Source rocks in sedimentary basins of continental margins in the early paleozoic     

A. I. Konyukhov 《Lithology and Mineral Resources》2014,49(3):250-271

During the Paleozoic, epochs with the relatively cold climate alternated with epochs marked by significant warming. Moreover, cooling epochs were characterized by the substantial sea level fall, while warming was accompanied by its rapid rise. In many basins located at margins of Laurentia, Baltica, and the North China continental block, such an alternation is reflected in the structure of sedimentary sequences and the lateral/vertical distribution of reservoirs, confining beds, and source rocks. Despite the fact that sediments with high concentrations of sapropelic OM accumulated in different periods, their distribution areas on continents and their margins became highly reduced during cold epochs, when these sediments filled mostly rift troughs and foreland basins. After the colonization of land by higher plant communities in the Carboniferous and Permian sediments deposited during cold epochs, the humic material became an important constituent of OM in the source rock sequences.  相似文献   

The palaeobiogeography of Permian anomodonts     

Gillian M. King 《地学学报》1992,4(6):633-640

It is generally considered that the oldest anomodont mammal-like reptiles are known from Late Permian sediments of the USSR and that during the rest of the Late Permian distribution of these fossils widens to encompass nearly all geographical areas by the end of the Period.
This study reviews the occurrence of anomodont genera in Permian sediments and reassesses the conventionally accepted distribution pattern. A broad correlation of terrestrial Permian rocks from different continents is attempted. Using recent reconstructions of Permian continental positions the effect of latitude on anomodont distribution is investigated. Some explanations for the restrictions operating on anomodont distribution are suggested.  相似文献   

Black shales and other sediments with high organic matter contents in Phanerozoic climatic cycles: Communication 2. Black shales during the Pangea existence     

A. I. Konyukhov 《Lithology and Mineral Resources》2016,51(1):38-60

According to recent concepts, the Earth surface was permanently transformed during its geological history. Some stages of its evolution were marked by the convergence of separate continental blocks to result in the formation of supercontinents, which resisted successfully centrifugal processes. Other stages were characterized by the opposite tendency: after their long existence, the supercontinents became disintegrated into several large and small blacks, the motion of which was accompanied by opening of new sea basins and closure of former basins with the oceanic crust. The second half of the Paleozoic was marked by amalgamation of large continental blocks. In the Devonian, collision between Laurentia and Baltica culminated in the formation of the Euroamerica continent. After the closure of the Ural paleocean in the terminal Carboniferous–initial Permian, it was united with the Siberian and Kazakhstan continental blocks. These events provided the prerequisites for the formation of a new supercontinent (Pangea), which acquired its final configuration at the end of the Permian. One of its segments located mainly south of the equator included Gondwana. Another segment located northward included Euroamerica, Kazakhstan, Siberian, and two China continental blocks. During its geological history, Pangea suffered many dramatic events including several extinctions of organisms. The most significant event took place in the terminal Permian–initial Triassic and at the transition between the Triassic and Jurassic periods.  相似文献   

Post-collisional crustal extension setting and VHMS mineralization in the Jinshajiang orogenic belt, southwestern China   总被引：2，自引：0，他引：2  

Hou Zengqian  Wang Liquan  Khin Zaw  Mo Xuanxue  Wang Mingjie  Li Dingmou  Pan Guitang 《Ore Geology Reviews》2003,22(3-4):177-199

The Jinshajiang orogenic belt (JOB) of southwestern China, located along the eastern margin of the Himalayan–Tibetan orogen, includes a collage of continental blocks joined by Paleozoic ophiolitic sutures and Permian volcanic arcs. Three major tectonic stages are recognized based on the volcanic–sedimentary sequence and geochemistry of volcanic rocks in the belt. Westward subduction of the Paleozoic Jinshajiang oceanic plate at the end of Permian resulted in the formation of the Chubarong–Dongzhulin intra-oceanic arc and Jamda–Weixi volcanic arc on the eastern margin of the Changdu continental block. Collision between the volcanic arcs and the Yangtze continent block during Early–Middle Triassic caused the closing of the Jinshajiang oceanic basin and the eruption of high-Si and -Al potassic rhyolitic rocks along the Permian volcanic arc. Slab breakoff or mountain-root delamination under this orogenic belt led to post-collisional crustal extension at the end of the Triassic, forming a series of rift basins on this continental margin arc. Significant potential for VHMS deposits occurs in the submarine volcanic districts of the JOB. Mesozoic VHMS deposits occur in the post-collisional extension environment and cluster in the Late Triassic rift basins.  相似文献   

Coevolution of Brachiopod Paleobiogeography and Tectonopaleogeography during the Early–Middle Permian     

WANG Chengwen  an  MAO Yongqin  LI Ning  ZONG Pu 《《地质学报》英文版》2015,89(6):1797-1812

A comprehensive compilation and systematic analysis of known early and middle Permian brachiopod faunas shows that the early Permian brachiopod faunas comprise three realms, six regions, and eleven provinces, while those of the middle Permian comprise three realms, four regions, and eight provinces. A comparison and analysis of brachiopod faunal patterns reveal a coevolution between global brachiopod paleobiogeography and tectonopaleogeography during the early–middle Permian. Although temperature/latitude is the main factor controlling the formation of three realms, tectonopaleogeographic factors determine the temperature/latitude in which the continents were located. The ‘continental barrier' of Pangea, as a ‘central axis' continent, divided the three realms into six regions, which indicates that the formation of biogeographic regions was controlled mainly by the tectonopaleogeographic factors. The evolution of tectonopaleogeography was sometimes a long-term process, so that the biogeographic regions(or provinces) controlled by tectonopaleogeography displayed relative stability. Shifts in the nature of biogeographic provinces(e.g., from cool water to warm water, and vice versa), extensions or narrowing of geographical ranges, and recombinations of some provinces were all related to regional tectonic evolution. The study of the coevolution between brachiopod paleobiogeography and tectonopaleogeography not only accounts for the formation mechanisms of brachiopod paleobiogeographic patterns during the early–middle Permian, but also provides evidences for the locations and configurations of oceans and plates(blocks) during this period.  相似文献   

前寒武纪的超大陆旋回及其板块构造演化意义   总被引：13，自引：1，他引：12  

李江海 《地学前缘》1998,(Z1)

太古代末早古生代存在４次超大陆或大陆聚合时期,超大陆的聚合与裂解造成全球性的重大构造热事件,成为全球板块构造演化的主线,威尔逊旋回在早前寒武纪已明显起作用。超大陆的聚合表现为克拉通的增生与陆块的碰撞造山作用;超大型的裂解表现为非造山岩浆活动、大规模基性岩墙群侵位及大陆裂谷的爆发等。超大陆的裂解可能与地幔柱上涌或超大陆下放射性物质积聚造成的热能积累有关,或地外物质冲击的触发有关。华北克拉通与世界古陆块的前寒武纪构造演化对比,及其在超大陆中的拼合模式成为我国大陆地质学研究面临的挑战性重大科学问题。  相似文献   

二叠纪东吴运动的沉积响应差异：来自扬子和华夏板块吴家坪组或龙潭组碎屑锆石LA-ICPMS U-Pb年龄研究   总被引：2，自引：0，他引：2  

梁新权  周云  蒋英  温淑女  付建刚  王策 《岩石学报》2013,29(10):3592-3606

二叠纪所发生的东吴运动是华南非常重要的构造事件之一。但在构造运动方式、动力学机制以及岩浆-沉积-成矿等方面存在明显的地区差异性。在扬子板块,东吴运动主要发生在中、晚二叠世之间,由地幔柱活动引起,表现为地壳的大规模抬升和大火成岩省的形成;而在华夏板块,东吴运动发生时间相对较早,始于早二叠世晚期,可能由古特提斯洋的俯冲、闭合以及陆陆碰撞引起,主要体现造山作用和前陆盆地的形成以及大量二叠纪花岗岩的侵入。对晚二叠世吴家坪组碎屑锆石所进行的LA-ICPMS U-Pb年龄系统研究表明,扬子和华夏碎屑锆石所构成的年龄频谱和所反映的信息亦存在明显的地区差异。来自扬子板块吴家坪组碎屑锆石年龄主要集中在250~272Ma,峰值为259Ma,这与峨眉山玄武岩的喷发时间非常一致,说明碎屑物质主要来自峨眉山大火成岩省;来自华夏板块龙潭组(相当于吴家坪组)碎屑锆石年龄明显与扬子板块吴家坪组碎屑锆石年龄不一样,华夏龙潭组碎屑锆石年龄变化范围宽广,介于250~3652Ma之间,具有258Ma、290Ma、447Ma、988Ma和1880Ma 5个大的峰值以及360Ma、541Ma、823Ma和2500Ma 4个小的峰值。这些锆石年龄,除了2500Ma外,在华夏地块中都有同期岩浆岩出露。这说明华夏吴家坪组碎屑物源复杂,源区经历了复杂的地壳演化历史,包括晋宁、加里东和印支等造山作用。华夏板块晚二叠世早期碎屑物源可能通过造山作用和短距离搬运来自华夏本身。  相似文献   

Phanerozic bauxite epochs     

B. A. Bogatyrev  V. V. Zhukov  Yu. G. Tsekhovsky 《Geology of Ore Deposits》2009,51(6):456-466

The Early Cambrian, Middle and Late Devonian, Middle and Late Carboniferous, Permian, Late Triassic-Early Jurassic, Late Cretaceous, Paleocene-Eocene, and Miocene epochs of bauxite formation have been the most productive. They lasted for no less than 10 Ma. The scope of bauxite deposition of various epochs is shown in the diagram, and the present-day localization of Cenozoic, Mesozoic, and Paleozoic bauxites is depicted in separate maps. The Cenozoic bauxite deposits are located in tropical and subtropical zones of the Southern and Northern hemispheres. The Mesozoic deposits occur in the Northern Hemisphere as far north as 50°N, and the Paleozoic deposits, as far north as 70°N. Palinspastic reconstructions show that during all the aforementioned epochs, bauxites were deposited at paleotropical latitudes. The current localization of the Paleozoic and Mesozoic bauxites at high latitudes up to the Polar Circle is caused by continental drift to the north in the Phanerozoic.  相似文献   

东亚原特提斯洋(Ⅱ):早古生代微陆块亲缘性与聚合   总被引：2，自引：7，他引：2  

李三忠  赵淑娟  余珊  曹花花  李玺瑶  刘鑫  郭晓玉  肖文交  赖绍聪  闫臻  李宗会  于胜尧  张剑  兰浩圆 《岩石学报》2016,32(9):2628-2644

原特提斯洋内存在塔里木、中祁连、柴达木、扬子、华夏、印支、兰坪-思茅等诸多陆块/微陆块,多数陆块之间在早古生代晚期发育有蛇绿岩带或高压-超高压带。原特提斯域形成于从Rodinia裂解到Pangea超大陆集结期间,存在复杂的洋-陆格局和聚散过程。原特提斯洋不同陆块/微陆块属性和关系及其拼合过程是恢复重建Pangea超大陆聚合前构造背景的关键,但对其认识迄今还存在争论。因此,本文采用综合对比方法,以期建立原特提斯洋陆块/微陆块的亲缘性和海-陆格局,厘定原特提斯微陆块拼合时序与方式。结果表明,早古生代早期除华北陆块不具有亲冈瓦纳大陆的特征外,扬子、华夏、塔里木、柴达木、阿拉善、北秦岭-中祁连-中阿尔金、欧龙布鲁克、北羌塘、南羌塘、拉萨、兰坪-思茅、印支等陆块/微陆块都具有亲冈瓦纳的特征。在450~400Ma左右这一系列陆块/微陆块都向南俯冲-增生,并逐步拼合于冈瓦纳大陆北缘东段,原特提斯洋关闭,并形成了原潘吉亚(Proto-Pangea)超大陆;原潘吉亚于380Ma以后裂离出塔里木-华北陆块和大华南陆块,分别出现勉略洋和古特提斯洋,直到240~220Ma逐步向北聚合,形成最终的劳亚古陆,此时才形成潘吉亚超大陆。  相似文献   

新疆吾拉斯台一带下二叠统乌郎组火山岩地球化学特征   总被引：1，自引：0，他引：1  

潘明臣  于海峰  梁有为  王福君  王粉丽  丁伟  李艳  李红梅  赵丽君  徐桂岩 《地质与资源》2011,20(6):452-457

乌郎组火山岩分布于哈萨克斯坦-准噶尔板块（Ⅰ级）伊犁-伊塞克湖微板块（Ⅱ级）阿吾拉勒晚古生代裂谷系（Ⅲ级）中,为一套陆相的火山岩和碎屑岩组合.吾拉斯台一带火山活动较强,火山堆积厚度巨大,区内厚近4000 m,属乌郎组中上部层位.火山岩主要由偏碱性的基性和酸性岩组成,总体以双峰式火山岩为特征.岩石地球化学所反映的构造环境为板内玄武岩和大陆裂谷玄武岩,这与所处的大地构造位置相吻合.顶部层位的粗面玄武岩²⁰⁷Pb/²⁰⁶Pb同位素年龄为285±30 Ma,时代为早二叠世.由此推断,阿吾拉勒晚古生代裂谷系火山活动在早二叠世时即将结束,之后晚二叠世接受陆相磨拉石堆积,进入稳定陆内盆地发展阶段.  相似文献   

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

V.V. Korobkin  M.M. Buslov 《Russian Geology and Geophysics》2011,52(12):1600-1618

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.  相似文献   

Chinese Continental Blocks in Global Paleocontinental Reconstruction during Paleozoic and Mesozoic     

WAN Tianfeng  ZHU Hong 《《地质学报》英文版》2011,85(3):581-597

The Cambrian to Cretaceous paleomagnetic data from Chinese continental and adjacent blocks were collected using principles to obtain reliable and high-precision paleomagnetic data and to pay attention to the similarity of paleobiogeography and the coordination of tectonic evolution. The Chinese continental blocks were laid up on the reconstruction of proposed global paleocontinents with almost the same scale. Thus, it can be clearly recognized that the global continents, including Chinese continental blocks, range along latitudes on the southern side of the equator during the Early Paleozoic. In the Paleozoic, Chinese continental blocks were still located among the Laurentia, Siberia and Gondwana plates, following the fast moving of the Siberia Plate northwards, the amalgamation in a north-south direction at the western parts of the Laurentia and Gondwana plates, and the Iapetus and Rheic Oceans were subducted, eventually to form a uniform Pangea in the Late Paleozoic. The Australian and Indian plates of Eastern Gondwana moved and dispersed gradually southwards, continued to extend the Paleo-Tethys Ocean. The Chinese continental and adjacent blocks were still located in the Paleo-Tethys Ocean, preserved the status of dispersion, gradually moving northwards, showing characteristics of ranging along a north–south orientation until the Permian. In addition, a series of local collisions happened during the Triassic, and consequently most of the Chinese continental blocks were amalgamated into the Pangea, except for the Gangdise and Himalayan blocks. There was a counter-clockwise rotation of the Eastern Asian continent in the Jurassic and northwards migration of the Chinese continent in varying degrees during the Cretaceous, but the Himalayan and Indian plates did not collide into the Chinese continent during this period.  相似文献   

First report of Lower Permian basalts in South Tibet: tholeiitic magmatism during break-up and incipient opening of Neotethys     

《Journal of Asian Earth Sciences》1999,17(4):533-546

The Neo-Tethys Ocean began to form at Early Permian times, when continental flood basalts were emplaced in various areas of the newly-formed Indian passive margin, exposed today in the so-called Tibetan Sedimentary Zone of the Himalaya. Lower Permian mafic volcanic rocks, which have long been known from various Himalayan localities from Kashmir to Arunachal Pradesh, are here for the first time reported to occur also in South Tibet (Bhote Kosi Basalts of the Gyirong County). The basalts unconformably overlie lowermost Permian diamictites, with locally intervening black shales and debris flow deposits, and are followed in turn by chert-bearing quartzarenites and silty to phosphatic marls yielding brachiopods of Roadian–Wordian age. The age of the lavas can thus be bracketed as late Early Permian (post-Sakmarian and pre-Roadian).The geochemistry of these subalkalic tholeiites, akin to MORBs, testifies to their similarity not only with the adjacent Nar-Tsum Spilites of central Nepal, but also with the Panjal Traps and Abor Volcanics of the western and eastern Himalayas respectively. The geochemical signature of Lower Permian volcanic rocks is in fact uniform all along the Himalayan Range, and markedly different from that of basaltic–rhyolitic alkalic products sporadically emplaced during the previous rifting stage. Rift volcanism in the Tethys Himalaya began in the Early Carboniferous and came to an end in Sakmarian times. In the Early Permian, initial submergence of the rift shoulders and sediment starvation were followed by tholeiitic magmatism, which is therefore interpreted as following break-up and incipient sea-floor spreading in the Neotethys Ocean. Roughly contemporaneous emplacement of continental flood basalts of similar geochemical signature along a 2000 km long rift axis would in fact suggest extensive mantle melting at the transition from continental rifting to break-up and opening of the Neotethys between Northern Gondwana and the Peri-Gondwanian blocks.  相似文献   

Upper Permian (Late Changhsingian) marine strata in Nan Province,northern Thailand     

《Journal of Asian Earth Sciences》2013

In the Upper Permian of northeastern Thailand (Loei Province), continental plants have been found and to the north in Laos near Luang Prabang, continental vertebrates (Dicynodon species) have been discovered. The Middle Permian is in sharp contrast to this as it is represented only by marine sediments. West of these areas in the province of Nan in Thailand, the Upper Permian is represented by marine sediments which extend to a high level in the Upper Permian and continental beds appear to be entirely absent, at least at Pha Dang Khwai, a locality where limestone extends from the end of the Lower Permian to the Triassic.  相似文献   

青藏高原北部半岛湖地区英安岩岩石特征及其地质意义   总被引：1，自引：0，他引：1  

王敏  黄勇  戴传固  陈仁  易成兴  贺永忠 《贵州地质》2004,21(3):141-147

青藏高原北部半岛湖地区英安岩岩石学、岩石化学、岩石地球化学特征指示半岛湖地区所属巴颜喀拉地体的大地构造位置在后中二叠世一段时期内曾经为可能受多岛弧背景影响的活动大陆边缘。  相似文献   

试论地幔柱构造与川滇西部古特提斯的演化   总被引：6，自引：0，他引：6  

肖龙  徐义刚  何斌 《地质科技情报》2005,24(4):1-6

基于全地幔对流(MOMO模式)提出的地幔柱构造理论将人们对地球深部的认识延伸到核幔边界.它和主要揭示地球表层构造的板块构造理论一起,为认识地球深部过程和大陆裂解等提供了新思路.在早古生代时期川滇西部古特提斯域几个大陆地块从位于赤道附近的冈瓦纳联合古大陆上裂解后又拼合到一起.该地区广泛分布的地幔柱活动产物和引起的浅表地质响应与特提斯的演化有很好的时空耦合关系,证明其间可能存在一个特提斯超级地幔柱,它可能是导致特提斯演化的原动力.根据古地磁资料和地幔柱活动的火成岩记录,认为特提斯超级地幔柱开始活动于晚志留世,结束于晚二叠世,历时约170 Ma.其幕式活动造成了3个陆块先后裂解脱离扬子地块,形成3个特提斯大洋和峨眉山大火成岩省.  相似文献   

The Oman Exotics: a key to the understanding of the Neotethyan geodynamic evolution     

Alain Pillevuit  Jean Marcoux  Gérard Stampfli  Aymon Baud 《Geodinamica Acta》2013,26(5):209-238

Abstract

The study of the exotic blocks of the Hawasina Nappes (Sultanate of Oman) leads to give apposit data that allow us to propose a new paleogeographic evolution of the Oman margin in time and space. A revised classification of exotic blocks into different paleogeographical units is presented. Two newly introduced stratigraphic groups, the Ramaq Group (Ordovician to Triassic) and the Al Buda’ah Group (upper Permian to Jurassic) are interpreted as tilted blocks related to the Oman continental margin. The Kawr Group (middle Triassic to Cretaceous) is redefined and interpreted as an atoll-type seamount. The paleogeography and paleoenvironments of these units are integrated into a new scheme of the Neotethyan rifting history. Brecciae and olistoliths of the Hawasina series are interpreted to have originated from tectonic movements affecting the Oman margin and the Neotethyan ocean floor. The breccias of late Permian age were generated by the extension processes affecting the margin, and by the creation of the Neotethyan oceanic floor. The breccias of mid-late Triassic age coincide in time with the collision of the Cimmerian continents with Eurasia. In constrast, the breccias of late Jurassic and Cretaceous age are interpreted as resulting to the creation of a new oceanic crust (Semail) off the Oman margin.  相似文献   

Depositional history and stratigraphical evolution of the Sakoa Group (Lower Karoo Supergroup) in the southern Morondava Basin, Madagascar     

William A. Wescott  John N. Diggens 《Journal of African Earth Sciences》1997,24(4):585-601

The Sakoa Group is the lowermost stratigraphical succession of the Karoo Supergroup and the oldest sedimentary unit in Madagascar, spanning the Late Carboniferous through Early Permian epochs. The Sakoa Group is exposed in the southern Morondava Basin. It is predominantly a siliciclastic sequence comprising seven lithofacies associations: (1) diamictites; (2) conglomeratic sandstones; (3) sandstones; (4) interbedded thin sandstones and mudstones; (5) mudstones; (6) coals; and (7) limestones. These facies represent deposition in the early extensional stages of continental rift development. The sediments were deposited predominantly on alluvial fans, and in braided to meandering stream and overbank environments. Locally lacustrine and coal swamp environments formed in low areas of the basin floor during rift initiation. Subsidence rates remained fairly constant throughout the Early Permian and were accompanied by a gradual reduction in relief of the basin margins and an increased geomorphic maturity of the fluvial systems flowing across the basin floor. Near the end of the Early Permian the southern Morondava Basin was inundated by a marine transgression , which resulted in deposition of the Vohitolia Limestone. Subsequent tectonic uplift and erosion resulted in a regional unconformity between the Sakoa Group and the overlying Sakamena Group.  相似文献   

The Role of India-Asia Collision in the Amalgamation of the Gondwana-Derived Blocks and Deep-Seated Magmatism During the Paleogene at the Himalayan Foreland Basin and Around the Gongha Syntaxis in the South China Block   总被引：1，自引：0，他引：1  

S.K. Acharyya 《Gondwana Research》2001,4(1):61

Southeast Asia comprises collage of continental blocks that were rifted out in phases from the northern parts of the Gondwanic Indo-Australian continent during the Paleozoic-Mesozoic time and were accreted through continental collision process following closure of the Paleo- and Neo-Tethys. The South China and Indo-China blocks were possibly rifted during early Palaeozoic, whereas, the Tibetan and SIBUMASU blocks were rifted during Permo-Carboniferous when the said margin was under glacial and/or cool climatic condition. The Indo-Burma-Andaman (IBA), Sikule, Lolotoi blocks were also rifted from the same Indo-Australian margin but during late Jurassic. This was followed by break-up of the Indian and the Australian continents during early Cretaceous. The opening of the Indian Ocean during the Tertiary was synchronous with closing of the Tethys.India-Asia collision during early-middle Eocene was a mega tectonic event. Apart from initiating the Himalayan orogeny and the eastward strike-slip extrusion of the Indochina block from the Southeast Asian continental collage along the Ailao Shan — Red River shear zone, it also caused early-mid Eocene continental-flood-basalt activity in the Himalayan foreland basin. Indian continent's post-collisional indentation-induced syntaxial buckling of Asian continental collage at its eastern end possibly caused late Paleogene highly potassic magmatism around the Gongha syntaxial area that was located close to the sutured margin of South China continent with Indochina block at the outer fringe of Namche Barwa syntaxis. These magmatic bodies are soon after left-laterally displaced by the Ailao Shan — Red River shear zone. The nature and chemistry of magma at these two settings indicate that both groups result from similar petrogenetic and tectonic processes representing deep-seated melts due to mantle decompression. Some deep faults produced at the edge of flexed Indian continental lithosphere and responsible for the development of the foreland basin may have produced continental-flood-basalt and related magma by decompressional melting of enriched sub-continental mantle. The site-specific location and time sequence of magmatism from the marginal parts of South China continent and located at the outer fringe of Namche Barwa syntaxis are strongly significant. It suggests that these magmatic bodies may also be genetically related to the India-Asia collision process and indentation-induced syntaxial buckling of upper mantle beneath the marginal parts of the South China rigid continent.  相似文献   

Ancient continental margins and comparative analysis of their oil-and-gas bearing     

A. Zabanbark  V. G. Kaz’min  L. I. Lobkovskii 《Doklady Earth Sciences》2010,431(1):308-311

Analysis of peculiarities in the distribution of hydrocarbon accumulations within the basins of Phanerozoic continental margins, which had completed their evolution, and complicated peripheral regions of ancient Laurasian and Gondwanian platforms nowadays, has enabled us to reveal certain regularities related to two stages in the evolution of sedimentary basins. The first stage of evolution of sedimentary basins (period of existence of the continental margin proper) is related to large accumulations of fluid and gaseous hydrocarbons in the margins of continents belonging to the Laurasian megablock; for the margins of continents belonging to Gondwana, this period was reflected in the formation of large gas accumulation only (in the Permian). At the second stage of sedimentary basin evolution, large oil and gas accumulations were formed in areas associated with fore deeps, which were laid in the boundary of the Gondwanian platforms and fold belts. In comparison, in fore deeps that emerged in the marginal parts of Laurasian platforms, less significant accumulations of fluid and gaseous hydrocarbons were found (Table 1). The results of comparative analysis in oil-and-gas bearing basins located in the margins of the Laurasian and Gondwanian megablocks would help in purposeful exploratory works for oil and gas.  相似文献