塔里木板块北缘前陆盆地的构造演化及其与油气的关系

循天山地区板块构造作用这主线,系统地讨论塔里木板块北缘前陆盆地和类前陆盆的构造演化,将前陆盆地和类前陆盆和类前陆盆地划分为两个阶段,指出前陆盆地演化具从不稳定向稳定发展的特征。早期前陆盆地以深水复理石建造为主,夹火山岩建造,晚期前陆盆地以磨拉石建造为主。前陆盆地和前陆隆起具横向和纵向上的迁移性,这种特性影响了类前陆盆地的演化和油气分布。     

The South Westland Basin: seismic stratigraphy, basin geometry and evolution of a foreland basin within the Southern Alps collision zone, New Zealand

This paper develops further the case for a foreland basin origin of South Westland Basin, located adjacent to the Southern Alps mountain belt. Geohistory analyses show Middle Miocene initiation of subsidence in the basin, with marked increases at 5–6 Ma. Five seismic reflection horizons, including basement, Middle Miocene (top Awarua Limestone), top Miocene, mid-Pliocene (PPB) and mid-Pleistocene (PPA) have been mapped through the grid of seismic data. A series of five back-stripped structure contour maps taken together with five isopach maps show that prior to the Middle Miocene, subsidence and sedimentation occurred mainly along the rifted continental margin of the Challenger Plateau facing the Tasman Sea; subsequently it shifted to a foredeep trending parallel to the Southern Alps and located northwest of them. Through the Late Miocene–Recent this depocentre has progressively widened, and the loci of thickest sediment accumulation have moved northwestward, most prominently during the Late Pliocene and Pleistocene with the progradation of a shelf–slope complex. At the northern end of the basin the shelf–slope break is currently located over the forebulge, which appears not to have migrated significantly, probably because the mountain belt is not advancing significantly northwestwards. Modelling of the lithospheric flexure of the basement surface normal to the trend of the basin establishes values of 3.1 to 9.8×10²⁰ N m for the flexural rigidity of the Australia Plate. This is at the very low end of rigidities for plates, and 1–2 orders of magnitude less than for the Australia Plate beneath the Taranaki Basin. Maps of tectonic subsidence where the influence of sediment loading is removed also clearly identify the source of the loading as lying within or beneath the mountain belt. The basin fill shows a stratigraphic architecture typical of underfilled ancient peripheral foreland basins. This comprises transgressive (basal unconformity, thin limestone, slope-depth mudstone, flysch sequence) and regressive (prograding shelf–slope complex followed by molasse deposits) components. In addition the inner margin of the basin has been inverted as a result of becoming involved in the mountain building, as revealed earlier by fission track thermochronological data. The timing and degree of inversion fits well with the geometrical and stratigraphic development of the basin. That the inversion zone and the coastal plain underlain by molasse deposits are narrow, and most of the basin is beneath the sea, highlights this as an underfilled active foreland basin. The basin is geodynamically part of the Southern Alps collision zone.     

云南楚雄前陆盆地晚三叠世沉积建造及盆地演化

根据沉积建造的类型、系列和体态认为楚雄盆地在晚三叠世经历了３个明显的发育阶段：第一阶段为早期聚敛碰撞阶段,发育了黑色页岩建造和碳酸盐复理石建造;第二阶段为构造相对静止期,发育了火山复理石建造和陆源复理石建造;第三阶段为盆地充填阶段,发育了海相磨拉石建造和陆相磨拉石建造。３个阶段中的沉积建造属于次稳定型和非稳定型两大类。     

塔里木北部周缘前陆盆地早二叠世快速迁移与沉积相突变:俯冲板片拆沉的响应

塔里木北部周缘前陆盆地发育于泥盆纪末至早三叠世期间,完整地记录了南天山造山带的发育过程。该盆地在早二叠世由复理石盆地转化为磨拉石盆地,同时发生快速南移。同期幔源物质加入,有山根地壳熔融的岩浆活动、南天山造山带的整体隆升、热液成矿作用集中发育和变形、变质作用的激化使俯冲岩片的拆沉成为盆地转化与迁移的最佳机制。相同的转化过程及深部机制在其他造山带中也明显存在,表明俯冲岩片拆沉是造山作用一个不可或缺的环节。     

From Flysch to Molasse——Sedimentary and Tectonic Evolution of Late Caledonian-Early Hercynian Foreland Basin in North Qilian Mountains

The Late Caledonian to Early Hercynian North Qilian orogenic belt in northwestern China is an elongate tectonic unit situated between the North China plate in the north and the Qaidam plate in the south. North Qiilan started in the latest Proterozoic to Cambrian as a rift basin an the southern mar-gin of North China, and evolved later to an archipelagic ocean and active continental margin during the Ordovician and a fardand basin from Silurian to the Early and Middle Devonian. The Early Silurian fly-sch and sulmmrine alluvial fan, the Middle to Late Silurian shallow marine to tidal flat deposits and the Early and Middle Devonian terrestrial.molasse are developed along the corridor Nansimn. The shallo-wing-upward succession from subabyssal flysch, shallow marine, tidal flat to terrestrial molasse and its gradually narrowed regional distribution demonstrate that the foreland basin experienced the transition from flysch stake to molasse stake during the Silurian and Devonian time.     

Synsedimentary tectonics of the Palaeozoic of the Drahany Upland (Sudeticum, Moravia, Czechoslovakia)

Southern parts of the Moravian Palaeozoic afford a good example of the complicated interrelationship between geosynclinal sedimentation and tectonics. The function of transverse deep-seated synsedimentary faults, separating the basin into big transverse blocks, is described in detail. The mobility of the basement of the individual transverse blocks influence sediment development, thickness, and the intensity of their deformation. The flysch and molasse facies complexes display a close relationship with the lifting of intermountain blocks and subsidence of basins. The clastic material was transported transverse to the basin axis. Where transverse axial depressions occur coarse clastic material accumulated as alluvial fans. This material was reworked by lateral currents and distributed parallel to the basin axis, within the limits of the zone of maximum subsidence. This zone of maximum subsidence shifted from the intermountain block toward the foreland (geosynclinal polariry in the sense of Aubouin, 1965). The transverse blocks with maximum sediment thickness (mainly those belonging to pre-flysch and flysch facies complexes) display the most distinct polarity and most intense sediment deformation. By contrast, transverse blocks with sedimentary sequences of small thickness (where carbonate, and eventually molasse facies complexes prevail) lack the pronounced polarity and are less deformed. Our observations lead to the conclusion that dilation stage of geosyncline development did not exist in the course of the deposition of pre-flysch facies complex.     

西秦岭礼岷前陆盆地构造演化与多金属成矿探讨

礼岷前陆盆地经历了早期深海—半深海的复理石沉积阶段和晚期陆相磨拉石沉积阶段。该盆地在成盆及盆山转换过程中在其前渊、隆后盆地以及褶皱冲断带内形成了Au、Ag、Pb、Zn、Cu、Mo等多金属矿床。     

秦岭加里东晚期-华力西早期复式前陆盆地

南秦岭西段的志留纪－早泥盆世及中秦岭北缘的志留纪－早石炭世的沉积特征表明,两区均存在有早期理里石相和晚期磨拉石相,构成完整的前陆盆地充填序列,并由冲断造山 －前渊－前隆３部分构成完整的前陆盆地体系,南秦岭前陆盆地是扬子北缘裂陷盆地闭合的产物,形成于４３０Ｍａ,结束于３９０Ｍａ,历时４０Ｍａ,属板内前陆盆地,中秦岭前陆盆地位于扬子北缘的边缘,是秦岭洋闭合后的产物,形成于４４０Ｍａ,结束于３２３Ｍａ,历时１０７Ｍａ,属周缘前陆盆地,北秦岭二郎坪弧后陆盆地的上限是３２０Ｍａ,是在另里东晚期－华力西早期于陆－弧－陆碰撞的背景下形成３种类型的前陆盆地,它们组成了秦岭复式前陆盆地,总历程达１２０Ｍａ。     

巴颜喀拉-川西边缘前陆盆地演化

巴颜喀拉古特提斯洋的消亡过程反映在巴颜喀拉残留盆地到边缘前陆盆地的转化的沉积记录中。鉴于这个前陆盆地与其向克拉通延伸的组成部分－四川盆地现为龙门山逆冲带所分隔，以致已往的沉积盆地研究多针其相割裂，本文将结合巴颜喀拉洋的消亡过程，把这两个盆地视为一个统一整体来加以分析，研究其演变历程。     

巴颜喀拉-川西边缘前陆盆地演化

巴颜喀拉古特提斯洋的消亡过程反映在巴颜喀拉残留盆地到边缘前陆盆地转化的沉积记录中。鉴于这个前陆盆地与其向克拉通延伸的组成部分——四川盆地现为龙门山逆冲带所分隔,以致已往的沉积盆地研究多将其相割裂,本文将结合巴颜喀拉洋的消亡过程,把这两个盆地视为一个统一整体来加以分析,研究其演变历程。
晚二叠世,扬子板块向西楔入的同时,发生向北（昆仑-柴达木陆块）和向南（羌塘-昌都陆块）的双向俯冲消减。本文提出了巴颜喀拉洋的主体闭合,从而开始转化为边缘前陆盆地阶段的时间是在拉丁（T₂²）中晚期,而不是晚三叠世的见解。这点可由拉丁中晚期时,四川盆地川中广大地区形成与前陆挠曲沉降相对应的前陆隆起得以证明。此时期发生的前陆沉降,结束了被动边缘的饥饿（T₁—T₂¹）沉积盆地状态,充填了厚逾2,000—10,000m的类复理石沉积,并向扬子克拉通边缘超覆。随着逆冲带的由北向南推进,在诺利一瑞替期形成了滨海含煤磨拉石和陆相含煤磨拉石（逆冲褶皱带地区大多后期被剥蚀）。晚三叠世中晚期,逆冲带侵位推进到四川盆地西部边缘的龙门山地带,从而前陆盆地迁移入四川盆地内,进入陆内汇聚的后造山陆相磨拉石前陆盆地阶段。晚白垩世一早第三纪,因四川盆地晚期的抬升,这一前陆盆地便逐渐萎缩消亡。     

Cretaceous–Tertiary Rhenodanubian flysch wedge (Eastern Alps): clues to sediment supply and basin configuration from zircon fission-track data

The provenance of Cenomanian to Eocene flysch deposits accreted along the northern margin of the Eastern Alps has been investigated by means of zircon fission-track (FT) geochronology and zircon morphology. The Rhenodanubian flysch and Ybbsitz klippen zone comprise several nappes representing the Main flysch and Laab basins. The Laab basin received sediments of stable European provenance, indicated by pre-Variscan, Variscan, and Permian–Triassic zircon FT ages, and was thus located in the immediate south of the European margin. The Main flysch basin was supplied mainly from the evolving Eastern Alps and was therefore situated south of the Laab basin. Zircon populations with Permian to Jurassic cooling ages in the Main flysch basin are related to increased heat fluxes during the break-up of Pangaea and are probably derived from the northwestern part of the Eastern Alps. The dominant Cretaceous zircon FT cooling ages reflect Eoalpine metamorphism in the Austroalpine realm.     

西藏南部聂拉木地区侏罗纪—白垩纪盆—山转换过程中的沉积学响应

西藏南部聂拉木—定日地区沉积地层记录着侏罗纪被动大陆边缘到白垩纪前陆盆地的盆—山转换演化历史。侏罗纪发育巨大的海侵—海退沉积序列，晚侏罗世喜马拉雅特提斯海底扩张速度明显加快，从0.32 cm/a上升为1.24 cm/a。前陆盆地演化分为早期深水复理石和晚期海相磨拉石两个阶段。前陆早期发育向上急剧加深的深水砂泥质复理石建造、黑色页岩建造和岛弧型火山岩建造沉积；前陆晚期海相磨拉石沉积总体表现为向上变粗、变浅的沉积序列。     

扬子地块西缘新生代造山作用与前陆盆地构造演化

地貌学、第四纪地质学。同位素及构造。沉积的综合分析表明，扬子地块西缘造山带的主体隆升时期发生于新生代特别是第四纪以来，其隆升幅度可达2000～4000m，中新世以来至少有5～6km地层被剥蚀，上升速率约达0．6mm／a；与其伴生的前陆盆地新生代沉积可分为老第三纪继承性萎缩拗陷盆地阶段和新第三纪─第四纪前陆盆地改造阶段。前者具有山间和山前磨拉石盆地特征，后者具有类磨拉石盆地性质。深部资料的进一步分析表明第四纪时期岩石图具四层结构，中地壳为一区域性韧性流壳层，是处于岩石图加厚后的均衡调整和区域伸展时期，盆山关系的分析也表明，造山带与前陆盆地在形成、演化和改造上具有统一的区域构造背景。     

Evolution of the European Cenozoic Rift System: interaction of the Alpine and Pyrenean orogens with their foreland lithosphere

The evolution of the European Cenozoic Rift System (ECRIS) and the Alpine orogen is discussed on the base of a set of palaeotectonic maps and two retro-deformed lithospheric transects which extend across the Western and Central Alps and the Massif Central and the Rhenish Massif, respectively.During the Paleocene, compressional stresses exerted on continental Europe by the evolving Alps and Pyrenees caused lithospheric buckling and basin inversion up to 1700 km to the north of the Alpine and Pyrenean deformation fronts. This deformation was accompanied by the injection of melilite dykes, reflecting a plume-related increase in the temperature of the asthenosphere beneath the European foreland. At the Paleocene–Eocene transition, compressional stresses relaxed in the Alpine foreland, whereas collisional interaction of the Pyrenees with their foreland persisted. In the Alps, major Eocene north-directed lithospheric shortening was followed by mid-Eocene slab- and thrust-loaded subsidence of the Dauphinois and Helvetic shelves. During the late Eocene, north-directed compressional intraplate stresses originating in the Alpine and Pyrenean collision zones built up and activated ECRIS.At the Eocene–Oligocene transition, the subducted Central Alpine slab was detached, whereas the West-Alpine slab remained attached to the lithosphere. Subsequently, the Alpine orogenic wedge converged northwestward with its foreland. The Oligocene main rifting phase of ECRIS was controlled by north-directed compressional stresses originating in the Pyrenean and Alpine collision zones.Following early Miocene termination of crustal shortening in the Pyrenees and opening of the oceanic Provençal Basin, the evolution of ECRIS was exclusively controlled by west- and northwest-directed compressional stresses emanating from the Alps during imbrication of their external massifs. Whereas the grabens of the Massif Central and the Rhône Valley became inactive during the early Miocene, the Rhine Rift System remained active until the present. Lithospheric folding controlled mid-Miocene and Pliocene uplift of the Vosges-Black Forest Arch. Progressive uplift of the Rhenish Massif and Massif Central is mainly attributed to plume-related thermal thinning of the mantle-lithosphere.ECRIS evolved by passive rifting in response to the build-up of Pyrenean and Alpine collision-related compressional intraplate stresses. Mantle-plume-type upwelling of the asthenosphere caused thermal weakening of the foreland lithosphere, rendering it prone to deformation.     

中生代羌塘前陆盆地充填序列及演化过程

中生代羌塘前陆盆地位于青藏高原巨型造山带内 ,夹于金沙江缝合带与班公湖—怒江缝合带之间 ,是一个与两侧缝合带逆冲作用相关的沉积盆地 ,由羌北盆地 (对应于金沙江缝合带 )、羌南盆地 (对应于班公湖—怒江缝合带 )和中央隆起带构成 ,其中中央隆起是北部前陆盆地和南部前陆盆地共有的前陆隆起 ,显示为对称型复合前陆盆地 ;该盆地形成于晚三叠世 ,并持续发育至早白垩世 ,盆地中充填了巨厚的同构造期的复理石和磨拉石 ,具有总体向上变粗变浅的充填序列 ,以不整合面可将其划分为 5个由顶底不整合面限制的构造层序 ,其中晚三叠世诺利期构造层序对应于金沙江缝合带主碰撞期 ,晚三叠世瑞替期构造层序对应于金沙江缝合带碰撞闭合后冲断抬升 ,早侏罗世构造层序对应于班公湖—怒江缝合带初始逆冲推覆 ,中侏罗世—早白垩世构造层序对应于班公湖—怒江缝合带主碰撞期 ,中白垩世构造层序为班公湖—怒江缝合带碰撞闭合后冲断抬升与金沙江缝合带冲断抬升的产物 ,为中生代羌塘盆地关闭后的磨拉石建造     

东准噶尔晚古生代洋陆转换过程:来自沉积学的约束

东准噶尔卡拉麦里造山带是中亚造山带西段一个很重要的构造单元,其构造演化为区域构造过程、动力机制等问题的研究提供关键证据,也为研究中亚造山带提供了重要的物质基础和理论依据.本文在前人研究的基础上,通过对卡拉麦里造山带野外剖面实测、构造现象描述、典型岩石观察,选取典型复理石、磨拉石建造剖面及古生物化石开展系统研究,结果表明...     

盆山转换与沉积地质记录——以楚雄前陆盆地分析为例

楚雄盆地位于扬子陆块的西南边缘,为一中生代周缘型前陆盆地。根据沉积相特征、层序地层结构和古地理演化的详细研究,结合古哀牢山造山带的构造演化,笔者认为楚雄盆地经历了从古生代被动大陆边缘沉积到中生代前陆盆地沉积的演化。前陆盆地演化的阶段性明显：晚三叠世卡尼期（云南驿组沉积期）和诺利早、中期（罗家大山组沉积期）为前陆复理石沉积;诺利晚期（花果山组沉积期）－古新世（赵家店组沉积期）为前陆磨拉石沉积。磨拉石     

楚雄中生代前陆盆地的构造沉降史研究

云南楚雄盆地位于场子陆块的西南边缘,为一典型的中生代周缘前陆盆地,盆地演化阶段明显,晚三叠世为前陆早期复理石沉积,侏罗纪则为前陆晚期磨拉石沉积。对盆地构造沉降史研究后笔者认为：①晚三叠世复理石沉积盆地构造沉降幅度巨大,沉降与沉积中心位于盆地最西部,紧邻古哀牢山造山带,沉积体呈形楔形展布;③侏罗纪磨拉石沉积盆地构造沉降和沉积中心以及前缘隆起向内陆方向迁移明显;③中生代构造快速沉降的沉积体的楔形展布表     

Structural inversion and its controls : examples from the Alpine foreland and the French Alps

Abstract

Positive structural inversion involves the uplift of rocks on the hanging-walls of faults, by dip slip or oblique slip movements. Controlling factors include the strike and dip of the earlier normal faults, the type of normal faults — whether they were listric or rotated blocks, the time lapsed since extension and the amount of contraction relative to extension. Steeply dipping faults are difficult to invert by dip slip movements; they form buttresses to displacement on both cover detachments and on deeper level but gently inclined basement faults. The decrease in displacement on the hanging-walls of such steep buttresses leads to the generation of layer parallel shortening, gentle to tight folds — depending on the amount of contractional displacement, back-folds and back-thrust systems, and short-cut thrust geometries — where the contractional fault slices across the footwall of the earlier normal fault to enclose a “floating horse”. However, early steeply dipping normal faults readily form oblique to strike slip inversion structures and often tramline the subsequent shortening into particular directions.

Examples are given from the strongly inverted structures of the western Alps and the weakly inverted structures of the Alpine foreland. Extensional faulting developed during the Triassic to Jurassic, during the initial opening of the central Atlantic, while the main phases of inversion date from the end Cretaceous when spreading began in the north Atlantic and there was a change of relative motion between Europe and Africa. During the mid-Tertiary well over 100 km of Alpine shortening took place; Alpine thrusts, often detached along, or close to, the basement-cover interface, stacking the late Jurassic to Cretaceous sediments of the post-extensional subsidence phase. These high level detachments were joined and breached by lower level faults in the basement which, in the external zones of the western Alps, generally reactivated and rotated the earlier east dipping half-graben bounding faults. The external massifs are essentially uplifted half-graben blocks. There was more reactivation and stacking of basement sheets in the eastern part of this external zone, where the faults had been rotated into more gentle dips above a shallower extensional detachment than on the steeper faults to the west.

There is no direct relationship between the weaker inversion of the Alpine foreland and the major orogenic contraction of the western Alps; the inversion structures of southern Britain and the Channel were separated from the Alps by a zone of rifting from late Eocene to Miocene which affected the Rhone, Bresse and Rhine regions. Though they relate to the same plate movements which formed the Alps, the weaker inversion structures must have been generated by within plate stresses, or from those emanating from the Atlantic rather than the Tethyan margin.     

Tectonic progradation and plate tectonic evolution of the Alps

Rifting and spreading, trench formation, flysch deposition, subduction and nappe formation prograde from internal to external parts of the Alpine orogen. The progradation is a characteristic feature of the evolution of the Alps. A plate tectonics model based on this cognition is presented and an attempt is made to integrate the plate movements of the Alpine region during the Mesozoic and Cenozoic into the plate pattern of the Western Mediterranean.

Important events in the evolution of the Alps are the successive opening and closing of the Piedmont (South Penninic) and Valais (North Penninic) oceans, and the two continental collisions related to this. The southward drift of the Briançonian plate in the Cretaceous closes the Piedmont and opens the Valais ocean. The evolution of these oceans is related to the plate movements in the North Atlantic. The second continental collision is followed by the formation of an exogeosyncline, the molasse foredeep.

Prograding orogens like the Alps are most likely to evolve in an originally continental environment by rifting. Retrograding orogens, however, indicate an originally oceanic environment with well-developed magmatic arcs and back-arc basins.