Earthquake Administration, Beijing. (in Chinese)
[5]	汤沛. 2013. 维西-乔后断裂巍山盆地段活动性研究[D]. 云南: 云南大学.
	TANG Pei. 2013. Research on the activity of Weixi-Qiaohou Fault in Weishan Basin[D]. Yunnan University, Yunnan. (in Chinese)
[6]	王长在, 吴建平, 房立华, 等. 2013. 玉树地震震源区速度结构与余震分布的关系[J]. 地球物理学报, 56(12): 4072-4083.
	WANG Chang-zai, WU Jian-ping, FANG Li-hua, et al. 2013. The relationship between wave velocity structure around Yushu earthquake source region and the distribution of aftershocks[J]. Chinese Journal of Geophysics, 56(12): 4072-4083. (in Chinese)
[7]	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)
[8]	王伟平. 2016. 鲜水河、安宁河和龙门山断裂带交会区双差层析成像研究[D]. 北京: 中国地震局地球物理研究所.
	WANG Wei-ping. 2016. Study on double-difference tomography in intersection areas of Xianshuihe, Anninghe and Longmenshan fault zones[D]. Institute of Geophysics, China Earthquake Administration, Beijing. (in Chinese)
[9]	小娜, 于湘伟, 章文波. 2014. 昭通地区地震层析成像及彝良震区构造分析[J]. 地球物理学进展, 126(4): 1573-1580.
	WANG Xiao-na, YU Xiang-wei, ZHANG Wen-bo. 2014. Seismic tomography in Zhaotong area and structural analysis in Yiliang earthquake area[J]. Progress in Geophysics, 126(4): 1573-1580. (in Chinese)
[10]	吴建平, 明跃红, 王椿镛. 2001. 云南数字地震台站下方的S波速度结构研究[J]. 地球物理学报, 44(2): 228-237.
	WU Jian-ping, MING Yue-hong, WANG Chun-yong. 2001. The S wave velocity structure beneath digital seismic stations of Yunnan Province inferred from teleseismic receiver function modelling[J]. Chinese Journal of Geophysics, 44(2): 228-237. (in Chinese)
[11]	熊绍柏, 郑晔. 1993. 丽江-攀枝花-者海地带二维地壳结构及其构造意义[J]. 地球物理学报, 36(4): 434-444.
	XIONG Shao-bai, ZHENG Ye. 1993. The 2-D structure and its tectonic implications of the crust in the Lijiang-Panzhihua-Zhehai region[J]. Chinese Journal of Geophysics, 36(4): 434-444. (in Chinese)
[12]	胥颐, 杨晓涛, 刘建华. 2013. 云南地区地壳速度结构的层析成像研究[J]. 地球物理学报, 56(6): 1904-1914.
	XU Yi, YANG Xiao-tao, LIU Jian-hua. 2013. Tomography of crustal velocity structure in Yunnan area[J]. Chinese Journal of Geophysics, 56(6): 1904-1914. (in Chinese)
[13]	张培震, 邓起东, 张竹琪, 等. 2013. 中国大陆的活动断裂、地震灾害及其动力过程[J]. 中国科学(D辑), 43(10): 1607-1620.
	ZHANG Pei-zhen, DENG Qi-dong, ZHANG Zhu-qi, et al. 2013. Active faults, earthquake hazards and associated geodynamic processes in continental China[J]. Science in China(Ser D), 43(10): 1607-1620. (in Chinese)
[14]	张晓曼, 胡家富, 胡毅力, 等. 2011. 云南壳幔S波速度结构与强震的构造背景[J]. 地球物理学报, 54(5): 1222-1232.
	ZHANG Xiao-man, HU Jia-fu, HU Yi-li, et al. 2011. The S-wave velocity structure in the crust and upper mantle as well as the tectonic setting of strong earthquake beneath Yunnan region[J]. Chinese Journal of Geophysics, 54(5): 1222-1232. (in Chinese)
[15]	Dorbath C, Gerbault M, Carlier G, et al. 2008. The double seismic zone of the Nazca plate in northern Chile: High resolution velocity structure, petrological implications and thermomechanical modelling[J]. Geochemistry, Geophysics, Geosystems, 9(7): 1-29. doi: 10.1029/2008GC002020. DOI
[16]	Hansen P C, Oleary D P. 1993. The use of the L-curve in the regularization of discrete ill-posed problems[J]. SIAM Journal on Scientific Computing, 14(6): 1487-1503. DOI URL
[17]	Humphreys E, Clayton R W. 1988. Adaptation of back projection tomography to seismic travel time problems[J]. Journal of Geophysical Research, 93(B2): 1073-1085. DOI URL
[18]	Michael A J, Eberhart P D. 1991. Relations among fault behavior, subsurface geology, and 3-dimensional velocity models[J]. Science, 253(5020): 651-654. PMID
[19]	Negia S S, Paul A, Cesca S, et al. 2017. Crustal velocity structure and earthquake processes of Garhwal-Kumaun Himalaya: Constraints from regional waveform inversion and array beam modeling[J]. Tectonophysics, 712: 45-63.
[20]	Paige C C, Saunders M A. 1982. LSQR: An algorithm for sparse linear equations and sparse least squares[J]. ACM Transactions on Mathematical Software, 8(1): 43-71. DOI URL
[21]	Pei S, Liu H, Ling B, et al. 2016. High-resolution seismic tomography of the 2015 M_W7.8 Gorkha earthquake, Nepal: Evidence for the crustal tearing of the Himalayan rift[J]. Geophysical Research Letters, 43(17): 9045-9052. DOI URL
[22]	Pei S, Niu F, Ben-Zion Y, et al. 2019. Seismic velocity reduction and accelerated recovery due to earthquakes on the Longmenshan Fault[J]. Nature Geoscience, 12(5): 387-392. DOI URL
[23]	Pesicek J D, Thurber C H, Zhang H, et al. 2010. Teleseismic double-difference relocation of earthquakes along the Sumatra-Andaman subduction zone using a 3-D model[J]. Journal of Geophysical Research: Solid Earth, 115(B10): B10303.
[24]	Qiong W, Yuan G. 2014. Rayleigh wave phase velocity tomography and strong earthquake activity on the southeastern front of the Tibetan plateau[J]. Science China Earth Sciences, 57(10): 2532-2542. DOI URL
[25]	Scarfì L, Giampiccolo E, Musumeci C, et al. 2007. New insights on 3D crustal structure in southeastern Sicily(Italy)and tectonic implications from an adaptive mesh seismic tomography[J]. Physics of the Earth and Planetary Interiors, 161(1-2): 74-85. DOI URL
[26]	Thurber C H. 1992. Hypocenter-velocity structure coupling in local earthquake tomography[J]. Physics of the Earth and Planetary Interiors, 75(1-3): 55-62. DOI URL
[27]	Thurber C H, Brocher T M, Zhang H, et al. 2007. Three-dimensional P wave velocity model for the San Francisco Bay region, California[J]. Journal of Geophysical Research: Solid Earth, 112(B7): B07313.
[28]	Thurber C, Zhang H J, Brocher T, et al. 2009. Regional three-dimensional seismic velocity model of the crust and uppermost mantle of northern California[J]. Journal of Geophysical Research: Solid Earth, 114(B1): B01304.
[29]	Waldhauser F, Ellsworth W. 2000. A double-difference earthquake location algorithm: Method and application to the northern Hayward Fault, California[J]. Bulletin of the Seismological Society of America, 90(6): 1353-1368. DOI URL
[30]	Wang W, Wu J, Fang L, et al. 2014. S wave velocity structure in southwest China from surface wave tomography and receiver functions[J]. Journal of Geophysical Research, 119(2): 1061-1078.
[31]	Xin H L, Zhang H J, Kang M, 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 URL
[32]	Zhang H, Thurber C. 2006. Development and applications of double-difference seismic tomography[J]. Pure and Applied Geophysics, 163(2-3): 373-403. DOI URL
[33]	Zhang H, Roecker S, Thurber C H, et al. 2012. Seismic imaging of microblocks and weak zones in the crust beneath the southeastern margin of the Tibetan plateau[J]. Earth Sciences, (3): 159-202.
[34]	Zhang H, Thurber C. 2003. Double-difference tomography: The method and its application to the Hayward Fault, California[J]. Bulletin of the Seismological Society of America, 93(5): 1875-1889. DOI URL
[35]	Zhang H, Thurber C. 2005. Adaptive mesh seismic tomography based on tetrahedral and Voronoi diagrams: Application to Parkfield, California[J]. Journal of Geophysical Research: Solid Earth, 110(B04): B04303.
[36]	Zhang H, Thurber C, Bedrosian P. 2009. Joint inversion for V_P, V_S, and V_P/V_S at SAFOD, Parkfield, California[J]. Geochemistry, Geophysics, Geosystems, 10(11): Q11002.
[37]	Zhao D, Hasegawa A, Horiuchi S. 1992. Tomographic imaging of P and S wave velocity structure beneath northeastern Japan[J]. Journal of Geophysical Research, 97(B13): 19909-19928. DOI URL
[38]	Zhao L, Luo Y, Liu T Y, et al. 2013. Earthquake focal mechanisms in Yunnan and their inference on the regional stress field[J]. Bulletin of the Seismological Society of America, 103(4): 2498-2507. DOI URL