中国东南海域中生界油气地质条件与勘探前景

中国东南海域中生代地处欧亚板块东南缘, 夹持于欧亚板块、太平洋板块与印度澳大利亚板块之间。以往对于该区域的油气勘探多集中于新生代。笔者在前人研究的基础之上, 结合新近获得的地震资料, 开展了中国东南海域及周缘油气地质条件研究。结果表明:中国东南海域中生界分布广, 东海南部、台湾岛以及台西南盆地发育中生界深海相硅质岩, 可能与冲绳缝合带和菲律宾巴拉望缝合带形成有关;南海北部及周缘陆区发育上三叠统下侏罗统海相和海陆交互相碎屑岩及上侏罗统白垩系陆相碎屑岩, 可能与印支期缝合带的形成有关。从海域钻井及周缘陆区沉积层序资料推断, 中国东南海域有两套发育良好的烃源岩, 具有较强的生烃潜力:上三叠统下侏罗统海相泥页岩, 有机碳质量分数为0.28%~14.96%, 干酪根类型主要以Ⅱ₂型和Ⅲ型为主;下白垩统海相泥页岩, 有机碳质量分数为0.60%~2.00%, 干酪根类型以偏Ⅱ₂Ⅲ型为主。该海域发育两套生储盖组合:一套以上三叠统下侏罗统泥页岩为烃源岩, 中、上侏罗统砂岩为储层, 下白垩统泥页岩为盖层;另一套以下白垩统泥页岩为烃源岩, 白垩系砂岩为储层, 上白垩统泥页岩为盖层。它们相互可以形成"古生新储"、"自生自储"油气藏组合。因此, 中国东南海域中生界是值得关注的油气勘探新领域。     

Palynology of seafloor samples collected by the 1911–14 Australasian Antarctic expedition: Implications for the geology of coastal East Antarctica

Fifty‐three sea‐floor samples close to Antarctica collected by Douglas Mawson during the Australasian Antarctic Expedition of 1911–1914 have beeen analysed for recycled palynomorphs. The distribution of the recycled microfossils provides a broad guide to the position of hidden sedimentary sequences on the Antarctic continental margin.

The samples were dredged off the East Antarctic coast between 91°E and 146°E. In three distinct ‐areas, concentrations of recycled palynomorphs suggest the presence nearby of eroding sedimentary sequences. Near the western edge of the Shackleton Ice Shelf the recycled suite suggests Early to Late Permian, Late Jurassic to mid‐Cretaceous, and Late Cretaceous to Early Tertiary sediments, with evidence for marine influence only in the Tertiary. Samples from the outer edge of the continental shelf and slope east of Cape Carr indicate Early Cretaceous and Late Cretaceous to Early Tertiary sequences, and the same age span is suggested by samples from the western side of the Mertz Glacier Tongue; in this area radio echosounding has suggested that inland sedimentary basins intersect the coast.

The sedimentary sequence predicted for the Shackleton Ice Shelf area probably faced the open Indian Ocean, at least since the Mesozoic. Cretaceous sequences predicted for the other localities occur at points on the Antarctic coast where they would be expected on the basis of most reconstructions. The area east of Cape Carr has as its conjugate’ coast part of the Great Australian Bight Basin; that off the Mertz Glacier, the area west of the Otway Basin. At both these areas on the southern Australian margin thick Cretaceous rift‐valley sequences occur.     

Bilelyeri Group, Antalya Complex: deposition on a Mesozoic passive continental margin, south-west Turkey

The Bilelyeri Group comprises complexly deformed Mesozoic sedimentary rocks of continental-margin affinities (Kumluca Zone). These are structurally intercalated between a coeval carbonate platform to the west (Bey Daǧlari Zone) and late Triassic ophiolitic rocks and sediments, interpreted as emplaced marginal oceanic crust, to the east (Gödene Zone). Four formations erected in the Bilelyeri Group record the later stages of continental rifting and the progressive development of part of a Mesozoic passive continental margin. The two late Triassic formations, the Telekta? Tepe and the Hatipalani Formations, are dominated by terrigenous clastic and calcareous clastic sediments, including large detached blocks of reef limestone. These rocks were laid down by mostly mass-flow and turbidity-flow into steep-sided rift depressions. Organic reefs were constructed in bordering shallow seas while terrigenous clastic sediment was shed from exposed basement horsts. Thick sequences of mafic lavas were extruded (Norian) in axial parts of the rift zones, followed by a regional change to deposition of pelagic Halobia-bearing limestone. This culminated in a major hiatus involving large-scale sliding of shallow-water limestones into deeper water. The Jurassic to early Cretaceous Dereköy Formation mostly consists of siltstones, radiolarian cherts and mudstones, intercalated with redeposited limestones and black shales. During this time parts of the margin were bordered by major offshore carbonate complexes constructed partly on basement fragments previously rifted off the parent continental areas. Black shales and reduced hemipelagic sediments were deposited in an elongate trough between the main platform and an offshore complex to the east. Some degree of margin reactivation in the early Cretaceous is indicated by renewed deposition of turbiditic sandstone and chloritic clays in some distal sequences. Strong relative enrichment of manganese in some horizons is attributed to offshore volcanic exhalations. Subsequent regional subsidence in the mid-to late Cretaceous is suggested by a switch to predominantly calcareous, pelagic sedimentation on the adjacent platform and the offshore massifs as well as on the Bilelyeri margin. Tectonic disruption of the platform edge during the late Cretaceous is implied by major redeposition of shallow-water shelf limestones in proximal Bilelyeri sequences. The Bilelyeri margin and the adjacent Gödene Zone were tectonically deformed in latest Cretaceous to early Tertiary time and were thrust over the adjacent Bey Daǧlari platform in the early Miocene. Viewed in an East Mediterranean perspective, the Bilelyeri sequences were part of a locally north-south trending segment of a regionally east-west margin to a substantial oceanic area further south. This segment apparently suffered significant strike-slip deformation both during its construction and its later emplacement. Instructive comparisons can be made with other areas of the East Mediterranean, especially south-west Cyprus.     

Cretaceous–Tertiary tectonic inversion of the Cotiella Basin (southern Pyrenees,Spain)

The Cotiella Nappe includes one of the most important Mesozoic basins of the southern Pyrenees, which was subsequently inverted during the Tertiary compression. The Late Cretaceous Cotiella Basin is here interpreted as the western sector of the Cretaceous Cotiella-Bóixols basin (100᎜ km wide), located in the central part of the southern Pyrenees. The present-day complex structure of the Cotiella Nappe is the result of the inversion process, linked to the emplacement of basement thrust sheets of the Axial zone. In its western sector, the Cotiella Nappe consists of several superimposed thrust sheets, with complex geometry, becoming simpler towards the east, with a single thrust surface and smaller displacements. The Cotiella-Bóixols basin underwent strong subsidence during the Early Cretaceous at its eastern sector, and its depocentre migrated westward during the Late Cretaceous. The reconstruction of the sedimentary basin to the pre-compressional stage shows that during the Mesozoic the Cotiella-Bóixols basin was located to the south of a basement high, which later became the Pyrenean Axial Zone. From a balanced cross section, it can be inferred that the Cotiella, north-verging extensional system was connected with the north-Pyrenean rift by means of a 10-km deep horizontal detachment. The compressional Tertiary detachment within the upper crust was shallower than the extensional detachment, and individualised four basement thrust sheets, which form the Axial Zone antiform.     

Stratigraphic and structural evolution of the Blue Nile Basin,Northwestern Ethiopian Plateau

The Blue Nile Basin, situated in the Northwestern Ethiopian Plateau, contains ∼1400 m thick Mesozoic sedimentary section underlain by Neoproterozoic basement rocks and overlain by Early–Late Oligocene and Quaternary volcanic rocks. This study outlines the stratigraphic and structural evolution of the Blue Nile Basin based on field and remote sensing studies along the Gorge of the Nile. The Blue Nile Basin has evolved in three main phases: (1) pre‐sedimentation phase, include pre‐rift peneplanation of the Neoproterozoic basement rocks, possibly during Palaeozoic time; (2) sedimentation phase from Triassic to Early Cretaceous, including: (a) Triassic–Early Jurassic fluvial sedimentation (Lower Sandstone, ∼300 m thick); (b) Early Jurassic marine transgression (glauconitic sandy mudstone, ∼30 m thick); (c) Early–Middle Jurassic deepening of the basin (Lower Limestone, ∼450 m thick); (d) desiccation of the basin and deposition of Early–Middle Jurassic gypsum; (e) Middle–Late Jurassic marine transgression (Upper Limestone, ∼400 m thick); (f) Late Jurassic–Early Cretaceous basin‐uplift and marine regression (alluvial/fluvial Upper Sandstone, ∼280 m thick); (3) the post‐sedimentation phase, including Early–Late Oligocene eruption of 500–2000 m thick Lower volcanic rocks, related to the Afar Mantle Plume and emplacement of ∼300 m thick Quaternary Upper volcanic rocks. The Mesozoic to Cenozoic units were deposited during extension attributed to Triassic–Cretaceous NE–SW‐directed extension related to the Mesozoic rifting of Gondwana. The Blue Nile Basin was formed as a NW‐trending rift, within which much of the Mesozoic clastic and marine sediments were deposited. This was followed by Late Miocene NW–SE‐directed extension related to the Main Ethiopian Rift that formed NE‐trending faults, affecting Lower volcanic rocks and the upper part of the Mesozoic section. The region was subsequently affected by Quaternary E–W and NNE–SSW‐directed extensions related to oblique opening of the Main Ethiopian Rift and development of E‐trending transverse faults, as well as NE–SW‐directed extension in southern Afar (related to northeastward separation of the Arabian Plate from the African Plate) and E–W‐directed extensions in western Afar (related to the stepping of the Red Sea axis into Afar). These Quaternary stress regimes resulted in the development of N‐, ESE‐ and NW‐trending extensional structures within the Blue Nile Basin. Copyright © 2008 John Wiley & Sons, Ltd.     

辽西中生代波罗赤盆地特征及盆地性质探讨

本文是朱碌科镇幅等两幅1：5万区调成果的一部分,通过分析盆地内的物质记录、火山岩特征、控盆构造,说明辽西地区中生代陆相沉积盆地的形成具有明显的旋回性,每一旋回均以强烈的火山喷发为先导,继而盆地沉降接受沉积.从早期到晚期,波罗赤盆地从西向东迁移.盆地早期形成于压性环境,晚期形成于拉张环境.波罗赤盆地形成时代为中侏罗世—晚白垩世早期.     

中国东南部侏罗纪—第三纪陆相地层沉积特征

系统分析、总结了中国东南部地区中新生代地层的分布状况、沉积作用、构造特征 ,反映出地层分布总体上具 NE走向、SE— NW的分带现象 ,现今盆地的面貌有五种不同类型及相应的几何形态。分析认为 ,中国东南部早、中侏罗世普遍为拉张裂陷沉积环境 ,在赣南、粤北、闽西一带发育双峰式火山岩 ;稍后可能受到区域性挤压 ,如皖南、浙西、赣东北等地有南东向北西逆冲的压性构造 ;早白垩世为火山喷发高峰期 ,研究区均不同程度发生了火山喷发 ,其中东南沿海发育大面积的火山岩 ;早白垩世以后华南全区转为拉张 ,发育大量中、小型断陷盆地等伸展型盆地 ;晚白垩世—第三纪地壳继续处于拉张松弛环境 ,形成以裂谷环境为主要特征的火山—沉积岩石组合。这些结果表明 ,早—中侏罗世受古特提斯构造域和太平洋构造域的共同影响 ,中侏罗世之后太平洋板块占主导 ,上述现象主要系太平洋板块在晚中生代不同阶段对中国东南部俯冲作用的方位、俯冲速率、俯冲角度有所变化所导致     

海南岛南部侏罗系的发现——来自碎屑锆石U-Pb年龄及Hf同位素的证据

海南岛一直被认为缺失侏罗纪沉积记录,指示了海南岛与大陆内部不一样的中生代演化特征。对海南岛南部三亚地区尖岭剖面和海螺岭剖面紫红色碎屑岩,以及早白垩世鹿母湾组进行了详细的野外地质调查和碎屑锆石U-Pb同位素分析。结果表明,尖岭剖面和海螺岭剖面的紫红色碎屑岩具有高度一致的碎屑锆石年龄谱,限定的最大沉积年龄为172～174Ma,完全不同于下伏晚奥陶世榆红组和海南岛早白垩世鹿母湾组沉积岩的碎屑锆石年龄谱。综合区域构造-岩浆活动和中—新生代碎屑锆石年代学分析结果及尖岭剖面紫红色碎屑岩中锆石Hf同位素特征,认为海南岛三亚地区尖岭和海螺岭紫红色碎屑岩应沉积于172～158Ma之间,属于中—晚侏罗世沉积岩。其沉积物源和构造背景与广东东部和福建沿海同时代沉积岩相似,指示华南东南沿海地区在中—晚侏罗世具有统一的大地构造背景。     

北京西山——一个早中生代拗拉谷的一部分

华北地台北部的燕辽带在晚元古代时为一拗陷带,蓟县地区的整个层系厚度在10,000m以上。中生代时发生强烈的岩浆活动和形变。其构造性质与地台的含义并不相符,前人对该区有沉降带、台褶带等提法。     

Hotspot origin of the Mississippi embayment and its possible impact on contemporary seismicity

Previous authors have related the Late Cretaceous/early Tertiary subsidence of the Mississippi embayment to the opening of the Gulf of Mexico, but the Gulf opened earlier in Triassic/Jurassic time. We offer an alternative hypothesis that development of the embayment was coeval with the passage of the Mississippi Valley graben system over the Bermuda hotspot about 90 Ma. Several lines of evidence of significant uplift of the embayment axis accompanying mid-Cretaceous magmatism and prior to Late Cretaceous subsidence support this proposal.

First, reactivation of the Pascola arch in the northern embayment is recorded by flanking deposits of basal Upper Cretaceous gravel. Second, beneath a regional mid-Cretaceous unconformity, subcrops of Jurassic and Early Cretaceous strata define a pronounced southwest-plunging arch in the southern embayment. This arch is collinear with an arch revealed in Paleozoic rocks after restoration to mid-Cretaceous structural geometries. Third, a deep weathering profile on mid-Cretaceous alkalic plutons along the western embayment margin is nonconformably overlain by Paleocene sediments, and rapid mid-Cretaceous cooling of these intrusions has been interpreted from apatite fission tracks. Moreover, exploratory holes along the embayment axis encountered similar weathered alkalic intrusions nonconformably overlain by basal Upper Cretaceous strata. Fourth, there was an anomalous influx of clastic sediment into the northern Gulf of Mexico during mid-Cretaceous time, and subsequent clastic facies patterns suggest the Mississippi River drainage began to enter the Gulf in the Late Cretaceous.

Passage of the Mississippi Valley graben over the Bermuda hotspot during elevated hotspot activity of Cretaceous time may have significantly weakened the previously rifted lithosphere. Rifted continental margin at Charleston, South Carolina, also passed over this hotspot in latest Cretaceous time. Similarly, the St. Lawrence rift system passed over the Great Meteor hotspot during the Cretaceous. It is important to note that these rift systems are the principal loci of strong seismicity in eastern North America, and thus weakening by increased Cretaceous hotspot activity may be an important common factor for these seismic rift zones.     

南海东北部中生界岩石学特征及沉积环境

南海东北部潮汕坳陷发现中—晚侏罗世到白垩纪的海相中生代地层,由泥岩、砂岩、放射虫硅质岩夹鲕粒灰岩及火山岩构成。岩石组合及沉积特征反映出,从中-晚侏罗世到白垩纪沉积水深经历了由浅到深,然后又转为陆地的一个完整旋回,沉积环境则经历了由滨浅海相到深海相,又到滨海过渡相和陆相河湖体系的演变过程,在深海相与滨海陆地过渡相之间存在一个明显的环境突变,为沉积环境缺失所致。与深海相放射虫硅质岩相伴,则夹有玄武岩（细碧岩）层。沉积反应的气候条件从中-晚侏罗世-早白垩世的温暖湿润气候环境过渡到晚白垩世的炎热干旱气候环境。这套海相中生代地层的存在对解释南海北部中生代大地构造演化以及古特提斯洋和太平洋的关系具有重要意义。     

西藏羌塘盆地中生界烃源岩探讨

羌塘盆地位于青藏高原中北部全球油气产量最高、储量最丰的特提斯构造域中段，是一复合对称型前陆盆地，具有广泛的中生界海相沉积和中国最年轻的海相地层，沉积厚度可达万米，其中侏罗系占一半以上。盆地经历了晚古生代大陆边缘沉积阶段、三叠纪陆间裂谷阶段、侏罗纪大陆边缘沉积阶段和侏罗纪末班公湖—怒江缝合带闭合以来的构造反转挤压一长期剥蚀阶段。羌塘盆地中生代具有广泛分布且发育良好的烃源岩，烃源岩厚度大，最厚处可达3000m以上，其中上三叠统的肖茶卡组、中侏罗统布曲组和夏里组有机质类型好，丰度高，成熟度从成熟到过成熟均有分布。埋藏较好，其生油量巨大，是盆地油气的主要来源之一。     

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。     

The transition from passive to active margin tectonics: a case study from the zone of Samedan (eastern Switzerland)

The Zone of Samedan is part of a fossil, early Mesozoic rift system originally situated in the distal, Lower Austro-Alpine domain of the Adriatic passive continental margin. An early Mesozoic configuration of asymmetrical rift basins bounded by relative structural highs compartmentalized Late Cretaceous active margin tectonics; Jurassic half-grabens were folded into arcuate synclines, whereas relative structural highs engendered thin, imbricated thrust sheets. West-directed thrusting and folding initiated at the surface and continued to depths favoring mylonitization under lower greenschist-facies conditions. At this time Liguria-Piemontese ophiolites were accreted to Lower Austro-Alpine units directly underlying the Zone of Samedan. Late Cretaceous orogenic collapse of the Adriatic active margin involved the reactivation of west-directed thrusts as low-angle, top-to-the-east, normal faults. These faults accommodated extensional uplift of Liguria-Piemontese ophiolites and Lower Austro-Alpine units beneath and within the Zone of Samedan. During Paleogene collision, some Late Cretaceous faults in the Zone of Samedan were reactivated under lower anchizonal conditions as north-directed thrusts. The latter stages of this early Tertiary thickening were transitional to brittle, high-angle normal faulting associated with top-to-the-east extension and spreading above the warm, uplifting Lepontine dome.     

大兴安岭─燕山地层分区中、新生代地层

对大兴安岭和燕山北部的中生代地层，进行了系统的总结。侏罗纪早中期为含煤地层，晚期为以兴安岭群为代表的火山堆积；白垩纪早期为火山－沉积含煤地层，晚期为红层。第三纪以二连盆地合大量哺乳动物群的杂色沉积为特征。     

Seismic stratigraphy of sedimentary cover in the Podvodnikov Basin and North Chukchi trough

The multichannel seismic reflection data (MCS data) obtained in the Arktika-2014 expedition revealed the essential fact that must be taken into account by the tectonic model of the Central Arctic region. The Brookian, Lower Cretaceous, and Upper Jurassic unconformities are continuously traced from the North Chukchi offshore trough into the Podvodnikov Basin, indicating that the depocenter in the latter accumulated both Cretaceous sedimentary sequences and Early–Middle Mesozoic ones.     

南沙海区礼乐盆地沉积地层与构造特征分析

通过对地震剖面、钻井及拖网采样资料的分析,认为礼乐盆地发育有海相的中、新生代地层,存在晚白垩世与晚渐新世两个区域性不整合面,将沉积层分为三套构造层:下构造层较厚,为中生代地层,表现为翘倾断块和宽缓背斜两种构造样式;中构造层较薄甚至局部缺失,为古新世-早渐新世充填的张裂期沉积,表现为半地堑构造样式;上构造层为晚渐新统至第四系沉积,充填区域沉降期海相地层,地层较为平稳。在中构造层沉积过程中发育多排NE向控洼断裂,断裂倾向NW,形成多个半地堑,控制了新生代早期的沉积充填,同时也表现出礼乐盆地在新生代早期受明显的张裂作用。通过对各构造层的构造、沉积特征分析,认为礼乐盆地经历了挤压、拉张、漂移、区域沉降四个构造演化阶段,是一个以中生代地层为主的叠合盆地。     

西藏措勤盆地中侏罗世—早白垩世沉积充填特征

位于班公湖 怒江缝合带与雅鲁藏布江缝合带之间的措勤盆地,在中侏罗世—早白垩世期间具有以且坎古昌 阿索裂谷带为沉积、沉降中心向南北两侧展开的古地理格局:①中晚侏罗世时期,裂谷带内由深水浊积岩、放射虫硅质岩和浅水碳酸盐岩、碎屑岩岩片及基性—超基性岩等组成;裂谷带两侧由滨浅海相碎屑岩和碳酸盐岩组成。该期盆地古地理演化具有先变深后变浅的沉积序列。②早白垩世早中期,裂谷带内仍由基性—超基性岩、深水复理石碎屑岩及放射虫硅质岩和浅水碳酸盐岩及碎屑岩组成;裂谷带两侧的日松革吉它日错分区主要由浅海相碎屑岩和灰岩组成;盆地南北部的措勤 申扎分区和木嘎岗日分区主要由滨岸 三角洲相碎屑岩及火山岩组成。各相带在纵向上均具有向上变深沉积序列。③早白垩世晚期,盆地以台地相碳酸盐岩沉积为主,裂谷带附近以发育台地边缘礁滩相沉积;裂谷带两侧的日松 革吉 它日错分区主要由开阔台地相灰岩组成;盆地南北部的措勤 申扎分区和木嘎岗日分区由局限台地相灰岩和陆源进积碎屑岩组成。     

Stratigraphy and sedimentary history of the Nepal Tethys Himalaya passive margin

The sedimentary history of the Nepal Tethys Himalaya began with deposition of thick carbonates in the Cambro?–Ordovician, followed by a mixed siliciclastic–carbonate epicontinental succession recording two major deepening events in the Early Silurian and Late Devonian. Fossiliferous carbonate ramp deposits in the Tournaisian were disconformably followed by white quartzose sandstones and black mudrocks with locally intercalated diamictites derived from sedimentary rocks and deposited in asymmetric tectonic basins (“rift stage”). Break-up in the mid-Early Permian, locally associated with effusion of tholeiitic lava flows, was followed by a transgressive sandy to shaly, locally coal-bearing or bioclastic unit capped by condensed pelagic carbonates in the Middle to Late Permian (“juvenile ocean stage”). Subsidence of the cooling stretched crust led close to bathyal water depths in the Olenekian, but then slowed down in the Middle Triassic to increase again sharply in the Late Triassic owing to renewed extensional tectonic activity and sediment loading during up- and out-building of the Indian continental terrace. Deposition of tropical platform carbonates finally became widespread in the middle Liassic (“mature passive margin stage”). The initial fragmentation of Gondwana in the Middle Jurassic led to rejuvenation of the Indian craton and deposition of quartzo-feldspathic hybrid arenites, capped by condensed oolitic ironstones deposited at warm subtropical latitudes in the late Bathonian/middle Callovian. Next, a discontinuous pelagic grey marly limestone unit was followed by the ammonoid-rich offshore Spiti Shale in the Late Jurassic. The final disintegration of Gondwana began in the Berriasian, when quartzose siliciclastics derived again from the rejuvenated Indian craton and partly from recycling of older clastic successions were followed by thick deltaic to shelf volcaniclastics documenting eruption of alkali basalts in the Valanginian? followed in the Hauterivian to Albian by more felsic differentiates such as the trachyandesites exposed in the Lesser Himalaya 120 km to the south. A widespread drowning episode, fostered by waning volcaniclastic supply during a global eustatic rise, is documented by a major glauconitic horizon deposited at middle southern latitudes in the late Albian, overlain by “Scaglia-like” pelagic limestones in the latest Albian. The final part of sedimentary history, during the rapid northward flight of India and its collision with Eurasia, is not documented anywhere in Nepal due to later erosion of Upper Cretaceous to Lower Tertiary strata.     

塔里木盆地西南缘中生代沉积古环境恢复

对塔里木盆地西南缘中生代沉积相和沉积环境的研究,不仅可以了解晚三叠世—晚白垩世塔里木板块南缘活动大陆边缘的历次碰撞事件,也为研究新生代中亚地区强烈的陆内变形活动提供了重要信息。本文利用野外地质调查结果和地球物理资料,在沉积相和地震相分析基础上,重建中生代沉积体系和沉积环境。结果表明:塔里木盆地西南缘中生界的原始分布受晚三叠世弧后前陆冲带冲断作用和造山后伸展作用形成的古地形控制。早侏罗世发育了一系列独立分割的小断陷,以巨厚的冲积扇、辫状河三角洲沉积为特征,其受控于NWW—SEE走向的正断层,而非NW—SE走向的古塔拉斯-费尔干纳右旋走滑断裂;早侏罗世晚期—中侏罗世广泛发育滨浅湖和河流-沼泽相沉积,可能存在一个连通了塔里木盆地南缘、吐拉以及柴达木盆地西缘的统一沉积坳陷;至晚侏罗世,冲积环境再次出现,发育的粗粒碎屑岩为早白垩世湖盆扩张前的产物;早白垩世,丰富的陆源碎屑在古昆仑山前形成多个相互叠置的冲积扇—扇三角洲—扇三角洲平原沉积体;晚白垩世,随着海水自西向东侵入,塔里木盆地西南缘陆相碎屑沉积向东逐渐退却,海相沉积占有优势。