苏、浙、皖地区沉积-大地构造演化

中国南部近东西延伸的扬子板块形成于距今800Ma 前。自震旦纪开始,在其东缘苏、浙、皖地区形成了两个呈北东东向展布的并在其东端相联的裂陷槽。其沉积厚度达万米。沉积演化晚期形成了复理石与磨拉石。复理石堆积于晚奥陶世,此时裂陷槽为两个向东开口的海湾,碎屑物来自盆地南北两侧的扬子古陆。磨拉石堆积的时代从晚奥陶世末到中泥盆世,碎屑物     

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.     

塔里木盆地构造—古地理演化

摘要构造—古地理演化对盆地分析与油气资源评价具有重要意义,通过古构造恢复结合区域地质背景,综合分析塔里木盆地构造—古地理演化过程。塔里木盆地经历克拉通基底形成阶段、南华—震旦纪强伸展—挤压阶段、寒武—奥陶纪弱伸展—强挤压阶段、志留—白垩纪振荡升降变迁阶段、新生代弱伸展—强挤压阶段等5大构造演化阶段。塔里木盆地南华—震旦纪发育北东向陆内窄深裂谷系统,不同于显生宙;寒武纪—早奥陶世发育“两台一盆”的“东西分块”的大型克拉通内碳酸盐岩台地,中-晚奥陶世碳酸盐岩台地快速演变为“南北分带”;志留—泥盆纪形成克拉通内坳陷海相碎屑岩沉积体系;石炭—二叠纪发育克拉通内碎屑岩夹碳酸盐岩的浅海—海陆过渡相沉积;中生代发育一系列分隔的快速变迁的陆内坳陷碎屑岩沉积;新生代发育前陆盆地陆相磨拉石沉积,形成复杂的叠合盆地。受控原—新特提斯洋与南天山洋的开启—闭合,以及新生代印度板块挤压的远程效应,塔里木盆地构造—古地理具有多期性、多样性、迁移性与强烈的改造性,不同于典型的克拉通盆地。     

塔里木盆地中-上奥陶统浊积岩物源分析及大地构造意义

通过地表露头及钻井取心的浊积岩沉积特征观察及古流向分析、砂岩主量元素化学成分分析及地震相分析,提出塔里木盆地奥陶系陆源碎屑浊积岩主要发育于塔东地区及塘古兹巴斯坳陷的上奥陶统之中,其浊流沉积物源主要来自盆地东南侧的阿尔金岛弧、其次来自盆地西南侧的库地活动陆缘隆起;仅盆地东北缘却尔却克山地区出露的中奥陶统顶部的却尔却克组下部陆源碎屑浊积岩的物源区,主要来自其北侧的库鲁克塔格被动陆缘隆起(台地隆起剥蚀区)。综合分析认为,晚奥陶世发生于板块南缘的阿尔金岛弧及库地活动陆缘隆起与塔里木板块的碰撞挤压运动产生的大量陆源碎屑物源,导致了板块内部多个孤立碳酸盐台地的逐步消亡及板块南部浊流盆地群的形成。     

一个已埋藏的古造山带探讨

本文从研究磨拉石与造山带的关系入手,分析了扬子板块东缘志留系磨拉石的沉积学特征和物质成分特点,进而推测出在磨拉石堆积区东侧(相当于现代长江口外)有一条近南北向的古造山带,该造山带始形成于奥陶纪末,现在已被剥蚀并被深埋于地下。这对重新认识华南大地构造演化及古生代油气分布规律都是很有意义的。     

Tectonics and geodynamics of the western Central Asian Fold Belt (Kazakhstan Paleozoides)

On the basis of stratigraphical and geological data, paleogeographical and palinspastic reconstructions of the Kazakhstan Paleozoides were done; their multistage geodynamic evolution was considered; their tectonic zoning was proposed. The main stages are described: the initiation of the Cambrian and Ordovician island arcs; the development of the Kazakhstan accretionary–collisional composite continent in the Late Ordovician as a result of continental subduction and the amalgamation of Gondwana blocks with the island arcs (a long granitoid collisional belt also formed in this period); the development of the Devonian and Carboniferous–Permian active margins of the composite continent and its tectonic destruction in the Late Paleozoic.In the Late Ordovician, compensated terrigenous and volcanosedimentary complexes formed within Kazakhstania and developed in the Silurian. The Sakmarian, Tagil, Eastern Urals, and Stepnyak volcanic arcs formed at the boundaries with the Ural, Turkestan, and Junggar–Balkhash Oceans. In the late Silurian, Kazakhstania collided with the island arcs of the Turkestan and Ob'–Zaisan Oceans, with the formation of molasse and granite belts in the northern Tien Shan and Chingiz. This was followed by the development of the Devonian and Carboniferous–Permian active margins of the composite continent and the inland formation of the Early Devonian rift-related volcanosedimentary rocks, Middle–Late Devonian volcanic molasse, Late Devonian–Early Carboniferous rift-related volcanosedimentary rocks, terrigenous–carbonate shelf sediments, and carbonaceous lake–bog sediments, and the Middle–Late Carboniferous clastic rocks of closed basins. In the Permian, plume magmatism took place on the southern margin of the Kazakhstan composite continent. It was simultaneous with the formation of red-colored molasse and the tectonic destruction of the Kazakhstan Paleozoides as a result of a collision between the East European and Kazakhstan–Baikal continents.     

博格达山晚古生代坳拉谷(Aulacogen)的初步研究

博格达地区在晚古生代不是与哈尔里克相联的岛弧,而是坳拉谷.它发育较完整的滨浅海→陆棚→陆坡→坡角→盆地平原相的沉积相序.建造类型和充填序列与国内外坳拉谷很相似,而与岛弧建造相差甚远.早期具多旋回的火山喷发,中期发育多种重力流沉积组分,晚期出现复理石和磨拉石建造.东与兴蒙大洋相联,西端伸入准噶尔小板块内部.从中泥盆世开始由巴里坤一带逐渐向乌鲁木齐地区发育.     

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.     

柴达木盆地构造古地理分析

研究的目的是分析柴达木盆地显生宙构造古地理特征和盆地叠合过程。在寒武纪—泥盆纪 ,柴达木板块处于低纬度区 ,从寒武纪时的南纬 4 1°往北漂移到泥盆纪时的北纬 10 6° ,与塔里木、华北、扬子等块体有较大的纬度差 ,表明柴达木板块在该时期是一个并不隶属于其它任何板块的独立的块体 :与华北板块之间以北祁连洋相隔 ,与塔里木板块之间以阿尔金洋相隔 ,与中昆仑地块之间以东昆仑洋相隔 ,柴达木板块内部也被赛什腾—锡铁山洋所分隔。这些洋盆经历了寒武纪—早、中奥陶世张裂阶段和晚奥陶世—早、中泥盆世聚敛阶段 ,最终于中泥盆世末期闭合。该时期在柴达木盆地内部 ,叠合在震旦纪大陆裂谷盆地之上的是寒武—奥陶纪台地—陆棚相碳酸盐岩和碎屑岩建造 ,生物发育 ;志留纪—早、中泥盆世柴达木盆地以隆起为特征。石炭纪—三叠纪柴达木板块继续北移 ,石炭纪时位于北纬 11 9° ,二叠纪时位于北纬 12 7° ,三叠纪时位于北纬 2 2 2° ,该时期柴达木板块已与华北板块、塔里木板块拼合 ,但与羌塘板块之间以南昆仑洋相隔 ,柴达木处于南昆仑洋的弧后部位 ,叠加在早期盆地之上的是石炭纪—早二叠世滨岸—台地—陆棚相碳酸盐岩、碎屑岩夹煤线。晚二叠世—三叠纪柴达木盆地再度隆升。侏罗纪以来 ,柴达木板块缓慢北     

Classic swiss clastics (flysch and molasse) The alpine connection

Abstract

Flysch and molasse are discussed in the light of alpine geodynamics. They are pre-collision and post-collision orogenic clastics which accumulated in basins under different geodynamic controls. We propose that in the case of the Alps, their succession records the change in geodynamics from pre-collision inversion of shallower extensio-nal structures, to post-collision inversion of one or more deep-seated features.

The classical flysch of the Prealps, lying within a pile of nappes at the front of the Western Alps, are invariably turbidite deposits. Flysch has therefore acquired a sedimentological connotation over the years, and this has been emphasized over the last few decades. Turbidite facies were also laid down in marginal and foreland locations during and a little after the collision between the South and North Tethyan Alpine margins, and this has obscured the possible deeper signification of flysch and molasse.

Geodynamic regimes dictate the subsidence behaviour of basins, so by use of geohistory analysis, the time and place of the onset of Molasse basin development may be located. This was at the southern margin of the Helvetic belt, from the start of the Oligocene. Along the Alpine traverse of Western Switzerland, the change in regime from flysch to molasse (i.e. from trench and forearc or retro-arc, to foreland basin deposits) suggests that a major deep-seated inversion structure was situated near the Helvetic-Ultrahelvetic boundary.     

塔里木盆地早古生代构造古地理演化与烃源岩

塔里木陆块为一具前寒武系基底的克拉通盆地,早震旦世—寒武纪陆块内和边缘发生裂解,至中奥陶世转为被动大陆边缘,组建塔北和塔中两个遥相对应的碳酸盐台地和边缘斜坡,其间的阿瓦提—满加尔地区为克拉通内浅海—深水盆。满参1井以东至满加尔为欠补偿的深海槽盆,早期沉积了富生物营养链的烃源岩,晚奥陶世克拉通转为前陆碎屑岩沉积,满加尔坳陷反转为浊流盆地。碎屑岩由东向西、由南东向北西迁移,造成向塔北和塔中海侵上超,结束碳酸盐台地演化的同时,沉积了局限台地型和台缘斜坡灰泥丘相的烃源岩。奥陶纪时塔里木盆地演化和沉积相的配置,是加里东期盆山转换的重要反响,形成多个沉积-构造转换面。早加里东运动,造成下早奥陶统与寒武系的假整合;中加里东运动即晚奥陶世始,塔里木转为前陆盆地,塔北和塔中分别为前陆隆起,阿瓦提—满加尔为复合隆间盆地;晚加里东运动(始于早志留世)发生了大规模的海退。     

北山地区早古生代板块构造特征

位于甘肃省西北边界和内蒙古自治区西端的北山地区,早古生代大地构造单元由塔里木板块东段北缘和北侧贝加尔期分裂出来的旱山微板块组成,其间被石板井-小黄山蛇绿混杂岩带所分隔。在漫长的构造演化进程中发育有蛇绿岩带。同时,经历了大西洋型、安第斯型(?)和西太平洋型大陆边缘的演化阶段,陆壳增厚,地壳成熟度增加,由大洋地壳和过渡型地壳向大陆型地壳转化。晚古生代初,全区进入板内活动时期。     

中国西北地区奥陶纪岩相古地理

中国西北地区是指贺兰山及六盘山以西和昆仑山以北的我国西北部的广大地区。在各露头及钻井剖面的地层学和岩石学研究的基础上,采用单因素分析综合作图法,编制出了中国西北地区奥陶系各统的各种单因素图和奥陶纪各世的岩相古地理图。这些岩相古地理图具有定 量、多级别和多类型的特点。定量,即每个古地理单元的划分和确定都有确切的定量的单因 素数据和图件为依据。多级别,即已划分出三级古地理单元,如陆和海为一级;在海中又划 分出台地、盆地和斜坡,为二级;在台地中,又划分出滩、坪等,为三级。多类型,即每个 古地理单元,主要是二级和三级古地理单元,还可根据其岩石特征区分出不同的类型,如台 地可区分出碳酸盐岩台地、碎屑岩台地、火山岩台地等,盆地可区分出泥岩盆地、硅岩盆地 、碎屑岩盆地、复理石盆地、火山岩盆地等,滩可区分出亮晶颗粒滩（准滩、雏滩）、灰泥 颗粒滩（准滩、雏滩）等。这种古地理图在西北地区还是首次出现。西北地区奥陶纪岩相古 地理格局可概括为“海陆并存,海中台盆相间分布,台中有滩和坪,台盆间有斜坡”。早奥 陶世继承了寒武纪的海进并进一步扩大,至中奥陶世海进达盛期,到晚奥陶世开始海退,从而完成了西北地区寒武纪和奥陶纪海进海退旋回。     

大别山造山带与安徽沿江中新生代盆地的盆山耦合关系

安徽沿江中新生代盆地位于大别山造山带南缘，为先挤压、后伸展形成的叠合盆地，是探讨扬子板块陆内深俯冲—大别山造山带隆起与中、下扬子盆地沉降的耦合关系的理想场所。在早中生代，大别山为华南和华北大陆碰撞造山带，华南地壳向深处俯冲并承受超高压变质作用，超高压变质岩不断向上折返，沿江坳陷具有前陆盆地性质，盆地充填有晚三叠世—中侏罗世磨拉石层序；在晚中生代，在中国东部整体的拉张背景下，大别山变质带完全折返上隆，处于变质核杂岩隆升状态，而沿江坳陷具有裂陷盆地性质，充填有晚侏罗世—早白垩世、晚白垩世—古近纪两个红色碎屑构造层序，起因于地壳拆沉而产生的均衡隆升和伸展断陷的构造耦合。     

从弧后盆地到前陆盆地——北祁连造山带奥陶纪—泥盆纪的沉积盆地与构造演化

北祁连加里东期造山带是在新元古代Rodinia联合大陆(Pangea-850)基础上裂解,经由寒武纪裂谷盆地、奥陶纪初期成熟洋盆、奥陶纪中晚期北祁连活动大陆边缘、志留纪—早、中泥盆世碰撞造山而形成的。奥陶纪中、晚期,北祁连、走廊地区中、上奥陶统发育洋壳-岛弧-弧后火山岩,形成典型的沟-弧-盆体系的沉积。志留纪—早、中泥盆世是北祁连-走廊沉积盆地的转换时期。除天祝、古浪、景泰及肃南等局部地区发育下志留统钙碱性系列火山岩以外,全区志留系均以碎屑岩沉积为主。志留系底部多见一套砾岩层。下—中志留统为典型复理石相的浊流沉积。上志留统变为滨浅海相磨拉石沉积。早、中泥盆世雪山群为典型的陆相粗碎屑磨拉石沉积。从空间分布上看,志留系—泥盆系在走廊—北祁连地区也有自北向南厚度加大、粒度变粗的特征,古流以由南向北、来自造山带的古流为特征。北祁连-河西走廊奥陶纪弧后盆地火山岩—志留系复理石-海相磨拉石—中、下泥盆统陆相磨拉石的充填序列以及空间分布特点,反映为典型的弧后盆地向前陆盆地转化的沉积序列。     

扬子克拉通南华纪-早古生代的构造-沉积旋回

根据影响克拉通盆地演化的板块活动所经历的威尔逊旋回,扬子克拉通南华纪-早古生代的构造-沉积旋回可分为5期,即南华纪-震旦纪的均衡调整期、寒武纪的扩张期、早-中奥陶世的汇聚期、中-晚奥陶世的碰撞期和志留纪新一轮的均衡调整期。发生在晚奥陶世的中加里东运动是加里东期最强烈的一次造山运动,而发生在晚志留世的晚加里东运动是一次地壳上升运动;相应的扬子古板块志留纪盆地的构造背景为造山期后的裂谷伸展环境,其原型盆地表现为周缘裂谷盆地与弱伸展的克拉通内盆地相间发育的格局。     

SPACE-TIME TEXTURE AND TECTONIC EVOLUTION OF QAMDO BLOCK IN EAST TIBET

SPACE-TIME TEXTURE AND TECTONIC EVOLUTION OF QAMDO BLOCK IN EAST TIBET     

Sedimentary history of the Tethyan basin in the Tibetan Himalayas

After an epicontinental phase, the sedimentary rocks in the Tibetan Himalayas document a complete Wilson cycle of the Neo-Tethyan (Tethys Ill) evolution between the Gondwana supercontinent and its northward drifting margin (Lhasa block) from the Late Permian to the Eocene.During the Triassic rift stage, the basin was filled with a huge, clastic-dominated sediment wedge with up to > 5 000 m of flysch in the northern zone. Widespread deltaic clastics and shallow-water carbonates of late Norian to earliest Jurassic age in the southern zone mark, in conjunction with decreasing tectonic subsidence, the transition to the drift stage.Some 4 500 m of Jurassic and Early Cretaceous shallow-water carbonates and siliciclastics accumulated on the Tethyan Indian passive margin. Deepening-upward sequences with condensed beds at their tops alternate with repeated progradational packages of shelf sediments. Extensive abyssal sediments with basaltic volcanics in the northern deep-water zone reflect continued ocean spreading and thermal subsidence. Paleomagnetic data, gained separately for the northern Indian plate and the Lhasa block, indicate that the Neo-Tethys reached its maximum width about 110 Ma ago with a spreading rate of 4.8 cm/year, before it commenced to close again.During the remnant basin stage in the Late Cretaceous and Paleogene, a shallowing-upward megasequence, capped by a carbonate platform, developed in the southern inner shelf realm. In the northern slope/basin plain zone, turbidites and chaotic sediments, derived from both the acretionary wedge and the steepening slope of the passive margin, accumulated. The depositional center of the remnant basin shifted southward as a result of flexural subsidence and southward overthrusting.The sediments from the Triassic to the Paleogene are tentatively subdivided into five mega-sequences, which are controlled mainly by regional tectonics. Climatic influence (e.g., carbonate deposition), due to northward plate motion, is partially subdued by terrigenous input and/or increased water depth. During the Oligocene and Miocene, crustal shortening led to rapid uplift and the deposition of fluvial molasse in limited basins.     

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。     

广西晚古生代构造沉积背景的初步研究

广西西部存在晚古生代连续深海沉积,其中各个时代玄武岩广泛分布,具大洋板内地化特征。桂西和柳州地区晚古生代硅质岩有明显的铈负异常,指示本区可能属远洋沉积环境。狭窄的深水地层条带具强烈的构造形变,所环绕的碳酸盐台地却产状平缓。区域地质分析表明,广西在晚古生代可能代表扬子和印支地块之间的古特提斯水道,碳酸盐台地可能为广海中的水下高地。