西准噶尔达拉布特断裂带中段晚古生代构造分析

走滑断裂构造在中亚造山带增生及演化过程的研究中扮演了重要角色,其主要构造单元均被走滑断裂带所分割。西准噶尔造山带是中亚增生型造山带的重要组成部分,达拉布特断裂是西准噶尔造山带中一条重要的走滑断裂,其复杂的构造表现吸引了大量研究者的关注。前人不仅在其构造解释上存在着走滑断层、逆冲断层或压扭性断层等诸多争议,且在其活动时代问题上也有不同的看法。本文依据在达拉布特断裂带中段开展的详细野外构造学工作,结合前人针对该地区石炭纪火山岩、浊积岩和造山后花岗岩侵入体所做的同位素年代学工作成果,对达拉布特断裂的活动性质和活动时代进行了讨论。结果确认在中二叠统沉积之前,达拉布特断裂带存在两期变形事件,分别对应于320Ma左右沿NE-SW的较深层次的左行走滑事件D1和表现为脆-韧性转换域的轴面倾向SE的褶皱作用构造事件D2。前者为主期变形事件,而后者发生在中二叠统沉积之前。本文同时报道了沿达拉布特断裂带出露右行走滑构造形迹,并讨论了其可能的成因。沿达拉布特断裂带的多期构造事件记录了西准噶尔地区造山后大规模走滑构造调整过程,是晚古生代晚期中亚各个陆块拼合后大规模陆内调整在西准噶尔造山带的具体体现。     

From oblique accretion to transpression in the evolution of the Altaid collage: New insights from West Junggar,northwestern China

Along active margins, tectonic features that develop in response to plate convergence are strongly controlled by subduction zone geometry. In West Junggar, a segment of the giant Palaeozoic collage of Central Asia, the West Karamay Unit represents a Carboniferous accretionary complex composed of fore-arc sedimentary rocks and ophiolitic mélanges. The occurrence of quasi-synchronous upright folds and folds with vertical axes suggests that transpression plays a significant role in the tectonic evolution of the West Junggar. Latest Carboniferous (ca. 300 Ma) alkaline plutons postdate this early phase of folding, which was synchronous with accretion of the Carboniferous complex. The Permian Dalabute sinistral fault overprints Carboniferous ductile shearing and split the West Karamay Unit ca. 100 km apart. Oblique convergence may have been provoked by the buckling of the Kazakh orocline and relative rotations between its segments. Depending upon the shape of the convergence zone, either upright folds and fold with vertical axes, or alternatively, strike–slip brittle faults developed in response to strain partitioning. Sinistral brittle faulting may account for the lateral imbrication of units in the West Junggar accretionary complex.     

A geological transect from Kun Lun to Karakorum (Sinkiang, China): the western termination of the Tibetan Plateau. Preliminary note

A geological-geophysical expedition (Ev-K2–CNR 1988) visited the area from West Kun Lun to Karakorum (K2–Gasherbrum). Seven tectonic units including sedimentary, magmatic and metamorphic rocks were distinguished in this area; the northernmost are suggested to belong to the Kun Lun and Qiangtang Microplates. The sedimentary sequence of Shaksgam is proved to extend from the Permian to the Jurassic, with Carboniferous and Cretaceous ages more doubtful. This sequence shows intermediate affinities between the Karakorum and the Qiangtang. The two southernmost units belong to the Karakorum Microplate. The Karakorum Fault Zone comprises a complex pattern of faults and thrusts, with brittle deformation and uplifting of granitoid bodies.     

Southern margin of the Variscan belt: the north-western Gondwana mobile zone (eastern Morocco and Northern Algeria)

Stratigraphic and structural correlations between the Palaeozoic massifs of eastern Morocco and northern Algeria allow three tectonic domains to be distinguished: (1) The cratonic zone, i.e. the West African platform which remained outside the Variscan chain and its peripherical margin (Moroccan Anti-Atlas and Algerian Ougarta); (2) a WSW-ENE trending zone, over 1500 km from Marrakech to Kabylia and Calabria (in their assumed Palaeozoic location). — This zone was characterized during the Late Palaeozoic by a continuous instability indicated by the development of successive turbiditic basins and a major orogeny at the Devonian-Carboniferous boundary; and (3) central and western Morocco, which corresponds to the external zones of the European Hercynides.The Marrakech-Kabylia zone separates the Variscan domain from the stable and undeformed West African craton. During Early Palaeozoic times it began as an extensive or transtensive zone. It has been deformed by the Late Devonian orogeny and by Carboniferous and Permian reactivation. The zone represents the southern limit of the Hercynian chain and is distinguished by its transcurrent regime throughout the Late Palaeozoic. Correspondence to: A. Piqué     

马朗凹陷断裂-烃源岩空间配置关系与石油垂向运移特征

马朗凹陷的原油类型可以划分为3大类,Ⅰ类原油来自二叠系芦草沟组,Ⅱ类原油来自石炭系哈尔加乌组,Ⅲ类原油为Ⅰ与Ⅱ类原油的混源油。通过断裂活动强度、垂向输导断裂与烃源岩的匹配关系的研究,结合原油含氮化合物的分析资料,分析了马朗凹陷油气的垂向运移特征。研究表明,断层的断裂活动强度控制着油气的垂向运移能力,垂向输导断裂与烃源岩相匹配时,烃源岩生成的油气才能向上运移至上覆地层聚集成藏。二叠系芦草沟组烃源岩厚度中心附近的垂向输导断裂断穿侏罗系,所以,芦草沟组烃源岩生成的Ⅰ类原油可以运移至侏罗系聚集成藏,而石炭系哈尔加乌组烃源岩附近的断裂大都未断至二叠系和侏罗系,所以哈尔加乌组烃源岩生成的Ⅱ类原油未能运移到侏罗系聚集成藏,而主要在石炭系成藏。与断裂输导分析相配合,含氮化合物可以很好示踪油气的垂向运移方向,沿断裂从深层到浅层,原油含氮化合物总浓度逐渐降低,1,8DMC/1,3 DMC或1,8DMC/2,4 DMC值增大。     

东非凯瑞巴斯盆地多期构造变形及对油气聚集的控制作用

利用最新的钻井、地震资料,对东非凯瑞巴斯盆地(Kerimbas Basin)进行构造–地层解释和构造演化过程恢复。结果显示,凯瑞巴斯盆地共发育了4期构造变形:(1)二叠纪–早侏罗世晚期的冈瓦纳陆内裂谷活动,全区发生伸展构造变形;(2)早侏罗世晚期–早白垩世晚期马达加斯加向南漂移,全区发生右行走滑变形;(3)新发现晚白垩世局部伸展构造变形;(4)中新世–第四纪的东非裂谷海域分支活动,导致研究区发生第三期伸展构造变形,形成凯瑞巴斯盆地现今地堑形态。三期伸展构造变形的应力方向均为近E-W向,断层展布方向均为近S-N向。每一期构造变形的范围,强度及对沉积地层的控制作用差异显著。凯瑞巴斯盆地控坳断层活动具有继承性。基于研究结果,建立凯瑞巴斯盆地构造成因模式。冈瓦纳陆内裂谷活动有利于二叠系–下侏罗统构造圈闭的形成,并沟通了烃源岩和储层,有利深层油气的聚集;东非裂谷海域分支裂谷活动沟通了前新生界烃源岩和西部陆坡古近系储层,但同时也破坏了盆地内及东部的圈闭。断层不发育的西部陆坡为主要油气聚集区。     

Normal fault linkage and reactivation,Dampier Sub-basin,Western Australia

The Northern Carnarvon Basin of Western Australia has experienced a polyphase deformation history during the breakup of Gondwana. Extension during the Carboniferous–Permian and a subsequent Early Jurassic rift event imposed two distinct fault systems, separated by a several kilometre-thick Triassic sedimentary sequence. Inboard areas, where Triassic sequences are thinner, Jurassic faults both detach above and also penetrate into Permian sequences. Other large-scale faults demonstrate a vertical hard/soft linkage between the two fault systems. In outboard areas where the Triassic is thicker, the relationship is less clear owing to the lower resolution of Permian sequences in seismic data. Here we undertake fault displacement analysis on three faults on the southern margin of the Exmouth Plateau to investigate the growth mechanism of Jurassic-aged faults and possible structural influence of deeper Permian faults. We find evidence of low-throw faults restricted to Mesozoic strata as more complex-segmented faults that have nucleated at a depth below that resolvable on seismic data. When considered in a regional context, the nature of faults in this study suggest oblique reactivation of the NE-trending Permian fabric, under east–west-oriented extension.     

Structure and tectonics along the inner edge of a foreland basin: The Hunter Coalfield in the northern Sydney Basin,New South Wales

From the early Late Permian onwards, the northeastern part of the Sydney Basin, New South Wales, (encompassing the Hunter Coalfield) developed as a foreland basin to the rising New England Orogen lying to the east and northeast. Structurally, Permian rocks in the Hunter Coalfield lie in the frontal part of a foreland fold‐thrust belt that propagated westwards from the adjacent New England Orogen. Thrust faults and folds are common in the inner part of the Sydney Basin. Small‐scale thrusts are restricted to individual stratigraphic units (with a major ‘upper decollement horizon’ occurring in the mechanically weak Mulbring Siltstone), but major thrusts are inferred to sole into a floor thrust at a poorly constrained depth of approximately 3 km. Folds appear to have formed mainly as hangingwall anticlines above these splaying thrust faults. Other folds formed as flat‐topped anticlines developed above ramps in that floor thrust, as intervening synclines ahead of such ramp anticlines, or as decollement folds. These contractional structures were overprinted by extensional faults developed during compressional deformation or afterwards during post‐thrusting relaxation and/or subsequent extension. The southern part of the Hunter Coalfield (and the Newcastle Coalfield to the east) occupies a structural recess in the western margin of the New England Orogen and its offshore continuation, the Currarong Orogen. Rocks in this recess underwent a two‐stage deformation history. West‐northwest‐trending stage one structures such as the southern part of the Hunter Thrust and the Hunter River Transverse Zone (a reactivated syndepositional transfer fault) developed in response to maximum regional compression from the east‐northeast. These were followed by stage two folds and thrusts oriented north‐south and developed from maximum compression oriented east‐west. The Hunter Thrust itself was folded by these later folds, and the Hunter River Transverse Zone underwent strike‐slip reactivation.     

西秦岭甘加地区OIB型钾质拉斑玄武岩的发现:对西秦岭晚中生代大陆裂谷作用的启示

西秦岭晚中生代火山岩出露于青海省泽库县多福屯地区、甘肃省夏河县红墙和甘加地区。初步研究表明,甘加火山岩属于一套钾质拉斑玄武岩。该玄武岩富集REE、LILE及HFSE,但轻、重稀土元素分馏程度及不相容元素含量均略低于典型OIB和西秦岭晚中生代钠质碱性玄武岩。岩浆起源于软流圈释放的小体积富挥发份硅酸盐熔体交代形成的富集岩石圈地幔,并在上升中经历了较大程度的镁铁质矿物的分离结晶作用。岩石具有典型的陆内OIB成因特点,既不同于前人提出的甘加海山玄武岩,也不属于“二叠纪隆务峡-甘加蛇绿岩”组成部分,而与西秦岭晚中生代钠质碱性玄武岩均为大陆裂谷系OIB型岩浆作用的产物。甘加玄武岩可能具有比较复杂的岩石组合,跨越了晚古生代到晚中生代的一个较长时间范围。西秦岭晚中生代的大陆裂谷作用夭折于岩石圈拉张的早期阶段,它的出现及研究区广泛发育的近SN向或NW向断裂,可能是贺兰-川滇南北构造带与大型走滑断裂系复杂叠加并相互影响与改造的表现。     

Mesozoic paleostress evolution in the Saharian platform (southern Tunisia)

Abstract

A detailed analysis of brittle deformations in the Saharian platform of southern Tunisia is based on studies of fault-slip data sets and joint sets. It allows reconstruction of the Mesozoic paleostress evolution. During the Permo-Triassic, N-S extensions occurred with high late Permian subsidence rates. During the Norian, strike-slip movements reactivated former normal faults. During the Jurassic and the Cretaceous a succession of extensional events was characterized by : (1) a N-S extension which dominated from late Triassic to early Aptian. We relate this extension to the Africa-Eurasia divergence; (2) a ENE-WSW extension during the Cenomanian. We relate this extension to the opening of «he African basins ; (3) a NE-SW Senonian extension that continued during the Cenozoic in the Jeffara and in the Gabes Gulf, during the further evolution of the northern African margin. The various compressional trends recorded in the platform are attributed to Cenozoic events.     

Late Permian–early Middle Triassic back-arc basin development in West Qinling,China

The Late Permian–early Middle Triassic strata of the northern West Qinling area, northeastern Tibetan Plateau, are composed of sediment gravity flow deposits. Detailed sedimentary facies analysis indicates these strata were deposited in three successive deep-marine environments. The Late Permian–early Early Triassic strata of the Maomaolong Formation and the lowest part of the Longwuhe Formation define a NW–SE trending proximal slope environment. Facies of the Early Triassic strata composing the middle and upper Longwuhe Formation are consistent with deposition in a base-of-slope apron environment, whereas facies of the Middle Triassic Anisian age Gulangdi Formation are more closely associated with a base-of-slope fan depositional environment. The lithofacies and the spatial–temporal changes in paleocurrent data from these strata suggest the opening of a continental margin back-arc basin system during Late Permian to early Middle Triassic time in the northern West Qinling. U–Pb zircon ages for geochemically varied igneous rocks with diabasic through granitic compositions intruded into these deep-marine strata range from 250 to 234 Ma. These observations are consistent with extensional back-arc basin development and rifting between the Permian–Triassic Eastern Kunlun arc and North China block during the continent–continent collision and underthrusting of the South China block northward beneath the Qinling terrane of the North China block. Deep-marine sedimentation ended in the northern West Qinling by the Middle Triassic Ladinian age, but started in the southern West Qinling and Songpan-Ganzi to the south. We attribute these observations to southward directed rollback of Paleo-Tethys oceanic lithosphere, continued attenuation of the West Qinling on the upper plate, local post-rift isostatic compensation in the northern West Qinling area, and continued opening of a back-arc basin in the southern West Qinling and Songpan-Ganzi. Rollback and back-arc basin development during Late Permian to early Middle Triassic time in the West Qinling area explains: the truncated map pattern of the Eastern Kunlun arc, the age difference of deep-marine sediment gravity flow deposits between the Late Permian–early Middle Triassic northern West Qinling and the late Middle Triassic–Late Triassic southern West Qinling and Songpan-Ganzi, and the discontinuous trace of ophiolitic rocks associated with the Anyemaqen-Kunlun suture.     

An Alleghenian orocline: the Asturian Arc,northwestern Spain

The Asturian Arc was produced in the Early Permian by a large E–W dextral strike–slip fault (North Iberian Megashear) which affected the Cantabrian and Palentian zones of the northeastern Iberian Massif. These two zones had previously been juxtaposed by an earlier Kasimovian NW–SE sinistral strike–slip fault (Covadonga Fault). The occurrence of multiple successive vertical fault sets in this area favoured its rotation around a vertical axis (mille-feuille effect). Along with other parallel faults, the Covadonga Fault became the western margin of a proto-Tethys marine basin, which was filled with turbidities and shallow coal-basin successions of Kasimovian and Gzhelian ages. The Covadonga Fault also displaced the West Asturian Leonese Zone to the northwest, dragging along part of the Cantabrian Zone (the Picos de Europa Unit) and emplacing a largely pelitic succession (Palentian Zone) in what would become the Asturian Arc core. The Picos de Europa Unit was later thrust over the Palentian Zone during clockwise rotation. In late Gzhelian time, two large E–W dextral strike–slip faults developed along the North Iberian Margin (North Iberian Megashear) and south of the Pyrenean Axial Zone (South Pyrenean Fault). The block south of the North Iberian Megashear and the South Pyrenean Fault was bent into a concave, E-facing shape prior to the Late Permian until both arms of the formerly NW–SE-trending Palaeozoic orogen became oriented E–W (in present-day coordinates). Arc rotation caused detachment in the upper crust of the Cantabrian Zone, and the basement Covadonga Fault was later resurrected along the original fault line as a clonic fault (the Ventaniella Fault) after the Arc was completed. Various oblique extensional NW–SE lineaments opened along the North Iberian Megashear due to dextral fault activity, during which numerous granitic bodies intruded and were later bent during arc formation. Palaeomagnetic data indicate that remagnetization episodes might be associated with thermal fluid circulation during faulting. Finally, it is concluded that the two types of late Palaeozoic–Early Permian orogenic evolution existed in the northeastern tip of the Iberian Massif: the first was a shear-and-thrust-dominated tectonic episode from the Late Devonian to the late Moscovian (Variscan Orogeny); it was followed by a fault-dominated, rotational tectonic episode from the early Kasimovian to the Middle Permian (Alleghenian Orogeny). The Alleghenian deformation was active throughout a broad E–W-directed shear zone between the North Iberian Megashear and the South Pyrenean Fault, which created the basement of the Pyrenean and Alpine belts. The southern European area may then be considered as having been built by dispersal of blocks previously separated by NW–SE sinistral megashears and faults of early Stephanian (Kasimovian) age, later cut by E–W Early Permian megashears, faults, and associated pull-apart basins.     

世界二叠纪生物礁的基本特征及其古地理分布

世界上早二叠世生物礁分布于泛大陆的西北陆棚、乌拉尔山脉的西侧、美国的二叠盆地等地,并集中分布于前两个地区。其早期,以Palaeoaplysina礁或Palaeoaplysina和叶状藻礁占优势,而至晚期则形成以Shamovella (Tubiphytes)和苔藓虫为骨架的礁。中二叠世栖霞期的礁仅发现于北美格拉斯山脉、帕米尔和我国的阿尔格山等地。茅口期的礁是世界上最发育的生物礁之一,北美瓜德罗普山脉的二叠纪礁已成为世界上最典型的礁,其相带分异之清晰堪称为世界之最。北非突尼斯的礁也是研究程度较高的礁之一。中二叠世的礁以海绵、苔藓虫、Shamovella的大量出现为特征,古石孔藻、Shamovella和笛苔藓虫是常见的包覆生物。晚二叠世生物礁分布于欧洲镁灰岩统盆地、特提斯海西缘和最北缘的陆棚以及特提斯海域内的一些地体。我国晚二叠世礁十分发育,成为世界二叠纪礁的一个亮点。礁内的造架生物以珊瑚海绵为主,包括房室海绵和纤维海绵,古石孔藻和Shamovella (Tubiphytes)作为常见的包覆联结生物。     

Relationships between gold concentration and structure in quartz veins from the Hodgkinson Province, northeastern Australia

The Hodgkinson Province is a tract of␣multiply deformed Silurian-Devonian rocks in north␣Queensland, Australia. Gold-bearing quartz veins from the West Normanby Goldfield in the northern Hodgkinson Province were emplaced during the Permian D₄ event, broadly coeval with regional granite emplacement. Taylors Fault, a major structure that formed during D₂, hosts the veins which infill dilatational jogs opened during sinistral-normal reactivation of the fault in D₄. Veins contain graphitic laminations that formed when fault planes segmented wallrocks adjacent to the veins, producing tabular clasts that were tectonically sliced into the reefs. Laminations are the result of progressive shear strain, associated with continued movement on the faults, which caused strain-enhanced dissolution of silicate minerals and residual graphite enrichment in the clasts. This process produced graphite-coated shear planes that delimit zones of grain size reduction in the veins. Laminations commonly contain stylolites, which nucleated on pronounced sinuosities of the shear planes due to progressive shortening during D₄. Gold particles have preferentially nucleated in zones of relatively coarser-grained quartz adjacent to the shear planes, where shortening strain caused microfracturing and allowed fluid access. Gold may have been introduced with the quartz, but was redistributed within the reefs and localized along the laminations by the effects of synchronous, progressive deformation. Regionally, gold deposits show close spatial relationships with granite plutons of the Permian Whypalla Supersuite. Relationships in the West Normanby Gold Field support a regional model of reef emplacement and gold mineralization during the Permian D₄ event. Received: 24 August 1997 / Accepted: 14 October 1997     

Palaeozoic multiphase magmatism at Barleik Mountain,southern West Junggar,Northwest China: implications for tectonic evolution of the West Junggar

The West Junggar lies in the southwest part of the Central Asian Orogenic Belt (CAOB) and consists of Palaeozoic ophiolitic mélanges, island arcs, and accretionary complexes. The Barleik ophiolitic mélange comprises several serpentinite-matrix strips along a NE-striking fault at Barleik Mountain in the southern West Junggar. Several small late Cambrian (509–503 Ma) diorite-trondhjemite plutons cross-cut the ophiolitic mélange. These igneous bodies are deformed and display island arc calc-alkaline affinities. Both the mélange and island arc plutons are uncomfortably covered by Devonian shallow-marine and terrestrial volcano-sedimentary rocks and Carboniferous volcano-sedimentary rocks. Detrital zircons (n = 104) from the Devonian sandstone yield a single age population of 452–517 million years, with a peak age of 474 million years. The Devonian–Carboniferous strata are invaded by an early Carboniferous (327 Ma) granodiorite, late Carboniferous (315–311 Ma) granodiorites, and an early Permian (277 Ma) K-feldspar granite. The early Carboniferous pluton is coeval with subduction-related volcano-sedimentary strata in the central West Junggar, whereas the late Carboniferous–early Permian intrusives are contemporary with widespread post-collisional magmatism in the West Junggar and adjacent regions. They are typically undeformed or only slightly deformed.

Our data reveal that island arc calc-alkaline magmatism occurred at least from middle Cambrian to Late Ordovician time as constrained by igneous and detrital zircon ages. After accretion to another tectonic unit to the south, the ophiolitic mélange and island arc were exposed, eroded, and uncomfortably overlain by the Devonian shallow-marine and terrestrial volcano-sedimentary strata. The early Carboniferous arc-related magmatism might reflect subduction of the Junggar Ocean in the central Junggar. Before the late Carboniferous, the oceanic basins apparently closed in this area. These different tectonic units were stitched together by widespread post-collisional plutons in the West Junggar during the late Carboniferous–Permian. Our data from the southern West Junggar and those from the central and northern West Junggar and surroundings consistently indicate that the southwest part of the CAOB was finally amalgamated before the Permian.     

塔里木盆地中部阿-满低梁带断裂构造分析

塔里木盆地北部坳陷中部存在一个北东-南西方向的下古生界的（鞍状）低梁带（阿-满低梁带）。它是阿瓦提凹陷和满加尔凹陷之间的天然分界,以此低梁带的脊线划分出两个凹陷。以三维地震资料解释为依据,本文研究了阿-满低梁带的断裂构造特征。研究区主要发育4期断裂构造：1）南华纪-奥陶纪的正断层与罗迪尼亚超大陆的裂解有关,并可进一步划分为南华纪-震旦纪和寒武纪-奥陶纪两个断裂活动阶段。南华纪-震旦纪正断层的成因是罗迪尼亚超大陆的裂解作用,形成堑垒构造,寒武纪-奥陶纪正断层的成因是塔里木自罗迪尼亚超大陆裂解出来后,游离于古特提斯洋所处的区域性弱伸展构造背景,形成负花状构造。2）晚奥陶世-中志留世断层包括晚奥陶世-志留纪初的滑脱-冲断构造和早-中志留世的挤压走滑断裂,形成断层传播褶皱和正花状构造。其形成的动力来源是昆仑加里东碰撞造山作用。3）晚志留世-石炭纪正断层是昆仑加里东碰撞造山后构造应力松弛阶段的产物,形成典型的负花状构造,组合成雁列状张扭性断层带。4）二叠纪正断层是大陆裂谷作用的结果,往往受相关岩浆作用的改造。剖面上形成堑垒构造和负花状构造,平面上组合成雁列状张扭性断层带。二叠纪断裂与晚志留世-石炭纪的断裂可能有继承关系。     

Seismic reflection evidence for the evolution of the Camden Syncline and Lapstone Structural Complex,central Sydney Basin,Australia

The Camden Syncline and the Lapstone Structual Complex are two major geological features of the central Sydney Basin. We have interpreted over 500 km (45 lines) of an unpublished recenty reprocessed seismic dataset as a means to elucidating the evolution of both features. Major horizons observed in the seismic data have been described and correlated with significant tectonic events that shaped the formation of the greater Sydney–Gunnedah–Bowen Basin; namely Early Permian extension, mid-Permian passive thermal subsidence and Late Permian to mid-Triassic foreland loading. Horizon mapping shows that the Camden Syncline is a broad north-northeast plunging structure whose western limb is truncated by the north–south trending faults and folds of the Lapstone Structural Complex. Furthermore, isochron maps reveal that the Late Permian to mid-Triassic sedimentary succession thickens towards the axis of the Camden Syncline, thus confirming it's role as a depocentre during this period of basin evolution. No abrupt thickening is observed in the Late Permian to mid-Triassic sedimentary succession in the vicinity of the Lapstone Structural Complex indicating that the Lapstone Structural Complex was formed subsequent to the deposition of the Permian–Triassic Sydney Basin sedimentary succession. Furthermore, our interpretation of the reprocessed seismic data confirms that the major structural style of the Lapstone Structural Complex is that of west dipping reverse faults and east facing monoclines.     

西准噶尔阿克巴斯陶岩体三维形态及其地质意义

西准噶尔地区广泛发育晚石炭世-二叠纪不同规模、形态各异的花岗岩体,阿克巴斯陶岩体是其中最具代表性岩体之一,但对于该岩体三维形态和侵位过程的研究尤显薄弱.基于详细的野外路线地质调查,通过对阿克巴斯陶岩体NE、NW、SE和SW侧接触边界产状、接触热变质带宽度、岩脉方位和发育程度、顶垂体和围岩捕虏体发育特征的研究,揭示出岩体NE、SE和SW侧与围岩呈低角度外倾接触,而岩体NW侧与围岩呈高角度接触.在此基础上,结合岩体出露区音频大地电磁反演结果,揭示出阿克巴斯陶岩体三维形态总体为不对称蘑菇状,岩体侵位时岩浆主要由NW向朝SE向斜向侵位,并建立了岩体的三维形态模型.阿克巴斯陶岩体三维形态的确定,揭示了西准噶尔地区晚石炭世晚期-早二叠世为后造山伸展环境.      

塔里木盆地塔中低凸起北斜坡古生代断裂展布与构造演化

通过对塔中低凸起北斜坡4500km2三维地震数据体的精细解析,根据不整合面和生长地层分析以及断层与地层之间的接触关系,厘定划分出四期不同应力性质的断裂体系,分别为寒武-早奥陶世拉张断裂,晚奥陶世冲断挤压和北西向走断裂,志留-泥盆纪北东向走滑断裂以及二叠纪的岩浆刺穿。寒武-早奥陶世拉张断裂展布形态和发育规模奠定了后期构造活动的基础;晚奥陶世断裂呈发散的帚状,向东南方向收敛,断裂分布具有明显的分带和分段性,东部主要为逆冲断裂,中西部发育北西向走滑断裂,晚奥陶世断裂体系可划分为六组呈北西向展布的弧型断裂带,各弧形断裂带由多条断裂组成,其形成可能与古生代阿尔金北缘北西向冲断挤压有关;塔中志留-泥盆纪走滑断裂体系主要是在挤压应力环境下形成的,呈北东向展布,走滑断裂体系由三部分组成：主干边界断裂、尾端羽列断裂和拉分地堑,其中主干断裂剖面上表现为高角度近似直立断面,直插基底,延伸较远,剖面上呈花状构造,尾端羽列断裂在主干断层的尾端发育,主要位于主干断裂的北端,拉分地堑平面上呈菱形,受多级断层控制;二叠纪岩浆刺穿在塔中三维区呈点状或条带状,岩浆刺穿对早期断裂进行叠置和改造,岩浆侵入和底辟作用致使地层隆升,形成一系列逆断层性质的“正花状构造”。构造活动决定了断裂发育,早古生代塔里木盆地及其周缘地区伸展－聚敛构造演化构成了一个较为完整的威尔逊旋回,寒武纪－早奥陶世塔里木周缘古大洋拉张裂解,早奥陶世末－晚奥陶世部分古大洋俯冲消减,晚奥陶世－泥盆纪周缘大洋部分闭合,发生弧陆或陆陆碰撞,二叠纪岩浆活动代表了另一个构造旋回的开始。     

Restoration of Exotic Terranes Along the Median Tectonic Line, Japanese Islands: Overview

This paper reviews recent progress on the geotectonic evolution of exotic Paleozoic terranes in Southwest Japan, namely the Paleo-Ryoke and Kurosegawa terranes. The Paleo-Ryoke Terrane is composed mainly of Permian granitic rocks with hornfels, mid-Cretaceous high-grade metamorphic rocks associated with granitic rocks, and Upper Cretaceous sedimentary cover. They form nappe structures on the Sambagawa metamorphic rocks. The Permian granitic rocks are correlative with granitic clasts in Permian conglomerates in the South Kitakami Terrane, whereas the mid-Cretaceous rocks are correlative with those in the Abukuma Terrane. This correlation suggests that the elements of Northeast Japan to the northeast of the Tanakura Tectonic Line were connected in between the paired metamorphic belt along the Median Tectonic Line, Southwest Japan. The Kurosegawa Terrane is composed of various Paleozoic rocks with serpentinite and occurs as disrupted bodies bounded by faults in the middle part of the Jurassic Chichibu Terrane accretionary complex. It is correlated with the South Kitakami Terrane in Northeast Japan. The constituents of both terranes are considered to have been originally distributed more closely and overlay the Jurassic accretionary terrane as nappes. The current sporadic occurrence of these terranes can possibly be attributed to the difference in erosion level and later stage depression or transtension along strike-slip faults. The constituents of both exotic terranes, especially the Ordovician granite in the Kurosegawa-South Kitakami Terrane and the Permian granite in the Paleo-Ryoke Terrane provide a significant key to reconstructing these exotic terranes by correlating them with Paleozoic granitoids in the eastern Asia continent.