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南沙海区万安盆地构造演化与成因机制 总被引:2,自引:1,他引:1
本文基于地震、钻井和区域地质资料,运用回剥法和平衡剖面技术定量研究了万安盆地的构造沉降和伸展程度,重建盆地的构造演化史并探讨其成因机制。模拟结果表明,万安盆地构造沉降曲线为多段式,其南北部构造沉降差异明显,且沉降中心逐渐向南发展的趋势。晚始新世-渐新世(37.8~23.03 Ma BP)盆地中、北部快速沉降,存在两个沉降中心;早中新世(23.03~16.0 Ma BP)盆地南部也发生快速沉降,整个盆地存在3个沉降中心;中中新世(约16.0~11.63 Ma BP)沉降作用减弱,盆地进入裂后热沉降期。万安盆地的伸展和形成演化呈现北早南晚的特征,与南海海底扩张密切相关,同时受控于万安断裂带交替地右旋-左旋走滑作用,是伸展和走滑双重作用的结果。盆地的构造演化过程可细分为4个阶段:初始裂谷期、主要裂谷期、走滑改造期和裂后加速沉降期。 相似文献
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The development of stratigraphic sequences has been demonstrated to be controlled by a set of factors including variations in subsidence, sediment input, eustatic sea level and physiography. Well and seismic data from the Jeanne d'Arc Basin, Grand Banks indicate that mid-Cretaceous tectonism controls at least three of these factors, namely subsidence, sediment input and physiography. North Atlantic rift tectonism was therefore the dominant factor in controlling the migration of coastal to shallow marine environments and the development of sequence stratigraphy in this basin during the mid-Cretaceous. The Avalon Formation respresents a mainly Barremian to Early Aptian regressive phase of clastic, marine to marginal marine sedimentation. This followed the deposition of a thick sequence of mainly marine limestones and shales of the Whiterose Formation above a mid-Valanginian sequence-bounding unconformity. The increased clastic input and northward progradation of coastal environments represented by the Avalon Formation occurred during uplift of a basement arch to the south with subsidence of the basin increasing to the north, accompanied by only relatively minor faulting. These features indicate that a period of epeirogenesis was initiated during the Barremian. Continuing uplift over an expanding area at the southern end of the basin is interpreted to have resulted in the development of an angular unconformity with incised valleys. This mid-Aptian unconformity defines the top of the Whiterose/Avalon sequence. Initiation of brittle fracturing of the sedimentary package and underlying basement (i.e. rifting) in mid-Aptian times resulted in rapid fault-controlled subsidence and fragmentation of the Jeanne d'Arc Basin. This great increase in subsidence rate caused retrogradation of coastal environments across the previously developed sequence-bounding unconformity, despite continuing high rates of sediment input from the uplifted basin margins. The transgressive, siliciclastic Ben Nevis Formation comprises two separate but related facies associations. A locally preserved basal association represents interfingering back-barrier environments and is herein defined as the Gambo Member. An upper, ubiquitous facies association comprises tidal-inlet channel, shoreface and lower shoreface/offshore transition sandstones. This upper facies association onlapped marine ravinement diastems above the laterally equivalent back-barrier facies. The rapid fault-controlled subsidence and high sediment input rate of this mid-Aptian to late Albian rift period resulted in the accumulation and preservation of very thick shoreface sandstones. The transgressive sandstones were buried by laterally equivalent offshore shales of the Nautilus Formation. Flooding of the basin margins induced by the onset of thermal subsidence in latest Albian or early Cenomanian times marks the top of the Ben Nevis/Nautilus syn-rift sequence. 相似文献
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A tectonostratigraphic model for the evolution of rift basins has been built, involving three distinct stages of basin development separated by key unconformities or unconformity complexes. The architecture and signature of the sediment infill for each stage are discussed, with reference to the northern North Sea palaeorift system. The proto-rift stage describes the rift onset with either doming or flexural subsidence. In the case of early doming, a proto-rift unconformity separates this stage from the subsequent main rift stage. Active stretching and rotation of fault blocks during the rift stage is terminated by the development of the syn-rift unconformity. Where crustal separation is accomplished, a break-up unconformity commonly marks the boundary to the overlying thermal relaxation or post-rift stage. Tabular architectures, thickening across relatively steep faults, characterize the proto-rift stage. Syn-rift architectures are much more variable. Depending on the ability of the sediment supply to fill the waxing and waning accommodation created during rotation and subsidence, one-, two- or three-fold lithosome architectures are likely to develop. During the post-rift stage, an early phase with coarse clastic infilling of remnant rift topography often precedes late stage widening of the basin and filling with fine-grained sediments. 相似文献
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Significant oil and gas accumulations occur in and around Lougheed Island, Arctic Canada, where hydrocarbon prospectivity is controlled by potential source rock distribution and composition. The Middle to Upper Triassic rocks of the Schei Point Group (e.g. Murray Harbour and Hoyle Bay formations) contain a mixture of Types I and II organic matter (Tasmanales marine algae, amorphous fluorescing bituminite). These source rocks are within the oil generation zone and have HI values up to 600 mg HC/g Corg. The younger source rocks of the Lower Jurassic Jameson Bay and the Upper Jurassic Ringnes formations contain mainly gas-prone Type II/III organic matter and are marginally mature. Vitrinite reflectance profiles suggest an effective geothermal gradient essentially similar to the present-day gradient (20 to 30°C/km). Maturation gradients are low, ranging from 0.125 to 0.185 log%Ro/km. Increases in subsidence rate in the Early Cretaceous suggest that the actual heat flow history was variable and has probably diminished from that time. The high deposition rates of the Christopher Formation shales coincide with the main phase of rifting in Aptian-Albian times. Uplift and increased sediment supply in the Maastrichtian resulted in a new sedimentary and tectonic regime, which culminated in the final phase of the Eurekan Orogeny. Burial history models indicate that hydrocarbon generation in the Schei Point Group took place during rifting in Early Cretaceous, long before any Eurekan deformation. 相似文献
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The Pelotas Basin is the classical example of a volcanic passive margin displaying large wedges of seaward-dipping reflectors (SDR). The SDR fill entirely its rifts throughout the basin, characterizing the abundant syn-rift magmatism (133–113 Ma). The Paraná–Etendeka Large Igneous Province (LIP), adjacent to west, constituted the pre-rift magmatism (134–132 Ma). The interpretation of ultra-deep seismic lines showed a very different geology from the adjacent Santos, Campos and Espírito Santo Basins, which constitute examples of magma-poor passive margins. Besides displaying rifts totally filled by volcanic rocks, diverse continental crustal domains were defined in the Pelotas Basin, such as an outer domain, probably constituted by highly stretched and permeated continental igneous crust, and a highly reflective lower crust probably reflecting underplating.The analysis of rifting in this portion of the South Atlantic is based on seismic interpretation and on the distribution of regional linear magnetic anomalies. The lateral accretion of SDR to the east towards the future site of the breakup and the temporal relationship between their rift and sag geometries allows the reconstitution of the evolution of rifting in the basin. Breakup propagated from south to north in three stages (130–127.5; 127.5–125; 125–113 Ma) physically separated by oceanic fracture zones (FZ). The width of the stretched, thinned and heavily intruded continental crust also showed a three-stage increase in the same direction and at the same FZ. Consequently, the Continental-Oceanic Boundary (COB) shows three marked shifts, from west to east, from south to north, resulting into rift to margin segmentation. Rifting also propagated from west to east, in the direction of the final breakup, in each of the three segments defined. The importance of the Paraná–Etendeka LIP upon the overall history of rupturing and breakup of Western Gondwanaland seems to have been restricted in time and in space only to the Pelotas Basin. 相似文献
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Analysis of multi-channel seismic data from the northern East China Sea Shelf Basin (ECSSB) reveals three sub-basins (Socotra, Domi, and Jeju basins), separated by structural highs (Hupijiao Rise) and faulted basement blocks. These sub-basins show a typical rift-basin development: faulted basement and syn-rift and post-rift sedimentation separated by unconformities. Four regional unconformities, including the top of acoustic basement, have been identified and mapped from multi-channel seismic data. Faults in the acoustic basement are generally trending NE, parallel to the regional structural trend of the area. The depths of the acoustic basement range from less than 1000 m in the northwestern part of the Domi Basin to more than 4500 m in the Socotra Basin and 5500 m in the Jeju Basin. The total sediment thicknesses range from less than 500 m to about 1500 m in the northwest where the acoustic basement is shallow and reach about more than 5500 m in the south.Interpretation of seismic reflection data and reconstruction of three depth-converted seismic profiles reveal that the northern ECSSB experienced two phases of rifting, followed by regional subsidence. The initial rifting in the Late Cretaceous was driven by the NW-SE crustal stretching of the Eurasian Plate, caused by the subduction of the Pacific Plate beneath the Eurasian Plate. Extension was the greatest during the early phase of basin formation; estimated rates of extension during the initial rifting are 2%, 6.5%, and 3.5% in the Domi, Jeju, and Socotra basins, respectively. A regional uplift terminated the rifting in the Late Eocene-Early Oligocene. Rifting and extension, although mild, resumed in the Early Oligocene; while fluvio-lacustrine deposition continued to prevail. The estimated rates of extension during the second phase of rifting are 0.7%, 0.8%, and 0.5% in the Domi, Jeju, and Socotra basins, respectively. A second phase of uplift in the Early Miocene terminated the rifting, marking the transition to the post-rift phase of regional subsidence. Regional subsidence dominated the study area between the Early Miocene and the Late Miocene. An inversion in the Late Miocene interrupted the post-rift subsidence, resulting in an extensive thrust-fold belt in the eastern part of the area. Uplift and subsequent erosion were followed by regional subsidence. 相似文献
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珠江口盆地第三纪古地理及沉积演化 总被引:5,自引:0,他引:5
珠江口盆地第三纪以来经历了断陷、拗陷两个构造演化阶段,具有“南北分带”、“东西分块”的构造格局和先陆后海的沉积特征。本文根据前人资料进行综合整理,编制了珠江口盆地古近纪神狐组、文昌组、恩平组、珠海组地层和新近纪珠江组地层的岩相古地理图。神狐组发育有冲积扇和河湖相,主要分布在珠三坳陷南断裂的狭长地带。文昌组沉积半深湖—深湖相,恩平组水深变浅,河沼相广泛分布。珠海组岩相古地理发生了较大的变化,为海陆过渡相沉积。随后海平面振荡上升,珠江口盆地处于陆架—陆坡环境,发育浅海—半深海沉积。对整个珠江口盆地岩相古地理图的编制为详细研究盆地内各区块的岩相古地理演变提供了区域背景,也为区域构造演化和油气地质条件的研究提供了基础依据。 相似文献
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The dynamic mechanism of post-rift accelerated subsidence in Qiongdongnan Basin, northern South China Sea 总被引:2,自引:0,他引:2
Zhongxian Zhao Zhen Sun Zhenfeng Wang Zhipeng Sun Jianbao Liu Zhangwen Wang Longtao Sun 《Marine Geophysical Researches》2013,34(3-4):295-308
A 1-D unloaded tectonic subsidence (air-loaded tectonic subsidence) model is proposed and applied to the Qiongdongnan Basin. Results show that three episodes of subsidence exist in Cenozoic, that is, syn-rift rapid subsidence (Eocene–Oligocene) with subsidence rate at 20–100 m/m.y., post-rift slow thermal subsidence (early-middle Miocene) around 40 m/m.y., and post-rift accelerated subsidence (since late Miocene) 40–140 m/m.y., which is substantially deviated from the exponentially decayed thermal subsidence model. For exploring the mechanism of post-rift accelerated subsidence, the faulting analyses are conducted and results show that there is a dramatically decrease in the numbers of active faults and fault growth rate since 21 Ma, which indicates that no active brittle crust extension occurred during post-rift period. Furthermore, previous studies have demonstrated that the stretching of the upper crust is far less than that affecting the whole crust. Therefore, we infer that the lower crust thinned during the post-rift period and a new model of basin development and evolution is put forward to explain the post-rift accelerated subsidence and depth-dependent crust thinning in the Qiongdongnan Basin, which is supported by gravity data. 相似文献
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《Marine and Petroleum Geology》1987,4(3):205-225
China comprises a mosaic of distinct continental fragments separated by fold belts. These fold belts are suture zones resulting from the accretion of various fragments formerly separated by intervening areas of oceanic crust.The major sedimentary basins onshore China can be classified into four groups. Those in western China are flexural, developing as a result of north-south compression. In contrast, those in the east are extensional and related to development of the Pacific oceanic margin. In central China, basins have a more problematic origin. Those of north central China (Ordos, Sichuan) are flexural basins controlled by eastward directed thrusting along their western margin. In contrast, basins further south (Chuxiong, Shiwandashan) are predominantly extensional and related to major strike-slip movements.By synthesizing basin stratigraphies across China in tectonostratigraphic terms (and in particular comparing the nature and timing of unconformities), it is possible to formulate a coherent model for the palaeoreconstruction of China. We identify five major tectonostratigraphic breaks which equate with the collision of the following continental fragments: Tarim/North China (Carboniferous-Permian), South China Block (Permian-Triassic), Qiantang (Late Triassic-Early Jurassic), Lhasa Block (Late Jurassic-Early Cretaceous) and India (Early Tertiary).Prior to Permian times, the southern margin of Eurasia ran approximately along the northern border of modern China. The Late Carboniferous collision of Tarim/North China with Eurasia resulted in the development of a flexural basin (Junggar) and deposition of non-marine clastics. To the south of the suture, shallow marine deposition continued. In the Late Permian-Early Triassic, the progressive collision from east to west of the South China Block with the North China Block resulted in a change to fluvial/lacutrine sedimentation across the entire North China-Tarim block. Open marine carbonate deposition in the north of the South China Block passed southward into a deeper marine clastic sequence deposited in a backarc basin. Further south, a subduction zone existed along the southeastern margin of the South China Block.In western China, northward subduction throughout the Triassic resulted in the development of the Songban-Ganzi accretionary prism with retroarc thrusting resulting in flexure and the first development of the Tarim basin. Oblique collision of the Qiantang Block in the Late Triassic along the east of the South China Block resulted in east-west directed thrusting which initiated the Suchuan and Ordos basins. Continued strike-slip deformation along the south western margin of the South China Block resulted in the development of basins with a significant extensional component such as Chuxiong.The collision of the Qiantang Block with the southern edge of the Tarim Basin (Early Jurassic) resulted in a renewed clastic influx in both the Tarim and Junggar basins. Along the eastern (Pacific) margin a compressional arc and retroarc basin in the south passed northwards into an extensional arc system. Subduction rollback of the extensional arc initiated rifting in the Late Jurassic in the Eren and Songliao basins.The Late Jurassic-Early Cretaceous collision of the Lhasa Block in the west rejuvenated the thrust systems bordering the western basin and resulted in a renewed clastic influx. In the southeast, the compressional arc phase culminated in widespread thrusting and folding of Early Cretaceous age. In the northeast, extension continued with the progressive migration of the rift system southward with time.The arrival of the Indian Block in the Early Tertiary rejuvenated the bounding thrust belts of all the western basins. In the east, the change in convergence of the Pacific plate to a more westerly direction is marked by extension and widespread rifting along the entire length of Eastern China.Throughout most of China, Mesozoic and Cenozoic deposition occurred in predominantly non-marine environments. Source rocks in such settings comprise principally mudstones deposited in lakes (organic-rich mudstones). These can accumulate in both deep and shallow lakes. In order to accumulate substantial volumes, the lake must be significant in space and time.In China, lacustrine ORMs occur in both rift and flexural basins. Lacustrine ORMs deposited under humid climatic conditions are restricted to the period of maximum tectonic subsidence. In the flexural basins of western China, source rock deposition follows basin initiation by 20–30 Ma. In the extensional basins of eastern China, source rock deposition takes place 5–15 Ma after basin initiation. By contrast, semi-arid and arid climate lacustrine ORMs, whilst being best developed during the period of maximum tectonic subsidence, occur at all stages in the basin history. 相似文献
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The initial configuration of the Arctida Craton was reconstructed from a complex geological-geophysical analysis of the anomalous magnetic field of the Canadian Basin in the Arctic Ocean. The modern version of the bottom geochronology indicates that the first stage of the formation of the Canadian Basin in the Arctic Ocean was related to extension and rifting in the Arctida Craton in the Kimmeridgian. The transformation of rifting into spreading presumably occurred during chron M22Ar (151 Ma). The second stage was related to the opening of the Canadian Basin within chrons M22Ar-M19 (151–145 Ma). The next stage of the opening of the basin was marked by a 100-km jump of the spreading axis to the east. This stage ended after chron M5 (130 Ma ago). At the fourth (Late Cretaceous) stage, extension spanned the Southern Canadian Basin with the formation of large igneous province. 相似文献
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《Marine and Petroleum Geology》2003,20(2):177-206
The Late Cretaceous–Paleocene rifting in the NW Vøring Basin is characterized by four main fault complexes and pronounced upper-crustal structural segmentation. The fault complexes are linked by accommodation zones, which separate fault systems of different polarities and thick from thinner coeval sedimentary successions. Structural and stratigraphic analyses suggest that the early rift phase (∼81 to 65 Ma) was characterized by large-scale normal faulting, along-margin segmentation and varying structural styles; whereas the late rift phase (∼65 to 55 Ma) was associated with continued extension, regional uplift, intrusive igneous activity and subsequent erosion. The rifting ended with breakup at ∼55 Ma accompanied by massive, but gradually waning extrusive igneous activity over the next 3 Myr. The mode of rifting appears to have changed from brittle to more ductile extensional deformation from the early to late rift phase. The changing rift rheology is probably related to the arrival of the Iceland mantle plume and initiation of associated igneous activity. Hence, the NW Vøring Basin provides an example of complex interaction of structural and magmatic relationships during rifting and breakup. 相似文献
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从地质演化特征探讨墨西哥湾地区油气富集的基本规律 总被引:2,自引:0,他引:2
墨西哥湾东部主体经历了中生代裂谷拉张、中侏罗世裂谷和地壳衰减、晚侏罗世洋壳形成及早白垩世的区域沉降4个演化阶段;西部主要受中生代太平洋板块向北美板块的俯冲影响,属弧后拉张。由于持续稳定的沉降,墨西哥湾沉积了巨厚的以海相地层为主的中生代地层,并提供了有利的烃源岩、储层和盖层。大量的构造、地层和复合型圈闭为油气富集提供了有利的场所。墨西哥湾盆地为典型的高演化拉张盆地,巴西东部(包括海区)为中等演化拉张盆地,二者均已成为重要的油气富集区。我国东部海区中生界南部以海相地层为主,北部以陆相地层为主,为一个低—中等演化的拉张盆地。前二者的油气富集规律为我国东部海区中生代盆地的找油提供了借鉴作用。 相似文献
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The evaporite-cored Hoodoo Dome on southern Ellef Ringnes Island, Sverdrup Basin, was examined to improve the understanding of its structural geological history in relation to hydrocarbon migration. Data from geological mapping, reflection seismic, thermal maturity and detrital apatite (U–Th)/He cooling ages are presented. Five stages of diapirism are interpreted from Jurassic to Recent times:1. 180 to 163 Ma (pre-Deer Bay Formation; development of a diapir with a circular map pattern).2. 163 to 133 Ma (Deer Bay to lower Isachsen formations; development of salt wings).3. 115 to 94 Ma (Christopher and Hassel formations; ongoing diapirism and development of an oval map pattern)4. 79 Ma (Kanguk Formation; reactivation of the central diapir).5. 42 Ma to 65 Ma (Eurekan Orogeny; tightening of the anticline).During phase1, the Hoodoo diapir was circular. During phase 2, salt wings formed along its margin. During phase 3, the Hoodoo Dome geometry evolved into a much larger, elongate, doubly plunging anticline. Phase 4 is inferred from thermochronology data as indicated by a cluster of cooling ages, but the extent of motion during that time is unknown. During Phase 5 the dome was tightened creating approximately 700 m of structural relief. Denudation since the end of the Eurekan Orogeny is estimated to be about 600 m.A one dimensional burial history model predicts hydrocarbon generation from Middle and Late Triassic source rocks between 140 and 66 Ma, with majority of hydrocarbon expulsion between 117 and 79 Ma. Hydrocarbon generation post-dates salt wing formation, so that this trap could host natural gas expelled from Triassic source rocks. 相似文献
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渤海湾及沿岸盆地的构造格局 总被引:4,自引:0,他引:4
渤海湾及沿岸盆地面积约20万平方公里,包括河北省,山东省北部和西部、辽宁省南部、河南省北部、天津市和北京市等陆地面积约12万7千平方公里,渤海海域面积为7万多平方公里。陆地面积大部被第四纪冲积层所覆盖。渤海最大深度为70米,平均深度为18米。这是一个大型的第三纪断陷-坳陷沉积盆地,是继大庆油田开发之后,在我国东部地区所开发的另一个重要的含油气盆地(图1)。 相似文献
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Tectonic evolution of the Cape and Karoo basins of South Africa 总被引:1,自引:0,他引:1
Anthony Tankard Herman Welsink Peter Aukes Robert Newton Edgar Stettler 《Marine and Petroleum Geology》2009,26(8):1379-1412
The Cape and Karoo basins formed within the continental interior of Gondwana. Subsidence resulted from the vertical motion of rigid basement blocks and intervening crustal faults. Each basin episode records a three-stage evolution consisting of crustal uplift, fault-controlled subsidence, and long periods of regional subsidence largely unaccompanied by faulting or erosional truncation. The large-scale episodes of subsidence were probably the result of lithospheric deflection due to subduction-driven mantle flow. The early Paleozoic Cape basin records the combined effects of a north-dipping intra-crustal décollement (a late Neoproterozoic suture) and a right-stepping offset between thick Rio de la Plata craton and Namaqua basement. Following the Saldanian orogeny, a suite of small rift basins and their post-rift drape formed at this releasing stepover. Great thicknesses of quartz sandstone (Ordovician–Silurian) and mudstone (Devonian) accumulation are attributed to subsidence by rheological weakening and mantle flow. In contrast, the Karoo basin is a cratonic cover that mimics the underlying basement blocks. The Permian Ecca and lower Beaufort groups were deposited in a southward-deepening ramp syncline by extensional decoupling on the intra-crustal décollement. Reflection seismic and deep-burial diagenetic studies indicate that the Cape orogeny started in the Early Triassic. Deformation was partitioned into basement-involved strike-slip faults and thin-skinned thrusting. Uplift of the Namaqua basement resulted in erosion of the Beaufort cover. East of the Cape fold belt, contemporaneous subsidence and tilting of the Natal basement created a late Karoo transtensional foreland basin, the Stormberg depocentre. Early Jurassic tectonic resetting and continental flood basalts terminated the Karoo basin. 相似文献
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琼东南盆地新生代构造研究现状及展望 总被引:1,自引:0,他引:1
琼东南盆地属于南海北部陆缘拉张盆地,但是由于其不同的发育历史及红河断裂的影响,具有与东部陆缘盆地不同的构造特征。琼东南盆地和珠江口盆地在地壳结构、基底特征等方面存在差异,但是这种差异的原因还不清楚。新生代沉降速率发生多期变化,并存在裂后异常沉降、沉降延迟等现象,其形成机制尚需要进一步研究;平面上,构造具有迁移性,但是对不同地质时期的构造迁移方向仍存在不同的看法。盆地沉降中心和沉积中心经历了由裂陷期和裂后早期的较好重合到裂后晚期的逐步分离,直至完全分离的过程。盆地形成与地幔流的关系,以及红河断裂对盆地裂后沉降迁移的影响,也都是需要进一步确定的工作。鉴于以上各方面存在的问题,对琼东南盆地与南沙的共轭关系、盆地异常沉降、红河断裂及内部构造转换带对构造迁移的影响、以及琼东南盆地与珠江口盆地的比较等方面的研究是下一步工作的重点。 相似文献
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The interpretation of 2-D seismic reflection data provides a modern structural framework including hydrocarbon potential in the present-day stratigraphic and structural traps of both the Davie Fracture Zone and the adjacent Nacala and Angoche basins. Possible stratigraphic traps were identified in submarine fan and channel depositional environments during Cretaceous to Tertiary times. Structural traps are mostly defined within compressional structures formed by a variety of fault-related folds and rift grabens within the Jurassic and Cretaceous successions.The Nacala and Angoche basins form two depressions separated by the Davie compressional zone. This compressional structure is a prominent interior high running approximately north-south. An event of transpression and contraction characterizes the main tectonic setting commonly hosting several detached compressional structures along the western edge of the transform zone.Both basins are associated with the Late Jurassic/Early Cretaceous rifting during the opening of the Mozambique Channel. The Angoche basin is proposed here to have formed by the earliest stage of break-up in mid-Jurassic time. The basin is bounded landward by the Angoche volcanic zone, a dyke swarm branch oriented N64degE forming part of the Karoo and Dronning Maud Land magmatism at c. 180 Ma.Subsequent rifting and break-up led to the drift of East Gondwana southwards along the dextral strike-slip Davie Fracture Zone. At about 150 Ma (Tithonian), East Gondwana appears to have rotated slightly clockwise about a pivot in the proximity of the Angoche basin leading to extension and rifting in the Rovuma basin to the north of the pivot point and compression west of the Davie Fracture Zone to the south. Consequently, the eastern boundary of the Angoche basin was compressed developing a typical growth wedge of massive thrust imbrication structures while extensional tectonics created several depressions and rift-grabens forming the Nacala and Quirimbas basins.Basin stratigraphy is interpreted along seismic reflection lines and correlated to the regional stratigraphic information and wells from the Zambezi Delta and Rovuma basins. 相似文献
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The Orange Basin records the development of the Late Jurassic to present day volcanic-rifted passive margin of Namibia. Regional extension is recorded by a Late Jurassic to Lower Cretaceous Syn-rift Megasequence, which is separated from a Cretaceous to present day post-rift Megasequence by the Late Hauterivian (ca. 130 Ma) break-up unconformity. The Late Cretaceous Post-rift evolution of the basin is characterized by episodic gravitational collapse of the margin. Gravitational collapse is recorded as a series of shale-detached gravity slide systems, consisting of an up-dip extensional domain that is linked to a down-dip zone of contraction domain along a thin basal detachment of Turonian age. The extensional domain is characterized by basinward-dipping listric faults that sole into the basal detachment. The contractional domain consists of landward-dipping listric faults and strongly asymmetric basinward-verging thrust-related folds. Growth stratal patterns suggest that the gravitational collapse of the margin was short-lived, spanning from the Coniacian (ca. 90 Ma) to the Santonian (ca. 83 Ma). Structural restorations of the main gravity-driven system show a lack of balance between up-dip extension (24 km) and down-dip shortening (16 km). Gravity sliding in the Namibian margin is interpreted to have occurred as a series of episodic short-lived gravity sliding between the Cenomanian (ca. 100 Ma) and the Campanian (ca. 80 Ma). Gravity sliding and spreading are interpreted to be the result of episodic cratonic uplift combined with differential thermal subsidence. Sliding may have also been favoured by the presence of an efficient detachment layer in Turonian source rocks. 相似文献