2010年10月24日周口太康MS4．6地震的震源机制解

利用河南省区域地震台网的近震波形资料,采用近震时间域方法,反演2010年10月24日16点58分太康 MS 4．6地震的地震矩张量,结果显示,该地震为走滑型地震。结合震后灾害考察,认为太康地震发生在周口-太康断裂上。     

2001年1月2 6日印度古杰拉特(Gujarat)Ｍem>Ssub>7.8地震时空破裂过程

从全球数字地震台网的长周期记录中,选择了震中距小于90的27个台站的54个P波震相和44个S波震相资料．首先,用波形反演方法确定了2001年1月26日印度古杰拉特(Gujarat)ＭS7.8地震的地震矩张量、震源机制、震源时间函数和时空破裂过程等震源参数．通过矩张量反演,并根据Kutch Mainland断层的走向、地震烈度的空间分布、余震震源的空间分布和震害的空间分布,确认2001年1月26日印度古杰拉特ＭS7.8地震的发震断层的走向为92、倾角为58、滑动角为62,即一走向近东-西向、断层面向南倾斜、以逆冲为主的左旋-逆断层．这次地震所释放的地震矩为3.51020 Nm,矩震级ＭW＝7.6．然后,借助合成地震图,采用频率域求谱商的方法,得到了依赖于台站方位的27个P波震源时间函数、22个S波震源时间函数以及平均的P波震源时间函数和S波震源时间函数．对震源时间函数的分析表明,这次地震是一次连续的破裂事件,开始比较急遽,但结束比较迟缓,总持续时间约19 s．最后,以所提取的P波和S波震源时间函数为资料,采用时间域的反演技术得到了断层面上滑动的时空分布．滑动量在断层面上的静态分布表明,断层面上的最大滑动量约为7 m．断层面上的最大应力降约为30 MPa,平均应力降约为7 MPa．滑动量大于0.5 m的区域在走向方向长85 km,在断层面倾斜方向宽约60 km(相应地,在深度方向约51 km)．破裂向东扩展约50 km,向西扩展约35 km．滑动量大于0.5 m的区域的主要部分呈椭圆形,其长轴取向与断层滑动方向一致．表明此区域破裂扩展的方向即是断层错动的方向．这种现象对于走滑断层情形是多见的,但对逆冲断层情形却少见．断层面上初始破裂点以东、以上部分面积大于初始破裂点以西、以下部分的面积,这是破裂非对称性的表现,表明破裂具有自西向东、自下向上单侧破裂的特征．从滑动率随时空变化的快照可以看出,滑动率在第4 s达到最大值,此时滑动率约为0.2 m/s,滑动基本上发生在破裂起始点及其周围．从第6 s开始,起始点的破裂基本结束,破裂开始向外围扩展．破裂向西的扩展速度明显小于向东的扩展速度．在第15 s,这种环形的扩展基本结束．自16 s以后,主要是一些零星的破裂点分布在破裂区的外围．从滑动量随时空变化的快照看,破裂自起始点开始后,逐渐向四周扩展．主要的破裂(滑动量大于5 m的区域)在6～10 s,具有明显的自西向东、向上的单侧破裂特征．在第11～13 s,破裂的西端向西、向下有所扩展．整个破裂过程持续约19 s．在整个破裂过程中的平均破裂速度约为3.3 km/s．     

CHARACTERISTICS OF FOCAL MECHANISMS AND STRESS FIELD OF YUNNAN AREA

Using the seismic waveform data recorded by regional seismic network of Yunnan and Sichuan and the method of CAP, we calculate and obtain the focal mechanism of 268 earthquakes with the magnitude of M_L≥4.0 occurring in Yunnan during Jan. 1999 to Aug. 2014; then, we analyze the types and the regional feature of the focal mechanism of earthquakes in Yunnan, on the basis of the focal mechanism of 109 earthquakes analyzed by Harvard University. Based on the data of the above focal mechanism solutions, we adopt the method of damped regional-scale stress inversion to calculate the best-fitting tectonic stress tensor of every grid in Yunnan; and adopt the method of maximum principal stress to calculate the direction of maximum horizontal principal stress in Yunnan. The result shows that: (1)the strike-slip type is the most principal type of the earthquake focus in the study area and the second is the normal faulting type; while, the reverse-fault type is relatively small. The spatial distribution of focal mechanism is obvious. This reflects that the dynamic source and acting force are different in different parts of the study area. (2)The direction of the stress field in Yunnan shows a certain spatial continuity. Maximum horizontal principal compressive stress is mainly clockwise from north to south and counterclockwise from the west to the east. The direction of stress field shows inhomogeneity in space. There exist two stress conversion zones respectively in EW and NS direction. The inversion result of stress field shows that the stress field in Yunnan is complex and the principal stress direction changes greatly; and there are obvious differences in different regions.     

汶川8.0级地震前龙门山断裂带的地震活动性和构造应力场特征

研究了2008年5月12日汶川8.0级地震前龙门山断裂带及其附近地区的地震活动.利用区域地震台网和流动测震台的数字地震波资料,测定了震源机制解.结果表明,震中所在的龙门山断裂带震前地震活动平稳,未出现显著异常增强或平静现象.根据汶川8.0级地震前地震活动求出的震源机制解,其主压应力P轴方位为WNE——ESE向,震源断层面呈NE向与NW 向两组节面走向.其中NE向节面呈N50deg;——70deg;E,断面倾角均陡,达60deg;——70deg;,震源力学作用方式多呈逆倾型,少部分呈走滑型．震前地震活动呈现的主压应力方位、震源断面走向及其错动类型,与汶川8.0级地震给出的解是一致的.巨大地震发生前沿龙门山断裂带微破裂呈现的平均应力场与主震一致．起始破裂区东侧20km内是紫坪铺水库水域区,这一区域发生小震活动增加的现象处于水库放水的卸载阶段.本文研究了汶川8.0级地震起始破裂区附近的小震活动,其震源参数表明,震源位于8.0级地震之上的5——14km深度,其震源参数与8.0级地震给出的解也是一致的．      

Tectonic analysis of mine tremor mechanisms from the Upper Silesian Coal Basin

Fault network of the Upper Silesian Coal Basin (USCB) is built of sets of strike-slip, oblique-slip and dip-slip faults. It is a typical product of force couple which acts evenly with the parallel of latitude, causing horizontal and anti-clockwise movement of rock-mass. Earlier research of focal mechanisms of mine tremors, using a standard fault plane solution, has shown that some events are related to tectonic directions in main structural units of the USCB. An attempt was undertaken to analyze the records of mine tremors from the period 1992–1994 in the selected coal fields. The digital records of about 200 mine tremors with energy larger than 1×10⁴ J (M _L >1.23) were analyzed with SMT software for seismic moment tensor inversion. The decomposition of seismic moment tensor of mine tremors was segmented into isotropic (I) part, compensated linear vector dipole (CLVD) part and double-couple (DC) part. The DC part is prevalent (up to 70%) in the majority of quakes from the central region of the USCB. A group of mine tremors with large I element (up to 50%) can also be observed. The spatial orientation of the fault and auxiliary planes were obtained from the computations for the seismic moment DC part. Study of the DC part of the seismic moment tensor made it possible for us to separate the group of events which might be acknowledged to have their origin in unstable energy release on surfaces of faults forming a regional structural pattern. The possible influence of the Cainozoic tectonic history of the USCB on the recent shape of stress field is discussed.     

汶川余震震源机制变化的原因

2008年5月12日,汶川M8.0主震是一个主压应力轴NW-SE的逆倾滑型的地震,而之后的余震震源机制解有的与主震震源机制解一致,有的发生了明显变化,由南至北逐步变成走滑型地震.主震和同主震震源机制解一致的部分余震,在构造应力场直接作用下,龙门山推复体向四川地块逆冲,致使在逆断层的上下盘之间的断层面上产生粘滑而发生逆倾...     

USE OF SEISMIC WAVEFORMS AND INSAR DATA FOR DETERMINATION OF THE SEISMOTECTONICS OF THE MAINLING MS6.9 EARTHQUAKE ON NOV.18, 2017

On November 18, 2017, a M_S6.9 earthquake struck Mainling County, Tibet, with a depth of 10km. The earthquake occurred at the eastern Himalaya syntaxis. The Namche Barwan moved northward relative to the Himalayan terrane and was subducted deeply beneath the Lhasa terrane, forming the eastern syntaxis after the collision of the Indian plate and Asian plates. Firstly, this paper uses the far and near field broadband seismic waveform for joint inversion (CAPJoint method)of the earthquake focal mechanism. Two groups of nodal planes are obtained after 1000 times Bootstrap test. The strike, dip and rake of the best solution are calculated to be 302°, 76° and 84° (the nodal plane Ⅰ)and 138°, 27° and 104° (the nodal plane Ⅱ), respectively. This event was captured by interferometric synthetic aperture radar (InSAR)measurements from the Sentinel-1A radar satellite, which provide the opportunity to determine the fault plane, as well as the co-seismic slip distribution, and assess the seismic hazards. The overall trend of the deformation field revealed by InSAR is consistent with the GPS displacement field released by the Gan Wei-Jun's team. Geodesy (InSAR and GPS)observation of the earthquake deformation field shows the northeastern side of the epicenter uplifting and the southwestern side sinking. According to geodetic measurements and the thrust characteristics of fault deformation field, we speculate that the nodal plane Ⅰ is the true rupture plane. Secondly, based on the focal mechanism, we use InSAR data as the constraint to invert for the fine slip distribution on the fault plane. Our best model suggests that the seismogenic fault is a NW-SE striking thrust fault with a high angle. Combined with the slip distribution and aftershocks, we suggest that the earthquake is a high-angle thrust event, which is caused by the NE-dipping thrust beneath the Namche Barwa syntaxis subducted deeply beneath the Lhasa terrane.     

2011年6月8日新疆托克逊Ms5.3地震震源机制解反演

2011年6月8日9时53分,新疆维吾尔自治区吐鲁番地区托克逊县发生Ms5.3地震.据新疆自治区民政厅报告,截至6月9日7时,地震造成托克逊县1241人受灾,324户1335间房屋不同程度受损,其中50户168间农牧民住房成为危房、无法居住,274户1135间房屋墙体开裂,博斯坦乡中学24间教室房屋开裂,伊拉湖乡医院8间病房开裂,无人员伤亡报告.     

日本至中国东北区域构造应力场分布与Benioff带的形态关系研究

收集2 291个来源于NIED F-net宽频带地震台网中心Mw≥3.0地震的震源机制解,采用MSATSI构造应力反演方法,得到反映应力相对大小的R值的量θ和3个主应力轴的方位角与倾伏角,同时反演出每个网格的极射赤平投影P、T轴.以3D应力反演为导向,采用矩阵网格分区的方法,以纬度、经度、深度为坐标,将发生在每一区域的...     

有关地震烈度速报信息化发展的思考

汶川8.0级地震给我们很多警示,其中之一就是地震观测系统应当在大地震后快速产出地震烈度分布图。本文对快速产出地震烈度的策略和方法进行了探讨,着重介绍了用同震位移分布快速获得地震烈度产出的方法。实现地震烈度快速产出这一目标应当走测震学、强地面运动学与信息技术有效结合的道路,这是大震后地震烈度快速产出的有效途径。