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1.
The seismogenic structure of the Lushan earthquake has remained in suspensed until now. Several faults or tectonics, including basal slipping zone, unknown blind thrust fault and piedmont buried fault, etc, are all considered as the possible seismogenic structure. This paper tries to make some new insights into this unsolved problem. Firstly, based on the data collected from the dynamic seismic stations located on the southern segment of the Longmenshan fault deployed by the Institute of Earthquake Science from 2008 to 2009 and the result of the aftershock relocation and the location of the known faults on the surface, we analyze and interpret the deep structures. Secondly, based on the terrace deformation across the main earthquake zone obtained from the dirrerential GPS meaturement of topography along the Qingyijiang River, combining with the geological interpretation of the high resolution remote sensing image and the regional geological data, we analyze the surface tectonic deformation. Furthermore, we combined the data of the deep structure and the surface deformation above to construct tectonic deformation model and research the seismogenic structure of the Lushan earthquake. Preliminarily, we think that the deformation model of the Lushan earthquake is different from that of the northern thrust segment ruptured in the Wenchuan earthquake due to the dip angle of the fault plane. On the southern segment, the main deformation is the compression of the footwall due to the nearly vertical fault plane of the frontal fault, and the new active thrust faults formed in the footwall. While on the northern segment, the main deformation is the thrusting of the hanging wall due to the less steep fault plane of the central fault. An active anticline formed on the hanging wall of the new active thrust fault, and the terrace surface on this anticline have deformed evidently since the Quaterary, and the latest activity of this anticline caused the Lushan earthquake, so the newly formed active thrust fault is probably the seismogenic structure of the Lushan earthquake. Huge displacement or tectonic deformation has been accumulated on the fault segment curved towards southeast from the Daxi country to the Taiping town during a long time, and the release of the strain and the tectonic movement all concentrate on this fault segment. The Lushan earthquake is just one event during the whole process of tectonic evolution, and the newly formed active thrust faults in the footwall may still cause similar earthquake in the future.  相似文献   

2.
半地堑反转构造的砂箱实验模拟   总被引:8,自引:1,他引:8  
设计了两组半地堑反转垢理想砂箱实验模型。实验结果表明,边界条件对半地堑反转构造形成特征有着十分明显的影响。刚性边界条件下,沿着边界断层可以产生一定的反转逆冲现象,反转逆冲的程度与边界断层的倾角大小有关,倾角越缓反转逆冲现象越显著,而在自由边界条件下,边界断层均无反转逆冲现象,只是发生倾角变陡现象。沿半地堑边界断层的反转逆冲作用十分有限,反转逆冲主要通过新生低角度逆冲断层得以实现,地堑内部断层通常不  相似文献   

3.
The Luonan-Luanchuan tectonic belt lies between the North China Block and Qinling Mountains, including the Luonan-Luanchuan fault zone and the strong deformation zone to the north of the fault. The ductile shear zone, imbricate brittle fault and duplex structure in the fault zone now are the expression of the same tectonic event in different depth. Such lineation structure exists in the tectonic belts as mineral lineation, elongation lineation, crenulation lineation, sheath folds and so on, indicating NE-directed plate motion. Fold axes and thrusts in the strong deformation zone are inclined to the Luonan-Luanchuan fault zone at small angles. The structures with different natures show a regular pattern, produced during oblique convergence of plates. The convergence factors are as follows: The direction of plate convergence is 22°, 31° and the angle between the plate convergence direction and plate boundary is 73°, 82° respectively in the west and east segment. The Luonan-Luanchuan tectonic belt was deformed strongly in 372 Ma, resulted from Erlangping back-arc ocean basin subduction sinistrally and obliquely to North China Block during the collision of North China Block and South China Block. Supported by National Natural Science Foundation of China (Grant Nos. 40372097 and 40772131)  相似文献   

4.
在川滇活动地块东南边界区域完成了盐源-西昌-昭觉-马湖深地震宽角反射/折射探测剖面.利用该剖面获得的Pg初至折射波走时,采用走时特征分析、有限差分反演、时间项反演等方法,获得了沿剖面的基底P波速度结构和基底界面构造图像.结果表明,研究区基底结构呈现强烈的非均匀性,不同构造区显示出不同的地壳变形特征.盐源盆地盖层表现为推...  相似文献   

5.
王永哲  陈石  陈鲲 《地震》2021,41(1):116-128
2020年3月20日, 处在北喜马拉雅断裂与申扎—定结断裂交会区的西藏定日发生MW5.7地震, 此次地震发震断层源模型的研究对于认识该地区的复杂地质构造具有重要意义。 本文利用升、 降轨Sentinel-1A星载SAR数据, 通过合成孔径雷达干涉测量(InSAR)处理获得了地震引起的地表位移场, 其中, 雷达视线方向(LOS)最大地表位移达到0.16 m。 基于均匀弹性半空间位错模型, 利用得到的地表形变数据, 通过非线性和线性反演确定了包含断层几何参数以及滑动分布的震源模型, 最后对发震断层的构造特点进行了分析。 结果表明, 发震断层是具有少量右旋走滑分量的浅部隐伏正断层, 断层走向为319°, 倾角为44°, 断层滑动主要集中在1~6 km深的范围内, 最大滑动量位于深度4 km处且达到0.8 m。 地震释放的地震矩为4.14×1017 N·m, 对应矩震级为MW5.7, 与地震波形反演结果一致。 通过分析, 我们认为此次定日地震的发震断层可能为申扎—定结主断裂南端“Y”字型的分支断裂, 该地区“Y”字型构造的存在可能是小震集中于此的主要原因。  相似文献   

6.
赵强  王双绪  蒋锋云  李宁 《地震》2017,37(2):95-105
2016年1月21日, 青海省门源县冷龙岭断裂带附近发生了MW5.9地震。 基于Sentinel-1A影像, 采用差分干涉雷达测量技术研究了此次地震产生的同震形变场, 结果表明, 门源地震的形变影响范围约20~30 km, 形变态势在升降轨道形变场均显示为隆升, 基本沿冷龙岭断裂呈近似同心圆展布, 推测可能是冷龙岭断裂与民乐—大马营断裂之间的一条逆断层, 沿雷达视线方向最大形变量级约为6 cm。 均匀滑动反演显示门源发震断层长7.3 km, 宽6.2 km, 走向298.6°, 倾角34.5°, 倾向宽度9.5 km, 沿走向滑动量为170 mm, 沿倾向滑动量为460 mm, 矩震级为MW5.97; 分布式滑动反演显示门源地震以逆冲为主, 兼具少量右旋走滑分量, 滑动量主要集中在沿断层倾向方向, 距离地表5~15 km处, 最大滑动量约0.3 m, 位于断层倾向深度10 km处, 矩震级为MW5.93。  相似文献   

7.
The May 12, 2008 MS7.9 Wenchuan earthquake is ranked as one of the most devastating natural disasters ever occurred in modern Chinese history. The Longmenshan Fault(LMSF) zone is the seismogenic source structure, which consists of three sub-parallel faults, i.e., the Guanxian-Jiangyou Fault(GJF) in the frontal, the Yingxiu-Beichuan Fault(YBF) in the central fault and the Wenchuan-Maowen Fault(WMF) in the back of the LMSF. In this study, geological survey and seismic profiles are used to constrain the faults geometry and medium parameters. Three visco-elastic finite element models of the LMSF with different main faults are established. From the phase of interseismic stress accumulation to coseismic stress release and postseismic adjustment, the Wenchuan earthquake is simulated using Continuous-Discrete Element Method(CDEM). Modeling results show that before the 2008 Wenchuan earthquake, the GJF becomes unstable due to the interaction between its unique fault geometry and the tectonic stress loading. In the fault geometry model, the GJF is the most gently dipped fault among the three faults, which in return makes it having the smallest normal stress and the greatest shear stress. The continuous shear stress loading finally meets the fault failure criteria and the Wenchuan earthquake starts to initiate on the GJF at the depth of 15~20km. The earthquake rupture then propagated to the YBF. At the same time, due to the GJF and YBF rupture, the interseismic stress accumulation has been greatly reduced, causing the WMF failed to rupture. Although the stress accumulation in the WMF has been reduced significantly after the earthquake, yet it has not been released completely, which means that the WMF likely has with high seismic risk after the 2008 Wenchuan earthquake. We also find that the stress perturbation caused by gently dipping segment of the fault can promote the passive rupture in the steeply dipping segment, making the upper limit of dip angles larger than traditional assumption.  相似文献   

8.
搜集了盈江及其邻区5组地震序列震源机制解并反演得到该区域的构造应力场。研究结果显示:盈江地区整体主压应力以NNE向为主,主张应力以ESE向为主;但其局部应力场不完全一致,沿苏典断裂分布的主压应力轴走向随着断裂走向由北向南延伸角度逐渐向北偏移,而盈江地区的西南部,其主压应力走向更偏向于东,这可能与大盈江断裂的横向拉伸有关。此外,本研究通过应力场反演识别出了5组地震序列震源机制解的主发震断层节面的走向、倾角、滑动角及发震断层的摩擦系数,为今后该区域的地震研究及地壳动力学变迁提供了参考。   相似文献   

9.
A detailed investigation of microseismicity and fault plane solutions are used to determine the current tectonic activity of the prominent zone of seismicity near Samos Island and Kusadasi Bay. The activation of fault populations in this complex strike-slip and normal faulting system was investigated by using several thousand accurate earthquake locations obtained by applying a double-difference location method and waveform cross-correlation, appropriate for areas with relatively small seismogenic structures. The fault plane solutions, determined by both moment tensor waveform inversions and P-wave first motion polarities, reveal a clear NS trending extension direction, for strike slip, oblique normal and normal faults. The geometry of each segment is quite simple and indicates planar dislocations gently dipping with an average dip of 40–45°, maintaining a constant dip through the entire seismogenic layer, down to 15 km depth.  相似文献   

10.
王金烁  王爱国  孙赫 《地震》2017,37(2):86-94
2003年7月7日发生在西藏与青海交界处的班戈MS6.1地震, 由于缺乏余震分布等可靠资料, 其发震构造及其活动性质等问题一直认识不清。 几家机构利用远场波动资料给出的震源机制解差异很大。 本文利用ENVISAT卫星ASAR数据和D-InSAR技术, 计算获得了该地震LOS方向的同震形变场图像, 并以此为约束反演获得了该地震的断层几何参数和同震滑动分布。 结果表明, 班戈MS6.1地震的发震构造为控制唐古拉山西边界的波涛湖—土门断裂, 其发震断层为走向161°的高角度右旋斜滑正断层, 破裂长度约10 km, 滑动量主要集中在3~7 km深度范围, 最大滑动量0.26 m, 矩震级MW5.6。  相似文献   

11.
Continental extension is forming the Gulf of Corinth across the strike of earlier Alpine evolution. Here, we present the first deep reflection sections with pre-stack depth-migration processing across the deep basin of the Corinth active rift, which image structures unpredicted by current models. Resolving the infill as a pile of layers that are broken by faults allows one to follow their subsidence and deformation history. Variation among the profiles suggests that southern normal faults control the rift in a time progression from the east towards its western tip. On the central, Derveni-Itea transect, a 3-km widening of the basin accrued since the initiation of this control that is marked by an unconformity between the two main sedimentary units. This is estimated to have occurred 0.5-0.6 Myr ago, assuming the glacio-eustatic sea-level changes have controlled the stratigraphy of sediments deposited as a succession of layers on the subsiding hangingwall, as they did on the southern footwall in forming the famous flight of marine terraces of Corinth. A roll-over anticline and crestal collapse graben are diagnostic of the control by a normal fault of dip varying with depth. The deeper low-angle part of this bi-planar fault is indeed imaged as a reflector in the basement. The occurrence of the collapse with a breakaway at the steep southern basin-bounding fault of the hangingwall slab can be estimated 0.12-0.2 Myr ago, with a marked increase in extension rate that brought it to its present fastest value over 10 mm/yr. The low-angle part of the active fault might also have controlled earlier evolution upslope and in the basin. When compared with inferences from earthquake studies, this low-angle active fault may not appear to be seismogenic but may participate to the seismic cycle, possibly in a conditionally stable regime. Active faults seen as sea-bottom scarps merely accommodate deformation of its subsiding hangingwall. The footwall of the low-angle faults, which current seismicity shows to be in extension, appears then as being pulled out from beneath the rift, in a motion towards the rolling-back slab that causes the Hellenic subduction retreat.  相似文献   

12.
We analyze co-seismic displacement field of the 26 December 2004, giant Sumatra–Andaman earthquake derived from Global Position System observations,geological vertical measurement of coral head, and pivot line observed through remote sensing. Using the co-seismic displacement field and AK135 spherical layered Earth model, we invert co-seismic slip distribution along the seismic fault. We also search the best fault geometry model to fit the observed data. Assuming that the dip angle linearly increases in downward direction, the postfit residual variation of the inversed geometry model with dip angles linearly changing along fault strike are plotted. The geometry model with local minimum misfits is the one with dip angle linearly increasing along strike from 4.3oin top southernmost patch to 4.5oin top northernmost path and dip angle linearly increased. By using the fault shape and geodetic co-seismic data, we estimate the slip distribution on the curved fault. Our result shows that the earthquake ruptured *200-km width down to a depth of about 60 km.0.5–12.5 m of thrust slip is resolved with the largest slip centered around the central section of the rupture zone78N–108N in latitude. The estimated seismic moment is8.2 9 1022 N m, which is larger than estimation from the centroid moment magnitude(4.0 9 1022 N m), and smaller than estimation from normal-mode oscillation data modeling(1.0 9 1023 N m).  相似文献   

13.
滇西北发震构造条件及其与鲜水河断裂带的对比   总被引:2,自引:0,他引:2       下载免费PDF全文
马瑾 《地震地质》1988,10(4):35
文章在分析滇西北发震构造条件的基础上,把它与鲜水河断裂带进行了对比。滇西北是一个伸展构造区,鲜水河断裂带为一平移剪切带。后者较前者断层面上正应力大、变形强烈、应变速率高。前者断层几何复杂,D?=1.56,后者断层几何简单,D?=1.08-1.2。震源深处变形环境前者者为低压中温,后为高压中温。由此造成地震活动性上的差异  相似文献   

14.
帕米尔高原位于地中海-喜马拉雅地震带上,晚新生代以来随着印度板块向欧亚板块持续不断地挤压汇聚,其构造运动是欧亚大陆最强烈的地区。高原腹地发育一系列近SN向正断层,包括近SN向的塔什库尔干正断层所处的帕米尔中部现代区域的构造应力场以EW向水平拉张为主。2016年11月25日发生的阿克陶MS 6.7级地震的发震构造为塔什库尔干断层分支的NWW向木吉盆地北缘断层,其具有右旋走滑兼正断性质。地震在震中附近产生同震地表形变带,全长约1km,呈近SN-NNE向水平拉伸,发育近EW—NWW向的张裂缝,为地震破裂的产物,张裂缝的最大水平拉伸位移量和最大垂直位移量分别为46cm和16cm。地表破裂带中的NE和NW向张剪裂缝只是连接贯通这些雁列的张裂缝,其水平相对位移量取决于张裂缝的水平拉伸量和张裂缝之间的几何关系。地表形变带表现的拉张性质与帕米尔高原腹地区域现代应力场最大主压应力为垂直向基本一致,可能与深部热物质上涌造成的上地壳拉伸有关。而地表形变带呈近SN向水平拉张,与区域近EW向拉张应力场之间存在显著差异,这可能是木吉盆地北缘右旋走滑正断层阶区局部应力场调整的结果。  相似文献   

15.
地震断裂带形状是活动构造和地球动力学的重要资料。2021年发生的玛多地震序列提供了丰富的震源机制资料,为统计震源机制节面并估计玛多地震发震断层面形状提供了很好机会。文章对地震的震源机制资料进行基于密度的聚类来确定断层的几何形态。首先对收集到的玛多地震序列的震源机制解进行中心解求解,从而获得更为精准的数据,然后对其进行DBSCAN方法的聚类分析,得到断层的走向为113.5°,倾角为88.2°,通过震源机制反演应力场,并将应力场投影到断层上,得到断裂带的相对剪应力和相对正应力分别为0.84和-0.79,剪应力强度较大,滑动角为-0.72°。结果表明玛多地震是发震断裂受NE-SW的挤压和NW-SE的拉张,形成了较大的剪切力,从而促使近东西的江错断裂发生左旋走滑错动所致。  相似文献   

16.
The concept of displacement transfer[1] was initially utilized by Dahlstrom (1970) to explain the relation- ships of overlapping thrusts in the Canadian Rockies wherein the displacement on one thrust is transferred to another, but the total displacement is still held con- stant along trend. Displacement transfer, which may exist in compressional[2] as well as tensile environ-ments[3], is a familiar kinematic mechanism that keeps the magnitude of deformation steady along trend in the linear str…  相似文献   

17.
During the July–August 2001 eruption of Mt. Etna development of extensional fractures/faults and grabens accompanied magma intrusion and subsequent volcanic activity. During the first days of the eruption, we performed an analysis of attitude, displacement and propagation of fractures and faults exposed on the ground surface in two sites, Torre del Filosofo and Valle del Leone, located along the same fracture system in the region surrounding the Valle del Bove depression on the eastern flank of Mt. Etna. Fractures and faults formed as the consequence of a shallow intruding dyke system that fed the several volcanic centres developed along the fracture system. The investigated sites differ in slope attitude and in geometrical relationships between fractures and slopes. In particular, the fracture system propagated parallel to the gentle slope (<7° dip) in the Torre del Filosofo area, and perpendicular to the steep slope (25° dip) in the Valle del Leone area. In the Torre del Filosofo area, slight graben subsidence and horizontal extension of the ground surface by about 3 m were recorded. In the Valle del Leone area, extensional faulting forming a larger and deeper graben with horizontal extension of the ground surface by about 10 m was recorded. For the Valle del Leone area, we assessed a downhill dip of 14° for the graben master fault at the structural level beneath the graben where the fault dip shallows. These results suggest that dyke intrusion at Mount Etna, and particularly in the region surrounding the Valle del Bove depression, may be at the origin of slope failure and subsequent slumps where boundary conditions, i.e. geometry of dyke, slope dip and initial shear stress, amongst others, favour incipient failures.  相似文献   

18.
Surface wave dispersion curves from microearthquakes are used to obtain group velocity dispersion maps. The calculation of the local dispersion curves for each grid point from these maps then produces the input data to retrieve the 3D shear wave velocity model of the Tehran region. The group velocity maps indicate that the tomographic results agree well with the three main tectonic features and the geological units in the study area. The tomographic maps generally possess high-velocity structures across most of the mountain belts (Central Alborz and east-southeast mountains), whereas the Tehran Basin correlates to a low-velocity structure. Increasing the period in the study area highlights four independent low-velocity zones that reflect faults and fault junction systems. The shear wave velocity profiles indicate that the depth to bedrock exhibits southward variation ranging from ~?300 m to ~?1500 m. We also focus our analysis on the existence of faults within the shear wave profiles and discuss the low shear wave velocity anomalies deeper than 2 km result from the main fault structures (e.g., North Tehran, North-South Rey and Parchin). Furthermore, we argue that the dip angle of the North Tehran fault varies along fault strike, whereas the North-South Rey fault possesses a constant dip angle. Moreover, initial model uncertainties and checkerboard resolution tests are used to identify reliable and robust anomaly features in the 3D shear wave velocity model and 2D tomographic maps, respectively. Microearthquake analysis provides an effective approach for studying the upper crustal structure heterogeneity, especially the fault structure, of the Tehran region.  相似文献   

19.
青藏高原东北缘莫霍界面的三维空间构造特征   总被引:15,自引:2,他引:13       下载免费PDF全文
通过在青藏高原东北缘设计专门的三维地震观测系统而获得的莫霍界面反射波,利用三维反演方法反演重建了该区莫霍(M)界面的构造形态,得到了研究区M界面的三维构造图像和地壳深断裂的展布,研究区M界面总体上由东北向西南方向呈逐渐下倾趋势,而在不同的块体内部又具有不同的倾斜态势,反映了不同块体之间的差异和复杂程度的不同.鄂尔多斯块体M界面变化平缓,内部结构完整且坚硬;弧形构造区M界面的倾斜趋势发生了逆转,此现象可视为该区域在挤压、变形构造作用下M界面发生了明显的扭曲变形;秦祁块体M界面呈现出较陡的倾斜趋势,在本块东南端与弧形区结合部,M界面所显示出的局部隆起可视为地壳发生了强烈扭曲变形的迹象.综合二维、三维结果认为,特殊而复杂的构造变形环境,为海原8.6级大地震的孕育和发生提供了地质条件和深部背景.  相似文献   

20.
Different mountain shapes in sedimentary sequences in the Canadian Rockies were enhanced by glacial erosion and have been modified postglacially by gravity-driven slope processes. Slope modification by both glacial erosion and postglaciation landslides is related to rock structure, particularly bedding dip, rock mass strength and slope geometry. Five mountain peak shapes in monoclinal sequences each fall into different ranges of bedding dips. Castellate (1) and matterhorn (2) mountains occur in sub-horizontal beds and their slopes on all sides follow combinations of bedding planes and joints. The overall slopes are generally 37 to 65° and oblique to both bedding and joints. Slopes in sub-horizontal beds may be controlled by their rock mass strength. Cuestas (3) develop in gently to moderately dipping beds. Dip slopes and steeper, normal escarpments form their cataclinal and anaclinal sides respectively, with the dihedral angle between them about 90°. Hogbacks (4) in moderately to steeply dipping beds have similar slope angles on both cataclinal and anaclinal slopes. Cataclinal slopes are either dip slopes or underdip slopes but anaclinal slopes are often steepened escarpments; the dihedral angle between the slopes is usually less than 90°. Dogtooth (5) mountains occur in steeply dipping to sub-vertical beds and the dihedral angle can be as low as 60°. Slope gradients in inclined beds are closely related to landslides, whose modes are controlled by bedding dips. Copyright © 1999 John Wiley & Sons, Ltd.  相似文献   

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