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用双差地震定位法对2005年9月23日克孜尔震群进行重新定位。 从平面上, 重新定位地震集中分布在一个长约14.5 km, 宽约 9.0 km的长方形内, 其长轴为N30°W向, 与克孜尔断裂近乎垂直。 从震源深度来看, 重新定位地震的震源深度全部分布在21 km以内, 集中分布在10~19 km, 平均深度为13.6 km; 震群中绝大部分小震发生在沉积层内, 而震级较大地震基本发生在结晶地壳的上地壳内。 其剖面图显示, 这次震群是从结晶地壳开始沿着N30°W方向向上破裂至沉积层。 根据震区附近断裂性质和该区历史小震震中分布分析认为, 克孜尔水库库区附近可能存在两条共轭断裂, 右翼断裂可能是这次震群的发震构造。 相似文献
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基于新疆区域数字地震台网震相观测报告, 采用双差定位方法对2019年新疆疏附MS5.1地震序列ML≥1.0地震进行重定位, 采用CAP波形反演方法, 获得了主震的震源机制解和震源矩心深度, 进而综合分析了本次地震可能的发震构造。 结果表明, 疏附5.1级地震震源位置为39.59°N, 75.57°E, 初始破裂深度为18 km, 震源矩心深度为18 km。 重定位后的地震序列呈两个优势方向展布, 分别为NEE向和NE向分支, NEE向为主要的余震优势分布区域, 呈长约13 km窄带状分布在喀什断裂附近。 另一条优势分布为沿NE向长度约9 km, 这可能与喀什断裂阶区有关。 深度剖面显示, 地震震源深度主要集中分布在8~20 km。 沿NEE走向深度剖面显示, 疏附5.1级地震破裂于深部, 余震沿优势分布的震源深度自SWW向NEE呈现逐渐加深的变化特征。 垂直于震中优势分布的深度剖面显示, 本次地震发震断层面倾向为N倾。 震源机制解显示本次地震断错类型为逆冲型, 结合震源深度剖面特征推断节面Ⅰ为本次地震的发震断层面。 综合地震序列空间分布特征、 震源机制以及震源区地质资料, 推测此次地震的发震构造可能为喀什断裂, 余震向浅部扩展。 相似文献
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根据2016年运城4.4级地震序列资料,进行余震精定位、主震震源机制和发震构造等研究。地震震中分布结果显示,本次地震的发生构造与以往该地区震群型地震发震构造不同,构造单元相对简单,发生在盐湖北岸断裂附近。余震双差精定位结果显示,余震优势分布呈NNE向,NW向也有零星活动。精定位后震源深度集中分布在15-24 km,平均深度20.2 km,断层剖面深度集中分布在18-23 km,倾向NW,与盆地地形构造吻合。采用Snoke与CAP方法得到的震源机制解基本一致,此次序列的主震错断方式为走滑兼逆冲,节面B参数与中条山山前断裂东段走向和倾向接近。综合认为,本次运城地震序列的余震呈NNE向优势分布,精定位结合地震震源机制结果,推断此次地震序列发震断裂为中条山山前断裂的NNE向隐伏断裂。 相似文献
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内蒙古敖汉旗地区在2018—2019年间曾发生多次小震丛集活动,不同地震事件的波形记录易相互交叠,导致地震目录缺失。针对以上问题,采用匹配定位(Match & Locate)方法,对台网遗漏地震进行识别、检测与定位,并通过CAP方法反演敖汉旗震群最大地震的震源机制解,利用匹配定位后的小震分布定量地拟合发震断层面参数,从而综合判定敖汉旗震群的发震断层面几何形态和发震构造。结果显示:通过匹配定位方法共识别、定位405个小震事件,是原有地震目录事件的5.4倍,震群主体沿NW?SE向展布于红山—八里罕断裂与赤峰—开源断裂相交区域的东侧,震源深度集中于8—10 km。断层拟合结果和最大地震震源机制解表明敖汉旗震群的发震构造应是一条左旋走滑型隐伏正断层,断层面走向为157°,倾角为84°。综合分析红山—八里罕断裂和赤峰—开源断裂的断层性质和活动特征,认为敖汉旗震群的发震断层可能是这两条深大断裂在不断活动中相互作用而形成。 相似文献
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使用汇集在四川台网中心的固定台站、震后架设的流动台站、周边水库台站等震中距150 km以内的震相数据,选用分层速度模型,对芦山7.0级地震及震后9天内的余震利用双差定位法进行了重新定位.给出了芦山7.0级地震的发震时刻为2013-04-20 08:02:46.8,震中位置30.278°N,102.989°E,震源深度16.67 km,给出了3324次余震的双差定位结果,并对发震构造进行了分析.结果表明:芦山地震主破裂长度约40 km,下倾宽度约20 km,破裂视面积约800 km2,主破裂沿南西走向,倾角约40°.余震震源优势深度为10~22 km.余震沿南西走向,主要集中于大邑-名山断裂上盘. 相似文献
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使用甘东南地区三维速度模型,利用三维网格搜索法和双差地震定位法对2013年7月22日甘肃岷县漳县MS6.6地震及其震后三天的余震序列进行了精确定位,结合地质构造资料对本次地震的发震构造进行了初步研究。其结果显示:主震的震中位置为34.54°N,104.189°E,震源深度13.5km;余震震中呈NW或NWW方向分布,与临潭-宕昌断裂的走向基本吻合,主要分布于5~20km的深度,震中在深度剖面上呈SW向;发震断裂为倾向SW的隐伏断层,位于临潭-宕昌断裂NE方向,距临潭-宕昌断裂约20km。 相似文献
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汶川8.0级地震序列重新定位及其发震构造初探 总被引:10,自引:1,他引:9
采用双差定位方法对汶川8.0级地震及其2,216次余震进行了重新定位,得到2,061次地震的震源位置,定位结果在水平向和垂直向的估算误差大致为1~2km和2~3km。8.0级主震的震中位置大致为北纬31.00°,东经103.38°,震源深度13km左右,发震构造为龙门山中央断裂。余震震中沿走向分布的总长度为330km左右,震源深度优势分布在3~20km,表现出明显的分段活动特征。南段以龙门山中央断裂活动为主,后山断裂和前山断裂也有地震发生,这3条断裂自西向东倾角似乎逐渐变缓,形成叠瓦状的破裂分布。北段龙门山中央断裂、平武-青川断裂等多条断裂参与了发震过程,地震破裂既有逆冲推覆,也有右旋走滑方式 相似文献
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利用双差地震定位法对2003年2月14日石河子5.4级地震及其余震进行重新定位。定位结果显示,石河子地震及其余震呈N40°E方向线性展布,与准噶尔南缘断裂近乎垂直;震源深度全部分布在15~30 km范围内,优势分布为15~25 km。石河子5.4级地震震中位置为44.001395°N,85.872175°E,距离新疆地震局测得的震中位置仅1.2 km,而距离宏观考察的震中位置约49 km。分析重定位结果其震源机制解得出,这次地震的发震构造是准噶尔南缘断裂,而不是宏观考察的以连哈比尔尕山断裂;节面Ⅰ是主破裂面,而且其走向与重定位地震序列的展布方向基本一致。 相似文献
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使用双差定位法对2017年11月18日米林6.9级地震和余震进行重新定位,得到691个地震定位结果,发现:①余震序列分布更加集中,地震序列震中呈NW-SE向分布,与雅鲁藏布江断裂在NE向构造转弯处的走向基本一致;②地震序列的震源深度主要分布在5-15 km,东南侧地震数量较少,震源深度相对较深,西北侧地震数量较多,震源深度较浅。 相似文献
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利用双差定位方法对2017年2月~2018年5月长岛震群进行重定位, 根据重定位结果计算长岛震群地震集中活动区域b值在深度上的变化分布。 结果显示: 长岛震群重定位的结果主要表现为北、 南两个地震活动区域。 北部地震活动区域的地震数量多, 时间跨度长; 南部地震活动区域的地震数量较少, 形成时间较晚, 震源深度主要集中在地壳深度4~25 km之间; 长岛震群北、 南两个地震活动区域的b值总体上均随深度增大而减小, 在8.5 km深度左右均存在转折上升的情况。 长岛震群b值的深度变化特征表明, 其应力主要受围岩静压力影响, 受断裂活动影响较小。 相似文献
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利用此次伽师地震序列震相数据,通过走时曲线得到震源区的初始一维速度模型。结合此速度模型,利用单纯形法测定了新疆伽师M S6.4地震参数。使用双差定位方法对伽师地震和M L≥1.8的297次余震事件进行了重新定位,得到结论:①伽师M S6.4地震参数为39.841°N、77.151°E、深度14.4 km。②伽师地震的破裂是非均匀、迁移的。主、余震整体分布呈“T”字型展布,主震位于“T”字底部,“T”字的横长竖短,多数余震向主震的正北方向延伸,余震整体呈近东西方向展布,东西方向长约40 km,南北方向长约20 km。前震、主震发生在震源区近南面的隐伏断层,可能是受塔里木盆地的阻碍,余震并没有向南发展,而是逐渐向北延伸至位于北面的隐伏断层,后又沿北面的断层向东发展。③通过序列整体分布呈“T”字型展布,初步判断伽师地震是一次共轭断层破裂事件。余震一边向主震正北方向发展,一边继续向东发展,表明发震断层是一条近EW向北倾断层,同时证明了塔里木盆地向北插入南天山。④地震震源深度主要集中在10~20 km,占73%,优势破裂深度在中地壳,中地壳积累和释放的能量居多。伽师地震位于塔里木盆地边缘,地表覆盖有7~8 km的低速沉积层。 相似文献
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MATCH AND LOCATE FOR SMALL EVENT DETECTION OF NINGXIA SHIZUISHAN EARTHQUAKE SWARM AND INVESTIGATION OF ITS SEISMOGENIC FAULT 
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下载免费PDF全文 In this paper, a new method for small event detection named Match & Locate(M&L)is used to detect and locate the small earthquakes that are missing in the catalogue of the February 28, 2014 Shizuishan ML4.4 earthquake swarm. A total of 34 earthquakes were detected, which is nearly 3 times as much as the number(13)of earthquakes from Ningxia seismic network. The number of earthquake swarm sequence is greatly increased. Then, it provides the possibility for the fine study of the earthquake swarm activity and seismogenic fault. The best double couple solution of the main shock obtained by the cut and paste method is strike 354°, dip 70° and slip 166° for nodal plane I, and strike 89°, dip 77° and slip 21°for nodal plane Ⅱ. The main shock is a dextral strike-slip earthquake with a small amount of thrust component. And, the depth of the main shock is 7~8km, which is a shallow earthquake, derived from the results of the double difference relocation and the best fitting depth of focal mechanism. Together with the results of deep 3-D seismic tomography of the Yinchuan Basin, our results show that the main shock and the largest aftershock more likely occurred in the upper crust, and the rest of earthquakes mainly occurred at the bottom of sedimentary layer or on the top of the upper crust crystallization basement. We find some interesting phenomena on the pattern of time-space evolution of the earthquake swarm. The distribution of earthquake swarm is in the near north-south direction. Aftershocks are mainly concentrated in the north region of the main shock, which show an obvious trend of extending gradually from the south to the north. Also, the result shows the general trend of shallower focal depth with the development of aftershocks to the north. The results of distribution and depth profile of the earthquake swarm and the focal mechanism of the main shock all show that the sequence probably occurred in the fault at the east foot of Helan Mountain with an eastward dip and a larger dip angle. Surface projection image of the earthquake sequence shows that the epicenter distribution extends northward from the northern end of the fault. This may suggest that the deep part of the fault is likely to extend northward. 相似文献
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STUDY ON THE SEISMOGENIC FAULT AND DYNAMICS PARAME-TERS OF THE 2014 MS6.6 JINGGU EARTHQUAKE IN YUNNAN 下载免费PDF全文
下载免费PDF全文 On October 17, 2014, a MS6.6 earthquake occurred in Jinggu, Yunnan. The epicenter was located in the western branch of Wuliang Mountain, the northwest extension line of Puwen Fault. There are 2 faults in the surrounding area, one is a sinistral strike-slip and the other is the dextral. Two faults have mutual intersection with conjugate joints property to form a checkerboard faulting structure. The structure of the area of the focal region is complex. The present-day tectonic movement is strong, and the aftershock distribution indicates the faulting surface trending NNW. There is no obvious surface rupture related to the known fault in the epicenter, and there is a certain distance from the surface of the Puwen fault zone. Regional seismic activity is strong. In 1941, there were two over magnitude 7.0 earthquakes in the south of the epicenter of Jinggu County and Mengzhe Town. In 1988, two mainshock-aftershock type earthquakes occurred in Canglan-Gengma Counties, the principal stress axes of the whole seismic area is in the direction of NNE. Geological method can be adopted to clarify the distribution of surficial fracture caused by active faults, and high-precision seismic positioning and spatial distribution characteristics of seismic sequences can contribute to understand deep seismogenic faults and geometric features. Thus, we can better analyze the three-dimensional spatial distribution characteristics of seismotectonics and the deep and shallow tectonic relationship. The focal mechanism reveals the property and faulting process to a certain extent, which can help us understand not only the active property of faults, but also the important basis for deep tectonic stress and seismogenic mechanism. In order to study the fault characteristic of the Jinggu earthquake, the stress field characteristics of the source area and the geometric parameters of the fault plane, this paper firstly uses the 15 days aftershock data of the Jingsuo MS6.6 earthquake, to precisely locate the main shock and aftershock sequences using double-difference location method. The results show that the aftershock sequences have clustering characteristics along the NW direction, with a depth mainly of 5~15km. Based on the precise location, calculations are made to the focal mechanisms of a total of 46 earthquakes including the main shock and aftershocks with ML ≥ 3.0 of the Jinggu earthquake. The double-couple(DC)component of the focal mechanism of the main shock shows that nodal plane Ⅰ:The strike is 239°, the dip 81°, and the rake -22°; nodal plane Ⅱ, the strike is 333°, the dip 68°, and the rake -170.31°. According to focal mechanism solutions, there are 42 earthquakes with a focal mechanism of strike-slip type, accounting for 91.3%. According to the distribution of the aftershock sequence, it can be inferred that the nodal plane Ⅱ is the seismogenic fault. The obtained focal mechanism is used to invert the stress field in the source region. The distribution of horizontal maximum principal stress orienation is concentrated. The main features of the regional tectonic stress field are under the NNE-SSW compression(P axis)and the NW-SE extension(T axis)and are also affected by NNW direction stress fields in the central region of Yunnan, which indicates that Jinggu earthquake fault, like Gengma earthquake, is a new NW-trending fault which is under domination of large-scale tectonic stress and effected by local tectonic stress environment. In order to define more accurately the occurrence of the fault plane of the Jinggu earthquake, with the precise location results and the stress field in the source region, the global optimal solution of the fault plane parameters and its error are obtained by using both global searching simulated annealing algorithm and local searching Gauss-Newton method. Since the parameters of the fault plane fitting process use the stress parameters obtained by the focal mechanism inversion, the data obtained by the fault plane fitting is more representative of the rupture plane, that is, the strike 332.75°, the dip 89.53°, and the rake -167.12°. The buried depth of the rupture plane is 2.746km, indicating that the source fault has not cut through the surface. Based on the stress field characteristics and the inversion results of the fault plane, it is preliminarily believed that the seismogenic structure of the Jinggu earthquake is a newly generated nearly vertical right-lateral strike-slip fault with normal component. The rupture plane length is about 17.2km, which does not extend to the Puwen fault zone. Jinggu earthquake occurred in Simao-Puer seismic region in the south of Sichuan-Yunnan plate. Its focal mechanism solution is similar to that of the three sub-events of the Gengma earthquake in November 1988. The seismogenic structure of both of them is NW-trending and the principal stress is NE-SW. The rupture plane of the Jinggu main shock(NW direction)is significantly different from the known near NS direction Lancang Fault and the near NE direction Jinggu Fault in the study area. It is preliminarily inferred that the seismogenic structure of this earthquake has a neogenetic feature. 相似文献
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利用精河M_W6.3地震有限断层破裂模型,计算了精河地震产生的位移场、应力场、周围主要断层上的静态库仑应力变化以及主震对余震的触发作用。结果表明:(1)精河地震产生的地表隆升最大值约为6.6cm,沉降最大值约为1.8cm;水平位移方向呈现震中南北侧向震中汇聚、震中东西侧向外"流出"的特点。(2)精河地震产生的水平面应力场展布南北侧物质主要受到指向震中的拉张力作用,东西两侧物质主要受到因震中过剩物质东西向排出而导致的东西向挤压力作用。(3)震中西侧距震中约20km的库松木契克山前断裂中段和震中东北部距震中约50km的四棵树-古尔图南断裂西段的库仑应力加载均大于0.01MPa,即2处为地震危险区。(4)在震源深度为8~12km的余震事件中,约有85.5%处于库仑应力加载区,即受到主震的的触发作用;在深度为4~8km的余震事件中,约有87%受到主震的应力触发作用。 相似文献
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2014年2月12日在新疆于田县发生了MS7.3地震,主震前一天在震区发生了MS5.4前震,震后余震活动频繁,由于震区台站十分稀疏和不均匀、地壳速度结构复杂,台网常规定位结果精度有限,很难从中获得序列的空间分布特征和活动趋势的正确认识.本文首先利用位于震区附近的于田地震台5年记录的远震波形数据,采用接收函数方法研究了震区附近的地壳结构,建立了震源区的地壳速度模型.在此基础上,联合震相到时和方位角对2014年于田MS7.3地震序列(从2014年02月11日-2014年04月30日,共计577次地震)进行了重新绝对定位.结果显示,(1) 重定位后的前震和主震震中位置明显向地表破裂带及其附近的阿尔金分支断裂(南肖尔库勒断裂和阿什库勒-肖尔库勒断裂)靠近,两者相距5.4 km,主震位置为36.076°N、82.576°E,震源深度为22 km, 前震位置为36.055°N、82.522°E,震源深度为19 km;(2) 本文重定位结果显示,余震序列沿NEE-SWW展布,优势分布长度约73 km、宽度约16 km,平均震源深度为14.8 km,其中77%的余震分布在地表破裂带的西南端,这部分余震中少数沿阿什库勒-肖尔库勒断裂分布,绝大多数沿北东东向的南肖尔库勒断裂分布,位于地表破裂带东北端的余震沿阿什库勒-肖尔库勒断裂分布,但发生在地表破裂带的余震极少;重定位后,位于地表破裂带西南侧的震中分布由台网目录的近南北向变为北东向,与地表破裂带、南肖尔库勒断裂和阿什库勒-肖尔库勒断裂走向一致;(3) 沿重定位剖面的地震分布,可推断位于地表破裂带西南段的南肖尔库勒断裂与位于北东段的阿什库勒-肖尔库勒断裂倾向反向,南肖尔库勒断裂的倾向为SE,阿什库勒-肖尔库勒断裂的倾向为NW,这与本次地震野外考察得到的断裂性质一致.综合重定位结果、地表破裂带分布、震源机制解、南肖尔库勒断裂和阿什库勒-肖尔库勒断裂的性质认为,2014年于田MS7.3地震的发震构造为阿尔金断裂西南尾段的两条分支断裂——南肖尔库勒断裂和阿什库勒-肖尔库勒断裂. 相似文献