金沙江矮子沟巨型古滑坡形成机制及运动过程研究          下载免费PDF全文

申通  黄志全  宋帅奇  郑超  袁玥  刘恒  吴旭阳  楚亚培 《地震学报》2023,(6):1091-1110

通过详细的野外调查，并结合遥感解译、室内试验以及数值模拟等手段，对矮子沟巨型古滑坡的基本特征、形成机制及运动演化过程进行了深入研究。矮子沟古滑坡的形成条件为：滑坡剪出口与坡脚之间存在巨大的高差，为滑坡的形成创造了良好的临空条件；顺向岸坡结构以及坡体内发育的多组控制性结构面是滑坡发生的结构基础；玄武岩系中的凝灰岩软弱夹层削弱了岩体的完整性，地表水及地下水长期入渗，水的软化作用降低了软弱夹层的抗剪强度；地震作用是造成岩体最终滑动失稳的关键因素。该滑坡的动力学过程可划分为四个阶段：(1)启程活动阶段。斜坡地形效应使得地震波在斜坡上部表现出异常放大现象，当短时间内积聚的振动能量超过岩土体的强度时，易形成高位滑坡，滑坡的变形破坏机制为拉裂-滑移；(2)近程活动阶段。近3.82×10⁸ m³的滑坡物质高位高速下滑，与矮子沟右岸坡体发生猛烈碰撞后进一步碎裂解体；(3)高速远程碎屑流阶段。碎屑流继续沿矮子沟高速运动约3 km；(4)堆积堵江阶段。滑坡物质最终形成体积为2.73×10⁸ m³的巨型堰塞坝，堵塞金沙江并...  相似文献   

2016年印尼苏门答腊岛海域M_W7.8地震震源运动学特征          下载免费PDF全文

赵旭  姚振兴 《地球物理学报》2018,61(3):880-888

根据中国和全球地震台网记录的波形记录，采用W震相矩张量反演、反投影分析及有限断层模型反演方法，研究了2016年3月2日印尼7.8级地震破裂过程，分析讨论印尼地震震源运动学特征.结果表明：此地震为一次对称的双侧破裂走滑型事件，北北东─南南西向的断层节面（走向5°/倾角85°）为发震断层面.标量地震矩约6.19×10²⁰ Nm，矩震级为7.79，最大的滑动量约11 m，位于破裂起始点北东，沿着断层走向约30 km处.破裂平均速度2.0~2.2 km·s^-1，破裂持续时间35 s，破裂在5~25 s内释放的能量，约占总能量的97%.最终形成了总长度90 km左右的断层.印尼地震具有破裂持续时间短、破裂速度慢、高滑动能量带相对集中等显著特点.本研究对进一步增进海洋岩石圈地震的震源特性认识有重要参考意义.  相似文献   

2013年南斯科舍海岭M_W7.8地震的多点震源机制反演          下载免费PDF全文

张喆  许力生 《地球物理学报》2020,63(8):2978-2998

2013年11月17日，在南极南奥克尼群岛北、南极板块与斯科舍板块之间发生了一次M_W7.8级地震（2013年南斯科舍海岭M_W7.8地震），我们利用全球分布的长周期和宽频带地震记录反演确定了这次地震随时间和空间变化的震源机制，验证了提出的一种多点震源机制反演的新方法.首先利用长周期记录的W震相反演了这次地震的矩心矩张量解并利用体波提取了视震源时间函数，同时利用台阵反投影技术从宽频带记录中获得了这次地震的高频源的时空分布，然后基于矩心矩张量解、视震源时间函数以及高频源的时空分布，实现了采用新方法对2013年南斯科舍海岭M_W7.8地震的多点震源机制反演.矩心矩张量解表明，地震矩心在44.50°W/60.18°S，矩心深度19 km，半持续时间49 s，释放标量地震矩4.71×10²⁰ N·m，发震断层走向104°，倾角54°，滑动角8°.视震源时间函数清楚地揭示了地震矩随时间变化的方位依赖性，总体上可以将时间过程分为前60 s和后50 s两个阶段，但前60 s可细分为两次子事件.根据台阵反投影结果，这次地震为沿海沟从西到东的单侧破裂，破裂长度达311 km，可以分为5次子事件，能量释放的峰值点依次为13 s、30 s、51 s、64 s和84 s，平均破裂速度分别为0.6 km·s^-1、2.6 km·s^-1、2.3 km·s^-1、2.8 km·s^-1和3 km·s^-1.多点震源机制反演显示，5次子事件的矩震级分别为M_W7.57，M_W7.48，M_W6.80，M_W7.53和M_W7.08，半持续时间依次为21 s，17 s，6 s，16 s和8 s，走向分别为95°，105°，81°，98°和98°，倾角依次为57°，49°，86°，46°和64°，滑动角-9°，1°，-17°，13°和-4°.这些在震源机制、能量释放以及持续时间方面的变化都是当地构造和应力环境复杂性的反映.  相似文献   

SBAS-InSAR技术在特大型滑坡变形监测中的应用     

郭一兵  翟向华  姜鑫  丁保艳  郭富赟  岳东霞 《地震工程学报》2023,(3):642-650,672

利用SBAS-InSAR技术对滑坡易发区域进行时序变形监测是研究滑坡机理和预防灾害的重要途径。文章利用SBAS-InSAR技术对甘肃省甘南州舟曲县果耶镇磨里滑坡灾害进行时序变形特征分析，基于2018—2021年光学遥感影像数据获取磨里滑坡所在区域的变形分布图和时序变形特征，再结合其他勘查成果资料验证变形监测结果的准确性，证明SBAS-InSAR技术在特大型滑坡变形监测中的可靠性。结果表明：(1)磨里滑坡滑坡平面形态呈“长舌状”,滑动方向最大长度1 500 m,滑坡体上窄下宽，平均宽度240～530 m,面积53×10⁴ m²;(2)磨里滑坡前部变形速度大于中后部，前缘局部形变速率最大可达140 mm/a;(3)磨里滑坡还在不断地发生变形，应进一步加强变形监测，做好应急避险和搬迁避让的措施。研究可为该地区特大型滑坡复活破坏机制和应急处置提供参考。  相似文献   

基于2001年M_W7.8可可西里地震震后形变模拟研究藏北地区岩石圈流变学结构          下载免费PDF全文

贺鹏超  王敏  王琪  沈正康 《地球物理学报》2018,61(2):531-544

青藏高原岩石圈的流变学结构和形变机制是地学界长期争论的重大科学问题.2001年发生在东昆仑断裂带的M_W7.8可可西里地震造成青藏高原北部地区岩石圈构造应力场的很大改变，引起下地壳与上地幔的快速弛豫形变，从而为研究这一问题提供了难得的机会.本研究采用该区域的GPS震后观测，反演这一地区岩石圈的流变学参数并探讨其形变机制.反演所采用的数据来自45个GPS观测点，其中包括一个中国地壳运动观测网络的基准站，数据最长时间跨度达6.4年.大地震震后形变场主要来源于地壳、上地幔的黏弹性松弛与断层面上的震后余滑，因此本研究同时反演介质的黏滞系数和断层的震后余滑.考虑到东昆仑断层南侧的巴颜喀拉-羌塘地区与北侧的柴达木盆地地区具有明显不同的地壳结构，断层南北两侧采用不同的Burgers体流变学结构，其下地壳-上地幔的短期和长期黏滞系数采用网格搜索法获得；断层震后余滑反演则同时施加近似正比于库仑应力的约束.最终结果显示：东昆仑断层北侧柴达木盆地地区下地壳-上地幔短期和长期黏滞系数分别为5×10¹⁸ Pa·s和1.5×10²⁰ Pa·s；东昆仑断层南侧巴颜喀拉-羌塘地区下地壳-上地幔短期和长期黏滞系数分别为1.5×10¹⁸ Pa·s和1.5×10¹⁹ Pa·s.这一结果表明：巴颜喀拉-羌塘地区下地壳-上地幔黏滞系数显著低于柴达木盆地，意味着巴颜喀拉-羌塘地区下地壳可能存在部分熔融，其地壳形变模式更趋近于连续形变，而柴达木盆地形变模式更趋近于块体运动.研究区下地壳长期黏滞系数比下地壳流模型所主张的黏滞系数高2~3个数量级，表明下地壳流在本地区可能不存在.  相似文献   

基于GRACE Follow-On卫星重力梯度法精确反演地球重力场   总被引：2，自引：1，他引：1       下载免费PDF全文

郑伟  许厚泽  钟敏  员美娟 《地球物理学报》2014,57(5):1415-1423

由于GRACE Follow-On双星系统等效于基线长为星间距离的一维水平重力梯度仪,因此本文基于GRACE Follow-On卫星重力梯度法开展了精确和快速反演下一代地球重力场的可行性论证研究. 研究结果表明：第一,基于GRACE Follow-On卫星重力梯度法（GFO-SGGM）,利用卫星轨道参数（轨道高度250 km、星间距离50 km、轨道倾角89°、轨道离心率0.001）、关键载荷测量精度（星间距离10^-6 m、星间速度10^-7 m·s^-1、星间加速度10^-10 m·s^-2、轨道位置10^-3 m、轨道速度10^-6 m·s^-1、非保守力10^-11 m·s^-2）、观测时间30天和采样间隔10 s反演了120阶地球重力场,在120阶处累计大地水准面精度为9.331×10^-4 m. 第二,在120阶内,利用将来GRACE Follow-On双星反演地球重力场精度较现有GRACE双星平均提高61倍,因此GRACE Follow-On卫星重力梯度法是进一步提高地球重力场反演精度的优选方法. 第三,下一代GRACE Follow-On计划较当前GRACE计划的优点如下：轨道高度更低（200~300 km）、载荷精度更高（10^-7 ~10^-9 m·s^-1）和星间距离更短（50~100 km）.  相似文献   

“9·5”泸定震后落井沟泥石流灾变过程预测分析     

李林泽  常鸣  李宏杰  胡锦凤  徐恒志  刘沛源 《地震工程学报》2023,(5):1116-1124

落井沟位于四川省泸定县得妥镇东南部，从沟口至其东南部约11 km处有正在运营的大岗山水电站。为有效防止落井沟泥石流对得妥人民的生命财产及大岗山水电站的运维造成的威胁与损毁，开展对泸定震后落井沟内物源分布特征与不同降雨周期下泥石流运动演化过程分析。“9·5”泸定地震后，耦合现场调查与地震前后遥感影像解译，得出强震致使落井沟流域内产生滑坡37处，总面积约0.125 km²,并采用LiDAR航拍技术优化解译结果，得到实际松散堆积物方量为15.52万m³。随后结合精准物源、精细化地形及5%、2%、1%降雨频率，开展基于OpenLISEM数值计算的落井沟泥石流运动演化特征研究。结果表明：5%、2%、1%降雨重现周期下落井沟泥石流运动过程的最大泥深分别为6、8、11 m,最大流速分别为5、7、10 m/s; 5%、2%降雨频率下泥石流对大渡河的堵江程度较小，1%频率下可造成半堵江状态。  相似文献   

四川芦山M_s7.0级强烈地震震源运动学特征          下载免费PDF全文

赵旭  黄志斌  房立华  李强  赵博  苗春兰 《地球物理学报》2014,57(2):419-429

使用中国数字地震台网记录的区域宽频带波形,通过频率域和时间域多步反演,研究了2013年四川芦山“4·20”7.0级强烈地震的震源运动学特征.基于点源的震源机制解揭示：地震发震断层面参数分别为走向214°/倾角47°/滑动角96°,表现为一次高倾角的逆冲型事件.矩心在水平方向上位于震中（30.303°N/102.988°E）西南向约4.5 km,矩心深度约17 km.平均总标量地震矩M₀为1.16×10¹⁹ N·m,矩震级M_w约6.6.进一步模拟高达0.5 Hz高频波形,获得了芦山地震破裂过程图像,结果显示：此地震为一次不对称双侧破裂事件.破裂半径约15 km,整个破裂面积为706.7 km²,平均滑动量约0.231 m.破裂在8 s内释放了大多数能量.震后0~3 s内,破裂以孕震点为中心向四周同时扩展,3 s后,破裂表现出明显的方向性,主要向北北东扩展,导致位于震中北东向多数台站视破裂持续时间总体偏小,最小值为4 s.破裂约8 s后基本停止.  相似文献   

2009年4月6日意大利拉奎拉(L′Aquila) M_W6.3地震的破裂过程——视震源时间函数方法与直接波形反演方法比较   总被引：3，自引：0，他引：3       下载免费PDF全文

张勇  陈运泰  许力生 《地球物理学报》2010,53(6):1428-1439

通过对视震源时间函数方法和直接波形反演方法在意大利拉奎拉（L′Aquila）M_W6.3地震破裂过程反演中的应用,分析比较了两种方法的特点.视震源时间函数结果表明,这次地震的破裂过程由两次子事件组成,其中第二次子事件的多普勒效应显著,表明破裂主要朝震中的东南方向传播.分别采用视震源时间函数方法和滑动角固定以及滑动角可变的直接波形反演方法对拉奎拉地震时空破裂过程进行反演所得到的结果一致表明：断层面上有两块滑动量集中的区域,分别位于震源处和沿走向（132°）方向距震源5~10 km处,最大滑动量分别约为1.2 m和1.0 m.破裂持续时间约为9.5 s.最大滑动速率达0.6~0.7 m/s,快速的破裂和上盘-下盘效应导致了拉奎拉城的严重破坏.  相似文献   

2019年秘鲁北部M7.8地震的矩张量解与破裂过程快速反演     

梁姗姗  徐志国  黄志斌  赵博  张广伟 《中国地震》2020,36(1):23-33

2019年5月26日（北京时间）秘鲁北部发生M7.8地震，震源深度为100km。本文利用国际地震学研究联合会数据管理中心（IRIS/DMC）提供的远场波形数据，通过波形反演方法快速反演得到此次地震的矩张量解和破裂过程。W震相快速矩张量解反演结果表明此次地震是一次中深源正断层型地震事件，可能是由于正在向下俯冲的纳斯卡板块产生规模巨大的伸展变形所致。远震体波反演有限断层模型结果显示此次地震的发震断层为高倾角的NNW向断层面，破裂从初始破裂点开始，由震中主要向NNW方向延伸破裂，最大滑移量约3m；地震破裂时间约为70s，在40~60s时释放了整个地震80%的地震矩能量，主要破裂区域在震后40s后才开始形成，在40s之前，破裂的集中程度和地震矩释放的规模均较弱，断层在破裂开始后逐渐加速破裂，约50s时地震矩释放速率达到峰值，60s后破裂迅速愈合。  相似文献   

Complex dynamics of repeating and river-blocking landslides in Jiangda during 2018          下载免费PDF全文

Wenying Li  Yong Zhang  Yueyi Xu  Xujun Zheng  Rongjiang Wang  Jinrong Su  Guixi Yi  Qinghua Huang 《地震科学（英文版）》2021,34(1):3-14

Two large landslides successively blocked the Jinsha River at the same location in Jiangda Village on October 10 and November 3,2018,respectively.The dynamic processes and possible interactions of the two landslides need to be studied to better understand the physical processes involved,and to provide information on future disaster mitigation.We investigated their force histories and sliding directions by inverting regional broadband seismograms.The scale of the October landslide was approximately three times that of the November event.The October event revealed a particularly strong deceleration force,which may have been caused by a collision between the sliding mass and ground surface.In contrast,the November event had a relatively weaker deceleration force,indicating that it may have been gradually stopped by the landslide dam formed during the October landslide.The sliding directions of the two landslides differed significantly in terms of both horizontal and vertical directions,indicating a change in their sliding surfaces.We conclude that unconsolidated materials at the top of the October landslide continued sliding along a curved slope during the November event.From our seismic models of dynamic processes,both the October landslide and local background may have affected and even changed a subsequent landslide's mechanism.  相似文献   

Impact of an 0.2 km3 Rock Avalanche on Lake Eibsee (Bavarian Alps,Germany) – Part II: Catchment Response to Consecutive Debris Avalanche and Debris Flow     

Sibylle Knapp  Flavio S. Anselmetti  Bernhard Lempe  Michael Krautblatter 《地球表面变化过程与地形》2021,46(1):307-319

The ~0.2 km³ Eibsee rock avalanche impacted Paleolake Eibsee and completely displaced its waters. This study analyses the lake impact and the consequences, and the catchment response to the landslide. A quasi-3D seismic reflection survey, four sediment cores from modern Lake Eibsee, reaching far down into the rock avalanche mass, nine radiocarbon ages, and geomorphic analysis allow us to distinguish the main rock avalanche event from a secondary debris avalanche and debris flow. The highly fluidized debris avalanche formed a megaturbidite and multiple swashes that are recorded in the lake sediments. The new calibrated age for the Eibsee rock avalanche of ~4080–3970 cal yr BP indicates a coincidence with rockslides in the Fernpass cluster and subaquatic landslides in Lake Piburg and Lake Plansee, and raises the possibility that a large regional earthquake triggered these events. We document a complex history of erosion and sedimentation in Lake Eibsee, and demonstrate how the catchment response and rebirth of the lake are revealed through the complementary application of geophysics, sedimentology, radiocarbon dating, and geomorphology. © 2020 The Authors. Earth Surface Processes and Landforms published by John Wiley & Sons Ltd  相似文献   

Rock fall dynamics and deposition: an integrated analysis of the 2009 Ahwiyah Point rock fall,Yosemite National Park,USA   总被引：1，自引：0，他引：1  

Valerie L. Zimmer  Brian D. Collins  Greg M. Stock  Nicholas Sitar 《地球表面变化过程与地形》2012,37(6):680-691

We analyzed a combination of airborne and terrestrial LiDAR, high‐resolution photography, seismic, and acoustic data in order to gain insights into the initiation, dynamics, and talus deposition of a complex rock fall. A large (46 700 m³) rock fall originated from near Ahwiyah Point in eastern Yosemite Valley and fell a total of 730 m to the valley floor on 28 March 2009. Analyses of remote sensing, seismic, and acoustic data were integrated to reconstruct the rock fall, which consisted of (1) the triggering of a 25 400 m³ rock block in an area of intersecting and sometimes highly weathered joint planes, (2) the sliding and subsequent ballistic trajectory of the block from a steeply dipping ledge, (3) dislodging of additional rock from the cliff surface from beneath the rock fall source area, (4) a mid‐cliff ledge impact that detached a volume of rock nearly equivalent in volume to the initial block, (5) sliding of the deteriorating rock mass down the remainder of the cliff, and (6) final impact at the base of the cliff that remobilized the existing talus downward and outward and produced an airblast that knocked down hundreds of trees. The depositional geomorphology indicates that the porosity of the fresh talus is significantly lower than that expected for typical blocky talus slopes, likely because the rock debris from this event was pulverized into smaller, more poorly sorted fragments and densified via dynamic compaction when compared to less energetic, fragmental‐type rock falls. These results suggest that accumulation of individual rock‐fall boulders tends to steepen talus slopes, whereas large, energetic rock falls tend to flatten them. Detachment and impact signals were recorded by seismic and acoustic instruments and highlight the potential use of this type of instrumentation for generalized rock fall monitoring, while LiDAR and photography data were able to quantify the cliff geometry, rock fall volume, source and impact locations, and geomorphological changes to the cliff and talus. Published in 2012. This article is a US Government work and is in the public domain in the USA.  相似文献   

Impact of an 0.2 km3 Rock Avalanche on Lake Eibsee (Bavarian Alps,Germany) – Part I: Reconstruction of the paleolake and Effects of the Impact     

Sibylle Knapp  Philipp Mamot  Bernhard Lempe  Michael Krautblatter 《地球表面变化过程与地形》2021,46(1):296-306

Rock avalanches destroy and reshape landscapes in only a few minutes and are among the most hazardous processes on Earth. The surface morphology of rock avalanche deposits and the interaction with the underlying material are crucial for runout properties and reach. Water within the travel path is displaced, producing large impact waves and reducing friction, leading to long runouts. We hypothesize that the 0.2 km³ Holocene Eibsee rock avalanche from Mount Zugspitze in the Bavarian Alps overran and destroyed Paleolake Eibsee and left a unique sedimentological legacy of processes active during the landslide. We captured 9.5 km of electrical resistivity tomography (ERT) profiles across the rock avalanche deposits, with up to 120 m penetration depth and more than 34 000 datum points. The ERT profiles reveal up to ~50 m thick landslide debris, locally covering up to ~30 m of rock debris with entrained fine-grained sediments on top of isolated remnants of decametre-wide paleolake sediments. The ERT profiles allow us to infer processes involved in the interaction of the rock avalanche with bedrock, lake sediments, and morainal sediments, including shearing, bulging, and bulldozing. Complementary data from drilling, a gravel pit exposure, laboratory tests, and geomorphic features were used for ERT calibration. Sediments overrun by the rock avalanche show water-escape structures. Based on all of these datasets, we reconstructed both position and size of the paleolake prior to the catastrophic event. Our reconstruction of the event contributes to process an understanding of the rock avalanche and future modelling and hazard assessment. Here we show how integrated geomorphic, geophysical, and sedimentological approaches can provide detailed insights into the impact of a rock avalanche on a lake. © 2020 The Authors. Earth Surface Processes and Landforms published by John Wiley & Sons Ltd  相似文献   

Landslides and increased debris-flow activity: A systematic comparison of six catchments in Switzerland     

Florian Frank  Christian Huggel  Brian W. McArdell  Andreas Vieli 《地球表面变化过程与地形》2019,44(3):699-712

An increase in debris-flow frequency is expected in steep Alpine catchments after the occurrence of a large landslide, such as a rock avalanche. Herein we describe changes in debris-flow activity following increases in sediment availability due to landslides, or accelerated rock-glacier movement, for five catchments in the Swiss Alps, the Spreitgraben, Schipfenbach, Bondasca, Riascio, and Dorfbach catchments. Documentation on debris-flow activity is available from both before and after the landslide that generated the new sediment deposits. Data from nearby meteorological stations were used to explore possible changes in rainfall activity, and how the intensity and duration of rainfall events may have changed. In all cases there was a considerable increase in debris-flows frequency for one to eight years following the landslide. The annual number of days with debris-flow activity following the landslide was similar to that observed for the Illgraben catchment, where many such landslides occur annually. No clear change in precipitation totals preceding debris flows was apparent for the Riascio catchment, suggesting that the increase in frequency of debris flows is related to the increase in the amount of sediment that can be readily mobilized. In the two cases where rainfall data were available on an hourly basis, no systematic changes in the intensity or duration of rainfall related to debris-flow triggering were apparent, as shown by the close-clustering of storms on the intensity-duration plots. Following the sediment-generating event, an initial and sudden increase of the sediment yield was observed, followed by a decrease over time towards pre-disturbance values. The response of the catchments appears to be related to the amount of debris-flow activity prior to the landslide: sediment yield from catchments with frequent debris flows prior to the landslide activity did not increase as dramatically as in catchments where debris-flow activity was less common prior to the landslide. © 2018 John Wiley & Sons, Ltd.  相似文献   

CHARACTERISTICS AND FORMATION MECHANISM OF LARGE ROCK AVALANCHES TRIGGERED BY THE LUDIAN M_S6.5 EARTHQUAKE AT HONGSHIYAN AND GANJIAZHAI          下载免费PDF全文

CHANG Zu-feng  CHANG Hao  YANG Sheng-yong  CHEN Gang  LI Jian-lin 《地震地质》2017,39(5):1030-1047

The 3 August 2014 Ludian, Yunnan M_S6.5 earthquake has spawned more than 1, 000 landslides which are from several tens to several millions and over ten millions of cubic meters in volumes. Among them, the Hongshiya and Ganjiazai landslides are the biggest two with volumes over 1 000×10⁴m³. The Hongshiya and Ganjiazai landslides are two typical landslides, the former belongs to tremendous rock avalanche, and the latter belongs to unconsolidated werthering deposit landslide developed in concave mountain slope. Based on field investigations, causes and formation mechanism of the two landslides are discussed in this study. The neotectonic movement in the area maintains sustainable uplifting violently all the time since Cenozoic. The landform process accompanied with the regional tectonic uplifting is the violent downward erosion along the Jinshajiang River and its tributary, forming landforms of high mountains and canyons, deeply cut valleys, with great height difference. The regional seismo-tectonics situation suggests that:Ludian earthquake region is situated on the southern frontier boundary of Daliangshan secondary active block, and is seismically the strongest active area with one earthquake of magnitude greater than M5.0 occurring every 6 years. Frequent and strong seismicity produces accumulated effects on the ground rock to gradually lower the mechanical strength of slopes and their stability, which is the basis condition to generate large-scale collapse and landslide at Hongshiyan and Ganjiazhai. The occurring of Hongshiyan special large rock avalanche is associated with the large terrain height difference, steep slope, soft interlayer structure and unloading fissures and high-angle joints. The formation mechanism of Hongshiyan rock avalanche may have three stages as follows:Stage 1, when P wave arriving, under the situation of free surface, rocks shake violently, the pre-existent joints(in red)parallel to and normal to the river and unloading cracks are opened and connected. Stage 2, on the basis of the first stage, when S wave arriving, the ground movement aggravates. Joints(in green)along beds develop further, resulting in rock masses intersecting each other. Stage 3, rock masses lose stability, sliding downward, collapsing, and moving over a short distance along the sliding surface to the inside of the valley, blocking the river to form the dammed lake. The special large landslide at Ganjiazhai is a weathering layer landslide occurring in the middle-lower of a large concave slope. Its formation process may have two stages as follows:Firstly, under strong ground shaking and gravity, the ground rock-soil body around moves and assembles to the lower of the central axis of the large concave slope, which suffers the largest earthquake inertia force and firstly yields plastic damage to generate compression-expansion deformation, because of the largest water content and volume-weight within the loose soil of it. Secondly, in view of the steep slope, along with the compression, the plastic deformation area enlarges further in the lower of slope, giving rise to a tensional stress area along the middle of the slope. As soon as the tensional stress exceeds the tensile strength of the weathering layer, a tensional fracture will occur and the landslide rolls away immediately making use of momentum. This two large landslides are the basic typical ones triggered by the M_S6.5 Ludian earthquake, and their causes and mechanism have a certain popular implication for the landslides occurring in this earthquake region.  相似文献   

CONTROLLING FACTORS AND MECHANISMS OF INCOMPLETE OBSTRUCTION SEISMIC LANDSLIDE MOBILITY          下载免费PDF全文

FAN Xiao-yi  LI Tian-hua  TIAN Shu-jun  ZHANG You-yi  SUN Xin-po 《地震地质》2017,39(4):754-767

The topography, occurrence mechanism and lithology are the important factors of landslide movement. The lithology, seismic intensity, geological structure and topography in the travel path of 215 incomplete obstruction landslides with volumes more than 10⁴m³ induced by Wenchuan earthquake were studied. Based on the classification of the factors established, we studied the factors influencing the movement distance of incomplete obstruction landslides. The following results are drawn. In the influence factors of topography in the travel path, the distance is largest in the straight valley topography, followed by the concave, ladder, turning valley, slope toe-type and slope-type landslides, in turn. The topography not only has remarkable influence on the distance of large-scale landslides, but also on the medium and small-scale landslides as well, which is the most important factor influencing the distance. The formation mechanism controlled by lithology, seismic intensity and geological structure has little influence on the mobility of medium-and small-scale landslides. For the large-scale landslides with volume more than 10⁶m³, the distance of landslide with medium hard rock is larger than landslides with hard and soft rock. In the seismic intensity Ⅸ to Ⅺ areas, the landslide distance decreases with intensity increasing, contrary to the distribution of landslide-point density and landslide-area density. The geological structure has influence on the slide aspect of landslides and occurrence mechanism, but the influence is not remarkable to the landslide movement distance.  相似文献   

A preliminary study of the failure mechanisms of cascading landslide dams     

《国际泥沙研究》2015,(3)

Landslide dams commonly form when mass earth or rock movements reach a river channel and cause a complete or partial blockage of the channel.Intense rainfalls can induce upstream flows along a sloping channel that significantly affect downstream landslide dams.If a series of landslide dams are collapsed by incoming mountain torrents(induced by intense rainfall),large debris flows can form in a very short period.Furthermore,the failure of these dams can amplify the magnitude and scale of debris flows in the flow direction.The catastrophic debris flows that occurred in Zhouqu County,China on 8 August 2010 were caused by intense rainfall and the upstream cascading failure of landslide dams along the gullies.Incorporating the role of outburst floods associated with the complete or partial failure of landslide dams is an interesting problem usually beyond the scope of analysis because of the inherent modeling complexity.To understand the cascading failure modes of a series of landslide dams,and the dynamic effect these failures have on the enlargement of debris flow scales,experimental tests are conducted in sloping channels mimicking field conditions,with the modeled landslide dams distributed along a sloping channel and crushed by different upstream flows.The failure modes of three different cascades of landslide dams fully or partially blocking a channel river are parametrically studied.This study illustrates that upstream flows can induce a cascading failure of the landslide dams along a channel.Overtopping is the primary failure mechanism,while piping and erosion can also induce failures for different constructed landslide dams.A cascading failure of landslide dams causes a gradually increasing flow velocity and discharge of the front flow,resulting in an increase in both diameter and percentage of the entrained coarse particles.Furthermore,large landslide blockages can act to enhance the efficiency of river incision,or conversely to induce aggradation of fluvial sediments,depending on the blockage factor of the landslide dams and upstream discharge.  相似文献   

宽频带地震台网在滑坡地质灾害监测预报中的应用     

刘文清  罗文行  董建辉  朱建  陈又华  周银兴  李茂华 《地震地磁观测与研究》2014,35(5):124-133

在千将坪滑坡前地震动事件分析基础上,总结滑坡前滑坡体内部岩体形变和破裂所产生地震信号的典型特征,并建立宽频带地震台,对金坪子滑坡体和早谷田危岩体进行监测实验,提取基岩类、土质类和危岩体类3种基本物质组成滑坡的微振动前兆信息特征,为地震台网在滑坡监测预报中的应用推广和监测预报系统软件的研制奠定基础.根据测震学原理,研发滑坡监测分析系统软件（Smas）,可为滑坡大规模活动前快速预警.  相似文献   

基于数值流形法的反倾层状岩质边坡倾倒破坏分析     

王欢欢  郭明珠 《震灾防御技术》2021,16(2):346-351

边坡破坏是累积性过程，从变形到破坏的过程中会产生永久位移，如果永久位移过大，极有可能产生滑坡。因此根据不同工况下采集到的位移数据，分析地震作用下反倾层状岩质边坡在不同内摩擦角下的破坏特征。利用二维数值流形法（NMM），以青藏高原金沙江流域西藏昌都地区芒康县索多西乡贡扎倾倒滑坡为研究对象，依据实地考察数据及室内力学试验得到的物理力学参数，建立数值计算模型，模拟地震作用下反倾层状岩质边坡倾倒破坏过程，并在边坡上布置3组监测点获取位移数据。模拟结果表明:随着内摩擦角的增大，边坡坡体从开始破坏到新的平衡状态和达到最大位移所需的时间越短，同时，滑动块体最大水平位移逐渐减小；内摩擦角＜40°时，坡体在前15 s呈整体移动趋势，大部分岩块产生整体滑移，靠近坡顶处的岩块发生轻微转动，推动前面的岩块加速滑动，呈倾倒-滑移模式；内摩擦角＞40°时，靠近坡顶的岩块首先产生滑动，并转动驱使前面的岩块，推动坡脚处岩块产生滑动，最终上部岩块达到新的平衡，呈渐进式倾倒破坏，产生整体性破坏的可能性较小。  相似文献