则木河断裂带的走滑位移及滑动速率

主要从则木河断裂带上不同地貌单元的走滑位移及分布情况,对则木河断裂各次级剪切断层滑动速率的研究,获得了它们不同时期的活动量。     

则木河断裂带的走滑位移及滑动速率

主要从则木河断裂带上不同地貌单元的走滑位移及分布情况,对则木河断裂各次级剪切断层滑动速率的研究,获得了它们不同时期的活动量.     

则木河断裂带断层活动特征与中强震关系浅析

通过对则木河断裂带上4个跨断层形变测点资料的分析,认为则木河断裂带断层活动分为4个不同的活动时段,其不同活动时段断层张压结合;在川滇交界区域发生中强地震前则木河断裂带跨断层形变资料中能捕捉到一定的前兆信息,地震大多发生在形变异常结束后50d内。     

大凉山断裂带南段滑动速率估计

大凉山断裂带是川滇活动块体东边界的重要组成部分,其活动速率的估计不仅对评价青藏高原东南边缘的地壳运动和变形模型具有重要理论意义,还对大凉山地区的地震危险性评价和地震中长期预测具有重要的应用价值。通过对大凉山断裂带南段交际河断裂和布拖断裂的详细野外调查、典型构造地貌GPS精细测量以及断错地貌的时间约束,获得大凉山断裂带南段全新世以来的滑动速率为2.5～4.5mm/a,交际河断裂平均滑动速率略大于布拖断裂的滑动速率。对比滑动速率发现,大凉山断裂带南段与鲜水河-小江断裂系中段西支的安宁河、则木河断裂带的水平滑动速率相当,表明大凉山断裂带活动强度不低于安宁河和则木河断裂带,随着大凉山断裂带逐渐取代安宁河和则木河断裂在鲜水河-小江断裂系中的作用,大凉山断裂带的活动强度将增强。     

凉山活动构造带晚新生代变形特征与位移规模

凉山近南北向活动构造带位于青藏高原东南边缘鲜水河 -安宁河 -则木河 -小江断裂带中段东侧 ,与鲜水河断裂带左阶雁列 ,与小江断裂带右阶雁列。大体呈南北或北北西方向展布的凉山构造带 ,自北而南主要包括普雄河断裂、布拖断裂和四开 -交际河断裂。晚新生代以来的活动 ,凉山南北向构造带以明显的左旋走滑为特征 ,相应的倾滑位移分量不大。初步统计得到其晚第四纪以来的走滑速率为 2mm/a左右 ,晚新生代以来位移规模 13.5～ 15.5km。凉山活动构造带的活动 ,弥补了鲜水河 -安宁河 -则木河 -小江断裂带中段安宁河 -则木河断裂带活动存在的位移和速率亏损 ,对于全面评价青藏高原东南边缘的地壳运动和变形模型具有重要意义     

安宁河—则木河断裂带1993～2012年重力动态变化

利用安宁河—则木河断裂带区域1993～2012年的流动重力观测数据,作出重力场动态图像和部分重力点值时序变化图,总结在这20年里安宁河—则木河断裂带的活动规律,分析研究安宁河—则木河断裂带区域及其临近区域较大震级的地震孕育过程中区域的重力变化情况,为安宁河—则木河断裂带区域地震预测预报提供经验和参考资料.     

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)

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     

则木河断裂晚第四纪位移及滑动速率

则木河断裂晚第四纪位移及滑动速率任金卫（国家地震局地质研究所，北京１０００２９）则木河断裂是青藏高原东边缘鲜水河～小江断裂带中段的一条走向北北西的活动断裂。第四纪以来具有左旋走滑为主的运动特征。通过野外调查，则木河断裂北段发现了５１个左旋水平位移点     

川西地区地壳形变和断层位移活动

大地测量资料的分析表明，川西地区的地壳形变和断层位移活动沿着已发展成为块体边界线的鲜水河断裂带—安宁河断裂带—则木河断裂带表现为最强，两侧块体内的断裂活动相对次之。区内的现今形变活动趋势仍继承着晚第四纪以来新构造活动的格局，地震形变是现今形变的最佳表现，断层位移活动具有显著的不均匀性。     

安宁河—则木河地震带震源参数及应力状态的研究

利用2001-2008年安宁河-则木河地震带100次3级以上中小地震波形资料计算了地震震源机制解.采用力轴张量法计算给出安宁河-则木河地震带平均主应力方向为NW-SE,与历史中强地震震源机制解结果一致;走滑错动占的比例较大,且分布集中.由小震的震源波谱参数绘制出视应力平面分布和深度分布剖面图,显示在安宁河-则木河地震带及其附近区域相对高视应力区出现在石棉附近地下5 km和15 km两个不连通区域,西昌以南的则木河断裂带地下5 km左右区域,以及西昌以北地下10～20 km区域.若将相对高视应力分布区作为未来强震危险性的估计指标,则安宁河断裂带北段及则木河断裂带中北段未来存在潜在的强震危险性,而在这些地段近8年也有小震活动的密度和强度的显现.     

利用黄土剖面的古土壤年龄研究毛毛山断裂的滑动速率

利用１４Ｃ、热释光（ＴＬ）样品年代及扩散方程计算结果，结合区域黄土剖面中古土壤年龄，对毛毛山地区晚第四纪各级地貌年龄进行了对比研究。根据毛毛山活动断裂水平位移和垂直位移分布明显的分组特征，求得毛毛山断裂带不同段落不同时段的平均滑动速率。大约自中更新世晚期以来，毛毛山断裂走滑段的平均水平滑动速率为２．３～３．９ｍｍ／ａ，垂直滑动速率为０．０７～０．１９ｍｍ／ａ；天祝盆地倾滑段垂直滑动速率为０．１１～０．８６ｍｍ／ａ。沿断裂带滑动速率具明显的非均匀性特点，表现为自东向西水平位移具累积滑动亏损特征，垂直位移则具补偿性     

The advance in obtaining fault slip rate of strike slip fault-A review

Slip rate along the major active fault is an important parameter in the quantitative study of active tectonics. It is the average rate of fault slip during a certain period of time, reflecting the rate of strain energy accumulation on the fault zone. It cannot only be directly applied to evaluate the activity of the fault, the probabilistic seismic hazard analysis, but also important basic data for the study of geodynamics. However, due to the nonstandardized process of obtaining fault slip rates for a given strike-slip fault, the results could be diverse based on various methods by different researchers. In this review, we analyzed the main advances in the approaches to obtain fault slip rate. We found that there are four main sources affecting the final results of slip rate: the displacement along the fault, the dating of the corresponding displacement, the fitting of the displacement and corresponding dating results, and paleoslip analysis. The main advances in obtaining fault slip rates are based on improving the reliability of the above four main factors. To obtain a more reasonable and reliable slip rate for a given fault, it is necessary to select a suitable method according to the specific situation.     

Slip Rate on the Altyn Tagh Fault on the West of the Cherchen River (Between 85°～85°45′E) Since Late Quaternary

Because of the significance to the formation and evolution of the Tibetan plateau, the displacement and slip rate of the Altyn Tagh fault have been topics full of disputation. Scientists who hold different opinions on the evolution of Tibet insist on different slip rates and displacements of the fault zone. In the article, study is focused on the late Quaternary slip rate of the Altyn Tagh fault west of the Cherchen River (between 85°E and 85°45'E). On the basis of high resolution SPOT images of the region, three sites, namely Koramlik, Aqqan pasture and Dalakuansay, were chosen for field investigation. To calculate the slip rate of the fault, displacement of terraces was measured on SPOT satellite images or in situ during fieldwork and thermo-luminescence (TL) dating method was used. To get the ages of terraces, samples of sand were collected from the uppermost sand beds that lie just under loess. The method for calculating slip rate of fault is to divide the displacement of terrace risers by the age of its neighboring lower terrace. The displacement of rivers is not considered in this article because of its uncertainties. At Koramlik, the slip rate of the Altyn Tagh fault is 11.6±2.6mm/a since 6.02±0.47ka B.P and 9.6±2.6mm/a since 15.76±1.19ka B.P. At Aqqan pasture, about 30km west of Koramlik, the slip rate is 12.1±1.9mm/a since 2.06±0.16 ka B.P. At Dalakuansayi, the slip rate of the fault is 12.2±3.0mm/a since 4.91±0.39ka B.P. Hence, we get the average slip rate of 11.4±2.5mm/a for the western part of the Altyn Tagh Fault since Holocene. This result is close to the latest results from GPS research.     

剪切破裂源及其近场影响

本文利用有限差分法对垂直走滑断层和垂直倾滑断层两种剪切破裂源在不同埋深和不同破裂尺度(指垂直于地面方向上断层尺度)情况下的近场理论地震图进行了讨论,并得到了地表不同震中距处的加速度付氏谱。通过对上述两种源所产生的近场效应的对比分析,本文得到了以下初步结果: (1) 在埋深相同,断层面宽度相同的情况下,垂直走滑断层源对近场地表的影响比垂直倾滑断层源大。(2) 在垂直倾滑断层源的埋深、破裂尺度相同的情况下,在地表同一震中距处产生的水平位移要比垂直位移大。(3) 两种破裂源在地表同一震中距处产生的位移的最大振幅随破裂尺度的增大而增大,且近似为线性关系;在极震区内不同震中距处产生的位移的最大振幅随震中距的增大而减小,且随震中距的变化率在减小;在地表不同震中距处产生的加速度的付氏谱的主峰周期随震中距的增大而变长,随破裂的增大,付氏谱中主峰周期也加长,且长周期成份愈多;随着破裂源埋深的增加,地表不同震中距处产生的位移的最大振幅变小,即等震线变疏。(4) 走滑断层源产生的加速度付氏谱的主峰周期比倾滑断层源长。     

A simple procedure to approximate slip displacement of freestanding rigid body subjected to earthquake motions

A simple calculation procedure for estimating absolute maximum slip displacement of a freestanding rigid body placed on the ground or floor of linear/nonlinear multi‐storey building during an earthquake is developed. The proposed procedure uses the displacement induced by the horizontal sinusoidal acceleration to approximate the absolute maximum slip displacement, i.e. the basic slip displacement. The amplitude of this horizontal sinusoidal acceleration is identical to either the peak horizontal ground acceleration or peak horizontal floor response acceleration. Its period meets the predominant period of the horizontal acceleration employed. The effects of vertical acceleration are considered to reduce the friction force monotonously. The root mean square value of the vertical acceleration at the peak horizontal acceleration is used. A mathematical solution of the basic slip displacement is presented. Employing over one hundred accelerograms, the absolute maximum slip displacements are computed and compared with the corresponding basic slip displacements. Their discrepancies are modelled by the logarithmic normal distribution regardless of the analytical conditions. The modification factor to the basic slip displacement is quantified based on the probability of the non‐exceedence of a certain threshold. Therefore, the product of the modification factor and the basic slip displacement gives the design slip displacement of the body as the maximum expected value. Since the place of the body and linear/nonlinear state of building make the modification factor slightly vary, ensuring it to suit the problem is essential to secure prediction accuracy. Copyright © 2006 John Wiley & Sons, Ltd.     

小江断裂带西支断裂南段新活动初探

本文根据实地调查,分析了小江西支断裂南段两条分支断裂的展布特征及其活动性。用冲沟长度、错动量及平均侵蚀速率,估算了断裂的水平滑动速率。指出南段分支断裂作多重右阶斜列展布,现今活动以左旋走滑为主,兼有倾向运动分量,全新世以来平均水平滑动速率为1.66mm/a。     

2016年8月24日意大利佩鲁贾MW 6.2级地震同震位移场估计和震源滑动模型反演

利用改进的自动经验基线校正方法SMBLOC,对2016年8月24日意大利佩鲁贾MW 6.2级地震震中周围约60 km内的近场强震记录进行基线校正并尝试给出同震位移场,与GPS观测结果进行对比分析,分别独立和联合两种资料反演震源滑动模型,并根据震源模型进一步给出全空间预测位移场分布.研究结果表明:(1)两种不同的资料给出的水平位移场幅值均为cm级,且均表明断层的错动以正断为主.(2)两种同震位移场分别独立和联合反演所得的震源静态滑动范围基本一致,最大滑动均发生在震中东北侧,强震模型表现出明显的双事件特征,较大滑动分布在震中东北侧和东南侧,GPS模型在震中东南侧的滑动相对较小,其双事件特征不明显.两种模型的最大滑动量分别为0.96 m和0.86 m,较为一致,反演的矩震级均在MW 6.3左右.(3)根据震源滑动模型计算所得的佩鲁贾地震全空间预测的水平同震位移场中最大位移分布区域与震后报告中受灾严重的地区基本一致.表明在一定的条件下,利用SMBLOC方法解算震级较小的MW 6.0左右地震强震记录的同震位移场,并反演震源滑动模型具有一定的可行性,且其同震位移场和滑动模型可为震后灾害快速评估、救援力量分配、余震趋势判定等快速应急响应工作提供参考依据.     

青藏高原东缘礼县-罗家堡断裂带晚更新世以来的活动性分析

礼县 -罗家堡断裂带晚更新世以来有过明显活动。在礼县—罗家堡段和天水镇—街子口段直接错断全新世地层。断裂沿线地表陡坎发育 ,水系被左旋位错。结合沿该断裂带广泛分布的地震滑坡、砂土液化等 ,认为礼县 -罗家堡断裂带是 1654年天水南 8级地震的发震构造。该断裂晚更新世以来的平均水平位错速率为 0 95mm/a ,平均垂直位移速率为 0 35mm/a ,垂直位移速率约为水平位移速率的 1/ 3。这个比值与一次断裂突发性垂直位错量 ( 1 9m)与水平位错量 ( 5 2m)的比值基本吻合     

SLIP OFFSET ALONG STRIKE-SLIP FAULT DETERMINED FROM STREAM TERRACES FORMATION

Slip rate is one of the most important parameters in quantitative research of active faults. It is an average rate of fault dislocation during a particular period, which can reflect the strain energy accumulation rate of a fault. Thus it is often directly used in the evaluation of seismic hazard. Tectonic activities significantly influence regional geomorphic characteristics. Therefore, river evolution characteristics can be used to study tectonic activities characteristics, which is a relatively reliable method to determine slip rate of fault. Based on the study of the river geomorphology evolution process model and considering the influence of topographic and geomorphic factors, this paper established the river terrace dislocation model and put forward that the accurate measurement of the displacement caused by the fault should focus on the erosion of the terrace caused by river migration under the influence of topography. Through the analysis of the different cases in detail, it was found that the evolution of rivers is often affected by the topography, and rivers tend to migrate to the lower side of the terrain and erode the terraces on this side. However, terraces on the higher side of the terrain can usually be preserved, and the displacement caused by faulting can be accumulated relatively completely. Though it is reliable to calculate the slip rate of faults through the terrace dislocation on this side, a detailed analysis should be carried out in the field in order to select the appropriate terraces to measure the displacement under the comprehensive effects of topography, landform and other factors, if the terraces on both sides of the river are preserved. In order to obtain the results more objectively, we used Monte Carlo method to estimate the fault displacement and displacement error range. We used the linear equation to fit the position of terrace scarps and faults, and then calculate the terrace displacement. After 100, 000 times of simulation, the fault displacement and its error range could be obtained with 95%confidence interval. We selected the Gaoyan River in the eastern Altyn Tagh Fault as the research object, and used the unmanned air vehicle aerial photography technology to obtain the high-resolution DEM of this area. Based on the terrace evolution model proposed in this paper, we analyzed the terrace evolution with the detailed interpretation of the topography and landform of the DEM, and inferred that the right bank of the river was higher than the left bank, which led to the continuous erosion of the river to the left bank, while the terraces on the right bank were preserved. In addition, four stages of fault displacements and their error ranges were obtained by Monte Carlo method. By integrating the dating results of previous researches in this area, we got the fault slip rate of(1.80±0.51)mm/a. After comparing this result with the slip rates of each section of Altyn Tagh Fault studied by predecessors, it was found that the slip rate obtained in this paper is in line with the variation trend of the slip rate summarized by predecessors, namely, the slip rate gradually decreases from west to east, from 10~12mm/a in the middle section to about 2mm/a at the end.