北秦岭构造带断裂遥感解译及其构造意义

秦岭造山带位于华北板块与扬子板块之间,造山带内发育若干条近平行的韧性剪切带和夹持其间的岩块,它们和次级断裂组成特有的构造图案。虽有后期脆性断裂的叠加,但依然可以看出这些断裂组成了具有规律性的构造图案,反映出不同的构造型式和构造活动。由于秦岭造山带山高林密,有些地段很难人力进行考察,给该区的构造研究增加了难度。为此,本文利用Google Earth软件获取高分辨率的卫星图像,对其进行影像处理和构造解译,分析了北秦岭地区的断裂构造的变形特征及组合样式,从造山带尺度研究大型断裂带的变形特征、样式图案,探求其运动方式和演化规律。     

恩格尔乌苏冲断带特征及大地构造意义

研究表明恩格尔乌苏冲断带是华北板块和塔里木板块的缝合线,北东东向断续延长800km以上。该冲断带连同南北陆缘地带构造构成典型的陆-弧-陆碰撞造山带,与碰撞造山作用同时,形成区域性透入性劈理。地层学和同位素地质年代学资料表明,碰撞造山作用发生于海西末期或印支早期。碰撞造山作用的动力学过程主要表现为向南的洋壳俯冲和向北的陆壳仰冲,并伴随右旋剪切滑移运动。恩格尔乌苏混杂岩带为韧性-韧脆性冲断推覆构造,其北侧的前陆褶皱冲断带为脆性-脆韧性冲断推覆及褶皱构造。     

Ore-controlling thrust faults at the Bazovskoe gold-ore deposit (Eastern Yakutia)

This work presents results of structural analysis of the orogenic Bazovskoe gold-ore deposit, the structure of which is controlled by an imbricate fan with frontal succession of ore-controlling thrust faults and conjugated thrust ramps. It was established that linear and stratified stockworks and their combinations are formed by several systems of quartz veins and veinlets, regularly related to thrusting along the ore-controlling zones and interlayer shears. In addition, superimposed shear deformations are widely distributed. The features revealed of the geological structure of the Bazovskoe gold-ore deposit allow us to refine the prospecting and searching pattern developed for gold-ore deposits of the Verkhoyansk–Kolyma fold belt.     

秦岭商丹断裂带南侧弧前沉积体的变形特征及其构造意义

本文选取秦岭商丹断裂带以南,南秦岭刘岭群以北的弧前沉积体为研究对象,研究扬子板块向北秦岭俯冲的运动学特征。这套弧前沉积体产状北倾,矿物拉伸线理为倾向线理,岩片强烈褶皱,断裂发育,表现出由北向南逆冲的运动学特征。利用糜棱岩与云母石英片岩中矿物变形温度计,结合石英C轴组构估算岩石变形温度集中在400℃～550℃之间。结合其所处的构造位置,本文认为这套强烈变形的岩石构造组合体形成于秦岭古岛弧弧前沉积背景,在扬子板块向北秦岭俯冲过程中,北秦岭沿着商丹带由北向南逆冲形成。后期又遭受商丹韧性剪切带左行走滑活动的改造。     

西南三江构造体系及演化、成因

西南三江构造体系突出表现为以昌都-兰坪-思茅地块为中轴的不对称走滑对冲构造,次为与走滑断裂相伴的伸展滑脱、走滑拉分盆地构造体系,再次为块体内部的近北东、北西向走滑断裂系.西南三江造山带构造体系演化分为挤压收缩变形、走滑深熔热隆、走滑剪切伸展、走滑剥蚀隆升等4个阶段.自晚白垩世开始,印度板块与欧亚板块碰撞,西南三江造山带...     

华北板块南缘的变形分解:洛南-栾川断裂带与秦岭北缘强变形带研究

秦岭洛南-栾川断裂带具有左旋斜向俯冲的运动学特征,其产状一般为107°/N∠65°。华南板块的俯冲方向为80°,俯冲角度为42°;华南板块运动方向为42°,运动方向与华北板块南部边界的夹角为65°,汇聚角25°。秦岭北缘强变形带内褶皱枢纽延伸方向为290°,与洛南-栾川断裂带存在15°的夹角。逆冲断层走向与褶皱的枢纽方向基本一致,大多数断层与洛南-栾川断裂带有相同的运动学极性,性质为左行平移逆断层。平移正断层走向主要为NE SW,断层性质、展布方向、运动学特征与板块汇聚的应力作用方式吻合;片理、片麻理走向117°,与洛南-栾川断裂带走向夹角为10°。在垂直剪切带的剖面上,系统观察岩石变形特征,测量面理产状,进行岩石有限应变测量,岩石非共轴递进变形分析结果表明:秦岭北缘强变形带内由南向北面理走向与剪切带走向的夹角逐渐增大,岩石剪应变量依次递减,造山带变形具有“三斜对称”特点。     

Syn-thrust deformation across a transverse zone: the Grem–Vedra fault system (central Southern Alps, N Italy)

The lateral continuity of the E?CW trending thrust sheets developed within the Lower to Middle Triassic cover of the central Southern Alps (Orobic belt) is disturbed by the occurrence of several N?CS trending transverse zones, such as the poorly known Grem?CVedra Transverse Zone (GVTZ). The GVTZ developed during the emplacement of the up to six S-verging thrust sheets consisting of Lower to Middle Triassic units, occurring immediately south of the Orobic Anticlines. The transverse zone, active during thrust emplacement related to the early Alpine compressions which pre-date the Adamello intrusion, includes three major vertical shear zones, the Grem, Pezzel and Zuccone faults. The major structure of the transverse zone is the dextral Grem fault, forming a deep lateral ramp between thrust sheets 3 and 5. A similar evolution also occurred along the Zuccone and Pezzel faults, which show a left-lateral displacement of syn-thrust folds. The Grem fault was later reactivated as an oblique tear fault during the emplacement of the Orobic Anticlines, due to back-thrusting along out-of-sequence thrust surfaces (Clusone fault). Transpressional deformations along the fault zone are recorded by the rotation of major syn-thrust folds, which also suggest a horizontal offset close to 0.5?km. Records of the first stage of evolution of the Grem fault are better preserved along its northern segment, and structural relationships suggest that it propagated southward and downward in the growing thrust stack. The study of the meso and megascopic structures developed along the GVTZ constrains the evolution of the transverse zone, illustrating the complex deformational phenomena occurring in a transpressional regime. The GVTZ probably reflects the existence of pre-existing tectonic lineaments with a similar orientation. Evidence of pre-existing structures are not preserved in the exposed units, nevertheless the N?CS extensional fault systems that characterize the Norian to Jurassic rifting history of the Lombardian basin are valid candidates.     

Role of strike-slip faults in the Betic-Rifian orogeny

A new model for the Betic-Rifian orogeny of the Western Mediterranean (Spain and North Africa) is proposed in which four strike-slip faults play an important role; the faults are not of the same age. Two faults, the left-lateral Jebha fault to the south (in Morocco and principally in the Mediterranean Sea) and the right-lateral North Betic fault (southern Spain) to the north, define the boundaries of the Alboran block (Betic and Rifian internal zones). Final movement along these faults was during the Burdigalian time. Two other faults, the left-lateral Nekor fault (North Africa) to the south of the Jebha fault and the right-lateral Crevillente fault, somewhat to the north of the North Betic fault, define a larger Alboran block (including part of the Betic and Rifian external zones) that was present during the Tortonian.The following sequence of events is proposed:

1. (a) During the Eocene and Oligocene, the African and European plates converged in a N-S sense causing the breakup and overthrusting of the Betic, Rifian and Kabyle internal zones and then the movement towards the WSW of the Alboran block by slip along the Jebha and North Betic faults.

2. (b) By the end of Burdigalian time, movement along the Jebha and North Betic faults ceased.

3. (c) With continued N-S convergence, the Nekor and Crevillente faults, which bound a larger Alboran block, were formed during the mid- and late Miocene. The Arc of Gibraltar (the zone lying between the four major faults) seems to be a result of WSW motion of a crustal block being thrust over external zones.

The model proposed adds to the earlier idea that tectogenesis proceeds from the interior to the exterior of an erogenic belt. In the Betic-Rifian orogeny major strike-slip fracture zones shifted to the exterior of the orogenic belt as the orogeny progressed in order to relieve the stress caused by locking of the more internal faults.     

扬子北缘复合构造带的结构、演化和动力学

扬子北缘复合构造带位于秦岭—大别造山带南缘与扬子板块北缘之间,由桐柏—大别造山带、武汉—怀宁断褶带、九岭—江南隆起带、瑞昌—铜陵断褶带和大冶—宿松对接带等构造单元组成,是中生代不同时期构造体制叠加,不同方向构造复合、联合的结果。该复合构造带北侧的桐柏—大别山南缘构造带和武汉—怀宁前陆断褶带由北向南逆冲,主要形成于晚印支期,是特提斯构造体制作用的产物; 而南侧的九岭—江南隆起带和瑞昌—铜陵断褶带,则由南向北逆冲,主要形成于早燕山期,是太平洋构造体制作用的产物,同时北侧的大别山南缘构造带和前陆断褶带受到影响,再次活动; 位于该复合构造带中部的大冶—宿松对接带是上述不同构造体制下,不同方向应力叠加,多期构造形迹复合最终形成的复杂构造带。所以,扬子北缘复合构造带是特提斯构造体制与太平洋构造体制转换的产物,是中下扬子两大构造体系转换的经典记录。     

前陆冲断带构造分段特征--以准噶尔盆地西北缘断裂构造带为例

前陆冲断带普遍具有构造分段的特点。横断层、侧断坡与斜断坡常是构造分段的边界 ,它们起着运动方向、变形速率、构造样式与成因机制转换的作用。准噶尔西北缘前陆冲断带是古生代晚期—中生代早期发展起来的大型冲断推覆系统 ,南自车排子 ,北至夏子街、红旗坝的大型断裂带为其冲断前锋断裂。由于形成时间、活动方式与受力条件等出现变化 ,车排子—夏子街断裂带被北西向的横断层分割为构造样式与地质结构截然不同的三段 ,南段为红山嘴—车排子断裂带 ,构成车排子断隆的东部逆冲边界 ;中段为具压扭性质的克拉玛依—百口泉断裂带 ;北段为具冲断推覆性质的乌尔禾—夏子街断裂带。中生代晚期—新生代以来该前陆冲断带被稳定埋藏 ,构造分段是导致含油气性差异的主要原因     

西秦岭勉略带陆内构造变形研究

秦岭造山带勉略缝合带是古特提斯洋盆向北俯冲形成的华北与华南最后拼接带。这个主缝合带俯冲-碰撞过程中以由北向南的一系列韧性逆冲推覆构造为特征,形成由前泥盆系、泥盆-石炭系和蛇绿混杂岩等不同构造岩片叠置的复杂构造带,碰撞时代从245Ma一直延续到230Ma左右。最近,作者对勉略缝合带内发育的韧性和脆性左行走滑剪切变形进行了研究,结果表明这些顺造山带的左行韧性走滑剪切变形带的变形时代为223±2Ma,与碰撞后花岗岩所确定的碰撞后构造环境的起始时间(225Ma)一致,显示这些韧性走滑剪切变形带是勉略带陆内变形初期变形产物。亦即华北、扬子大陆碰撞之后很快就转入陆内变形阶段,并且是以顺造山带的侧向走滑位移为主要变形方式。勉略带内顺造山带的脆性左行走滑断层的发育,表明这种顺造山带的侧向位移过程从深部到地壳浅层是一致的。因此,大陆碰撞在直接碰撞之后很快转变为顺造山带的侧向走滑位移为主的陆内变形,这种位移可能表现为两个大陆碰撞后的相对走滑,或是碰撞带中强烈变形部分顺造山带的侧向挤出,从而消减了正向碰撞所造成的地壳缩短和增厚。     

塔里木盆地北部构造转换形式及其成因

摘 要　 塔里木盆地北部褶皱 逆冲断层变形在平行于区域构造方向上通过构造转换而变化。 构造转换形式包括纵向(渐变)和横向(突变)两种。 变形缩短程度沿走向保持均一或渐变时发 生纵向转换, 其中包括雁列式断裂间的转换和逆冲断层向其他构造(末端背斜、 分支断层)的 转换, 横向转换调节变形缩短程度沿走向的突然变化。 在前陆盆地内, 横向转换带的发育主 要与沉积层厚度变化、 滑脱层分布、 造山带的作用程度和方式有关;前陆克拉通地区横向转 换带的发育则可能主要与板块边界形态等边界条件有关。 纵向转换带的发育与内在、 外在变 形条件沿走向的渐变有关     

Structural Mapping of the Bentong‐Raub Suture Zone Using PALSAR Remote Sensing Data,Peninsular Malaysia: Implications for Sediment‐hosted/Orogenic Gold Mineral Systems Exploration

The Bentong‐Raub Suture Zone (BRSZ) of Peninsular Malaysia is one of the major structural zones in Sundaland, Southeast Asia. It forms the boundary between the Gondwana‐derived Sibumasu terrane in the west and Sukhothai Arc in the east. The BRSZ is genetically related to the sediment‐hosted/orogenic gold deposits associated with the major lineaments in the Central Gold Belt of Peninsular Malaysia. In this investigation, the Phased Array type L‐band Synthetic Aperture Radar (PALSAR) satellite remote sensing data were used to map major geological structures in Peninsular Malaysia and provide detailed characterization of lineaments and curvilinear structures in the BRSZ, as well as their implication for sediment‐hosted/orogenic gold exploration in tropical environments. Major structural lineaments such as the Bentong‐Raub Suture Zone (BRSZ) and Lebir Fault Zone, ductile deformation related to crustal shortening, brittle disjunctive structures (faults and fractures) and collisional mountain range (Main Range granites) were detected and mapped at regional scale using PALSAR ScanSAR data. The major geological structure directions of the BRSZ were N–S, NNE–SSW, NE–SW and NW–SE, which derived from directional filtering analysis to PALSAR fine and polarimetric data. The pervasive array of N–S faults in the Central Gold Belt and surrounding terrain is mainly linked to the N–S trending of the Suture Zone. N–S striking lineaments are often cut by younger NE–SW and NW–SE‐trending lineaments. Gold mineralized trend lineaments are associated with the intersection of N–S, NE–SW, NNW–SSE and ESE–WNW faults and curvilinear features in shearing and alteration zones. Compressional tectonic structures such as the NW–SE trending thrust, ENE–WSW oriented faults in mylonite and phyllite, recumbent folds and asymmetric anticlines in argillite are high potential zones for gold prospecting in the Central Gold Belt. Three generations of folding events in Peninsular Malaysia have been recognized from remote sensing structural interpretation. Consequently, PALSAR satellite remote sensing data is a useful tool for mapping major geological structural features and detailed structural analysis of fault systems and deformation areas with high potential for sediment‐hosted/orogenic gold deposits and polymetallic vein‐type mineralization along margins of Precambrian blocks, especially for inaccessible regions in tropical environments.     

天山东段推覆构造研究

本文概括性总结了天山东段大型推覆构造的基本特征。根据地质证据和同位素年龄,东天山存在早古生代末,晚古生代晚期和新生代三期推覆构造;根据推覆构造分布规律及构造背景,在平面上划分为五大推覆带、9个大型韧剪带;根据出露岩石的矿物变形相将东天山推覆构造划分为深、中深和浅三个深度层次;通过韧剪变形组构的观察分析,确定了多期韧性变形性质与运动方向。糜棱岩中超微构造、古应力及小构造变形缩短率测量统计,证明东天山推覆变形具有显著的地壳缩短增厚作用。新生代板块碰撞导致本区中新生代盆地基底向造山带A型俯冲,造山带向盆地推覆,其结果就构成了今日看到的镶嵌状盆地-山脉构造地貌景观。     

Structural analysis of the Lombard thrust sheet and adjacent areas in the Helena salient,southwest Montana,USA

The Helena salient is a prominent craton–convex curve in the Cordillera thrust belt of Montana, USA. The Lombard thrust sheet is the primary sheet in the salient. Structural analysis of fold trends, cleavage attitudes, and movement on minor faults is used to better understand both the geometry of the Lombard thrust and the kinematic development of the salient.Early W–E to WNW–ENE shortening directions in the Lombard sheet are indicated by fold trends in the center of the thrust sheet. The same narrow range of shortening directions is inferred from kinematic analysis of movement on minor faults and the orientations of unrotated cleavage planes along the southern lateral ramp boundary of the salient. As the salient developed, the amount and direction of shortening were locally modified as listric detachment faults rotated some tight folds to the NW, and as right-lateral simple shear, caused by lock-up and folding of the Jefferson Canyon fault above the lateral ramp, rotated other folds northeastward. Where the lateral ramp and frontal-oblique ramp intersect, folds were rotated back to the NW. Our interpretation of dominant W–E to WNW–ESE shortening in the Lombard sheet, later altered by local rotations, supports a model of salient formation by primary parallel transport modified by interactions with a lateral ramp.     

秦岭南缘大巴山褶皱－冲断推覆构造的特征

秦岭造山带南缘的大巴山巨型逆冲推覆构造主要是在秦岭造山带板块俯冲碰撞造山与中、新生代以来陆内造山过程中长期复合作用形成的。详细的室内外构造研究表明,巴山逆冲推覆构造可以巴山弧形断裂带为界划分为北大巴山逆冲推覆构造和南大巴山逆冲推覆构造。北大巴山自北而南依次由安康－武当推覆体、紫阳－平利推覆体、高桥－镇坪推覆体和高滩推覆体逆冲叠置而成。南大巴山则以镇巴－阳日断裂为界,分为北部的前陆冲断褶皱带和南部的前陆褶皱带。北大巴山主要是印支期碰撞造山作用和燕山期陆内逆冲推覆作用叠加改造的结果,南大巴山则主要是燕山期递进变形过程中的产物。构造变形北强南弱,北以冲断褶皱变形为特征,南以皱褶作用为主;北部褶皱紧闭复杂,向南渐变为宽缓的薄皮构造。逆冲作用在时序上具有由北向南扩展传递的特点。     

Oblique collision and evolution of large-scale transcurrent shear zones in the Kaoko belt,NW Namibia

Early structures in the central part of the Kaoko orogenic belt of NW Namibia suggest that the initial stage of collision was governed by underthrusting of the medium-grade Central Kaoko zone below the high-grade Western Kaoko zone, resulting in the development of an inverted metamorphic gradient. In the Western zone, early structures were overprinted by a second phase of deformation, which is associated with localization of the transcurrent Puros shear zone along the contact between the Western and Central zones. During this second phase, extensive partial melting and intrusion of ∼550 Ma granitic bodies occurred in the high-grade Western zone. In the Central zone, the second phase of deformation led to complete overprinting of the early foliation in the zone adjacent to the Puros shear zone, and to the development of kilometre-scale folds in the more distal parts. Strain partitioning into transcurrent deformation along the Puros shear zone and NE–SW oriented shortening in the Central zone is consistent with a sinistral transpressional regime during the second phase of deformation. Transcurrent deformation continued during cooling of the entire belt, giving rise to the localized low-temperature Village Mylonite Zone that separates a segment of elevated Mesoproterozoic basement from the rest of the Western zone in which only Pan-African ages have so far been observed. The data suggest that the boundary between the Western and Central Kaoko zones represents a modified thrust zone controlling the tectonic evolution of the Pan-African Kaoko belt.     

龙门山断裂带印支期左旋走滑运动及其大地构造成因

位于青藏高原东缘的龙门山构造呈北东—南西向将松潘—甘孜褶皱带和华南地块分割开。前者主要是由一套巨厚的三叠纪复理石沉积组成 ,分布在古特提斯海的东缘。后者由前寒武纪基底和上覆的古生代和中生代沉积盖层组成。位于汶川—茂汶断裂以东的前龙门山存在一系列倾向北西的逆掩断层 ,它们将许多由元古宙和古生代岩层组成的断片向南东置于四川盆地的中生代红层之上 ,构成典型的薄皮构造。许多研究由此断定松潘—甘孜褶皱带和四川盆地之间在中生代发生过大规模的北西—南东向挤压。然而 ,汶川—茂汶断裂西侧的松潘—甘孜褶皱带内部的挤压构造线大多是垂直于而不是平形于龙门山断裂带 ,这表明当时的挤压应力不是北西—南东向而是北东—南西向。近年来在龙门山构造带内发现 ,在三叠纪时龙门山断裂带在发生推覆的同时还经历过大规模的北东—南西向的左旋走滑运动 ,协调走滑运动的主要构造为汶川—茂汶断裂。走滑运动的成因与松潘—甘孜褶皱带北东—南西向缩短有关。汶川—茂汶断裂的左旋走滑在龙门山的北东端被古特提斯海沿勉略俯冲带的消减和发生在大巴山的古生代 /中生代岩层的褶皱和冲断作用所吸收 ,在龙门山的南西端被古特提斯海沿甘孜—理塘俯冲带的消减和松潘—甘孜三叠纪复理石的褶皱和冲断作用所吸?     

华北板块南缘石人山岩块晚古生代陆内变形特征及侧向挤出构造

华北板块南缘在古生代时期经历了复杂的陆内变形过程。石人山岩块边界断裂发育大量平行于断裂带的A型褶皱和近水平的矿物生长线理,表明其经历了以走滑剪切变形为主的构造阶段。动力学研究表明石人山岩块具有南西向逆冲的运动学特征,其南侧洛南—栾川断裂带（洛栾断裂带）以左行剪切变形为主,北东侧鲁山断裂带以北西向逆冲兼有右行剪切变形为特征,夹于其中的石人山岩块显示为向西、向上挤出的特征。选择典型岩石样品进行同位素测年来限定断裂活动的时代,其中,洛栾断裂带内同构造花岗岩脉的锆石U- Pb定年结果为413. 6±7. 4 Ma,鲁山断裂带内走滑剪切特征明显的构造透镜体内变形岩石的锆石定年结果为419. 3±11. 2 Ma。虽然洛栾断裂与鲁山断裂的运动方向不同,但是同位素年代学研究限定了两条断裂带发生走滑变形的时间都是晚古生代泥盆纪末期,从而共同构成了石人山岩块整体向西挤出的构造特征,同时也表明,相互碰撞的大陆在碰撞之后将很快转变为以平行造山带侧向挤出与走滑位移为主的陆内变形演化阶段。     

楔形构造在山前冲断构造位移量消减中的作用

介于复活的天山造山带与稳定的准噶尔克拉通之间的准噶尔盆地南缘前陆冲断带,是印度板块与欧亚大陆碰撞的远距离效应产物,也是新近纪以来青藏高原隆升并向北推挤的直接结果。前陆冲断带吸收了来自造山带的水平缩短构造位移量后,克拉通一侧构造趋于稳定。准噶尔盆地南缘与世界上多数前陆冲断带构造地质特征相似,通过区域地震剖面的精细构造几何学和运动学解析,发现其中的楔形构造非常典型,是前陆冲断带内部冲断构造位移量消减的主要方式之一,控制着前陆冲断带分布范围和变形方式。准噶尔盆地南缘构造变形主要由南侧的天山造山带向北逆掩冲断,但是大部分冲断构造位移量是通过楔形构造反向传递后消减。紧邻天山北麓的齐古-喀拉扎-昌吉等构造带,山前深部的楔形体沿侏罗系西山窑组煤层向北扩展过程中,部分位移量沿构造楔顶部的反冲断层向南消减,并切割上覆地层形成第一排背斜带,另一部分位移量则继续向北传递,在断坡位置引发褶皱变形,形成霍-玛-吐第二排构造带和安集海-呼图壁第三排背斜带。准噶尔盆地南缘第二、三排构造带中-新生界内部发育多个小型的构造楔型体,这些互相叠置的楔型构造横向延伸不大,加大了构造变形的复杂性和构造圈闭识别的难度。