印度板块挤压驱动龙门山断裂带活动的三维数值模型   总被引：2，自引：0，他引：2  

戴黎明  李三忠  陶春辉  李西双  刘鑫  索艳慧  周淑惠  周永刚  高武斌 《地球物理学进展》2011,26(1):41-51

采用有限元方法模拟了印度板块的持续向北推进、挤压对龙门山断裂带及其邻区的影响,根据模拟结果,对比GPS、地震和地质学观测数据,定量分析了汶川大地震发生前断裂带的走滑速率以及最大主应力的分布特征,据此探讨了汶川大地震的发震机理.模型由弹性上地壳和粘弹性下地壳组成,其中上地壳包括了青藏高原、四川盆地、华南地块以及印支地块,...  相似文献   

红河断裂带活动性研究   总被引：4，自引：0，他引：4  

朱俊江  詹文欢  唐诚  丘学林  孙宗勋 《华南地震》2003,23(2):13-19

红河断裂带是一条大型的走滑断裂带，该断裂带北起青藏高原东部，云南西北部，穿越越南北部，向东南延伸到南海，全长超过1000km。根据印支半岛前新生代的古地块与华南地块的接触关系，将红河断裂带分为海陆两段。断裂带自从第三纪以来，经历了左旋运动，右旋运动以及局部旋转，南北两段的活动性有一定的差异性，现今断裂带在最北端活动强烈，曾多次发生6级以上地震，南段现今活动较为平静。  相似文献   

太行山南缘断裂带新构造活动及其区域运动学意义   总被引：3，自引：0，他引：3       下载免费PDF全文

张岳桥  马寅生  杨农 《地震地质》2003,25(2):169-182

基于TM遥感影像的构造地貌解译和野外活动断层滑动矢量的测量和分析 ,阐述了太行山南缘断裂带第四纪左旋走滑活动的构造和地貌标志 ,反演了断裂变形的构造应力场 ,探讨了太行山南缘断裂带左旋走滑活动的区域运动学意义。研究表明 ,第四纪时期太行山南缘断裂带是一条斜张左旋走滑断裂。断层滑动矢量观测显示新近纪以来有 2期引张应力作用 :早期为NE -SW向引张 ,晚期为NNW -SSE向引张 ,这个观测结果与渭河地堑盆地的新近纪—第四纪 2期引张构造应力场一致。根据华北盆地构造资料推断 ,太行山南缘断裂带向东延伸与盆地内的泌阳 -开封 -商丘断陷带相接 ,共同构成了南华北和北华北 2个断陷区的构造边界。指出该断裂带作为南华北块体北缘 ,其新构造时期的斜张左旋走滑活动与南部秦岭断裂系左旋走滑活动一致 ,它们组成了一个宽阔的、向东撒开的、弥散型分布的左旋走滑形变带 ,调节着华南地块相对于华北地块向SEE方向的构造挤出  相似文献   

四川则木河断裂带微断层地貌的地形测量和走滑速率的估算(英文)   总被引：1，自引：1，他引：0       下载免费PDF全文

何宏林  宋方敏  李传友 《地震地质》1999,21(4):361-369

则木河断裂带南北分别与安宁河断裂带和小江断裂带相接,自中更新世复活以来,以左旋走滑为主,并成为一条重要的地震断层。据TL和ESR 测年分析,则木河谷地广泛存在的最低一级冲积扇为10 000 ～15 000 年以来形成。切割这些冲积扇的冲沟被则木河断裂带错断,其发生时间与冲积扇相当或者更新,平均位移值测量为86m 。据此计算,则木河断裂带晚更新世以来的平均走滑速率为5-8 ～8-6m m/a  相似文献   

用阶地测量方法探讨阿尔金断裂中段全新世滑动速率   总被引：9，自引：3，他引：6       下载免费PDF全文

王峰  徐锡伟  郑荣章 《地震地质》2004,26(1):61-70

通过分析高精度数字化SPOT卫星影像 ,结合野外考察和年代学测试 ,对阿尔金南缘走滑断裂带的 3个典型走滑断层断错地貌点进行了研究。在安南坝沟 ,阿尔金南缘走滑断裂带一主要分支自 (9.36± 0 .73)kaBP以来的左旋滑动速率为 (7.5± 1.7)mm/a ;在七个泉子阿尔金南缘走滑断裂带有 4条分支 ,其中 1条规模较小的断层分支自 (13 86± 1 0 7)kaBP以来的左旋滑动速率为 (2 .3±0 5 )mm/a ,由此推断七个泉子附近断裂带全新世以来的滑动速率为 (6 .9± 1.5 )～ (9.2± 2 .0 )mm/a ;约马克其断裂带自 (4 .73± 0 .38)kaBP以来的左旋滑动速率为 (10 .6± 3.0 )mm/a。综合以上各点结果 ,阿尔金南缘走滑断裂带中段 88°30′E与 93°0 5′E之间全新世以来的水平滑动速率为 7～ 11mm/a ,与最新的GPS观测结果非常接近  相似文献   

东昆仑断裂带东端的构造转换与2017年九寨沟M_S7.0地震孕震机制          下载免费PDF全文

任俊杰  徐锡伟  张世民  罗毅  梁欧博  赵俊香 《地球物理学报》2017,60(10):4027-4045

2017年四川九寨沟M_S7.0地震是继2008年汶川M_S8.0地震和2013年芦山M_S7.0地震之后，青藏高原东缘在不到十年的时间内发生的第三个震级M_S7.0以上的强震.这次地震发生在东昆仑断裂带东端，作为青藏高原东北缘的一条大型左旋走滑断裂带，东昆仑断裂带与东端其它构造之间的转换关系仍不清楚，因区内地质构造和地形复杂，东昆仑断裂带东端的主要构造仍缺少深入的研究.本文在总结区域地震构造活动特征、历史地震和现代地震基础上，通过东昆仑断裂带东端已有的和最近开展的活动构造定量研究结果，并结合现今GPS变形场资料和2017年九寨沟M_S7.0地震灾害特征分析，发现东昆仑断裂带最东段塔藏断裂上的左旋走滑除了一小部分继续向东传播转移到文县断裂带上外，大部分转化为其南侧的龙日坝断裂带北段、岷江断裂和虎牙断裂上的近东西向地壳缩短，这可能是岷山隆起的构造机制，而2017年九寨沟M_S7.0地震正是左旋走滑的东昆仑断裂带在东端继续向东扩展的结果.  相似文献   

阿尔金断裂带东段距今20ka以来的滑动速率   总被引：13，自引：6，他引：13       下载免费PDF全文

王峰  徐锡伟  郑荣章 《地震地质》2003,25(3):349-358

阿尔金断裂带作为青藏高原北部边界 ,其走滑量和走滑速率一直为地学界所关注 ,对这样一条大陆内部巨型走滑断裂带的滑动速率进行研究 ,对于了解阿尔金断裂带左旋走滑和青藏高原北部隆升之间的耦合关系 ,具有重要意义。在阿尔金断裂带东段的疏勒河口以西 ,阿尔金断裂错断了几条规模相近的河流阶地和洪积扇 ,形成典型的走滑断层断错地貌。通过对这些典型断错地貌点的地貌观测和年代学研究 ,得到阿尔金断裂带东段石堡城以东疏勒河以西自 2 0kaBP以来的滑动速率约为 4～ 5mm/a。自 50kaBP以来 ,阿尔金断裂带东段断层平均滑动速率具有较高的时间、空间一致性 ,约为 4～ 6mm/a ,表明利用河流阶地和洪积扇位错作为断层走滑位移标志计算断层滑动速率 ,具有较高的可信度  相似文献   

芦山M_S7.0地震后鲜水河断裂带南东段活动特征     

《华北地震科学》2015,(3)

在大地震沿鲜水河断裂带向ES迁移和鲜水河断裂带SE段较长时间未发生强震的背景下,本文收集了2013年芦山MS7.0地震前后(2010—2014年)鲜水河断裂带SE段3个跨断层短基线测点数据,分析了芦山地震前后该段近场断裂活动。研究结果表明:1)芦山地震前后,鲜水河断裂带在SE段断层的走滑方式存在左旋和右旋相互交替现象。2)芦山地震后该段近场滑动速率小于1mm/a,与震前较长时间的测量结果相比无明显变化,说明SE段已经进入震间锁闭阶段,应变持续积累,芦山地震并未对该区域断裂活动产生明显影响。根据断层运动随时间变化的模型,认为鲜水河断裂带SE段距离该段上次大地震时间长于EW段距离上次大地震的时间是2段滑动速率不同的原因之一。  相似文献   

小江和曲江-石屏两断裂系统的构造动力学与强震序列的关联性   总被引：1，自引：0，他引：1  

闻学泽  杜方  龙锋  范军  朱航 《中国科学:地球科学》2011,(5):713-724

SN向小江断裂带与NW-NWW向曲江-石屏断裂带是云南地区两个相邻的活动断裂系统及强震发生带.为了了解它们的相互作用及其可能对地震发生的影响,基于活动构造、历史地震、重新定位的小震、GPS站速度与震源机制解等资料进行综合分析,结果表明：（1）小江断裂带西盘（川滇块体）的主动向南运动对曲江-石屏断裂带具有长期强烈的作用;后一断裂带以右旋走滑/剪切-横向缩短/逆冲变形的方式吸收与转换前一断裂带西盘的向南运动.（2）小江断裂带的现代左旋走滑/剪切变形速率由其北、中和中-南段的10～8mma-1减小到南段的4mma-1,速率减小的部分由曲江-石屏断裂带及其附近地区以逆-右旋走滑断层作用和分布式的右旋剪切与横向缩短变形进行调节.（3）小江与曲江-石屏断裂带的构造动力学关系还表现在它们地震活动的紧密关联上：1500～1850年期间小江断裂带及其以北的则木河断裂带完成了一个长达351a的强震、大地震发生序列,显示出应变逐渐加速释放、M≥7事件间隔逐渐缩短、大释放集中在序列中-后期等特征;作为对于这一序列的响应,曲江-石屏断裂带在滞后88a后,发生一个长达383a（1588～1970年）、具有相同加速释放与时间进程特征的强震与大地震序列.（4）至今,小江断裂带已有177a未发生M≥7地震,应注意并进一步研究该断裂带未来的强震与大地震危险性.  相似文献   

再议走滑断裂与地震孕育和发生条件   总被引：1，自引：0，他引：1       下载免费PDF全文

邓起东  朱艾斓  高翔 《地震地质》2014,36(3)

走滑断裂是与大地震关系最紧密的活动断裂带。研究走滑断裂带上大地震是如何孕育和发生的是地震学家们极为关心的问题。构造地质学研究表明,走滑断裂是一个复杂的构造系统,反映了在剪切作用下产生的各类变形组合。文中立足于国内外不同走滑断裂带实例,对连续或不连续走滑断裂的几何学、运动学和演化过程进行了研究和总结;分析了走滑断裂的枢纽作用,发现枢纽轴部强烈挤压,形成闭锁,应力在此集中,应变在此局部化,地震在此成核和孕育。当闭锁的枢纽轴被突破时,沿走滑断裂发生失稳错动,产生突发性大位移,伴随大地震发生。而在不连续走滑断裂不同性质的阶区,则遵循其相应的应力场和破裂机制孕育和发生相应规模和类型的地震。  相似文献   

滇西南地区孟连断裂晚第四纪走滑速率的厘定   总被引：1，自引：1，他引：0       下载免费PDF全文

刘炳旭  袁道阳  王爱国  何文贵  邵延秀  方良好  高效东 《地震工程学报》2019,41(3):770-780

通过卫星影像解译和野外实地调查，获得滇西南地区孟连断裂的几何特征和活动性参数。孟连断裂总体走向NE-NEE向，不具有明显的分段性，连续性较好。断裂从单侧控制着沿线的勐滨、孟连和勐马三个新生代盆地的发育。断裂沿线地貌以线性较好的断层谷、断层崖和断层陡坎为主，并发育多级左旋位错的河流、冲沟和阶（台）地等，观测到的最小左旋位错约为7 m。采用高精度Li-DAR测量方法，对4处典型水平位错地貌进行精细测量，根据获得的相应地貌面年代，得到孟连断裂晚第四纪以来平均左旋走滑速率为2.2±0.4 mm/a。其结果与滇西南地区其他NE向左旋走滑断裂滑动速率相当，反映了区域构造活动的整体协调性。根据跨断层地质体最大左旋位错量9.5±1.8 km，估算断裂开始左旋走滑的时代为距今4.7±1.6 Ma左右，即中新世中晚期。  相似文献   

Structural analysis and interpretation of the surface deformation associated with the Ning’er,Yunnan Province,China <Emphasis Type="Italic">M</Emphasis><Subscript>S</Subscript>6.4 earthquake of June 3, 2007     

杨晓平  陈立春  马文涛  陈慧  周挚  李岩峰  谢英情  施伟华  常祖峰 《地震科学（英文版）》2008,21(2):170-180

The seismogenic fault and the dynamic mechanism of the Ning’er, Yunnan Province M_S6.4 earthquake of June 3, 2007 are studied on the basis of the observation data of the surface fissures, sand blow and water eruption, landslide and collapse associated with the earthquake, incorporating with the data of geologic structures, focal mechanism solutions and aftershock distribution for the earthquake area. The observation of the surface fissures reveals that the Banhai segment of the NW-trending Ning’er fault is dominated by right-lateral strike-slip, while the NNE-trending fault is dominated by left-lateral strike-slip. The seismo-geologic hazards are concentrated mainly within a 330°-extending zone of 13.5 km in length and 4 km in width. The major axis of the isoseismal is also oriented in 330° direction, and the major axis of the seismic intensity VIII area is 13.5 km long. The focal mechanism solutions indicate that the NW-trending nodal plane of the Ning’er M_S6.4 earthquake is dominated by right-lateral slip, while the NE-trending nodal plane is dominated by left-lateral slip. The preferred distribution orientation of the aftershocks of M_S≥2 is 330°, and the focal depths are within the range of 3～12 km, predominantly within 3～10 km. The distribution of the aftershocks is consistent with the distribution zone of the seismo-geologic hazards. All the above-mentioned data indicate that the Banhai segment of the Ning’er fault is the seismogenic fault of this earthquake. Moreover, the driving force of the Ning’er earthquake is discussed in the light of the active block theory. It is believed that the northward pushing of the Indian plate has caused the eastward slipping of the Qinghai-Tibetan Plateau, which has been transformed into the southeastern-southernward squeezing of the southwest Yunnan region. As a result, the NW-trending faults in the vicinity of the Ning’er area are dominated by right-lateral strike-slip, while the NE-trending faults are dominated by left-lateral strike-slip. This tectonic framework might be the main cause of the frequent occurrence of M_S6.0～6.9 earthquakes in the area.  相似文献   

2014年2月12日新疆于田M_S7.3地震序列及其构造背景研究          下载免费PDF全文

程佳杨文刘杰  周龙泉 《地震学报》2014,36(3):350-361

2014年2月12日新疆于田发生M_S7.3地震,该震前1天曾发生M_S5.4前震,震后余震活动频繁.截止到2月20日12时,该地震序列记录到4000多次余震,最大余震为2月12日M_S5.7地震,序列类型为前震—主震—余震型.该地震前震的b值明显低于该区域正常活动的b值和余震的b值.这次地震位于西昆仑断裂带与阿尔金断裂带的交汇区域的阿什库勒断裂北段,震源机制解为走滑型.余震区NE向长70 km、宽20 km,分为主余震分布区和次余震分布区,其中M_L4.0以上强余震基本位于NE向主余震分布区,N--S向的次余震分布区则以M_L3.0左右地震分布为主,显示该部分可能受到主震的触发作用.于田地区曾发生的2008年3月21日M_S7.3地震的震源机制解为正断型,距这次地震约100 km;2012年8月12日发生的M_S6.2地震的震源机制解为正断型,距这次地震约10 km.该地区的发震构造背景是:在NE向阿尔金断裂带尾端向SW方向延伸过程中,左旋走滑作用逐渐转换为拉张作用,形成多条左旋走滑兼具拉张作用的断裂. 2014年于田M_S7.3地震的发震模式表现为:左旋走滑的阿什库勒断裂北段与南段因速率差异而产生的小型构造盆地,在区域拉张作用力下顺时针旋转;2008年M_S7.3张性地震后区域的伸展作用增强,导致盆地南侧的苦牙克断裂发生2012年M_S6.2张性地震,该地震引起2014年M_S5.4前震,两者激发其后在盆地北侧阿什库勒断裂发生了2014年M_S7.3主震.   相似文献   

THE LATE QUATERNARY ACTIVITY AND FORMATION MECHANISM OF BAOERTU FAULT ZONE,EASTERN TIANSHAN SEGMENT          下载免费PDF全文

REN Guang-xue  LI Chuan-you  WU Chuan-yong  WANG Si-yu  ZHANG Hui-ping  REN Zhi-kun  LI Xin-nan 《地震地质》2019,41(4):856-871

Influenced by the far-field effect of India-Eurasia collision, Tianshan Mountains is one of the most intensely deformed and seismically active intracontinental orogenic belts in Cenozoic. The deformation of Tianshan is not only concentrated on its south and north margins, but also on the interior of the orogen. The deformation of the interior of Tianshan is dominated by NW-trending right-lateral strike-slip faults and ENE-trending left-lateral strike-slip faults. Compared with numerous studies on the south and north margins of Tianshan, little work has been done to quantify the slip rates of faults within the Tianshan Mountains. Therefore, it is a significant approach for geologists to understand the current tectonic deformation style of Tianshan Mountains by studying the late Quaternary deformation characteristics of large fault and fold zones extending through the interior of Tianshan. In this paper, we focus on a large near EW trending fault, the Baoertu Fault (BETF) in the interior of Tianshan, which is a large fault in the eastern Tianshan area with apparent features of deformation, and a boundary fault between the central and southern Tianshan. An M_S5.0 earthquake event occurred on BETF, which indicates that this fault is still active. In order to understand the kinematics and obtain the late Quaternary slip rate of BETF, we made a detailed research on its late Quaternary kinematic features based on remote sensing interpretation, drone photography, and field geological and geomorphologic survey, the results show that the BETF is of left-lateral strike-slip with thrust component in late Quaternary. In the northwestern Kumishi basin, BETF sinistrally offsets the late Pleistocene piedmont alluvial fans, forming fault scarps and generating sinistral displacement of gullies and geomorphic surfaces. In the bedrock region west of Benbutu village, BETF cuts through the bedrock and forms the trough valley. Besides, a series of drainages or rivers which cross the fault zone and date from late Pleistocene have been left-laterally offset systematically, resulting in a sinistral displacement ranging 0.93~4.53km. By constructing the digital elevation model (DEM) for the three sites of typical deformed morphologic units, we measured the heights of fault scarps and left-lateral displacements of different gullies forming in different times, and the result shows that BEFT is dominated by left-lateral strike-slip with thrust component. We realign the bended channels across the fault at BET01 site and obtain the largest displacement of 67m. And we propose that the abandon age of the deformed fan is about 120ka according to the features of the fan. Based on the offsets of channels at BET01 and the abandon age of deformed fan, we estimate the slip rate of 0.56mm/a since late Quaternary. The Tianshan Mountains is divided into several sub-blocks by large faults within the orogen. The deformation in the interior of Tianshan can be accommodated or absorbed by relative movement or rotation. The relative movement of the two sub-blocks surrounded by Boa Fault, Kaiduhe Fault and BETF is the dominant cause for the left-lateral movement of BETF. The left-lateral strike-slip with reverse component of BETF in late Quaternary not only accommodates the horizontal stain within eastern Tianshan but also absorbs some SN shortening of the crust.  相似文献   

Structural analysis and interpretation of the surface deformation associated with the Ning’er, Yunnan Province, China M _S6.4 earthquake of June 3, 2007     

杨晓平  陈立春  马文涛  陈慧  周挚  李岩峰  谢英情  施伟华  常祖峰 《地震学报(英文版)》2008,21(2):170-180

The seismogenic fault and the dynamic mechanism of the Ning’er, Yunnan Province MS6.4 earthquake of June 3, 2007 are studied on the basis of the observation data of the surface fissures, sand blow and water eruption, land-slide and collapse associated with the earthquake, incorporating with the data of geologic structures, focal mecha-nism solutions and aftershock distribution for the earthquake area. The observation of the surface fissures reveals that the Banhai segment of the NW-trending Ning’er fault is dominated by right-lateral strike-slip, while the NNE-trending fault is dominated by left-lateral strike-slip. The seismo-geologic hazards are concentrated mainly within a 330°-extending zone of 13.5 km in length and 4 km in width. The major axis of the isoseismal is also oriented in 330° direction, and the major axis of the seismic intensity VIII area is 13.5 km long. The focal mechanism solutions indicate that the NW-trending nodal plane of the Ning’er MS6.4 earthquake is dominated by right-lateral slip, while the NE-trending nodal plane is dominated by left-lateral slip. The preferred distribution orientation of the aftershocks of MS≥2 is 330°, and the focal depths are within the range of 3~12 km, predominantly within 3~10 km. The distribution of the aftershocks is consistent with the distribution zone of the seismo-geologic hazards. All the above-mentioned data indicate that the Banhai segment of the Ning’er fault is the seismogenic fault of this earthquake. Moreover, the driving force of the Ning’er earthquake is discussed in the light of the active block theory. It is believed that the northward pushing of the Indian plate has caused the eastward slipping of the Qinghai-Tibetan Plateau, which has been transformed into the southeastern-southernward squeezing of the southwest Yunnan region. As a result, the NW-trending faults in the vicinity of the Ning’er area are dominated by right-lateral strike-slip, while the NE-trending faults are dominated by left-lateral strike-slip. This tectonic  相似文献   

2013年川滇交界香格里拉—得荣震群序列的重新定位、震源机制及发震构造   总被引：1，自引：0，他引：1       下载免费PDF全文

吴微微  龙锋  杨建思  梁明剑  苏金蓉  魏娅玲  吴朋  卢婷 《地球物理学报》2015,58(5):1584-1596

2013年8月28日和31日四川得荣县与云南德钦县、香格里拉县交界地区分别发生MS5.2和MS5.9地震.这两次主震连同截至2013年12月31日发生的589次M≥1.5余震,构成香格里拉—得荣震群序列.该序列的震区位于青藏高原东南隅横断山脉的三江构造带地区,地处川滇菱形块体西边界,当地有多组交错的活动断裂.为了了解这一震群序列的震源构造特征以及震区的构造动力环境,我们利用区域地震台网的数字波形资料以及中国地震台网中心的有关震相数据,建立了分区速度结构模型;使用Loc3D(川滇走时表定位软件)重新测定该震群序列中10次MS4.0地震的位置,利用双差法对该序列中的更小地震进行重新定位;同时,采用地震矩张量的时间域反演方法获得10次MS4.0地震震源机制的矩张量解.重新定位结果显示:香格里拉—得荣震群序列的绝大部分地震发生在NW向德钦—中甸—大具断裂中段7~15km深度的基底层,整个序列的震源分布长度约17km,横向宽度约7km;震源分布在横剖面表现为负花状构造的断裂带内,其中,NE倾向的主干活动断裂及其北东侧一条SW倾向的次级断裂分别控制该负花状构造的两个侧边.本研究反演得到的震源机制解显示:该序列所有MS4.0地震均是德钦—中甸—大具断裂中段在近S-N向—NNE-SSW向拉张作用下的正断层作用的结果,右旋走滑作用并不明显.这与该断裂晚第四纪活动的地质地貌特征—右旋走滑为主、正断倾滑为辅—并不吻合.这种不一致可能暗示震区的现今构造运动与以往有所不同,为进一步研究青藏亚板块东南隅与缅甸亚板块以及印度板块交界地区的现今构造动力学提出了问题与线索.  相似文献   

TERRACE DEFORMATION AND SLIP RATES OF THE DONGBIELIEKE FAULT IN WESTERN JUNGGAR BASIN SINCE THE LATE QUATERNARY          下载免费PDF全文

YAO Yuan  LI Shuai  HUANG Shuai-tang  JIA Hai-liang 《地震地质》2019,41(4):803-820

Strike-slip fault plays an important role in the process of tectonic deformation since Cenozoic in Asia. The role of strike-slip fault in the process of mountain building and continental deformation has always been an important issue of universal concern to the earth science community. Junggar Basin is located in the hinterland of Central Asia, bordering on the north the Altay region and the Baikal rift system, which are prone to devastating earthquakes, the Tianshan orogenic belt and the Tibet Plateau on the south, and the rigid blocks, such as Erdos, the South China, the North China Plain and Amur, on the east. Affected by the effect of the Indian-Eurasian collision on the south of the basin and at the same time, driven by the southward push of the Mongolian-Siberian plate, the active structures in the periphery of the basin show a relatively strong activity. The main deformation patterns are represented by the large-scale NNW-trending right-lateral strike-slip faults dominated by right-lateral shearing, the NNE-trending left-lateral strike-slip faults dominated by left-lateral shearing, and the thrust-nappe structure systems distributed in piedmont of Tianshan in the south of the basin. There are three near-parallel-distributed left-lateral strike-slip faults in the west edge of the basin, from the east to the west, they are:the Daerbute Fault, the Toli Fault and the Dongbielieke Fault. This paper focuses on the Dongbielieke Fault in the western Junggar region. The Dongbielieke Fault is a Holocene active fault, located at the key position of the western Junggar orogenic belt. The total length of the fault is 120km, striking NE. Since the late Quaternary, the continuous activity of the Dongbielieke Fault has caused obvious left-lateral displacement at all geomorphologic units along the fault, and a linear continuous straight steep scarp was formed on the eastern side of the Tacheng Basin. According to the strike and the movement of fault, the fault can be divided into three segments, namely, the north, middle and south segment. In order to obtain a more accurate magnitude of the left-lateral strike-slip displacement and the accumulative left-lateral strike-slip displacement of different geomorphic surfaces, we chose the Ahebiedou River in the southern segment and used the UAV to take three-dimensional photographs to obtain the digital elevation model(the accuracy is 10cm). And on this basis, the amount of left-lateral strike-slip displacement of various geological masses and geomorphic surfaces(lines)since their formation is obtained. The maximum left-lateral displacement of the terrace T₅ is(30.7±2.1)m and the minimum left-lateral displacement is(20.1±1.3)m; the left-lateral displacement of the terrace T₄ is(12±0.9)m, and the left-lateral displacement of the terrace T₂ is(8.7±0.6)m. OSL dating samples from the surface of different level terraces(T₅, T₄, T₂ and T₁)are collected, processed and measured, and the ages of the terraces of various levels are obtained. By measuring the amount of left-lateral displacements since the Late Quaternary of the Dongbielieke Fault and combining the dating results of the various geomorphic surfaces, the displacements and slip rates of the fault on each level of the terraces since the formation of the T₅ terrace are calculated. Using the maximum displacement of(30.7±2.1)m of the T₅ terrace and the age of the geomorphic surface on the west bank of the river, we obtained the slip rate of(0.7±0.11)mm/a; similarly, using the minimum displacement of(20.1±1.3)m and the age of the geomorphic surface of the east bank, we obtained the slip rate of(0.46±0.07)mm/a. T₅ terrace is developed on both banks of the river and on both walls of the fault. After the terraces are offset by faulting, the terraces on foot wall in the left bank of the river are far away from the river, and the erosion basically stops. After that, the river mainly cuts the terraces on the east bank. Therefore, the west bank retains a more accurate displacement of the geomorphic surface(Gold et al., 2009), so the left-lateral slip rate of the T₅ terrace is taken as(0.7±0.11)mm/a. The left-lateral slip rate calculated for T₄ and T₂ terraces is similar, with an average value of(0.91±0.18)mm/a. In the evolution process of river terraces, the lateral erosion of high-level terrace is much larger than that of low-level terrace, so the slip rate of T₄ and T₂ terraces is closer to the true value. The left-lateral slip rate of the Dongbielieke Fault since the late Quaternary is(0.91±0.18)m/a. Compared with the GPS slip rate in the western Junggar area, it is considered that the NE-trending strike-slip motion in this area is dominated by the Dongbielieke Fault, which absorbs a large amount of residual deformation while maintaining a relatively high left-lateral slip rate.  相似文献   

1999年山西大同Ms 5.6地震的震源断层   总被引：9，自引：0，他引：9  

王焱  刁桂苓  张四昌  王勤彩  刘允清  朱振兴  张彦清 《中国地震》2002,18(1):96-101

大同震区先后在 1989、1991和 1999年发生MS >5地震 ,利用大同遥测地震台网的记录资料进行比较精确的地震序列震源定位 ,结合宏观烈度分布和震源机制解资料 ,详细地分析对比了 3次子序列的异同。结果显示 ,1999年MS5 .6地震的震源断层是走向NWW、长 16km、宽12km、埋深 5km以下、倾角近直立的左旋走滑断层。而前 2个子序列是NNE为主的右旋走滑断层活动所致 ,表明地震破裂方向发生了变化。这种 2个以上方向先后出现、并且强弱有别的地震破裂是普遍存在的 ,表明震源环境的复杂程度与地震序列的类型有关。虽然震区存在NE向的大王村断裂和NW向的团堡断裂 ,但目前没有证据说明震源断层和 2条构造断层连通。 3次子序列的震源断层都是走滑断层 ,也和 2条构造正断层有别。 1999年的子序列可能属于新破裂。  相似文献   

HOLOCENE PALAEOSEISMOLOGIC RECORD AND RUPTURE BEHAVIOR OF LARGE EARTHQUAKES ON THE XIANSHUIHE FAULT          下载免费PDF全文

LI Dong-yu  CHEN Li-chun  LIANG Ming-jian  GAO Shuai-po  ZENG Di  WANG Hu  LI Yan-bao 《地震地质》2017,39(4):623-643

The Xianshuihe Fault, the boundary of Bayan Har active tectonic block and Sichuan-Yunnan active tectonic block, is one of the most active fault zones in the world. In the past nearly 300 years, 9 historical earthquakes of magnitude ≥ 7 have been recorded. Since 2008, several catastrophic earthquakes, such as Wenchuan M_S8 earthquake, Yushu M_S7.1 earthquake and Lushan M_S7 earthquake, have occurred on the other Bayan Har block boundary fault zones. However, only the Kangding M_S6.3 earthquake in 2014 was documented on the Xianshuihe Fault. Thus, the study of surface deformation and rupture behavior of large earthquakes in the late Quaternary on the Xianshuihe Fault is of fundamental importance for understanding the future seismic risk of this fault, and even the entire western Sichuan region. On the basis of the former work, combined with our detailed geomorphic and geological survey, we excavated a combined trench on the Qianning segment of Xianshuihe fault zone which has a long elapse time. Charcoal and woods in the trench are abundant. 30 samples were dated to constrain the ages of the paleoseismic events. Five events were identified in the past 9  000 years, whose ages are:8070-6395 BC, 5445-5125 BC, 4355-4180 BC, 625-1240 AD and the Qianning earthquake in 1893. The large earthquake recurrence behavior on this segment does not follow the characteristic earthquake recurrence model. The recurrence interval is 1000~2000 years in early period and in turn there is a quiet period of about 5 000 years after 4355-4180 BC event. Then it enters the active period again. Two earthquakes with surface rupture occurred in the past 1000 years and the latest two earthquakes may have lower magnitude. The left-lateral coseismic displacement of the 1893 Qianning earthquake is about 2.9m.  相似文献   

RESEARCH OF SEISMOGENIC STRUCTURE OF THE MENYUAN M_S6.4 EARTHQUAKE ON JANUARY 21, 2016 IN LENGLONGLING AREA OF NE TIBETAN PLATEAU          下载免费PDF全文

JIANG Wen-liang  LI Yong-sheng  TIAN Yun-feng  HAN Zhu-jun  ZHANG Jing-fa 《地震地质》2017,39(3):536-549

On January 21 2016, an earthquake of M_S6.4 hit the Lenglongling fault zone(LLLFZ)in the NE Tibetan plateau, which has a contrary focal mechanism solution to the Ms 6.4 earthquake occurring in 1986. Fault behaviors of both earthquakes in 1986 and 2016 are also quite different from the left-lateral strike-slip pattern of the Lenglongling fault zone. In order to find out the seismogenic structure of both earthquakes and figure out relationships among the two earthquakes and the LLLFZ, InSAR co-seismic deformation map is constructed by Sentinel -1A data. Moreover, the geological map, remote sensing images, relocation of aftershocks and GPS data are also combined in the research. The InSAR results indicate that the co-seismic deformation fields are distributed on both sides of the branch fault(F₂)on the northwest of the Lenglongling main fault(F₁), where the Earth's surface uplifts like a tent during the 2016 earthquake. The 2016 and 1986 earthquakes occurred on the eastern and western bending segments of the F₂ respectively, where the two parts of the F₂ bend gradually and finally join with the F₁. The intersections between the F₁ and F₂ compose the right-order and left-order alignments in the planar geometry, which lead to the restraining bend and releasing bend because of the left-lateral strike-slip movement, respectively. Therefore, the thrust and normal faults are formed in the two bending positions. In consequence, the focal mechanism solutions of the 2016 and 1986 earthquakes mainly present the compression and tensional behaviors, respectively, both of which also behave as slight strike-slip motion. All results indicate that seismic activity and tectonic deformation of the LLLFZ play important parts in the Qilian-Haiyuan tectonic zone, as well as in the NE Tibetan plateau. The complicated tectonic deformation of NE Tibetan plateau results from the collisions from three different directions between the north Eurasian plate, the east Pacific plate and the southwest Indian plate. The intensive tectonic movement leads to a series of left-lateral strike-slip faults in this region and the tectonic deformation direction rotates clockwise gradually to the east along the Qilian-Haiyuan tectonic zone. The Menyuan earthquake makes it very important to reevaluate the earthquake risk of this region.  相似文献