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1.
断层旋性与地震危险性   总被引:1,自引:0,他引:1  
郭增建  吴瑾冰 《地学前缘》2001,8(2):247-252
文中以“平行同旋走滑断层减震”的观点论证了兰州、北京、昆明这些位于强震活动区的大城市今后百年内不会发生 6 .5级以上地震。以“平行异旋走滑断层加震”的观点解释了西南棱形块体北边界和南边界在发生大震方面相互促进的现象。对于由构造分段求震级来说 ,在遇到不同的横交断层作为分段点时 ,还需考虑将来发震时始破裂点的位置以及发震断层的旋性 ,不然就会造成对震级估计不足 ,继而成为抗震建设的潜在不安全因素。在主震后为了预报余震的强度 ,可应用物理学中的科里奥利力理论 ,应用时必须知道断层类型和旋性。对于走滑断层来说 ,左旋余震弱 ,右旋余震强。例如 1997年藏北玛尼 7.5级地震 ,余震仅为 5 .3级 ,震级偏小 ,因主震为左旋的缘故 ;1976年唐山 7.8级地震 ,余震可达 7.1级 ,因主震是右旋。对于逆断层来说 ,上盘错动方向在当地子午面左侧者余震强度大 ,在右侧者余震强度弱。据此讨论了 1999年台湾南投 7.6级大震余震强度达 7.1级是因为主震为逆断层 ,上盘向西错动。  相似文献   

2.
The 12 May 2008 Wenchuan Ms8.0 earthquake produced surface displacements along the causative fault, the Yingxiu–Beichuan Fault, which are up to several meters near the fault. Because of the large gradient, satellite synthetic aperture radar (SAR) interferometric data are strongly incoherent; the usual SAR interferometry method does not allow such displacements to be measured. In the present study, we employed another approach, the technique based on pixel offset tracking, to solve this problem. The used image data of six tracks are from the Advanced Land Observing Satellite, Phased Array type L-band Synthetic Aperture Radar (ALOS/ PALSAR) dataset of Japan. The results show that the entire surface rupture belt is 238 km long, extending almost linearly in a direction of 42° north–east. It is offset left laterally by a north–west-striking fault at Xiaoyudong, and turns at Gaochuan, where the rupture belt shifts toward the south by 5 km, largely keeping the original trend. In terms of the features of the rupture traces, the rupture belt can be divided into five sections and three types. Among them, the Beichuan–Chaping and Hongkou–Yingxiu sections are relatively complex, with large widths and variable traces along the trend. The Pingtong–Nanba and Qingping–Jingtang sections appear uniform, characterized by straight traces and small widths. West of Yingxiu, the rupture traces are not clear. North of the rupture belt, surface displacements are 2.95 m on average, mostly 2–3.5 m, with 7–9 m the maximum near Beichuan. South of the rupture belt, the average displacement is 1.75 m, dominated by 1–2 m, with 3–4 m at a few sites. In the north, the displacements in the radar line of sight are of subsidence, and in the south, they are uplifted, in accordance with a right-slip motion that moves the northern wall of the fault to the east, and the southern wall to the west, respectively. Along the Guanxian–Jiangyou Fault, there is a uplift zone in the radar line of sight, which is 66 km long, 1.5–6 km wide, and has vertical displacements of approximately 2 m, but no observable rupture traces.  相似文献   

3.
2022年1月8日青海门源MS 6.9地震发生在青藏高原东北缘的祁连山断块内部,仪器震中位于海原活动断裂系西段的冷龙岭断裂带上,是该断裂系自1920年海原8.5级大地震后再次发生M>6.5的强震。考察结果的初步总结表明,此次门源地震产生了呈左阶斜列分布、总长度近23 km的南北两条破裂,在两者之间存在长约3.2 km、宽近2 km的地表破裂空区。南支破裂(F1)出现在托来山断裂的东段,走向91°,长约2.4 km,以兼具向南逆冲的左旋走滑变形为主,最大走滑位移近0.4 m。北支主破裂(F2)出现在冷龙岭断裂的西段,总长度近20 km,以左旋走滑变形为主,呈整体微凸向北东的弧形展布,包含了走向分别为102°、109°和118°的西、中、东三段,最大走滑位移出现在中段,为3.0±0.2 m。此外,在北支主破裂中—东段的北侧新发现一条累计长度约7.6 km、以右旋正断为主的北支次级破裂(F3),累计最大走滑量约0.8 m,最大正断位移约1.5 m。综合分析认为,整个同震破裂以左旋走滑变形为主,具有双侧破裂特点,宏观震中位于北支主破裂的中段,其地表走滑位移很大可能与震源破裂深度浅有关,其中的右旋正断次级破裂可能是南侧主动盘向东运移过程中拖曳北侧块体发生差异运动所引起的特殊变形现象。印度与欧亚板块近南北向强烈碰撞挤压导致南祁连断块沿海原左旋走滑断裂系向东挤出,从而引发该断裂系中的托来山断裂与冷龙岭断裂同时发生破裂,成为导致此次强震的主要动力机制。在此大陆动力学背景下,以海原左旋走滑断裂系为主边界的祁连山断块及其周边的未来强震危险性需得到进一步重视。   相似文献   

4.
研究区位于青藏高原的东北隅(96°~107°E,30°~35°N)。基于该地区长度大于2km的4 781条1∶20万数字化实测断裂、1900年以来的5 220条数字地震记录,以及野外地质观测数据,识别出993条不同属性的地震断层,构建了该地区百年地震构造格局。1970年以来十年期地震断层跃迁图像表明,自20世纪80年代中期白马—虎牙强烈震群爆发之后,地震活动在沿各主要走滑断层带自西(北西)向东(南东)迁移的同时,逐渐向中部贡玛—达曲断裂带和南部鲜水河断裂带的东南段集中。地震活动的断裂构造联系主要表现为挤压剪切转换机制和典型的楔顶效应。研究区165个GPS速度矢量展现了与3个地块和以鲜水河断裂带为主的速度域、速度梯度带和速度扰动区。跨研究区南缘鲜水河断裂带的位移速率因贡玛—达曲断裂带汇聚而达到了6.5~8.6mm/a,而跨北缘东昆仑断裂带的位移速度只有1.8~2.2mm/a。因鲜水河断裂走向在其中南段发生向南的急剧偏转,垂直断层面的位移矢量分量不断增强,形成了汶川8.0级地震成核及NE向单边破裂的动力学条件。  相似文献   

5.
The 26th January 2001 Bhuj earthquake occurred in the Kachchh Rift Basin which has a long history of major earthquakes. Great Triangulation Survey points (GTS) were first installed in the area in 1856–60 and some of these were measured using Global Positioning System (GPS) in the months of February and July 2001. Despite uncertainties associated with repairs and possible reconstruction of points in the past century, the re-measurements reveal pre-seismic, co-seismic and post-seismic deformation related to Bhuj earthquake. More than 25 Μ-strain contraction north of the epicenter appears to have occurred in the past 140 years corresponding to a linear convergence rate of approximately 10 mm/yr across the Rann of Kachchh. Motion of a single point at Jamnagar 150 km south of the epicenter in the 4 years prior to the earthquake, and GTS-GPS displacements in Kathiawar suggests that pre-seismic strain south of the epicenter was small and differs insignificantly from that measured elsewhere in India. Of the 20 points measured within 150 km of the epicenter, 12 were made at existing GTS points which revealed epicentral displacements of up to 1 m, and strain changes exceeding 30 Μ-strain. Observed displacements are consistent with reverse co-seismic slip. Re-measurements in July 2001 of one GTS point (Hathria) and eight new points established in February reveal post-seismic deformation consistent with continued slip on the Bhuj rupture zone.  相似文献   

6.
2017年8月8日四川省九寨沟县发生Ms7.0级地震,构造部位处于青藏高原东缘的巴颜喀拉地块东北角,震中位置是岷江断裂、塔藏断裂、虎牙断裂和雪山梁子断裂围闭的空震区。哪条断裂发震,如何界定其与周边活动断裂的关系,与青藏高原东缘近年来发生的大地震是否有成因联系等问题对于理解该区域现今构造活动模式、预判地震发展趋势和部署地震地质灾害防控等工作具有重要意义。利用地震前后两期Sentinel-1合成孔径雷达数据对地表同震形变场进行了InSAR测量,获取了极震区约2000 km2范围内的雷达视线向变形(-13~28 cm)和运动方向,呈现为主动盘单侧走滑兼逆冲的变形模式,结合震源机制、断裂展布、构造背景和近年地震迁移的分析,揭示了控震构造是巴颜喀拉地块北缘边界断裂弧形旋转体系的尾端构造,发震断层是该断裂系中塔藏断裂的南段,并有与虎牙断裂贯通的趋势,因此,应重视本次地震与虎牙断裂之间的空震区未来的强震危险性问题;从区域上看,此次九寨沟地震可能与汶川地震具有一定的时空成因联系,因在巴颜喀拉地块南北边界断裂破裂基本贯通的条件下,2008年汶川地震诱发的东缘中部锁固破裂导致块体加速向东挤出,2013年鲁甸地震又释放了东缘南段挤压构造应力,从而进一步加剧了东北角的应力集中,促使九寨沟地震的发生。  相似文献   

7.
On 21 March 2008, a Ms7.3 earthquake occurred at Quickbird, Yutian County, Xinjiang. We attempt to reveal the features of the causative fault of this shock and its coseismic deformation field. Our work is based on analysis and interpretation to high-resolution satellite images as well as differential interferometric synthetic aperture radar (D-InSAR) data from the satellite Envisat SAR, coupled with seismicity, focal mechanism solutions and active tectonics in this region. The result shows that the 40?km-long, nearly NS trending surface rupture zone by this event lies on a range-front alluvial platform in Qira County. It is characterized by distinct linear traces and simple structure with 1–3-m-wide individual seams and maximum 6.5?m width of a collapse fracture. Along the rupture zone many secondary fractures and fault-bounded blocks are seen, exhibiting remarkable extension. The coseismic deformation affected a large area 100×100?km2. D-InSAR analysis indicates that the interferometric deformation field is dominated by extensional faulting with a small strike-slip component. Along the causative fault, the western wall fell down and the eastern wall, that is the active unit, rose up, both with westerly vergence. Because of the big deformation gradients near the seismogenic fault, no interference fringes are seen on images, and what can be determined is a vertical displacement 70?cm or more between the two fault walls. According to the epicenter and differential occurrence times from the National Earthquake Information Center, China Earthquake Network Center, Harvard and USGS, it is suggested that the seismic fault ruptured from north to south.  相似文献   

8.
本文采用有限差分和随机振动合成结合的复合方法,模拟了当礼县—罗家堡断裂发生矩震级Mw7.7级大地震时,在天水盆地产生的宽频带地震动场,分析了在设定地震条件下盆地内的地震动分布特征,为该区黄土地震滑坡分析提供了地震动参数结果。结果显示:(1)有限差分法和随机振动合成法可以很好地互补,得到盆地内地表宽频带地震动;(2)地震在盆地区域产生了强烈地震动,PGA(峰值加速度)介于150~900 gal,离断层较近的区域东南角的PGA最大,随着断层距的增加,PGA逐渐减小。河谷南侧的PGA值相比北侧较大,具备诱发滑坡的强大动力条件;(3)盆地区域PGV(峰值速度)最大为120 cm/s。受第四系覆盖层放大效应和地形放大效应共同影响,水平向地震动在盆地区域东侧和中部具有较大PGV,而西侧PGV相对较小。竖向地震动在盆地区域东侧较弱,而在中部和西侧较强,特别是最西侧陡峭的山坡上,PGV达到了最大值。此外,竖向地震动明显受到覆盖层厚度的影响,譬如在盆地区域南侧的中间部位,也具有较大的PGV。  相似文献   

9.
巴颜喀拉块体及周缘是近年来中国大陆大震主要发震区域之一,2013年4月20日四川省芦山7.0级强烈地震就发生在巴颜喀拉块体东缘的龙门山断裂带的西南段上。以巴颜喀拉块体中东段为研究区,通过对该区域地震前后的多期区域水准观测数据和GNSS连续站观测数据进行计算处理,得出研究区垂直形变速率图像和水平形变速率图像;结合区域地质构造,建立地震诱发模型,解释芦山地震主震发震和余震活动源于龙门山断裂带中大型块体的突然断裂和小型块体集合的流动机制;通过对垂直形变速率图像和水平形变速率图像的分析,认为芦山地震是龙门山断裂带逆冲活动的结果,东昆仑断裂带中东段未来大震发生的可能性增大;提出未来5年基于区域水准测量和GNSS测量为技术手段的监测建议。  相似文献   

10.
The Sichuan – Yunnan region is divided into nine active secondary crustal blocks, based on several GPS repeat surveys at more than 200 GPS sites during the period 1999 – 2005. Velocities of the nine secondary blocks are calculated and analysed. The strain field within the area related to the 2004 Sumatra – Andaman earthquake event is also analysed. Results indicate that the crustal movement in the northern and western areas of the Sichuan – Yunnan region is stronger than that in the south and east. The horizontal velocities change from 19 – 20 mm/y in the northern and the central rhombic block to 11.7 mm/y in the southern rhombic block. The orientations of block motion vary from 99° in the north to 126 – 150° in the central area and 156 – 188° in the south, implying that the motion of the Sichuan – Yunnan rhombic block is dominated by a clockwise rotation. The velocity differences between blocks inside and outside the rhombic block are about 6.5 – 7.7 mm/y in the northern and central Sichuan – Yunnan region. The southeastward extrusion rate of the Tibetan Plateau shows a remarkable downtrend of up to 47% along the Xianshuihe Fault, suggesting an increase in strain accumulation and hence an area prone to strong earthquakes. The horizontal coseismic deformation caused by the Mw9.0 Sumatra – Andaman earthquake is <10 mm with a south-southeast orientation towards the earthquake epicentre. The dilatational strain rates from coseismic displacements reveal a possible interaction between the extrusion from the Tibet plateau interior and the underthrust effects from the Sumatra – Andaman earthquake.  相似文献   

11.
2017年8月8日21时19分,四川阿坝州九寨沟县发生7.0级地震,震中位于巴颜喀拉块体东边界虎牙断裂和东昆仑断裂带东段塔藏断裂交汇区域,地震构造背景较为复杂。地震导致了房屋和道路破坏、滑坡崩塌。根据高分辨率卫星影像解译、阶地坎变形的测量和测年数据得到:塔藏断裂东段晚第四纪以来以左旋走滑为主,兼逆分量,水平滑动速率为2.7~4.1 mm/yr,垂直滑动速率为0.56~0.6 mm/yr。结合此次地震的主余震分布、主震震源机制解等综合结果,初步建立了三维发震构造模型,分析认为此次地震属于走滑型地震,主破裂倾角57°~77°,发震断层可能是塔藏断裂的一条分支,是青藏高原块体向东推挤的一次地震事件。基于历史地震、活动断裂和形变观测方面的研究,巴颜喀拉块体具备显著的强震构造背景,对于该块体边界带周缘的强震活动和变形需要继续关注。  相似文献   

12.
史料记载1901年4月26日西藏尼木发生M 6?级地震,其发震构造尚未有报道,对其发震构造的厘定有助于理解尼木地堑群的地震复发规律,科学评价周边地区的未来强震危险性。遥感解译与地质调查表明,尼木地堑群内部的庞刚地堑西边界断裂长约30 km,走向近北西—北北西,以彭刚玛曲为界分为南北两段。北段断裂地貌线性特征显著,陡坎发育,断错了多级冰碛物及河流阶地。位移恢复结果显示,河流阶地垂直断距T0约1.0 m,T1约2.6 m,T2约5.0 m。南段断裂沿虾庆曲展布,地貌线性特征显著,陡坎发育,断错了多期冲洪积扇体。尼木县城北部发现断裂错动T2阶地剖面,显示该断裂延伸至尼木县城北部。根据位移-震级经验公式计算,庞刚地堑西边界断裂最新一次地震的矩震级约为MW 6.8,这与尼木地震比较吻合。遥感解译、地质调查与震级表明,庞刚地堑可能为1901年尼木地震的发震构造。结合历史地震记录分析认为,尼木地堑群中各个地堑具有独立发生中强地震的能力,其地震复发模式及其与亚东-谷露裂谷南北两段的地震活动差异等尚需进一步研究。   相似文献   

13.
四川汶川Ms 8.0地震地表破裂构造初步调查与发震背景分析   总被引:13,自引:3,他引:10  
5月16-24日对川西汶川大地震震中区的发震断裂地带进行的实地考察和初步测量,获得了宝贵的地表变形和同震位移最数据资料,证实汶川地震属于逆冲断裂型地震,主破裂沿映秀-北川断裂带发育,前山地区滑灌县-安县断裂也有地表破裂,同震位移量在3~5m.汶川地震产牛的地表破裂构造和运动性质显示明显分段特性,映秀-北川段以挤压逆冲为主,而北川以北段则伴有显著的右旋走滑分量.  相似文献   

14.
The central Kutch region of Gujarat, India, experienced a M7.7 earthquake on January 26, 2001, causing large-scale ground deformations including a huge loss of lives and infrastructure. The rupture of a hidden reverse fault was the reason for this intense tectonic activity. The post-seismic ground deformations, attributed to the relaxation phase of a stressed crustal layer, have been analyzed using a pair of Advanced Land Observation Satellite-Phased Array type L-band Synthetic Aperture Radar interferometric synthetic aperture radar (InSAR) images. The InSAR images were obtained in 2007 and 2010, covering an area around Bhuj. It falls on the Kutch Mainland Fault and Katrol Bhuj Fault. Using the ADORE-DORIS software, interferometric imagery has successfully been generated, covering the study area. This allowed making interesting geological inferences. Three different regions in the study area elicited countable visible colored fringes, indicating different amounts of positive and negative ground deformations (surface motion with respect to the satellite). They occurred within the InSAR data acquisition dates. The region around Bhuj and to the north and east of Bhuj showed top surface deformations of about 35, 35, and 24 cm, respectively. The synoptic view of the interferometric image of the study area suggests two crustal fault lines running to the north and south of Bhuj city. The Institute of Seismological Research, geophysical and Global Positioning System data, indicates that huge seismic events occurred during the year 2007–2010 and supports the observational inference of clustering of interferometric fringes to the E and NE of the study area.  相似文献   

15.
南水北调西线工程区地震危险性分析及预测   总被引:2,自引:1,他引:1  
作者已在《青藏高原地质过程与环境灾害效应》文集中, 对南水北调西线调水区地震与活动断裂的关系及其特征进行了论述, 本文通过南水北调西线工程区地震活动特点, 利用区域地震资料采用统计的方法研究地震发生的时空分布特点及预测未来发生地震的可能性。   相似文献   

16.
根据陕西省2001和2002年两期的GPS测站的观测资料,给出了渭河盆地及周邻地区地壳运动速度场和该区现今地壳水平应变场,结果表明:(1)渭河盆地及邻区的运动速率呈现较明显的北东向条带状变化特征,该区有整体不连续性逆时针旋转运动的特征;(2)渭河盆地中部的彬县—西安—蓝田一线存在一个左旋剪切带(东侧),该左旋剪切带的北部区域与铜川—泾阳—临潼小发震带恰好对应;(3)渭河盆地中部与北部以压应变为主,南部以张应变为主,高值区主要分布在该区主要断裂带的附近,尤其是在宝鸡一太白、渭南—蓝田和合阳—韩城附近分别形成应变高值区,并且应变梯度也较大;该区渭河断裂以北大部分地区以面收缩为主,以南则以面膨胀为主,面应变高值区与压应变高值区以及最大剪应变高值区有着较好的对应关系。  相似文献   

17.
2008年5月12日汶川MS8.0级特大地震发生后,在北川县擂鼓地区出露了一条擂鼓同震地表破裂带,该破裂带呈近南北向展布,位于映秀-北川断裂的中北段,其北东起于擂鼓镇柳林村北部,南西止于石岩村南部,以脆性破裂为特征,分别由3条呈北北东、北西西、北北东走向的地表破裂组成,延伸长度约4~5km,并切割了多种地貌单元,其平均垂直断距为1.5m,平均水平断距为1.4m,垂直与水平断距之比为1.07∶1。通过对该地表破裂带野外测量数据、几何展布结构及其成因机制的初步分析表明: 擂鼓断裂是出露于擂鼓地区的捩断层,具有捩断层的基本特性;其主要特征包括:1)擂鼓断裂的形成是由于在汶川地震中其东西两侧逆冲块体之间的差异性运动而引起; 2)断裂呈近南北向展布,与映秀-北川主干断裂近垂直相交;3)断面倾角较陡,为高角度断面的逆断层,具有逆冲兼走滑特征。  相似文献   

18.
新生代以来,印度板块与欧亚大陆的碰撞和持续的汇聚在青藏高原西北部的帕米尔地区造成了强烈的陆内变形,形成一系列典型的构造地貌。文章在卫片解译、DEM数据处理的基础上,结合野外地质、地貌观察与测量,对帕米尔东北缘的构造地貌与活动构造特征进行了研究,取得以下认识: 1)在英吉沙地区,通过测量地貌变形面计算出英吉沙背斜隆起高度约为230m,并利用面积平衡法估算出英吉沙背斜的最小构造缩短量约为110m,参考前人的年代学数据计算出英吉沙背斜在中更新世以来的最低隆升速率约为0.23mm/a,最小构造缩短速率约为0.11mm/a; 2)在帕米尔前缘,乌泊尔断裂为一条伴随右旋走滑分量的逆冲断裂,该断裂的右旋走滑作用错断了古近纪地层及流过断裂的河流,通过测量单次地震造成的水系错断量并参考前人研究的该地区大震复发周期约为1000年,估算出该断裂的平均走滑速率为 4.0~6.8mm/a,并推测断裂开始活动的时间大约在 2.2~3.0Ma以前; 3)对喀什地区构造地貌特征的观察与研究表明,明尧勒-喀什背斜和阿图什-踏浪河背斜可能分别为帕米尔东北缘西昆仑山山前冲断带和西南天山山前冲断带的前缘,该地区以西,帕米尔东北缘西昆仑山和西南天山两大构造系统已经发生了碰撞和拼贴。  相似文献   

19.
The 26th January 2001 Bhuj earthquake was followed by intense aftershock activity. Aftershock data from United States Geological Survey (USGS) utilized in this study encompasses three months period from 26th January to 26th April 2001. Epicenters of the aftershock are plotted on a map depicting active faults. All the aftershocks of magnitude > 5 and 70% of those ranging between magnitude 3 and 5 are confined to an area resembling a horseshoe pattern with a pointed end towards NE. The other 20% of magnitude 3 to 5 are enclosed within an almost parallel boundary. Only 10% are found to be beyond this limiting boundary. 50% of the recorded after-shocks took place within the first week of the main event and this study reveals that the basic characteristic pattern of aftershock activity can be determined on the basis of the data of only one week. Four major NW-SE trending active faults are mapped in the Kutch region. They define the western limit of Cambay structure and also mark the western limit of Dharangadhra and Wadhwan basins along the SE continuation in Saurashtra. These faults separate the Kutch region into two geologically different blocks. On the SW side the mapped horseshoe pattern gets characteristically truncated along the western most fault, which is characterized by a strike-slip movement in the south and vertical movement in the north. The present study has revealed that the epicenter of the 26th January earthquake is located in the vicinity of the Bhachau township, close to the intersection with the Kutch mainland fault. Furthermore, it has been noticed that most of the epicenters of the aftershock are confined in the intersectional area of the Kutch mainland fault and the NW-SE faults.  相似文献   

20.
利用近年来采集的高分辨率地震剖面资料,编制了渤海海峡跨海通道工程区主要活动断裂分布图,并对其中各断裂的垂直活动速率进行计算,发现渤海海峡跨海通道工程区内NE—NNE向断裂晚更新世以来的平均垂直活动速率为0103 mm/a,NW向断裂的平均垂直活动速率为0080 mm/a,其中NE—NNE向断裂和NW向断裂的活动速率呈由南到北逐渐增强的趋势,NW向断裂还表现出明显的自西向东活动速率逐渐增强的特点。另外,通过与现代小震资料和历史地震资料进行对比,发现研究区内地震分布具有不均匀性,地震活动性随着与断裂之间距离的增加而减弱,且在断裂交点和端点处活动性较强。研究区内地震的这些分布特征能够用弹性回跳学说解释。此外,研究区内地震活动性与断裂的水平位移速率关系可能更为密切,其与断裂垂直活动速率的关系还需要进一步研究。  相似文献   

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