Study on rupture zone of the M=8.1 Kunlun Mountain earthquake using fault-zone trapped waves

The observation of the fault-zone trapped waves was conducted using a seismic line with dense receivers across surface rupture zone of the M=8.1 Kunlun Mountain earthquake. The fault zone trapped waves were separated from seismograms by numerical filtering and spectral analyzing. The results show that: a) Both explosion and earthquake sources can excite fault-zone trapped waves, as long as they locate in or near the fault zone; b) Most energy of the fault-zone trapped waves concentrates in the fault zone and the amplitudes strongly decay with the distance from observation point to the fault zone; c) Dominant frequencies of the fault-zone trapped waves are related to the width of the fault zone and the velocity of the media in it. The wider the fault zone or the lower the velocity is, the lower the dominant frequencies are; d) For fault zone trapped waves, there exist dispersions; e) Based on the fault zone trapped waves observed in Kunlun Mountain Pass region, the width of the rupture plane is deduced to be about 300 m and is greater than that on the surface.

Decomposing InSAR LOS displacement into co-seismic dislocation with a linear in-terpolation model: A case study of the Kunlun Mountain M_s=8.1 earthquake

It has always been a difficult problem to extract horizontal and vertical displacement components from the InSAR LOS （Line of Sight） displacement since the advent of monitoring ground surface deformation with InSAR technique. Having tried to fit the firsthand field investigation data with a least squares model and obtained a preliminary result, this paper, based on the previous field data and the InSAR data, presents a linear cubic interpolation model which well fits the feature of earthquake fracture zone. This model inherits the precision of investigation data; moreover make use of some advantages of the InSAR technique, such as quasi-real time observation, continuous recording and all-weather measurement. Accordingly, by means of the model this paper presents a method to decompose the InSAR slant range co-seismic displacement （i.e. LOS change） into horizontal and vertical displacement components. Approaching the real motion step by step, finally a serial of curves representing the co-seismic horizontal and vertical displacement component along the main earthquake fracture zone are approximately obtained.

A discussion on Corioli force effect and aftershock activity tendency of the M=8.1 Kunlun Mountain Pass earthquake on Nov. 14, 2001

Following the theory and definition of the Corioli force in physics, the Corioli force at the site of the M=8.1 Kunlun Mountain Pass earthquake on November 14, 2001, is examined in this paper on the basis of a statistical research on relationship between the Corioli force effect and the maximum aftershock magnitude of 20 earthquakes with M7.5 in Chinese mainland, and then the variation tendency of aftershock activity of the M=8.1 earthquake is discussed. The result shows: a) Analyzing the Corioli force effect is an effective method to predict maximum aftershock magnitude of large earthquakes in Chinese mainland. For the sinistral slip fault and the reverse fault with its hanging wall moving toward the right side of the cross-focus meridian plane, their Corioli force pulls the two fault walls apart, decreasing frictional resistance on fault plane during the fault movement and releasing elastic energy of the mainshock fully, so the maximum magnitude of aftershocks would be low. For the dextral slip fault, its Corioli force presses the two walls against each other and increases the frictional resistance on fault plane, prohibiting energy release of the mainshock, so the maximum magnitude of aftershocks would be high. b) The fault of the M=8.1 Kunlun Mountain earthquake on Nov. 14, 2001 is essentially a sinistral strike-slip fault, and the Corioli force pulled the two fault walls apart. Magnitude of the induced stress is about 0.06 MPa. After a comparison analysis, we suggest that the aftershock activity level will not be high in the late period of this earthquake sequence, and the maximum magnitude of the whole aftershocks sequence is estimated to be about 6.0.

Horizontal crustal movement in Chinese mainland before and after the great Kunlun Mountain M=8.1 earthquake in 2001

The continuous GPS observation at the fiducial stations in the Crustal Movement Observation Network of China (CMONOC) recorded the crustal movement of Chinese mainland before and after the great Kunlun Mountain earthquake of M=8.1 on November 14, 2001, especially the horizontal crustal movement in the western part of China. Based on the datum defined by a group of stable stations with small mutual horizontal displacements for a few years, the time series of horizontal displacements at fiducial stations were obtained. Significant anomalous horizontal displacements had appeared at the fiducial stations in the western part of China since early November 2000 and several earthquakes with the magnitudes about 6.0 had occurred in Yunnan and Sichuan Provinces. The northward components of the horizontal displacement at the fiducial stations in west China had decreased signifi-cantly and even changed in the opposite sense since mid April 2001. After the earthquake, the northward dis-placements still decreased and there were significant westward displacements. The process of the crustal move-ment in the western part of Chinese mainland (in reference to east China) suggests that the main force source for this earthquake came from the northward pushing of the Indian plate. The great earthquake released a large amount of energy, as a result, the action applied by the Indian plate to Chinese mainland diminished significantly and after the great earthquake, the seismic activity in Chinese mainland decreased considerably until the end of 2002.

Characteristics of Collapses Caused by the M8.1 Earthquake West of the Kunlun Mountains Pass

An M 8.1 earthquake that occurred west of the Kunlun Mountains Pass has caused more than 20 collapse bodies or zones, which are mainly distributed near the surface seismic rupture zone, west of Hoh Sai Lake. The collapses are of four types, bedrock, soil mass and ice mass collapses and avalanches. The spatial distribution and the characteristics of development of the collapses are analyzed in the paper. Comparised with those caused by other earthquakes, the collapses are smaller in scale. In addition to the lithological characteristics of the crustal media, topographic, geomorphic and climatic factors, weaker seismic ground motion is an important cause for formation of the smaller-scale collapses. The long surface rupture zone and weaker ground motion are important features of the seismic rupture, which may be related to the structure of the preexisting fault.

Influence of the Kunlun Mountain M_S8.1 Earthquake on Horizontal Crustal Deformation in the Sichuan and Yunnan Area

In order to track the space-time variation of regional strain field holistically(in a large scale) and to describe the regional movement field more objectively,the paper uses a nonlinear continuous strain model focused on extracting medium-low frequency strain information on the basis of a region with no rotation.According to the repeated measurements(1999～2001～2004) from GPS monitoring stations in the Sichuan and Yunnan area obtained by the Project of "China Crust Movement Measuring Network",and with the movement of 1999～2001(stage deformation background) as the basic reference,we separated the main influencing factors of the Kunlun Mountain M-S8.1 earthquake in 2001 from the data of 2001 and 2004,and the results indicate:(1) the Kunlun Mountain M-S8.1 earthquake has a discriminating effect on the Sichuan and Yunnan area,moreover,the deformation mode and background had not only certain similitude but also some diversity;(2) The movement field before the earthquake was very ordinal,while after the earthquake,order and disorder existed simultaneously in the displacement field;The displacement quantities of GPS monitoring stations were generally several millimeters;(3) The principal strain field before earthquake was basically tensile in an approximate EW direction and compressive in the SN direction,and tension was predominant.After the earthquake,the principal strain field in the Sichuan area was compressive in the EW direction and tensile in the SN direction,and the compression was predominant.In the Yunnan area,it was tensional in the NE direction and compressive in the NW direction,and tension was predominant;(4) The surficial strain before the earthquake was dominated by superficial expansion,the contractive area being located basically in the east boundary of Sichuan and Yunnan block and its neighborhood.After the earthquake,the Sichuan area was surface contractive(the further north,the greater it was),and south of it was an area of superficial expansion.Generally speaking,the Kunlun Mountain M-S8.1 earthquake played an active role in the accumulation of energy in the Sichuan and Yunnan area.Special attention shall be focused on the segment of Xichang-Dongchuan and its neighborhood.

The Frozen Soils and Devastating Characteristics of West Kunlun Mountains Pass M_S 8.1 Earthquake Area in 2001

The investigation on damages to frozen soil sites during the West Kunlun Mountains Pass earthquake with M S 8.1 in 2001 shows that the frozen soil in the seismic area is composed mainly of moraine, alluvial deposit, diluvial deposit and lacustrine deposit with the depth varying greatly along the earthquake rupture zone. The deformation and rupture of frozen soil sites are mainly in the form of coseismic fracture zones caused by tectonic motion and fissures, liquefaction, seismic subsidence and collapse resulting from ground motion. The earthquake fracture zones on the surface are main brittle deformations, which, under the effect of sinistral strike-slip movement, are represented by shear fissures, tensional cracks and compressive bulges. The distribution and configuration patterns of deformation and rupture such as fissures, liquefaction, seismic subsidence and landslides are all related to the ambient rock and soil conditions of the earthquake area. The distribution of earthquake damage is characterized by large-scale rupture zones, rapid intensity attenuation along the Qinghai-Xizang (Tibet) Highway, where buildings distribute and predominant effect of rock and soil conditions.

Source process of the 14 November 2001 western Kunlun Mountain M_S=8.1 earth-quake

Based on digital teleseismic P-wave seismograms recorded by 28 long-period seismograph stations of the global seismic network, source process of the November 14, 2001 western Kunlun Mountain MS=8.1 (MW=7.8) earth- quake is estimated by a new inversion method. The result shows that the earthquake is a very complex rupture event. The source rupture initiated at the hypocenter (35.95°N, 90.54°E, focal depth 10 km, by USGS NEIC), and propagated to the west at first. Then, in several minutes to a hundred minutes and over a large spatial range, several rupture growth points emerged in succession at the eastern end and in the central part of the finite fault. And then the source rupture propagated from these rupture growth points successively and, finally, stopped in the area within 50 km to the east of the centroid position (35.80°N, 92.91°E, focal depth 15 km, by Harvard CMT). The entire rupture lasted for 142 s, and the source process could be roughly separated into three stages: The first stage started at the 0 s and ended at the 52 s, lasting for 52 s and releasing approximately 24.4% of the total moment; The sec- ond stage started at the 55 s and ended at the 113 s, lasting for 58 s and releasing approximately 56.5% of the total moment; The third stage started at the 122 s and ended at the 142 s, lasting for 20 s and releasing approximately 19.1% of the total moment. The length of the ruptured fault plane is about 490 km. The maximum width of the ruptured fault plane is about 45 km. The rupture mainly occurred within 30 km in depth under the surface of the Earth. The average static slip in the underground rocky crust is about 1.2 m with the maximum static slip 3.6 m. The average static stress drop is about 5 MPa with the maximum static stress drop 18 MPa. The maximum static slip and the maximum stress drop occurred in an area within 50 km to the east of the centroid position.

2001年新疆昆仑山M_(S)8.1地震前地脉动参数异常变化

1研究背景。冯德益等(1994)研究发现,在中强地震发生前后地震波参数和地脉动参数都会有各种异常形态出现,且短周期地脉动参数异常可用于地震短期预报。李志雄等(2008)编制了海南数字地脉动参数处理系统,系统自动计算2005—2007年海南地震台网各个台站的地脉动参数,发现在海南及邻区显著地震前和地震活动活跃时地脉动参数有一定异常变化。

Continental dynamics and continental earthquakes

Two key research projects in geoscience field in China since the IUGG meeting in Birmingham in 1999, the project of East Asian Continental Geodynamics and the project of Mechanism and Prediction of Strong Continental Earthquakes are introduced in this paper. Some details of two projects, such as their sub-projects, some initial research results published are also given here. Because of the large magnitude of the November 14, 2001 Kunlun Mountain Pass MS=8.1 earthquake, in the third part of this paper, some initial research results are reviewed for the after-shock monitoring and the multi-discipline field survey, the impact and disaster of this earthquake on the construction site of Qinghai-Xizang (Tibet) railway and some other infrastructure.

昆仑山口西Ms8.1地震前地下流体的远场异常及其意义

简要介绍了2001年11月14日昆仑山口西MS8.1级地震前在河北、陕西、四川、青海、新疆等距震中几百至几千公里之外记录到的地下流体的远场异常(场兆或远兆),并以此为基础讨论了地震孕育的理论与地震预测的科学思路等问题。

2001年11月14日昆仑山口西M_S8.1地震震源破裂过程研究

根据IRIS全球地震台网 2 8个台的长周期地震仪记录的P波数字地震图 ,用直接由远场体波地震图反演震源破裂过程的一种新方法 ,研究了 2 0 0 1年 1 1月 1 4日昆仑山口西MS8.1地震的震源破裂过程 .结果表明 :这是一次极为复杂的地震破裂事件 .破裂从震源位置(3 5 .95°N ,90 .5 4°E ,h :1 0km)开始后 ,先向西扩展 ,后在有限断层的东端和中部的大尺度空间范围内接连出现了多个破裂生长点 .破裂在这些生长点先后扩展 ,最后在矩心位置(3 5 .80°N ,92 .91°E ,h :1 5km)以东 5 0km范围内结束 .整个破裂持续了约 1 42s.破裂过程可粗略地分为 3个阶段 :第一阶段 ,从第 0s开始至第 5 2s结束 ,持续了 5 2s,释放的地震矩约为总地震矩的 2 4.4% ;第二阶段 ,从第 5 5s开始至第 1 1 3s结束 ,持续了 5 8s,释放的地震矩约为总地震矩的 5 6.5 % ;第三阶段 ,从第 1 2 2s开始至第 1 42s结束 ,持续了 2 0s,释放的地震矩约为总地震矩的 1 9.1 % .地震破裂面长约 490km ,破裂面最大宽度达 45km .破裂主要发生在 3 0km深度范围内 .地下岩层的平均静态位错量约为 1 .2m ,最大静态位错量达 3 .6m ,平均静态应力降约为 5MPa ,最大静态应力降达 1 8MPa .静态位错量和静态应力降最大的区域位于矩心位置以东 5 0km范围内 .

青海昆仑山口西M_S8.1级地震地表破裂带特征与主要震害——对青藏高原区域稳定性评价的制约

通过对昆仑山口西8.1级地震地表破裂全带的野外考察,发现本次地震地表破裂带由3条具有一定宽度和长度规模并且延伸稳定的右接斜列的破裂带组成,呈近东西(N80°W)走向延展,长度约350km;断裂错动以左旋走滑性质为主,发震断裂属昆仑山南缘断裂带;地震裂缝、地震鼓梁(包)、地震塌陷等形迹所构成的新破裂切割了老的地震形变带;宏观震中位于布喀达坂峰东侧25km附近,比较接近中国地震速报台网确定的仪器震中;极震区地震烈度为Ⅺ度。地震地表破裂带是本次地震形成的最主要的地震地质灾害。另外还伴随发育地震边坡崩塌、雪崩、湖岸震陷、山体震裂、地面喷沙冒水等地震地质灾害现象。

2001年11月14日昆仑山口西M8.1地震前的缓慢地震事件

20 0 1年 1 1月 1 4日昆仑山口西M 8 1地震前发生了缓慢运动事件 ,新疆地震台网记录分析结果表明 ,这次事件在大震前 3 5天开始出现 ,长周期前驱波持续约4 7小时 ,波列呈现规则的正弦波形 ,视周期约为 8 8秒。笔者认为 ,该慢地震事件是M 8 1大震前中昆仑断裂临震预滑动引起的。事实表明 ,慢地震的观测与研究对深入了解断层失稳过程和实现地震短临预报具有重大意义 ,同时也显示了宽频带数字地震台网的优越性。

昆仑M_S8.1地震前青藏块体北、东缘水平运动变形的关联特征

青藏块体东北缘和川滇GPS监测区 1991(1993)、1999和 2 0 0 1年高精度GPS观测资料揭示 :2 0 0 1年 11月 14日昆仑MS8 1地震前 ,青藏块体北、东缘构造区域水平运动变形场动态演变具有一定的关联性特征。即 :在继承性运动总体背景下 ,临近大震发生时两区域运动强度同步减弱且变形状态发生变化。结合地质构造分析研究认为 ,昆仑MS8 1地震前 ,青藏块体边界运动变形的关联性变化与大震孕育后期大范围应力应变快速积累所形成的扰动应力场有关 ;随着块体内部大震的发生、应变能的大量释放和构造应力场的调整 ,可能会促使块体边界地带具有较高应变积累的相关构造部位 (尤其是未被历史强震破裂贯通的地带 )的应力应变的进一步积累或破裂释放。

关于2001年昆仑山8.1级大地震前后中国大陆地壳水平运动的讨论

中国地壳运动观测网络基准网GPS连续观测 ,获得了 2 0 0 1年 11月 14日昆仑山 8.1级大地震前后中国大陆 ,特别是西部地区的地壳水平运动信息 .以东部长期相互间相对水平位移很小的几个站组成的一组稳定点作为基准 ,据此获得水平位移分量时间序列 .2 0 0 0年 11月上旬起中国西部的GPS基准站开始出现显著的异常位移 ,此后在云南及四川发生多次 6级左右的地震 .自 2 0 0 1年 4月中旬开始 ,中国西部GPS基准站向北的水平位移速率明显减小 ,甚至反向 ,临震前及震后略有恢复 ,但震后向北的水平位移速率仍减小 ,并有明显的向西运动 .近几年中国大陆西部 (相对东部 )的地壳运动过程表明 ,印度板块的向北挤压是昆仑山8.1级大地震的主要力源 ,大地震释放了大量的能量 ,印度板块对中国大陆的作用力明显降低 ,大震后至 2 0 0

利用断层围陷波研究昆仑山口西8.1级地震破裂面

利用横跨地表破裂带的小点距的地震测线, 对2001年11月14日昆仑山口西8.1级地震进行了断层围陷波的观测实验. 经过数字滤波和频谱分析等技术, 由地震记录图中分离出了断层围陷波. 资料处理结果表明: ①无论是人工地震震源还是天然地震震源, 只要位于断层带内或紧靠断层带, 均能激发断层围陷波; ②断层围陷波的能量主要集中于断层带内, 其振幅随测点与断层带距离的增加而急剧衰减; ③断层围陷波的优势频率与断层的宽度及断层带内介质的速度有关, 断层带越宽, 或断层带内部介质速度越低, 则观测到的断层围陷波的优势频率越低; ④断层围陷波存在着频散现象; ⑤根据昆仑山口西地震测线断层围陷波的观测结果, 可推断该处破裂面宽度为300 m左右, 远远大于地表破裂带的宽度.

中国大陆M≥7(3/4)地震活动的特点及趋势分析

利用发生在中国大陆地区 M≥ 7 浅源地震资料 ,得出 1 90 0年以来 M≥ 7 地震活动具有成组性和区域性的特点 ,认为 2 0 0 1年 1 1月 1 4日昆仑山 8.1级地震的发生 ,标志着中国大陆地区 M≥ 7 地震第 5个活动组的开始。未来 1～ 6年在以 8.1级地震为中心、半径 5 0 0 km～ 1 0 0 0 km内是发生 M≥ 7 地震的主要场所。通过对 M≥ 7 地震发生后 3年 7级地震活动研究 ,中国大陆未来 3年内仍具有发生 7级地震的可能。

2001年昆仑山口西8.1级大震预报的再讨论

由立交模式、静中动判据和高山峰指标讨论了 2 0 0 1年昆仑山口西 8 1级大震的地点预报。由 74年周期性、三性法和倍九律讨论了这个 8 1级大震的时间预报。倍九律包括热红外异常、 6级地震活动和K

昆仑山口西8.1级地震前新疆定点形变异常初析

昆仑山口西 8.1级地震发生在新疆形变监测台网的东南 ,距震中 70 0— 1 2 0 0 km范围内有 6台项资料显示出地壳形变前兆异常。分析认为地壳形变异常具有一定的阶段性特征 ,中短期异常多出现在 NS向 ,8.1级地震前 2 0天 EW向出现加速或反向突变 ,临震前 4天重力仪记录到强烈的地脉动异常。这些异常的出现与 2 0 0 0— 2 0 0 1年中国西部地区 3次明显的地壳水平运动在时间上有一定的相关性。