2020年西藏尼玛MW6.3地震的InSAR同震形变与构造意义

doi:10.3969/j.issn.0253-4967.2021.06.013

摘要/Abstract

摘要：

2020年西藏尼玛 M_W6.3 地震发生在羌塘块体中部、依布茶卡-日干配错断裂系内的半地堑盆地内, 基于震源机制解确定的发震断层存在较大差异。文中采用InSAR技术和Sentinel-1卫星升、降轨SAR数据获取了同震形变场, 基于弹性半空间位错模型反演确定了发震断层参数, 基于非均匀位错模型获得了断层面上的精细滑动分布。结果表明: 1)在升、降轨InSAR同震形变场中, 尼玛地震引起一椭圆形沉降区(长约12km, 宽约8km), 最大LOS向沉降值分别为-0.298m、 -0.238m。2)同震位错以正断倾滑为主, 兼有少许走滑分量, 滑动主要集中在3~12km深度, 最大滑动量达1.1m, 位于7km深处。3)发震断层为依布茶卡-日干配错断裂西侧的分支断层, 走向约为30°, 倾角约为68°, 滑动角约为-73°。4)此次地震的破裂模式显示依布茶卡-日干配错走滑断裂存在张性应力积累, 羌塘块体中部处于张性应力状态。

关键词: 尼玛地震, InSAR, 同震形变, 滑动分布, 依布茶卡-日干配错断裂

Abstract:

The Qinghai-Tibet Plateau has always been one of the areas with frequent strong earthquakes in China. On July 23, 2020, an M_W6.3 earthquake occurred in Nima, Tibet in a half-graben basin of the Yibug Caka-Riganpei Co fault zone in the central Qiangtang block. After the earthquake, many institutions have calculated the focal mechanism solutions based on seismic waves. Although there are differences in the source location and the parameters of the seismic fault, they all show that it is a normal fault earthquake. This is inconsistent with the strike-slip character of the Yibug Caka-Riganpei Co Fault. In addition, this earthquake is another strong earthquake that occurred on Yibug Caka-Riganpei Co Fault after the Gaize M_S6.9 event on January 9, 2008. Therefore, by studying this earthquake, we can better determine the tectonic movement of the seismogenic fault, so it has great significance for understanding the seismogenic mechanism and risk of the central Qiangtang block.
The average elevation in the central Qiangtang is more than 4 800m, the environment is harsh and it is difficult to carry out the field survey of the earthquake. At the same time, GNSS sites near the epicenter are extremely sparse. Therefore, the InSAR technology, which has been successfully applied to several earthquakes in Qinghai-Tibet Plateau, and the Sentinel-1 SAR data, which can be downloaded free of charge, are used to study this earthquake.
Firstly, we obtain the coseismic deformation field based on GAMMA software and select SRTM data with 30m resolution(http://gdex.cr.usgs.gov/gdex/)as the reference DEM. In order to improve the orbit error in interferogram, the precise orbit data provided by ESA(https://qc.sentinel1.eo.esa.int/aux_poeorb/)is used for correction. The adaptive filtering method with filtering function based on local fringe spectrum is used to filter the interferograms, and the filtering windows are set to 128×128 and 32×32, respectively. This iterative filtering window setting from large to small can greatly improve the coherence of the interferogram. Unwrapping phase method uses minimum cost flow(MCF)technology and irregular triangular mesh(TIN). In the ascend and descend InSAR deformation field, we can observe that both deformation trends are basically consistent. The earthquake caused an elliptic settlement area(~12km long and~8km wide)in the basin, and the maximum settlements in line-of-sight direction are -0.298m and -0.238m in the ascend and descend InSAR deformation field, respectively. It can also be observed that the basin has a small amount of horizontal sliding relative to the mountains on both sides. Based on the ascending and descending deformation field, the deformation pattern of the earthquake accords with the main characteristics of normal-fault event, which is consistent with seismological results.
Secondly, taking the focal mechanism solutions published by GCMT and NEIC as initial reference values, the seismic fault parameters are determined based on the elastic half-space dislocation model and InSAR deformation field. Then, according to the linear relationship between the slip and the deformation on the fault plane, SDM method is used to invert the coseismic slip distribution on the fault. In the inversion, since the average Poisson's ratio in Qiangtang is significantly higher than that in the normal crust, the Poisson's ratio is set at 0.29. The results show that: 1)The coseismic slip is dominated by normal dip-slip motion, with small amount of strike-slip component, and the slip is mainly distributed at the depths of 3~12km, with the maximum slip of approximately 1.1m at the depth of 7km. The causative fault did not rupture the surface; 2)The seismic fault is the west branch fault of the Yibug Caka-Riganpei Co Fault, with a strike of ~30°, a dip of ~68°, a slip of ~-73°.
The Yibug Caka-Riganpei Co Fault is still active today, and it is generally a left-lateral strike-slip fault. The Yibug Caka Lake in the epicentral area is a pull-apart basin controlled by the strike-slip fault. The rupture pattern of the Nima earthquake is similar to that of the Gaize M_S6.9 earthquake in 2008, both of which are normal dip-slip caused by accumulation of tensile stress. This is different from the strike-slip character of Yibug Caka-Riganpei Co Fault, indicating that there is extensional stress accumulation in the Yibug Caka-Riganpei Co strike-slip fault and the central part of the Qiangtang block is under an extensional stress regime. Most shallow earthquakes in Qiangtang block occur at the junctures of active faults. Therefore, more attention should be paid to this kind of areas in the future research on seismic risk of Qiangtang block.

Key words: 2020 Nima earthquake, InSAR, coseismic slip distribution, Yibug Caka-Riganpei Co Fault

中图分类号:

P315.2

邱江涛, 季灵运, 刘雷, 刘传金. 2020年西藏尼玛M_W6.3地震的InSAR同震形变与构造意义[J]. 地震地质, 2021, 43(6): 1586-1599.

QIU Jiang-tao, JI Ling-yun, LIU lei, LIU Chuan-jin. INSAR COSEISMIC DEFORMATION AND TECTONIC IMPLICATIONS FOR THE 2020 M_W6.3 NIMA EARTHQUAKE IN XIZANG[J]. SEISMOLOGY AND EGOLOGY, 2021, 43(6): 1586-1599.

图/表 9

表1 不同机构给出的2020年尼玛地震的震源机制解

Table1 Focal mechanism solutions of the 2020 Nima earthquake from different institutions

机构	震中位置		震级 /M_W	深度 /km	节面1/(°)			节面2/(°)
	东经/(°)	北纬/(°)			走向	倾角	滑动角	走向	倾角	滑动角
GCMT	33.09	86.86	6.4	17.3	187	44	-94	12	46	-86
NEIC	33.131	86.840	6.3	10	203	29	-88	20	61	-91
IPGP	33.13	86.84	6.3	10	174	45	-106	17	47	-74
GFZ	33.13	86.78	6.4	10	204	41	-65	353	52	-109

图 1 2020年尼玛地震的区域构造背景地形起伏数据来自网页①(①http://dx.doi.org/10.1029/2019EA000658。); 断层数据来自全国活断层展示系统②(②http://www.neotectonics.cn/); 黑色实线箭头为GPS水平速度场, 数据来自文献(Wang et al., 2020), 红色五星为此次地震的震中位置, 红色实心圆为2008年改则地震震中位置, 数据来自中国地震台网中心③(③https://www.cenc.ac.cn/cenc/dzxx/index.html。)

Fig. 1 Map showing tectonic setting of the 2020 Nima earthquake.

表2 SAR干涉图信息

Table2 Parameters of SAR interferograms

模式	轨道号	入射角	影像日期		基线距离/m	时间间隔/d
			震前	震后
升轨	12	41.7°	2020-07-18	2020-07-30	-86.679	12
降轨	121	44.0°	2020-07-14	2020-07-26	112.262	12

图 2 2020年尼玛地震的InSAR同震形变场 a、 c 升、降轨干涉图, 实线箭头表示卫星飞行方向, 虚线箭头表示雷达视线方向; b、 d 跨震中区域的升、降轨形变剖面;e Google Earth上的地形, 数字为白色实心点处的高程

Fig. 2 Coseismic deformation fields from InSAR.

图 3 断层参数的最优解纵轴为1×106次迭代中参数的选中频次; 横轴为给定的参数范围; 红色竖线为最优值

Fig. 3 Optimal solution of the estimated fault parameters.

图 4 分布式滑动模型的拟合结果 a—c分别为升轨T12的同震形变场、拟合同震形变场和残差图; d—f分别为降轨T121的同震形变场、拟合同震形变场和残差图; 白色实线表示模拟断层的地表迹线

Fig. 4 Simulation results of distributed-slip model.

图 5 同震滑动分布图 a和b分别为断层面滑动分布的二维和三维显示; 震源机制解通过反演得到, 坐标为最大滑动量在地表的投影位置

Fig. 5 Maps of coseismic slip distributions.

图 6 2020年尼玛地震的成因机制示意图红色实线为本文推断的发震断层; 震源机制解的侧视图表示地震的类型; 白色箭头表示区域构造应力为拉张

Fig. 6 Model of the genetic mechanism of the 2020 Nima earthquake.

图 7 同震错动造成周围区域的静态库仑应力变化黑色圆点为2020年7月23日主震之后发生在震中附近的余震(数据来自网站①(①https://earthquake.usgs.gov/earthquakes。))

Fig. 7 The static Coulomb stress change caused by the coseismic slip.

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