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1.
利用垂直向和波振幅比方法计算了2003年1月至2009年10月间宁夏北部及邻区的31个中小地震震源机制解,然后对计算所得的31个地震震源机制解进行系统聚类及应力场分析,并利用格点尝试法研究阿拉善区域(I区)和银川盆地及以北地区(II区)的平均震源机制解。结果表明:31个中小地震中走滑型地震占了近77%,显示出宁夏北部及邻近地区地震错动方式以近走滑为主;I区域地震产生的震源区构造变形是近南北向发生压缩,近东西向发生相对扩张;II区域构造应力场主压应力方向以水平作用为主,地震产生的震源区构造变形是北东向发生压缩,北西向发生相对扩张。 相似文献
2.
东亚大陆大地震的活动带走向、活动方式、震源主压应力方向、总迁移方向,沿纬度的分布和发震频度随时间的变化,均与地球自转速率变化有成因联系。本文从地球自转加速、减速、匀速的变化趋势进行这方面的观测资料分析,证明地球速率变化是东亚大陆地震的基本动力来源 相似文献
3.
用航磁资料研究了青海柴达木盆地中部的深部构造环境。结果表明:该地区存在由东西向、北西向和北东向各两条断裂组成的构造系统;地震主要分布在由两条东西向断裂和两条北东向断裂交截形成的顺扭平形四边形的角区;构造应力场主压应力方向大致为近南北方向,在其作用下,北东向和东西向断裂都是该地区主要的发震构造。 相似文献
4.
海丰震区发育着规模宏大的 NE 向海丰——梅陇断裂及一系列与其平行的次级断裂.同时,还存在与其共轭的断续分布的 NW 向断裂.震群中的三个子群的主震的震源机制解非常类似,其中一节面为 NE,另一节面为 NW.从余震的空间分布及极震区的长轴方向来看,2月26日 ML3.3和4月9日 MLL,4.2地震的断层面为 NE 向;而3月14日 ML,3.4地震,其断层面应取 NW 向.又据137个小震的四个台的 P 波初动符号的组合特征,可划分为八个类型并作出相应的迭加震源机制解.综上所述,本区破裂过程,主震及Ⅰ、Ⅳ 类地震是岩块沿NE 及 NW 向共轭构造的粘滑;Ⅱ——Ⅴ、Ⅶ、Ⅷ 类地震是岩块在粘滑过程中对前后邻接岩块引起平行滑动方向的挤压(前)和引张(后)的转换应力场所产生的剪切破裂. 相似文献
5.
Focal mechanism solutions and its tectonic significance in the trench of the eastern South China Sea 总被引:1,自引:0,他引:1
Introduction South China Sea (SCS) is located in the convergence zone between Euro-Asian plate, Pacific plate (Philippine plate) and Indian plate. Interactions of three plates made the crust of this region suffer tectonic stress in many directions and made the South China Sea be in the complex environ-ment of the tectonic stress. There are four different marginal types in the surrounding of the South China Sea: The tectonic zone of the rifting margin in the north of SCS, the NS direct… 相似文献
6.
使用143组中、小地震单震震源机制解和17组小区域综合机制解资料,统计分析了华东地区的现代构造应力场特征。华东地区现今处在NEE向(80°左右)主压、NNW向(350°左右)主张应力场的控制下;主应力作用方式以水平和近水平为主。在应力场方向和作用方式基本一致的背景上,不同地震构造分区存在一些差异,这些差异可能与相应区域主要活动断裂的主体分布方向有关,可能表征了现存构造对地震错动特征的影响和控制作用。现代中、小地震震源机制解,历史中、强地震和现代有感地震最内等震线长轴方向等资料显示华东地区地震主要沿NE,NW2个方向破裂错动,兼有NNE,NEE,NWW或近EW方向。以走滑和近走滑方式为主,兼有少量斜向滑动。地震断层的错动方式存在某些分区差异。华东地区历史中、强地震以NE向破裂错动为主,而现代中强地震在陆域以NW-SE为主,海域NE,NW兼有 相似文献
7.
利用双差定位方法对2018年松原MS5.7地震序列中ML≥1.0地震重新定位,之后使用CAP方法求解松原MS5.7地震序列中强地震的震源机制解,再借助MSATSI软件包反演得到松原地区的区域应力场。综合分析以上研究结果得到如下结论:① 松原MS5.7地震序列发生在NW走向的第二松花江断裂与NE走向的扶余—肇东断裂交会处,将地震精定位结果沿两条断层走向作剖面分析,NW向剖面主轴长度约为5 km,震中分布均匀,NE向剖面主轴长度亦约为5 km,震中呈倾向NE的高倾角分布;② 该序列中的4次ML≥3.7地震的震源机制解具有良好的一致性:节面Ⅰ走向为NE向,节面Ⅱ走向为NW向,均为高倾角走滑断层。中强地震的震源机制节面解与第二松花江断裂性质基本一致,由此推断第二松花江断裂是本次松原地震的发震断层;③ 松原地区的主压应力方位角为N86°E,倾角为7°,主张应力方位角为N24°E,倾角为71°。松原地区的区域应力场既受到大尺度的板块构造运动的控制,又受到区域构造运动的影响。在太平洋板块对北东亚板块向西俯冲作用下,东北地区产生了近EW向的主压应力,受周边地质构造控制,松辽盆地内NE向断裂与NW向断裂交会处易发生走滑型地震,2018年松原MS5.7地震正是在这种构造作用控制下发生的中强地震。 相似文献
8.
COULOMB STRESS CHANGE ON ACTIVE FAULTS IN SICHUAN-YUNNAN REGION AND ITS IMPLICATIONS FOR SEISMIC HAZARD 
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下载免费PDF全文 Coulomb stress change on active faults is critical for seismic hazard analysis and has been widely used at home and abroad. The Sichuan-Yunnan region is one of the most tectonically and seismically active regions in Mainland China, considering some highly-populated cities and the historical earthquake records in this region, stress evolution and seismic hazard on these active faults capture much attention.
From the physical principal, the occurrence of earthquakes will not only cause stress drop and strain energy release on the seismogenic faults, but also transfer stress to the surrounding faults, hence alter the shear and normal stress on the surrounding faults that may delay, hasten or even trigger subsequent earthquakes. Previously, most studies focus on the coseismic Coulomb stress change according to the elastic dislocation model. However, the gradually plentiful observation data attest to the importance of postseismic viscoelastic relaxation effect during the analysis of seismic interactions, stress evolution along faults and the cumulative effect on the longer time scale of the surrounding fault zone. In this paper, in order to assess the seismic hazard in Sichuan-Yunnan region, based on the elastic dislocation theory and the stratified viscoelastic model, we employ the PSGRN/PSCMP program to calculate the cumulative Coulomb stress change on the main boundary faults and in inner blocks in this region, by combining the influence of coseismic dislocations of the M≥7.0 historical strong earthquakes since the Yongsheng M7.8 earthquake in 1515 in Sichuan-Yunnan region and M≥8.0 events in the neighboring area, and the postseismic viscoelastic relaxation effect of the lower crust and upper mantle.
The results show that the Coulomb stress change increases significantly in the south section of the Xianshuihe Fault, the Anninghe Fault, the northern section of the Xiaojiang Fault, the southern section of the Longmen Shan Fault, the intersection of the Chuxiong-Jianshui Fault and the Xiaojiang Fault, and the Shawan section of the Litang Fault, in which the cumulative Coulomb stress change exceeds 0.1MPa. The assuming different friction coefficient has little effect on the stress change, as for the strike-slip dominated faults, the shear stress change is much larger than the normal stress change, and the shear stress change is the main factor controlling the Coulomb stress change on the fault plane. Meanwhile, we compare the Coulomb stress change in the 10km and 15km depths, and find that for most faults, the results are slightly different. Additionally, based on the existing focal mechanism solutions, we add the focal mechanism solutions of the 5 675 small-medium earthquakes(2.5≤M≤4.9)in Sichuan-Yunnan region from January 2009 to July 2019, and invert the directions of the three principal stresses and the stress shape factor in 0.1°×0.1° grid points; by combining the grid search method, we compare the inverted stress tensors with that from the actual seismic data, and further obtain the optimal stress tensors. Then, we project the stress tensors on the two inverted nodal planes separately, and select the maximum Coulomb stress change to represent the stress change at the node. The results show that the cumulative Coulomb stress change increase in the triple-junction of Sichuan-Yunnan-Tibet region is also significant, and the stress change exceeds 0.1MPa.
Comprehensive analysis of the Coulomb stress change, seismic gaps and seismicity parameters suggest that more attention should be paid to the Anninghe Fault, the northern section of the Xiaojiang Fault, the south section of the Xianshuihe Fault, the southern section of the Longmen Shan Fault and the triple-junction of the Sichuan-Yunnan-Tibet region. These results provide a basis for future seismic hazard analysis in the Sichuan-Yunnan region. 相似文献
9.
为配合汶川地震断裂带科学钻探工程(WFSD),中国地震局地球物理研究所在四川省绵竹市天池乡和灌县—安县断裂附近分别架设了15套微震仪器和17个短周期地震台.基于WFSD-3附近的微震、短周期和区域台网的固定台站记录的近震数据,通过横波窗内S波分裂计算,得到其上地壳各向异性参数,即快波偏振方向和慢波的时间延迟,并分析了研究区的上地壳各向异性特征.结果显示,研究区大部分区域的快波偏振方向为NE向,与龙门山断裂带走向一致,但在研究区微震台阵布设小区域内,快波偏振方向表现出东西分区特征,东部为NE向,西部为NW向.上地壳各向异性主要是受到岩层中随应力分布排列的微裂隙和岩石或矿物结构的影响,研究区内快波偏振方向主要表现为NE方向,与断裂走向一致,反映了研究区上地壳各向异性主要受控于结构控制的各向异性,局部区域的快波偏振方向为NW向,与区域最大主压应力方向一致,说明区域应力场对研究区上地壳各向异性也有影响.通过分析微震台阵的归一化时间延迟随时间的变化情况可以反映区域应力场的变化情况.微震台阵的慢S波时间延迟在2012、2013年较为离散,在2014年有收敛的趋势,反映了强震后区域应力场逐渐稳定的趋势. 相似文献
10.
由跨断层形变测量反映的华北地块近期断裂活动特征 总被引:3,自引:0,他引:3
通过对华北地块不同构造部位、不同地震活动时段的跨断层测量资料研究表明,华北地块对于NE走向断裂作用为主的构造单元(包括地块和边界带)的强震活跃时段的断层运动速率明显小于强震不活跃时段;对于NW走向断裂作用为主的构造单元,其强震活跃时段的断层运动速率明显大于强震不活跃时段;对于NE、NW走向断裂共同作用的构造单元,断层运动速率变化特征类似于NW走向断裂作用为主的构造单元。结果还表明,华北地块现今强震活动主要受NW走向断裂的控制。 相似文献
11.
华东中强震的构造分类及地震活动图像中、 短期异常特征 总被引:2,自引:1,他引:1
基于在相似外加载荷作用下结构相似的构造可表现出类似的破裂图像及前兆演化特征的实验室研究结果, 对华东地区现代中强地震进行了初步构造分类, 在此基础上分析研究了19次震例前地震活动图像异常的统计特征。 结果表明: ① 大多数震例前具有2~3年尺度的地震学异常, 图像以“条带”和“增强”为主; ② 多数地震在条带异常后有1~2年的中期平静, 震前0.5~1年左右在中期平静背景上出现“集中、 收缩”图像; ③ 震前3个月左右的较短时间内, 多数震例震中附近以短期“平静”为主; ④ 部分震例前短时间内震中附近有“显著性地震”事件发生; ⑤ 不同构造类型震例前, 地震异常图像可能存在差异; ⑥ 华东地区中强地震可能更多是属于沿原存断裂继承性破裂导致的地震, 震源力学性质多为拉张型。 拉张与挤压型地震的异常特点也可能存在差异。 但由于震例较少, 其确定性和成因还需进一步探讨。 相似文献
12.
Gao Guoying 《中国地震研究》2007,21(4):397-408
Jiashi and its surrounding areas are composed of many structural zones. Using the focal mechanism solutions of 59 moderately strong earthquakes in Jiashi and its surrounding areas, and combining these with the calculation results of system cluster and stress field inversion, we analyzed the evolvement characteristics of the stress field for different times and different regions. The results were as follows: The earthquakes in Jiashi are mainly strike-slip. However, those of the Kalpin block are mainly reverse events, showing an obvious thrusting. The regional characteristics are different from other areas. The direction of the regional principal stress field is near NS. However, under different tectonic backgrounds, the directions of the stress fields are different. The direction of the principal compress stress is near NS in the Kashi-Wuqia area. But before and after the 3 earthquakes with M7.0, dynamic evolution from NW to NS and then to NE with time process was observed. The Kalpin block has been dominated by a consistent stress field in the NW direction for a long time. However, the direction of the stress field of the Jiashi region is NE. Since 1996, the direction of the regional stress field has changed obviously. The direction of the P axis was deflected towards the NE, and the plunge angle increased. The result shows clearly the regional characteristics and variation of the distribution pattern of the stress field in different tectonic environments. 相似文献
13.
新疆伽师及周围构造应力场区域特征探讨 总被引:1,自引:0,他引:1
在利用伽师及周围58次中强地震震源机制解对这一地区的构造应力场进行分析的基础上,结合系统聚类和应力场反演计算结果,对不同时期、不同区域应力场的变化特征进行了分析。该区域地震以走滑错动为主,柯坪块体逆冲作用更为明显。区域最大主压应力方向近SN,但不同构造背景下的主压应力方向存在着较明显的差异。乌恰-喀什地区P轴基本近SN向,但存在着由NW—SN—NE的随时间变化的过程;柯坪块体内部长期以来受较为一致的NW-SE向压应力作用;伽师震区P轴方向为NE-SW。1996年区域应力场方向开始发生明显的变化,P轴方位向NE偏转,倾角增大。结果表现出不同构造环境下应力场分布格局的特征或变化 相似文献
14.
分析研究了南黄海和东海地区18口石油勘探钻井的井孔崩落特征,结合对琉球岛弧和冲绳海槽地区浅源地震震源机制解的分析,确认了南黄海地区与我国华北地区有类似的现代构造应力场特征;并得出东海地区的最大水平压应力方向为NEE-SWW,最小水平压应力方向为NNW-SSE,它们分别与冲绳海槽地区的最大和最小主压应力方向接近;东海地区地壳上层的水平差应力可能不强,这与该地区没什么地震活动的特点是一致的.根据应力场特征推断,我国东部地区并未受到菲律宾海板块俯冲的推挤作用,而是可能受到垂直于冲绳海槽走向的拉伸作用的影响. 相似文献
15.
STUDY ON SOURCE PARAMETERS OF THE 8 AUGUST 2017 M7.0 JIUZHAIGOU EARTHQUAKE AND ITS AFTERSHOCKS,NORTHERN SICHUAN 下载免费PDF全文
下载免费PDF全文 WU Wei-wei WEI Ya-ling LONG Feng LIANG Ming-jian CHEN Xue-fen SUN Wei ZHAO Jing 《地震地质》1979,42(2):492-512
On August 8, 2017, a strong earthquake of M7.0 occurred in Jiuzhaigou County, Aba Prefecture, northern Sichuan. The earthquake occurred on a branch fault at the southern end of the eastern section of the East Kunlun fault zone. In the northwest of the aftershock area is the Maqu-Maqin seismic gap, which is in a locking state under high stress. Destructive earthquakes are frequent along the southeast direction of the aftershocks area. In Songpan-Pingwu area, only 50~80km away from the Jiuzhaigou earthquake, two M7.2 earthquakes and one M6.7 earthquake occurred from August 16 to 23, 1976. Therefore, the Jiuzhaigou earthquake was an earthquake that occurred at the transition part between the historical earthquake fracture gap and the neotectonic active area. Compared with other M7.0 earthquakes, there are few moderate-strong aftershocks following this Jiuzhaigou earthquake, and the maximum magnitude of aftershocks is much smaller than the main shock. There is no surface rupture zone discovered corresponding to the M7.0 earthquake. In order to understand the feature of source structure and the tectonic environment of the source region, we calculate the parameters of the initial earthquake catalogue by Loc3D based on the digital waveform data recorded by Sichuan seismic network and seismic phase data collected by the China Earthquake Networks Center. Smaller events in the sequence are relocated using double-difference algorithm; source mechanism solutions and centroid depths of 29 earthquakes with ML≥3.4 are obtained by CAP method. Moreover, the source spectrum of 186 earthquakes with 2.0≤ML≤5.5 is restored and the spatial distribution of source stress drop along faults is obtained. According to the relocations and focal mechanism results, the Jiuzhaigou M7.0 earthquake is a high-angle left-lateral strike-slip event. The earthquake sequence mainly extends along the NW-SE direction, with the dominant focal depth of 4~18km. There are few shallow earthquakes and few earthquakes with depth greater than 20km. The relocation results show that the distribution of aftershocks is bounded by the M7.0 main shock, which shows obvious segmental characteristics in space, and the aftershock area is divided into NW segment and SE segment. The NW segment is about 16km long and 12km wide, with scattered and less earthquakes, the dominant focal depth is 4~12km, the source stress drop is large, and the type of focal mechanism is complicated. The SE segment is about 20km long and 8km wide, with concentrated earthquakes, the dominant depth is 4~12km, most moderate-strong earthquakes occurred in the depth between 11~14km. Aftershock activity extends eastward from the start point of the M7.0 main earthquake. The middle-late-stage aftershocks are released intensively on this segment, most of them are strike-slip earthquakes. The stress drop of the aftershock sequence gradually decreases with time. Principal stress axis distribution also shows segmentation characteristics. On the NW segment, the dominant azimuth of P axis is about 91.39°, the average elevation angle is about 20.80°, the dominant azimuth of T axis is NE-SW, and the average elevation angle is about 58.44°. On the SE segment, the dominant azimuth of P axis is about 103.66°, the average elevation angle is about 19.03°, the dominant azimuth of T axis is NNE-SSW, and the average elevation angle is about 15.44°. According to the fault profile inferred from the focal mechanism solution, the main controlling structure in the source area is in NW-SE direction, which may be a concealed fault or the north extension of Huya Fault. The northwest end of the fault is limited to the horsetail structure at the east end of the East Kunlun Fault, and the SE extension requires clear seismic geological evidence. The dip angle of the NW segment of the seismogenic fault is about 65°, which may be a reverse fault striking NNW and dipping NE. According to the basic characteristics of inverse fault ruptures, the rupture often extends short along the strike, the rupture length is often disproportionate to the magnitude of the earthquake, and it is not easy to form a rupture zone on the surface. The dip angle of the SE segment of the seismogenic fault is about 82°, which may be a strike-slip fault that strikes NW and dips SW. The fault plane solution shows significant change on the north and south sides of the main earthquake, and turns gradually from compressional thrust to strike-slip movement, with a certain degree of rotation. 相似文献
16.
根据华北地区61次中、小地震(3.0≤M≤5.5)和10次M≥6.0大地震的震源机制结果的统计分析,得到地震释能应力场的优势方向,主压应力轴为70°-80°,主张应力轴为340°-350°,它们的仰角基本上小于45°。这表明,华北地区处于以北东东向水平压应力和北北西向水平张应力为主的现代构造应力场中。指出了这一地区6级以上地震和震源深度大于17公里的中、小地震应力场方向一致性较好,可能更接近构造应力场方向。华北地区一致性应力场的南缘,可能在秦岭、大别山及长江下游一带。 相似文献
17.
2019年7月4—6日位于美国南加州城市Ridgecrest附近地区,在不足两天的时间内接连发生了一系列地震,其中包括震级达M W6.4和M W7.1的强震.震后两天对震中区产生的地表破裂进行了实地地质调查和测量,发现两次地震分别产生了NW方向长度50 km和NE方向长度10 km的两条破裂带.根据野外调查,NW方向的地表破裂表现出右旋走滑特征,是M W7.1地震产生的破裂带,而NE方向的地表破裂表现为左旋走滑性质,是M W6.4地震产生的破裂带.地表破裂野外调查和地震序列统计分析表明,NW方向是本次地震序列的主要破裂带,释放了本次地震的大部分地震矩.通过发震的时序关系和地震序列密集条带分布推断,本次地震是NE和NW两个方向应力作用下,两条共轭断层先后破裂产生的一组复杂共轭地震,推测M W6.4地震是一次强烈前震,促进了震级更大的M W7.1主震发生. 相似文献
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调查了北部湾6.1、6.2级地震的烈度分布,陆地最高达六度,六度区的长轴呈NW向。研究了海底地形、重力资料、断裂产状、震中空间分布以及震源机制解,结果表明,该地震序列是在南北向的区域应力场作用下产生的共轭剪切错动,NW向的涠洲-斜阳断裂为主要发震构造,一系列较小的余震则是NE向断裂活动引发的。 相似文献
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本文根据我国及邻区40年来(1937—1977年)173次浅源地震的断层面解结果以及其他资料, 讨论了我国及邻区普遍存在着的以水平压应力为特征的现代构造应力场.其区域特征表现为:(1)华南地区以北西西走向的水平压应力为主;(2)华北以及朝鲜和西南日本是以北东东走向的水平压应力和北北西走向的水平张应力为其特点;(3)青藏高原的大部分直到蒙古西部均处在近南北到北东走向的水平压应力作用之下, 兰州amp;amp;mdash;察隅一线以东的压应力呈现有规则的向东南偏转.西天山地区具有北西向压应力.我国大陆板块内部的现代构造应力场与周围岩石圈板块运动和上地幔的物质运动有关. 相似文献
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利用宽频带流动地震台阵和首都圈固定台网记录到的近震波形数据,研究了首都圈地区(386°N~410°N,〖JP〗1150°E~1197°E)的横波分裂,给出了快波偏振优势方向的场分布,讨论了首都圈地区的应力场特征. 在此基础上,采用二维线弹性有限元数值模拟方法,探讨了断层不均匀滑动对区域构造应力场的影响. 结果表明:(1)首都圈地区的应力场整体特征表现为NE向的背景应力场和受张家口-蓬莱断裂带控制的NW向的局部应力场;(2)在研究区域的西半部分和中部,最大主压应力方向为NE60°~70°,在唐山大震区及其东部区域,最大主压应力方向近WE向;(3)首都圈地区的局部应力场最大主压应力方向比较一致,基本上都与张家口-蓬莱断裂带走向平行,为120°~130°;〖JP2〗(4)首都圈区域内断层的存在及其郴均匀滑动是研究区内出现大量局部应力场的一个重要原因,张家口-〖JP〗蓬莱断裂带对首都圈局部应力场起着重要的控制作用. 相似文献