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1.
南沙海域万安盆地地质构造与沉积体系特征 总被引:5,自引:0,他引:5
万安盆地是其东侧万安走滑断裂发生右旋走滑所派生的扭张应力作用下形成的一个走滑拉张盆地。NE、NEE和SN向的断裂是盆内最主要的断裂,它们在盆内局部形成"三隆四坳"的格局。盆地构造演化经历了基底形成、初始裂谷作用、裂谷发育(第一阶段裂谷作用)、裂谷后早期(第二阶段裂谷作用)、构造反转和裂后期(区域沉降阶段)等几个阶段。根据钻井资料和地震资料中叠加速度建立的时-深关系,在该盆地可划分出4个巨层序界面:MB1,声波基底的顶部(前古近纪);MB2,渐新世顶部(24Ma);MB3,晚中新世(8Ma);MB4,早上新世(4Ma)。每一个巨层序界面(MB)之上都有与之对应的巨层序(MS),从老到新依次为MS1—MS4。盆地晚始新世—渐新世以湖泊-三角洲沉积体系为主;晚中新世时经历了非海相-海陆交互相-陆架沉积体系的过渡;中新世—早上新世为碳酸盐岩-浅海陆架-三角洲沉积体系;早上新世—第四纪为陆架-陆坡-深海沉积体系。 相似文献
2.
南昆嵩地区是万安盆地西部负向构造单元,其中部N–S向断裂贯穿南北,独特的构造特征使其成为研究万安盆地西部构造演化与区域断裂走滑活动的窗口。将研究区沉积地层划分为3套构造层,通过回剥法绘制南昆嵩地区构造–沉积充填剖面,并计算南昆嵩地区构造沉降量以及构造沉降速率,论述南昆嵩地区构造演化史与沉降过程以及控制因素。研究结果表明:下部构造层和中部构造层中断裂组合样式主要为卷心型断层、“Y”型断层、阶梯状断层和高角度花状构造等,断裂延伸方向大致可分为:N–S向、W–E向和NE–SW向3种;上部构造层断裂不发育,为稳定沉积;在区域走滑断裂以及南海扩张运动的控制下,南昆嵩地区始新世以来构造演化经历4个阶段:初始裂谷期、伸展断拗期、走滑改造期和热沉降期,新生代地层构造性质也表现为以伸展与走滑作用为主–走滑断裂控制–热沉降的三段式转变。 相似文献
3.
《海洋地质与第四纪地质》2017,(6)
盆地的构造沉降史是盆地基底垂向升降的历史记录,不仅可以反映盆地形成演化历史,而且可能记录了深部地质过程的信息。近年来,越来越多的地球物理证据显示,雷琼地区深部存在延伸到下地幔的柱状低速异常体。为了揭示该深部异常体的活动信息,利用地震资料和钻孔资料,采用回剥和应变速率反演技术,计算了珠三坳陷各构造单元的构造沉降曲线和理论构造沉降曲线。结果显示,珠三坳陷新生代构造沉降可划分为5个阶段:初始张裂慢速沉降(65~49.5 Ma),张裂期快速沉降(49.5~30 Ma),裂后慢速热沉降阶段Ⅰ(30~23.03 Ma),裂后加速沉降(23.03~16.5 Ma),裂后慢速热沉降阶段Ⅱ(16.5~0 Ma)。珠三坳陷在裂陷期存在沉降亏损现象,裂后期存在300~800m异常沉降可能是对前期沉降不足的补偿,可能与裂陷期软流圈热物质上涌和消退有关。研究结果还表明23.03~10.5 Ma珠三坳陷构造沉降中心发生北东向的迁移,是否与深部异常体活动有关或受区域应力场影响,还需进一步研究。 相似文献
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5.
南海万安盆地构造沉降及其油气成藏控制作用 总被引:11,自引:0,他引:11
万安盆地是南海重要的新生代含油气盆地之一,是较为典型的新生代走滑拉张盆地。根据对横穿盆地的多道地震反射剖面的平衡剖面模拟和断层活动速率计算,可知万安盆地经历了4个主要构造沉降过程,而断层大多为源自基底的生长断裂,在晚始新世—早中新世盆地发生走滑拉张断拗沉降阶段,断层活动最为强烈。各构造沉降阶段分别控制了盆地中油气生成、运聚和保存等成藏条件与过程。 相似文献
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7.
立足于大西洋的形成与演化,划分了贝宁盆地构造演化阶段,厘定了裂陷期盆地的边界,分析了盆地结构和构造特征,明确了盆地构造样式。贝宁盆地经历裂陷期、漂移期两个构造演化阶段,不发育盐岩。受早白垩世裂陷期盆地东、西部应力差异控制,盆地形成了东部拉张构造区和西部走滑构造区,盆地裂谷分布具有"东宽西窄"的特征。东部拉张构造区发育近东西向断裂体系,主要为拉张作用形成的铲式正断层,西部走滑作用区发育NE—SW向走滑断裂体系,发育陡直的走滑断裂,主要为走滑作用形成的走滑断层。受早白垩世东、西部应力差异和晚白垩世构造反转、新生代重力滑脱作用的控制,盆地发育拉张、扭张、挤压、重力滑脱4类构造样式,丰富的构造样式为盆地构造圈闭发育提供了有利的条件。 相似文献
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印度最大的油气聚集区位于西印度,具有独特的构造事件集中发生。中生代沿元古代活动带构造方向的裂谷作用形成了印度海岸的被动边缘盆地。Campanian期(83.5—70.6Ma),马达加斯加与印度发生分离,南北向正断层传播进入到Cambay Graben地区。在初始德干Reunion热点之上,晚Maastrichtian(70.6—65.5Ma)隆起在西北印度海岸产生了伸展应力场,形成盂买高断块。早古新世,德干溢流玄武岩喷发后,伸展在薄弱的地壳中继续,引起了孟买地堑和Surat坳陷沉降的加强、Seychelles微大陆从印度分离以及孟买高地上正断层的重新活动。孟买地堑和Surat(Danahu)坳陷在热沉降期间充填了富有机质页岩,在缓慢沉降的盂买台地上发育了始新-中新世浅水碳酸盐,海平面波动产生了次生孔隙的发育。晚第三纪成熟的Surat(Danahu)坳陷页岩生成烃类,运移至孟买高的碳酸盐储层。Canlpanian构造事件之后,Konkan—kerala和印度东海岸的较老盆地并未受到影响,缺乏有利的成藏要素是该地区的特点。 相似文献
9.
阳江-一统东断裂是珠江口盆地西部一条重要的NW向区域大断裂,是盆地东西分块的重要分界线。南海北部陆缘在新生代经历了大陆裂谷-裂离-海底扩张-热沉降的过程,阳江-一统东断裂在新生代的活动是这一复杂过程的一部分。对分处断裂两侧的从陆架延伸至洋陆边界的两条NNW向多道地震剖面进行了地质解释,研究了珠江口西部的构造和沉积特征。利用2D-Move软件及构造回剥法建立了平衡剖面模型,计算了断层活动速率,结合构造位置、构造演化史、标志构造和应力分析推断了阳江-一统东断裂在新生代的活动史。结果表明,阳江-一统东断裂可以中部坳陷带为界分为两段,从65Ma到32Ma,断裂整体表现为左旋活动,继承了断裂在中生代时期的先存左旋走滑,其中,在此时期断裂南段主要表现为伸展活动,伴随着轻微的左旋走滑,这种伸展活动控制了云开低凸起的形成和演化;从32Ma到23.8Ma,断裂北段的左旋走滑活动持续,而南段逐渐转为轻微的右旋走滑或左旋活动停止。在23.8Ma之后,断裂南段的右旋走滑活动持续,北段的左旋走滑逐渐停止,或转为轻微的右旋走滑。阳江-一统东断裂的这种走滑旋向的转变可能与在珠江口盆地南部洋陆过渡带区域的岩浆底侵作用有关。根据对盆地构造活动强度和裂谷格架的分析,认为阳江-一统东断裂的新生代活动在珠江口盆地裂谷伸展过程中起到了应力调节的作用。 相似文献
10.
琼东南盆地新生代沉降特征 总被引:9,自引:0,他引:9
利用回剥技术对琼东南盆地进行了沉降史计算和分析,主要包括北部坳陷带的崖北凹陷、崖南凹陷,中央坳陷带的乐东凹陷,和南部坳陷带的华光凹陷.按照地震测线的分布和凹陷特征,我们共选取了30口模拟井进行一维沉降史计算,并展示了具有代表性的8口井,分析他们在小同时期的构造沉降速率与总沉降速率.分析结果表明,新生代以来,琼东南盆地主要经历厂三个主要的沉降幕:(1)始新世至渐新世,盆地处于裂陷期,构造沉降速率较大,平均为81m·Ma-1,沉降中心位于中央坳陷带.(2)早中新至中中新世,盆地由裂陷期向坳陷期转化,平均构造沉降速率减小至68m·Ma-1;(3)晚中新世以后,瓮地进入新一期的沉降阶段,平均构造沉降速率增加至84m·Ma-1;上新世以后,中央坳陷带发生快速沉降,达到了110m·Ma1. 相似文献
11.
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
12.
珠江口盆地?琼东南盆地深水区新生代构造沉积演化对比分析 总被引:1,自引:1,他引:0
南海北部陆缘记录了南海形成演化的历史,但是其新生代构造沉积演化特征在东段和西段的差异及其原因目前还不太清楚。本文分别在珠江口盆地和琼东南盆地的深水区选择了数口构造地理位置相似的井通过精细地层回剥分析,重建了两沉积盆地的沉积速率和沉降速率并结合前人研究成果进行了对比分析。研究结果发现,两沉积盆地在裂陷期的沉积和沉降特征基本相似,但是两者在裂后期的构造沉积演化特征差异明显。珠江口盆地深水区沉积和沉降速率都表现为幕式变化特征,其中沉积速率表现为“两快三慢”的特征而沉降速率表现为“两快一慢”的特征。琼东南盆地深水区的沉积速率表现为“地堑式”变化特征,但是沉降速率表现为“台阶式”上升的变化特征。琼东南盆地“台阶式”上升的沉降速率推测主要是受到海南地幔柱伴随红河断裂的右旋走滑而向西北漂移的影响,这也与南海西北部的岩浆活动以及周围盆地的沉降特征吻合。红河断裂在2.1 Ma BP的右旋走滑控制了琼东南盆地1.8 Ma BP以来的快速沉积和加速沉降分布。 相似文献
13.
In this short note, we report the ages of five lava samples from a segment of the Eastern Lau Spreading Center (ELSC) and three samples from the Valu Fa Ridge (VFR) in the southern Lau Basin. These samples were collected in situ from the axes and flanks of the spreading centers in the basin. These ages provide a key to better understanding the spreading mode, crustal formation and overall tectonic evolution of the basin. Except for two basaltic andesites and one andesite, the lavas analyzed are basalts. The ages of the lavas from ELSC range from (1.45 ± 0.15) Ma to (0.74 ± 0.04) Ma whereas those from VFR range from (0.50 ± 0.06) Ma to (0.32 ± 0.27) Ma, and the basalts give the oldest ages. The relatively younger ages of the VFR lavas are consistent with proposed tectonic evolution of the southern Lau Basin, i.e., VFR is a propagating extension of ELSC. The occurence of older lavas close to or on spreading axes in the southern Lau Basin implies the complex tectonic evolution of the basin. These results underscore a need for further detailed geophysical and geological studies in the southern Lau Basin, in order to better clarify the crustal accretion tectonic evolution in this area. 相似文献
14.
Jurassic-Cretaceous rift successions and basin geometries of the Sverdrup Basin are reconstructed from a review and integration of stratigraphy, igneous records, outcrop maps, and subsurface data. The rift onset unconformity is in the Lower Jurassic portion of the Heiberg Group (approximately 200–190 Ma). Facies transgress from early syn-rift sandstones of the King Christian Formation to marine mudstones of the Jameson Bay Formation. The syn-rift succession of marine mudstones in the basin centre, Jameson Bay to Deer Bay formations, ranges from Early Jurassic (Pleinsbachian) to Early Cretaceous (Valanginian). Early post-rift deposits of the lower Isachsen Formation are truncated by the sub-Hauterivian unconformity, which is interpreted as a break up unconformity at approximately 135–130 Ma. Cessation of rift subsidence allowed for late post-rift sandstone deposits of the Isachsen Formation to be distributed across the entire basin. Marine deposition to form mudstone of the Christopher Formation throughout the Canadian Arctic Islands and outside of the rift basin records establishment of a broad marine shelf during post-rift thermal subsidence at the start of a passive margin stage. The onset of the High Arctic Large Igneous Province at approximately 130 Ma appears to coincide with the breakup unconformity, and it is quite typical that magma-poor rifted margins have mainly post-rift igneous rocks. We extend the magma-poor characterization where rifting is driven by lithospheric extension, to speculatively consider that the records from Sverdrup Basin are consistent with tectonic models of retro-arc extension and intra-continental rifting that have previously been proposed for the Amerasia Basin under the Arctic Ocean. 相似文献
15.
法尔维海盆位于西南太平洋海域豪勋爵海丘东侧、新喀里多尼亚岛西侧,是全球油气勘探的前沿地区。但目前对于该海盆的构造演化研究较为薄弱,限制了该海盆油气资源的进一步勘探开发。本文通过从新西兰塔斯曼海数据库搜集到大量地球物理资料,使用2D Move软件,通过平衡剖面技术进行构造演化模拟,结合区域动力学机制将海盆北部和南部的构造演化分为7个阶段:(1)早白垩世至晚白垩世陆内裂谷阶段;(2)晚白垩世断坳过渡阶段;(3)始新世早期坳陷阶段;(4)始新世晚期一次构造反转阶段;(5)始新世至渐新世热沉降阶段;(6)渐新世至中新世二次构造反转阶段;(7)中新世至今海洋沉降阶段。由于海盆中部未发现有明显的二次构造反转阶段,所以将海盆中部的构造演化划分为5个阶段:(1)早白垩世至晚白垩世陆内裂谷阶段;(2)晚白垩世断坳过渡阶段;(3)始新世早期坳陷阶段;(4)始新世晚期构造反转阶段;(5)中新世至今海洋沉降阶段。此阶段海盆整体下坳,逐渐形成现今样貌。法尔维海盆北部受到区域构造活动影响较大,白垩系地层发育较多的断裂构造;海盆中部晚白垩统地层发生较多的底辟构造;海盆南部从形成至今,受到构造活动影响较小,发育地层完整,前新生代地层较厚。整个法尔维海盆北部构造活动较强,中部较弱,南部较小。沉积地层从北到南由厚变薄。 相似文献
16.
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
17.
台西南盆地的构造演化与油气藏组合分析 总被引:14,自引:2,他引:14
杜德莉 《海洋地质与第四纪地质》1994,14(3):5-18
本文根据台西南盆地的地质、地球物理资料,对台西南盆地的地壳结构、基底特征、沉积厚度、断裂构造等基本地质构造特征^[1]作了研究,探讨了台西南盆地的构造发展演化及及油气藏组合。认为该盆地的构造演化为幕式拉张。幕式拉张可分为三大张裂幕,相应的热沉降作用使盆地在不同的张裂幕时期发展为断陷,裂陷,裂拗-拗陷。它们分别与板块作用下的区域构造运动阶段相对应,说明区域构造运动不但控制了盆地的发展演化,同时也制约 相似文献
18.
Monika Hölzel Kurt Decker András Zámolyi Philipp Strauss Michael Wagreich 《Marine and Petroleum Geology》2010
The tectonic evolution of the Vienna Basin overlying the Alpine-Carpathian fold and thrust belt includes two stages of distinct basin subsidence and deformation. The earlier phase contemporaneous with thrusting of the Alpine-Carpathian floor thrust is related to the formation of a wedge-top basin (“piggy-back”), which was connected to the evolving foreland basin (Lower Miocene; c. 18.5–16 Ma). This stage is followed by the formation of a pull-apart basin (Middle to Upper Miocene; c. 16–8 Ma). Sediments of the latter unconformably overly wedge-top basin strata and protected them against erosion. 相似文献
19.
Controls on turbidite sand deposition during gravity-driven extension of a passive margin: examples from Miocene sediments in Block 4, Angola 总被引:1,自引:0,他引:1
In recent years, exploration of the Lower Congo Basin in Angola has focused on the Neogene turbidite sand play of the Malembo Formation. Gravity tectonics has played an important role during deposition of the Malembo Formation and has imparted a well-documented structural style to the post-rift sediments. An oceanward transition from thin-skinned extension through mobile salt and eventually to thin-skinned compressional structures characterises the post-rift sediments. There has been little discussion, however, regarding the influence of these structures on the deposition of the Malembo Formation turbidite sands. Block 4 lies at the southern margin of the Lower Congo Basin and is dominated by the thin-skinned extensional structural style. Using a multidisciplinary approach we trace the post-rift structural and stratigraphic evolution of this block to study the structural controls on Neogene turbidite sand deposition.In the Lower Congo Basin the transition from terrestrial rift basin to fully marine passive margin is recorded by late Aptian evaporites of the Loeme Formation. Extension of the overlying post-rift sequences has occurred where the Loeme Formation has been utilised as a detachment surface for extensional faults. Since the late Cretaceous, the passive margin sediments have moved down-slope on the Loeme detachment. This history of gravity-driven extension is recorded in the post-rift sediments of Block 4. Extension commenced in the Albian in the east of the block and migrated westwards with time. In the west, the extension occurred mainly in the Miocene and generated allochthonous fault blocks or “rafts”, separated by deep grabens. The Miocene extension occurred in two main phases with contrasting slip vectors; in the early Miocene the extension vector was to the west, switching to southwest-directed extension in the late Miocene. Early Miocene faults and half-grabens trend north–south whereas late Miocene structures trend northwest–southeast. The contrast in slip vectors between these two phases emphasises the differences in driving mechanisms: the early Miocene faulting was driven by basinward tilting of the passive margin, but gravity loading due to sedimentary progradation is considered the main driver for the late Miocene extension. The geological evolution of the late Miocene grabens is consistent with southwest-directed extension due to southwest progradation of the Congo fan.High-resolution biostratigraphic data identifies the turbidite sands in Block 4 as early Miocene (17.5–15.5 Ma) and late Miocene (10.5–5.5 Ma) in age. Deposition of these sands occurred during the two main phases of gravity-driven extension. Conditions of low sedimentation rates relative to high fault displacement rates were prevalent in the early Miocene. Seafloor depressions were generated in the hangingwalls of the main extensional faults, ultimately leading to capture of the turbidity currents. Lower Miocene turbidite sand bodies therefore trend north–south, parallel to the active faults. Cross-faults and relay ramps created local topographic highs capable of deflecting turbidite flows within the half grabens. Flow-stripping of turbidity currents across these features caused preferential deposition of sands across, and adjacent to, the highs. Turbidite sands deposited in the early part of the late Miocene were influenced by both the old north–south fault trends and by the new northwest–southeast fault trends. By latest Miocene times turbidite channels crosscut the active northwest–southeast-trending faults. These latest Miocene faults had limited potential to capture turbidity currents because the associated hangingwall grabens were rapidly filled as pro-delta sediments of the Congo fan prograded across the area from the northeast. 相似文献