走滑断裂粘滑,蠕滑作用形成的地质貌特征

在室内航片解释的基础上，依据野外现场实测资料，应用地质地貌学方法，对走滑断裂上有作用形成的弧形，“正”、“逆”牵引变形山脊及断错变形冲沟的４种地貌形态进行了讨论，并根据这些蠕滑志标，测量了昌马断裂带中、东段的蠕滑量。给出了粘滑与蠕滑量的比值及蠕滑量占总走滑量的比例在断裂带上的分布情况。     

昌马断裂带断层岩研究及其粘滑,蠕滑特征

在对断层岩的分布、内部结构、宏观变形及断层泥中石英颗粒形态、表面特征研究分析的基础上，讨论了昌马断裂带粘滑、蠕滑特征。同时指出，昌马断裂带虽以粘滑运动为主，但仍伴有一定量的蠕滑活动。     

鲜水河断裂带跨断层形变测量及其地震学意义

通过对鲜水河断裂带多年跨断层形变测量资料的分析，揭示出鲜水河断裂带不同部位的形变特征，断裂带破裂区表现为较高速率的蠕滑运动，其运动速率又以极震区为中心向两侧衰减，“闭锁区”则具有运动停滞的特点，并有明显的分段性。断层形变的特殊形态还与地震有一定的关系，如每当形变出现“Ｖ”（或倒“Ｖ”）字型时，会有中小地震对应；断层扭动反向与变化也与地震有关     

利用滑动速率、古地震资料估算走滑断裂的粘滑及蠕滑量的方法

断层走滑包括粘滑和蠕滑,前者是伴有强震发生的快速运动,后者则是一种缓慢的无震稳滑运动。这２ 种运动常随时间交替出现,共同构成了断层的基本运动方式。在利用断层滑动速率讨论大震重复率的问题中,人们最关心的问题则是如何从总滑动量中分辨和划分出其中所包含的粘滑和蠕滑量,特别是对蠕滑量的划分,因为它直接影响着大震重复率的正确性。笔者在野外考察的基础上,对昌马活动断裂的位移量进行了分级,确定出昌马断裂带全新世以来的水平滑动量大致可划分为５个级别：３１～４１ ｍ ;２５～３１ ｍ ; １５～２２ ｍ ; ８～１３ ｍ ;１～５．５ ｍ ,同时依据古地震学方法并结合１４Ｃ断代法及断层崖形成年代的数学模拟计算,求得全新世以来在昌马断裂带上共发生５ 次古地震事件。在上述２ 项资料确定的基础上,进一步对昌马断裂带的粘滑及蠕滑量进行了划分,并给出了它们随时间的变化情况     

青藏高原北部大型走滑断裂带近地表地质变形带特征分析

阿尔金断裂带、东昆仑断裂带和海原断裂带是青藏高原北部的大型左旋走滑断裂带,具有相对高的地质和GPS滑动速率,地表破裂型地震频发。在阿尔金断裂带阿克塞老城西和半果巴、东昆仑断裂带西大滩和玛沁、海原断裂带松山等地点的探槽地质剖面揭露了这些走滑断裂带累积地质变形带的基本特征。阿尔金断裂带半果巴探槽和阿克塞老城西探槽、东昆仑断裂带西大滩探槽和玛沁探槽揭露出的地质变形带宽度约12m左右;海原断裂带松山拉分盆地边界单条走滑断层地质变形带宽度不足10m,考虑到地震期间拉分盆地可能会出现较严重的变形,则拉分盆地本身也应作为强变形带处理。由此可见,经历过多个地震地表破裂循环的东昆仑断裂带、海原断裂带和阿尔金断裂带其地质变形带的宽度是有限的,具有变形局部化特征。单条走滑断层的地质变形带宽度一般为10余米,比较保守地估计应<30m,走滑断层斜列阶区的地质变形带宽度取决于阶区本身的宽度     

红河断裂带南段中新世以来大型右旋位错量的定量研究

红河断裂带南段(元江—元阳一带)穿经盆地内的“中谷断裂”,是一条新构造期明显活动的主平移断裂。它的新近活动将中新世红河盆地一分为二,右旋切错至倮头山—大曼迷一带。与此相伴,山前断裂则以正断活动为主。沿“中谷断裂”高角度切错中新统的剪切走滑断面,被断错的中新世条形盆地内发育轴向NE的挤压褶皱及压缩变形的空间变化特征,下中新统、中上中新统、上新统及第四系的分布依次自SE向NW有序迁移且在“中谷断裂”的东北盘节节错后分布等,均表明红河断裂南段中新世以来自SE向NW的不断破裂扩展和右旋走滑位错;区段内中下中新统较厚的山前磨拉石沉积建造、卷入“中谷断裂”剪切变形的强度中新统明显强于上新统等表明,红河断裂南段大规模的右旋走滑运动应发生在中中新世前后,其FT年龄约为距今13.7Ma;根据切错的中新统的平面尺度、用平衡剖面法恢复压缩前盆地的长度和由断层变形带宽度等计算,求得红河断裂带南段中新世以来大型右旋位错总量介于62~69km,中值为65km。研究资料还表明,红河断裂右旋走滑运动作为一个过程,经历转换活动期(N1)、右旋走滑初始期(N21)、大型右旋走滑期(N31—N21)和右旋走滑扩展期(N22—Qp1)等多个发生、发     

利用滑动速率,占地震资料估算走滑断裂的粘滑及蠕滑量的方法

断层走滑包括粘滑和蠕滑,前者是伴有强震发生的快速运动,后者则是一种缓慢的无震稳滑运动,这２种运动常随时间交替出现,共同构成了断层的基本运动方式,在利用断层滑动速率讨论大震重复率的问题中,人们最关心的问题则是如何从总滑动量中分辨和划分出其中包包含的粘滑和蠕滑量,特别是对蠕滑量的划分,因为它直接影响大震重复率的正确性,笔者在野外考察的基础上,对昌马活动断鲜明的位移量进行了分级,确定出昌马断裂带全新以来     

活动断裂带上的粘滑和蠕滑标志及其研究意义

简要概述活动断裂带上粘滑与蠕滑标志研究进展,着重探讨活动断裂带中赋存的显微粘滑与蠕滑标志,立足于天然断错产物的微观观测与岩石实验成果相结合的分析,初步提出一些对比性较好的的活动方式标志,以此为活动断裂带粘滑和蠕滑段的划分提供微观依据,并就微观粘、蠕滑标志在断裂分段中的应用、定向微观活动方式标志的运动学和动力学意义以及利用其确定古地震期次和重复间隔等作了有益的讨论.     

大青山山前活动断裂变形产物中的微观粘滑与蠕滑标志

本文通过对大青山山前活动断裂带上的变形产物进行定向采集、原态固结并进行系统微观观测，结合宏观和实验岩石学资料分析，归纳出能反映该断裂运动特性的微观粘滑与蠕滑标志，并对有关问题进行了讨论。     

基于声发射实验结果讨论大震前地震活动平静现象的机制

基于岩石变形声发射实验结果讨论了大震前地震活动平静现象的机制。在双轴压缩、等位移速率加载条件下 ,挤压型雁列断层、含宏观凹凸体断层、Ⅲ型剪切断层等非连续断层在临近滑动失稳前 ,声发射活动均出现了明显的相对平静现象 ,表现为声发射事件的发生率和应变能释放水平显著降低。与此阶段相对应 ,断层带 (特别是非连续部位上新形成的一小段断层 )发生了蠕滑和匀阻化作用 ,并使得标本的差应力开始下降。根据实验结果提出 ,大地震前断层的“蠕滑 -匀阻化”过程是造成地震活动平静现象的可能机制     

A PRELIMINARY RESEARCH ON THE RIGHT-LATERAL STRIKE-SLIP CHARACTERISTICS AND THE STRUCTURAL SIGNIFICANCE OF THE NORTHERN KUANTANSHAN FAULTS,HEXI CORRIDER,BASED ON HIGH-RESOLUTION IMAGERY

The sinistral strike-slip characteristic of the Altyn Tagh Fault gradually disappears near the Jiuxi Basin at the west end of Hexi Corridor, and the Kuantanshan Fault and the northern marginal fault of Heishan on its east are thrust structures. There are two faults distributed in the north of Kuantanshan, namely, the Taerwan-Chijiaciwo Fault and the Ganxiashan Fault, both are featured with obvious activity. Predecessors thought that the Taerwan-Chijiaciwo Fault is a thrust fault with low movement rate, but there is few detailed study on its horizontal motion. Is there horizontal strike-slip movement in the northern marginal fault of Kuantanshan? This issue has an important significance to further explore the structural transformation mode between the Altyn Tagh strike-slip faults and the northern thrust faults in the north margin of Qilianshan. Using high resolution remote sensing images and field work, such as combining with UAV SfM photogrammetry, the paper studies the strike-slip characteristics of the Taerwan-Chijiaciwo Fault and Ganxiashan Fault on the northern margin of Kuantanshan, and get two preliminary understandings:(1) The northern marginal fault of Kuantanshan is an active right-lateral strike-slip fault with thrust component, the horizontal to vertical dislocation ratio is about 3-4 times. Based on the statistics of dislocation amount of the gullies and terraces along the north marginal Kuantanshan fault, it is preliminarily estimated that the late Pleistocene right-lateral strike-slip rate is about 0.2-0.25 mm/a and the Holocene right-lateral strike-slip rate is about 0.5-1.5 mm/a. (2) The main driving force to the tectonics at the western end of Hexi Corridor, where the northern marginal fault of Kuantanshan locates, comes from the northward extrusion of the Qilian Mountains, which results in the right-lateral strike-slip of the northern marginal fault of Kuananshan and the thrust movement of several faults inside the Jiuxi Basin. The effect of the Altyn Tagh Fault on other tectonic structures is not obvious in this region.     

THE PALEOSEISMIC SURFACE RUPTURE AT SOUTH OF CENTRAL ALTYN TAGH FAULT AND ITS TECTONIC IMPLICATION

In this study, we described a 14km-long paleoearthquakes surface rupture across the salt flats of western Qaidam Basin, 10km south of the Xorkol segment of the central Altyn Tagh Fault, with satellite images interpretation and field investigation methods. The surface rupture strikes on average about N80°E sub-parallel to the main Altyn Tagh Fault, but is composed of several stepping segments with markedly different strike ranging from 68°N~87°E. The surface rupture is marked by pressure ridges, sub-fault strands, tension-gashes, pull-apart and faulted basins, likely caused by left-lateral strike-slip faulting. More than 30 pressure ridges can be distinguished with various rectangular, elliptical or elongated shapes. Most long axis of the ridges are oblique(90°N~140°E)to, but a few are nearly parallel to the surface rupture strike. The ridge sizes vary also, with heights from 1 to 15m, widths from several to 60m, and lengths from 10 to 100m. The overall size of these pressure ridges is similar to those found along the Altyn Tagh Fault, for instance, south of Pingding Shan or across Xorkol. Right-stepping 0.5~1m-deep gashes or sub-faults, with lengths from a few meters to several hundred meters, are distributed obliquely between ridges at an angle reaching 30°. The sub-faults are characterized with SE or NW facing 0.5~1m-high scarps. Several pull-apart and faulted basins are bounded by faults along the eastern part of the surface rupture. One large pull-apart basins are 6~7m deep and 400m wide. A faulted basin, 80m wide, 500m long and 3m deep, is bounded by 2 left-stepping left-lateral faults and 4 right-stepping normal faults. Two to three m-wide gashes are often seen on pressure ridges, and some ridges are left-laterally faulted and cut into several parts, probably owing to the occurrence of repetitive earthquakes. The OSL dating indicates that the most recent rupture might occur during Holocene.
Southwestwards the rupture trace disappears a few hundred meters north of a south dipping thrust scarp bounding uplifted and folded Plio-Quaternary sediments to the south. Thrust scarps can be followed southwestward for another 12km and suggest a connection with the south Pingding Shan Fault, a left-lateral splay of the main Altyn Tagh Fault. To the northeast the rupture trace progressively veers to the east and is seen cross-cutting the bajada south of Datonggou Nanshan and merging with active thrusts clearly outlined by south facing cumulative scarps across the fans. The geometry of this strike-slip fault trace and the clear young seismic geomorphology typifies the present and tectonically active link between left-lateral strike-slip faulting and thrusting along the eastern termination of the Altyn Tagh Fault, a process responsible for the growth of the Tibetan plateau at its northeastern margin. The discrete relation between thrusting and strike-slip faulting suggests discontinuous transfer of strain from strike-slip faulting to thrusting and thus stepwise northeastward slip-rate decrease along the Altyn Tagh Fault after each strike-slip/thrust junction.     

西秦岭北缘断裂带黄香沟段晚第四纪水平位移特征及其微地貌响应

西秦岭北缘断裂带是青藏高原东北部一条左旋走滑为主的活动断裂带,其在黄香沟一段活动性较强,活动现象典型。对沿断裂带分布的地貌、地质体等晚第四纪位移量的研究表明,在黄香沟一带,断裂晚更新世晚期以来的水平位移量最大为40~60m;最小为6~8m,可能是一次滑动事件的特征位错量。断裂带上的位移具有分组特征,各组位移值之间具有6~8m的稳定增量。位移值的分组性和增量特征反映了该段断裂具有特征地震的活动特征,而7组位错值则反映了断裂7次特征活动事件。关于黄香沟一带与断裂相关的微地貌分析,也获得了大致相对应的事件次数。并由此初步推测,晚更新世晚期以来,该断裂带有过多次强烈活动,活动期次明显     

断层泥的再生显微结构特征及其地震地质意义

三轴剪切摩擦实验后的断层泥与天然断层泥的再生显微结构特征研究表明，断层泥的显微结构特征与断层滑动方式之间有一定的关系，稳滑使断层泥变形均匀，产生低角度剪切（＜１４°）、布丁构造和颗粒碎裂流动。粘滑使断层泥局部发生强烈变形、高角度剪切（＞１４°）和碎粒出现随机裂纹等。断层泥的再生显微结构特征可用作鉴别古地震的存在     

郯庐活断层的分段及其大震危险性分析

郯庐活断层长３６０ｋｍ，通过系统的填图可将其分为３个独立的活断层破裂段。对每段的几何形态、最新活动时代、大震复发间隔、现今活动状态以及分段障碍体等作了介绍，并对各段未来的大震危险性做了初步分析     

1303年洪洞8级地震震源过程研究

运用霍山断裂滑动速率和１３０３年洪洞８级地震错距的资料，将霍山断裂面取作位错面，使用粘弹介质中位错模型的有限单元公式￣［１］，计算震前断层蠕滑动和震时断层错动对应的临汾盆地应力和应变能密度年速率分布，由此得出：（１）１３０３年洪洞地震前，在临汾盆地以霍山断裂中段和南段应力和应变能密度年速率正值最高，为积累过程，而震时（含震后），年速率负值最高，为释放过程；（２）１３０３年洪洞地震加速了１６９５年临汾地震应力和应变能积累；（３）用有限单元分析方法中的劈节点技术离散位错面，可以符合位错概念     

THE GEOLOGICAL AND ROCK MECHANICAL DISTINCTION EVIDENCE BETWEEN STICK-SLIP AND CREEP IN HOST ROCK SEGMENTS OF FAULT

Paleo-seismic and fault activity are hard to distinguish in host rock areas compared with soft sedimentary segments of fault. However, fault frictional experiments could obtain the conditions of stable and unstable slide, as well as the microstructures of fault gouge, which offer some identification marks between stick-slip and creep of fault. We summarized geological and rock mechanical distinction evidence between stick-slip and creep in host rock segments of fault, and analyzed the physical mechanisms which controlled the behavior of stick-slip and creep. The chemical composition of fault gouge is most important to control stick-slip and creep. Gouge composed by weak minerals, such as clay mineral, has velocity weakening behavior, which causes stable slide of fault. Gouge with rock-forming minerals, such as calcite, quartz, feldspar, pyroxene, has stick-slip behavior under condition of focal depth. To the gouge with same chemical composition, the deformation mechanism controls the frictional slip. It is essential condition to stick slip for brittle fracture companied by dilatation, but creep is controlled by compaction and cataclasis as well as ductile shear with foliation and small fold. However, under fluid conditions, pressure solution which healed the fractures and caused strength recovery of fault, is the original reason of unstable slide, and also resulted in locking of fault with high pore pressure in core of fault zone. Contrast with that, rock-forming minerals altered to phyllosilicates in the gouges by fluid flow through degenerative reaction and hydrolysis reaction, which produced low friction fault and transformations to creep. The creep process progressively developed several wide shear zones including of R, Y, T, P shear plane that comprise gouge zones embedded into wide damage zones, which caused small earthquake distributed along wide fault zones with focal mechanism covered by normal fault, strike-slip fault and reverse fault. However, the stick-slip produced mirror-like slide surfaces with very narrow gouges along R shear plane and Y shear plane, which caused small earthquake distributed along narrow fault zones with single kind of focal mechanism.     

甘肃古浪、景泰活断层上的树木地震学研究

在树木地震学测年技术研究的基础上，沿古浪活断层西段鉴定和评价了数百棵树。对树木生长速率及年轮比率低值偏离的３种类型进行了有效的识别。结果表明：断崖上被破坏的青海云杉中，记录的结构和生长速率异常，可以归因于１９２７年５月２３日古浪８级大地震的影响。从而为古浪地震断层的判定提供了准确的年代证据。并将前人认为的古浪地震断层位置向冷龙岭北麓南移了３０余公里。用该方法在老虎山活断层上对１８８８年１１月２日景秦６１／４级地震破裂带定年，再次获得成效     

龙陵-瑞丽断裂带附近的构造地貌与断裂活动性

利用ALOS全色、ASTER多光谱遥感影像和SRTM数字高程模型数据解译,并结合野外地质调查和实时差分GPS测量,对龙陵-瑞丽断裂带晚第四纪活动的构造地貌和地质特征进行了研究。综合遥感解译、构造地貌和地震地质调查的结果认为,龙陵-瑞丽断裂带是一条以左旋走滑作用为主的断裂,在晚第四纪具有一定的活动性;并确定了龙陵-瑞丽断裂带各活动段落的空间分布情况。选取朱家寨一带开展了探槽挖掘工作。探槽很好地揭露了基岩中发育的新鲜断层面和晚第四纪冲洪积层,但是未发现断层错动晚第四纪沉积物的迹象。采集了冲洪积层底部的植物化石进行了14C测年,结果为（1150±30）a BP。据此推测,从距今1150年以来,龙陵-瑞丽断裂带活动断层在北段未再发生过破坏性古地震事件。综合分析1976年龙陵地震的发震特点,认为1976年发生在龙陵的大地震未发生在龙陵-瑞丽断裂带上,其震源机制解和余震分布特征表明地震活动与NNW向展布的新生断裂带活动有关,这很有可能造成了NE向龙陵-瑞丽断裂带晚第四纪构造活动性减弱。     

GEOLOGICAL AND GEOMORPHIC EXPRESSIONS OF LATE QUATERNARY STRIKE-SLIP ACTIVITY ON JINTA NANSHAN FAULT IN NORTHERN EDGE OF QING-ZANG BLOCK

Jinta Nanshan Fault is an important fault in northeast front of Qing-Zang Plateau, and it is crucial for determining the eastern end of Altyn Tagh Fault. However, there is still debate on its significant strike-slip movement. In this paper, we study the Late Quaternary activity of Jinta Nanshan Fault and its geological and geomorphic expressions by interpreting aerial photographs and high-resolution remote sensing images, surveying and mapping of geological and geomorphic appearances, digging and clarifying fault profiles and mapping deformation characteristics of micro-topographies, then we analyze whether strike-slip activity exists on Jinta Nanshan Fault. We get a more complete fault geometry than previous studies from most recent remote sensing images. Active fault traces of Jinta Nanshan mainly include 2 nearly parallel, striking 100°~90° fault scarps, and can be divided into 3 segments. West segment and middle segment form a left stepover with 2~2.5km width, and another stepover with 1.2km width separates the middle and east segment. We summarize geomorphic and geologic evidence relating to strike slip activity of Jinta Nanshan Fault. Geomorphic expressions are as follows:First, fault scarps with alternating facing directions; second, sinistral offset of stream channels and micro-topographies; third, pull-apart basins and compressive-ridges at discontinuous part of Jinta Nanshan Fault. Geologic expressions are as follows:First, fault plane characteristics, including extremely high fault plane angle, unstable dip directions and coexistence of normal fault and reverse fault; second, flower structures. Strike-slip rate was estimated by using geomorphic surface age of Zheng et al.(2013)and left-lateral offset with differential GPS measurements of the same geomorphic surface at field site in Fig. 4e. We calculated a strike-slip rate of (0.19±0.05)mm/a, which is slightly larger than or almost the same with vertical slip rate of (0.11±0.03)mm/a from Zheng et al.(2013). When we confirm the strike-slip activity of Jinta Nanshan, we discuss its potential dynamic sources:First, eastern extension of Altyn Tagh Fault and second, strain partitioning of northeastward extension of Qilian Shan thrust belt. The first one is explainable when it came to geometric pattern of several E-W striking fault and eastward decreasing strike slip rate, but the former cannot explain why the Heishan Fault, which locates between the the Altyn Tagh Fault and Jinta Nanshan Fault, is a pure high angle reverse fault. The latter seems more explainable, because oblique vectors may indeed partition onto a fault and manifest strike-slip activity.