共查询到18条相似文献,搜索用时 93 毫秒
1.
西藏冈底斯当惹雍错-许如错南北向地堑的特征及成因 总被引:3,自引:0,他引:3
当惹雍错-许如错南北向地堑位于青藏高原冈底斯中部, 由一组南北向高角度正断层与夹其中间的当穹错、当惹雍错、许如错等3个湖泊盆地构成.地堑发育于中新世晚期, 一直活动到全新世.沿着地堑边缘分布中新世碱性火山岩.白榴石响岩的K-Ar年龄为12.6Ma, 其岩石化学特征显示出陆内伸展构造环境.地堑内部发育晚更新世至全新世的湖相沉积物.当惹雍错-许如错地堑是在青藏高原板内构造隆升过程中, 层流加厚的下地壳热垫作用导致上地壳发生伸展作用, 随着青藏高原地壳物质的东流, 南北向伸展作用转向东西向伸展作用, 形成近南北走向的地堑. 相似文献
2.
东营凹陷伸展断弯褶皱的构造几何学分析 总被引:14,自引:6,他引:8
东营凹陷是渤海湾盆地南部一个典型的中新生代半地堑盆地。本文通过对横穿东营凹陷的地震反射剖面进行精细的构造解析,发现这个半地堑盆地的伸展构造具有明显的膝折变形特征,基本上符合伸展断弯褶皱模型。由此运用伸展断弯褶皱理论,同时按照平衡剖面原理,详细恢复了东营凹陷伸展构造的发育过程。经过对盆地内部构造变形的反复拟合和测算,我们确定了东营凹陷伸展断弯褶皱的构造几何学特征及其运动学过程,揭示出东营凹陷各主要裂谷阶段的地壳水平伸展量,并且将其中的背斜解释为上凹与上凸断层转折组合所形成的一个伸展背斜构造。同时采用构造几何学方法推断在白垩纪末期该地区曾经历过大约1750m厚的剥蚀作用,总伸展量可达25km。 相似文献
3.
以北黄海盆地构造几何学、运动学特征为基础,探讨了北黄海盆地的构造变形样式及动力学演化过程。研究表明,北黄海盆地的构造变形包括伸展构造变形、挤压构造变形、扭动构造变形以及反转构造变形等,北黄海盆地发育的区域动力学背景即是以区域拉伸作用为主、且叠加有水平挤压作用以及相关的扭动作用,并由此导致了北黄海盆地是以一系列地堑、半地堑式坳陷组成的拉张断陷盆地;北黄海盆地的伸展、挤压与升降作用受控于板块相互作用引起的区域引张与挤压应力场并辅以深部软流圈的微弱上拱隆起作用,其动力学演化过程包括晚侏罗世—早白垩世伸展断陷、晚白垩世—古新世热隆、始新世—渐新世裂陷、渐新世末期—新近纪早期构造反转以及新近纪热沉降等5个阶段。 相似文献
4.
陆内裂陷盆地通常发育大量地堑、半地堑,盆地结构和构造样式受盆地内部地堑、半地堑的叠加与复合方式的影响。文中将由多条断层、不同期次的断层共同控制的断陷称为"复式断陷"。依据同一时期断陷复合构成的盆地结构可以将复式断陷划分为串联式、并联式、斜列式和交织式等4种复合型式,依据不同时期断陷叠加构成的盆地样式可以划分为继承型、利用型、新生型3种叠加类型。海-塔盆地在早白垩世最初是发育大量相对分隔的小型地堑、半地堑,随着地壳渐进的伸展构造变形,多个同期小型半地堑复合在一起形成相对大的断陷(相当于铜钵庙组沉积期)。在早白垩世中期(相当于南屯组沉积期),新发育的断陷叠置在早先发育的断陷之上,最终形成了盆地中的17个区域规模的复式断陷。海-塔盆地早白垩世的断陷复合和叠加过程直接影响沉积盆地的油气成藏条件。并联式、交织式复合和继承型、利用型叠合形成的复式断陷有利于优质烃源岩的发育,断陷复合过程中的构造变换带有利于优质储集层的发育,长期活动的基底断裂及相关构造带有利于形成含油气构造带。 相似文献
5.
松辽盆地南缘长岭凹陷断陷层的构造特征与应变模式 总被引:1,自引:0,他引:1
以松辽盆地南缘的长岭凹陷断陷层为对象,采用构造-地层分析方法,在确定盆缘断裂活动期次、样式及由沉积记录示踪的构造变形的基础上,进一步通过系统的二维构造-地层平衡恢复,揭示出在长岭凹陷断陷层的发育过程中,盆地伸展方向存在自NE—SW至近EW向的顺时针旋转。旋转主要发生于下白垩统沙河子组形成时期。位于松辽盆地中央凹陷带南端的长岭凹陷由于构造部位的特殊性,在形成的早期表现出较明显的北东向伸展断陷的特征,并与后期北西向的构造伸展相叠加,形成了较复杂的构造样式。在盆地伸展的过程中,存在应变机制的转变,早期以纯剪变形为主,以发育地堑式伸展构造样式为特征;后期以简单剪切变形为主,以发育半地堑式伸展构造样式为特征 相似文献
6.
运用平衡剖面分析和构造物理模拟实验方法研究了典型铲式正断层模型上盘盆地的发育过程.研究表明,铲式正断层的产状以及断层上盘的变形方式直接影响上盘盆地的形态和沉积层序结构.简单铲式正断层的上盘发育相对简单的半地堑盆地,复杂铲式(坡坪式)正断层的上盘则发育包含有内部次级背斜凸起和向斜凹陷的复式半地堑,而且半地堑盆地的宽度与拆离断层面深度成正比.在沉积物补偿充填的情况下,渐进伸展将使半地堑的宽度也保持不变,从而使半地堑构造斜坡上产生“视水退”的层序结构现象,并且使盆地中“垂向加积”的沉积层序演变为宏观上“侧向加积”的沉积层序.这种由构造因素对半地堑盆地的层序充填的影响在渤海湾盆地的部分老第三纪断陷中得到印证. 相似文献
7.
长江源地区近南北走向的地堑构造是该区现今最为显著的构造现象,也是青藏高原迄今发现的同类构造发育的最北部地区。长江源地区地堑构造包括温泉、常错、当拉错纳玛和沱沱河4个规模较大的近南北向地堑。断层年代学和断陷盆地沉积作用研究结果表明,研究区伸展变形至少自中新世末—上新世初就已开始,对长江源地区现今的地貌格局、水系型式具有显著的制约作用。长江源区主要水系是沿南北走向的地堑构造和正断层侵蚀发育而成的。青藏高原新生代伸展地堑构造是高原经历早期地壳强烈缩短变形之后,在深部动力学机制作用下快速隆升的产物。 相似文献
8.
长江源地区近南北走向的地堑构造是该区现今最为显著的构造现象,也是青藏高原迄今发现的同类构造发育的最北部地区.长江源地区地堑构造包括温泉、常错、当拉错纳玛和沱沱河4个规模较大的近南北向地堑.断层年代学和断陷盆地沉积作用研究结果表明,研究区伸展变形至少自中新世末-上新世初就已开始,对长江源地区现今的地貌格局、水系型式具有显著的制约作用.长江源区主要水系是沿南北走向的地堑构造和正断层侵蚀发育而成的.青藏高原新生代伸展地堑构造是高原经历早期地壳强烈缩短变形之后,在深部动力学机制作用下快速隆升的产物. 相似文献
9.
长江源区新生代地堑的构造特征与形成机制 总被引:1,自引:2,他引:1
长江源地区近南北走向的地堑构造是该区现今最为显著的构造现象,也是青藏高原迄今发现的同类构造发育的最北部地区.长江源地区地堑构造包括温泉、常错、当拉错纳玛和沱沱河4个规模较大的近南北向地堑.断层年代学和断陷盆地沉积作用研究结果表明,研究区伸展变形至少自中新世末-上新世初就已开始,对长江源地区现今的地貌格局、水系型式具有显著的制约作用.长江源区主要水系是沿南北走向的地堑构造和正断层侵蚀发育而成的.青藏高原新生代伸展地堑构造是高原经历早期地壳强烈缩短变形之后,在深部动力学机制作用下快速隆升的产物. 相似文献
10.
利用地震资料、油气勘探资料分析了南海北部大陆边缘珠江口-琼东南新生代盆地断裂系统的时空差异及动力学成因机制.珠江口-琼东南盆地古近系裂陷构造层以NE向、近EW向基底正断层构成的伸展断裂系统的几何学、运动学沿着盆地走向有明显变化,盆地内部隐伏的区域性和局部的NW向断裂及相关构造变形带构成伸展断裂系统之间的构造变换带.在空间上,区域性的云开、松涛-松南等NW向构造变换带以西为NE-NEE向正断层构成的"非拆离"伸展断层系,以东为NE向正断层、近EW向正断层(走滑正断层)复合而成的拆离伸展断层系.在时间上,古近纪裂陷作用可划分为早(文昌组沉积期)、中(恩平组/崖城组沉积期)、晚(珠海组/陵水组沉积期)3个有明显差异的裂陷期.裂陷早期,盆地西部以平面式正断层控制的简单地堑、半地堑为主,伸展量相对较小,东部则以铲式正断层控制的复式地堑、半地堑为主,伸展量相对大,断层向深部收敛在中地壳韧性层构成拆离的伸展断层系统.裂陷中期,琼东南盆地、珠江口盆地西部断裂具有继承性活动特点,珠江口盆地东部发育NWW-EW向伸展断层,并向深层切割早期浅层拆离断层,形成深层拆离伸展断层系统,而沿着云开构造变换带发育反转构造.裂陷晚期,琼东南盆地、珠江口盆地西部断裂具有活动性减弱特点,琼东南盆地东部发育NWW-EW向伸展断层,形成深层拆离伸展断层系统,而沿着琼中央构造变换带发育反转、走滑构造.珠江口-琼东南盆地不同区段断裂系统及其构造演化的差异性受盆地基底先存构造、地壳及岩石圈结构及伸展量等多方面因素的影响,拆离伸展断层系统与发育NWW向"贯穿"断裂的基底构造薄弱带、现今地壳局部减薄带相关,南海扩展由东而西的迁移诱导北部大陆边缘块体沿着先存NW向深大断裂发生走滑旋转是导致变换构造带两侧差异伸展的动力学原因,应力场及岩石圈热结构变化是引起拆离断层深度变化的重要因素. 相似文献
11.
This paper discusses the Neogene tectonic evolution of the Tunisia offshore Gulf of Hammamet basin. Based on seismic and well data, this basin was created during the Miocene and is currently trending NE–SW. During the Neogene, the study area was affected by geodynamic interactions controlled simultaneously by convergence of the Eurasia and Africa plates and the opening of the Atlantic Ocean. These interactions generated compressive and extensional regimes which led to a variety of structures and basin inversions.The middle Miocene extensional regime created horst and graben structures (e.g. the Halk El Menzel graben). The two major compressive phases of the Tortonian and post Villafranchian age created different structures such as Ain Zaghouan and Fushia structures and the Jriba trough, and led to the reactivation of the old normal faults as reverse faults. During the Plio-Pleistocene and the Quaternary times, the Gulf of Hammamet was affected by an extensional regime related to the Siculo-Tunisian rift, which led to the development in the area of several sedimentary basins and new normal fault patterns.The Gulf of Hammamet shows several basins ranging in age from the Tortonian to the Quaternary, which display different structural and stratigraphic histories. Two main groups of sedimentary basins have been recognized. The first group has Tortonian–Messinian sedimentary fill, while the second group is largely dominated by Plio-Quaternary sediments. The shortening during the Tortonian and post Villafranchian times has led to the tectonic inversion of these basins. This shortening could be correlated to the Europe–Africa collision.Despite the large number of hydrocarbon discoveries, the Gulf of Hammamet remains under-explored, in particular at deeper levels. This study aims to guide future exploration and to highlight some new play concepts. 相似文献
12.
北山—阿拉善地区白垩纪、侏罗纪盆地叠合特征 总被引:3,自引:0,他引:3
研究区发育侏罗纪盆地和白垩纪盆地,侏罗纪盆地受近东西向断裂的控制,为东西向展布的断陷湖盆。白垩纪盆地受北东向断裂的控制,为北东向展布的断陷湖盆,经历早白垩世的伸展断陷及其以后的后期改造阶段。两大世代的盆地在空间上存在翘倾叠合、叠合保存、部分叠合改造等三种方式。盆地的叠合保存对侏罗系烃源岩的油气形成最为有利。 相似文献
13.
L.S. Shu X.M. Zhou P. Deng B. Wang S.Y. Jiang J.H. Yu X.X. Zhao 《Journal of Asian Earth Sciences》2009,34(3):376-391
In order to better understand the Mesozoic tectonic evolution of Southeast China Block (SECB in short), this paper describes geological features of Mesozoic basins that are widely distributed in the SECB. The analyzed data are derived from a regional geological investigation on various Mesozoic basins and a recently compiled 1:1,500,000 geological map of Mesozoic–Cenozoic basins. Two types of basin are distinguished according to their tectonic settings, namely, the post-orogenic basin (Type I) and the intracontinental extensional basin (Type II); the latter includes the graben and the half-graben or faulted-depression basins. Our studies suggest that the formation of these basins connects with the evolution of geotectonics of the SECB. The post-orogenic basin (Type I) was formed in areas from the piedmont to the intraland during the interval from Late Triassic to Early Jurassic; and the formation of the intracontinental extensional basin (Type II) connects with an intracontinental crustal thinning setting in the Late Mesozoic. The graben basin was generated during the Middle Jurassic and is associated with a bimodal volcanic eruption; and the half-graben or faulted-depression basin, filled mainly by the rhyolite, tuff and sedimentary rocks during Early Cretaceous, is occupied by the Late Cretaceous–Paleogene red-colored terrestrial clastic rocks. We noticed that the modern outcrops of numerous granites and basins occur in a similar level, and the Mesozoic granitic bodies contact with the adjacent basins by large normal faults, suggesting that the modern landforms between granites and basins were yielded by the late crustal movement. The modern basin and range framework was settled down in the Cretaceous. Abundant sedimentary structures are found in the various basins, from that the deposited environments and paleo-currents are concluded; during the Late Triassic–Early Jurassic time, the source areas were situated to the north and northeast sides of the outcrop region. In this paper, we present the study results on one geological and geographical separating unit and two separating fault zones. The Wuyi orogenic belt is a Late Mesozoic paleo-geographically separating unit, the Ganjiang fault zone behaves as the western boundary of Early Cretaceous volcanic rocks, and the Zhenghe–Dapu fault zone separates the SE-China Coastal Late Mesozoic volcanic-sedimentary basins and the Wuyi orogenic belt. Finally, we discuss the geodynamic mechanisms forming various basins, proposing a three-stage model of the Mesozoic sedimentary evolution. 相似文献
14.
15.
东非海岸盆地天然气资源丰富,是世界天然气勘探的热点地区.东非海岸重点盆地的天然气为腐泥型高温裂解气,主要来源于下侏罗统局限海相优质烃源岩.大型断裂控制了东非海岸重点盆地天然气的垂向运移,研究区主要发育大型伸展断裂和大型走滑断裂.大型走滑断裂是坦桑尼亚盆地南部天然气藏的主要运移通道,其主要活动时期为晚白垩世-古新世,控制了白垩系-古近系浊积砂岩气藏的油气运移成藏.大型伸展断裂是鲁伍马盆地天然气藏的主要运移通道,其主要活动时期为古新世、渐新世和新近纪,控制了古近系浊积砂岩气藏的油气运移成藏.砂体规模控制了深水区岩性或构造-岩性圈闭的大小,进而控制了天然气藏的规模.受天然气运移方式的控制,东非海岸盆地形成了大型走滑断裂控藏模式和大型伸展断裂控藏模式. 相似文献
16.
《Geodinamica Acta》2001,14(1-3):45-55
Field studies on the Neogene successions in south of İzmir reveal that subsequent Neogene continental basins were developed in the region. Initially a vast lake basin was formed during the Early–Middle Miocene period. The lacustrine sediments underwent an approximately N–S shortening deformation to the end of Middle Miocene. A small portion of the basin fill was later trapped within the N–S-trending, fault-bounded graben basin, the Çubukludağ graben, opened during the Late Miocene. Oblique-slip normal faults with minor sinistral displacement are formed possibly under N–S extensional regime, and controlled the sediment deposition. Following this the region suffered a phase of denudation which produced a regionwide erosional surface suggesting that the extension interrupted to the end of Late Miocene–Early Pliocene period. After this event the E–W-trending major grabens and horsts of western Anatolia began to form. The graben bounding faults cut across the Upper Miocene–Pliocene lacustrine sediments and fragmented the erosional surface. The Çubukludağ graben began to work as a cross graben between the E–W grabens, since that period. 相似文献
17.
华北克拉通及邻区晚中生代伸展构造及其动力学背景的讨论 总被引:13,自引:8,他引:5
欧亚大陆东部晚中生代伸展构造十分显著,表现为大量发育的变质核杂岩、同构造岩浆岩、韧性拆离断层带等伸展成因的穹隆和地堑-半地堑盆地.通过对这些伸展构造进行系统分析、归纳和总结,将欧亚大陆东部晚中生代伸展构造发育区划分为:泛贝加尔-鄂霍次克带、华北西部带、华北东部带、华北南缘及秦岭-大别带和华南内陆带.这些伸展构造记录了大区域上的NW-SE方向伸展,构成了全球最大的陆壳伸展地区.这些伸展构造使地壳深部的岩石沿拆离断层折返至地表,从而使中下地壳结构发生了强烈的改造.除华北东部带给出了一个较为宽泛的伸展时段外,各个研究区所涉及的伸展穹隆及其相关的拆离断层所表现的伸展峰期时间均十分相近:位于130 ~ 126Ma之间.岩石圈根部的拆沉可能是这个巨型伸展构造带形成的动力学机制.这个模型为探讨华北克拉通破坏和减薄的时限、机制、模式及深部动力学背景提供直接的构造证据. 相似文献
18.
《Geodinamica Acta》2013,26(3-4):167-208
The Denizli graben-horst system (DGHS) is located at the eastern-southeastern converging tips of three well-identified major grabens, the Gediz, the Küçük Menderes and the Büyük Menderes grabens, in the west Anatolian extensional province. It forms a structural link between these grabens and the other three NE-NW-trending grabens—the Çivril, the Ac?göl and the Burdur grabens—comprising the western limb of the Isparta Angle. Therefore, the DGHS has a critical role in the evolutionary history of continental extension and its eastward continuation in southwestern Turkey, including western Anatolia, west-central Anatolia, and the Isparta Angle. The DGHS is a 7-28-km wide, 62-km long, actively growing and very young rift developed upon metamorphic rocks of both the Menderes Massif and the Lycian nappes, and their Oligocene-Lower Miocene cover sequence. It consists of one incipient major graben, one modern major graben, two sub-grabens and two intervening sub-horsts evolved on the four palaeotectonic blocks. Therefore, the DGHS displays different trends along its length, namely, NW, E-W, NE and again E-W. The DGHS has evolved episodically rather than continuously. This is indicated by a series of evidence: (1) it contains two graben infills, the ancient graben infill and the modern graben infill, separated by an intervening angular unconformity; (2) the ancient graben infill consists of two Middle Miocene-Middle Pliocene sequences of 660 m thickness accumulated in a fluvio-lacustrine depositional setting under the control of first NNW-SSE- and later NNE-SSW-directed extension (first-stage extension), and deformed (folded and strike-slip faulted) by a NNE-SSW- to ENE-WSW-directed phase of compression in the latest Middle Pliocene, whereas the modern graben infill consists of 350-m thick, undeformed (except for local areas against the margin-bounding active faults), nearly flat-lying fanapron deposits and travertines of Plio-Quaternary age; (3) the ancient graben infill is confined not only to the interior of the graben but is also exposed well outside and farther away from the graben, whereas the modern graben infill is restricted to only the interior of the graben. These lines of evidence imply an episodic, two-stage extensional evolutionary history interrupted by an intervening compressional episode for the DGHS. Both the southern and northern margin-bounding faults of the DGHS are oblique-slip normal faults with minor right- and/or left-lateral strike-slip components. They are mapped and classified into six categories, and named the Babada?, Honaz, A?a??da?dere, Küçükmal?da?, Pamukkale and Kaleköy fault zones, and composed of 0.5-36-km long fault segments linked by a number of relay ramps. Total throw amounts accumulated on both the northern and southern margin-bounding faults are 1,050 m and 2,080 m, respectively. In addition, the maximum width of the DGHS and the thickness of the crust beneath it are more or less same (~ 28 km). The total of these values indicate a vertical slip rate of 0.15-0.14 mm/year and averaging 7% extension for the asymmetrical DGHS. The master faults of the Babada?, Honaz, Küçükmal?da?, Pamukkale and Kaleköy fault zones are still active and have a potential seismicity with magnitudes 6 or higher. This is indicated by both the historical (1703 and 1717 seismic events) to recent (1965, 1976, 2000 seismic events) earthquakes sourced from margin-bounding faults and some diagnostic morphotectonic features, such as deflected drainage system, degraded alluvial fans with apices adjacent to fault traces, back-tilting of fault-bounded blocks, and actively growing travertine occurrences. The kinematic analyses of main fault-slip-plane data, Upper Quaternary fissure ridges and focal-mechanism solutions of some destructive earthquakes clearly indicate that the current continental extension (second-stage extension) by normal faulting in the DGHS continues in a (mean) 026° to 034° (NNE-SSW) direction. Detailed and recent field geological mapping, stratigraphy of the Miocene-Quaternary basins, palaeostress analysis of fault populations and main margin-bounding faults of these basins, extensional gashes to fissures, and focal-mechanism solutions of destructive earth-quakes that have occurred in last century strongly indicate that extension is not unidirectional and confined only to western Anatolia, but also continues farther east across the Isparta Angle and west-central Anatolia, up to the Salt Lake fault zone in the east and the inönü-Eski?ehir fault zone in the north-northeast. Therefore, the term “southwest Turkey extensional province” is proposed in lieu of the term “west Anatolian extensional province”. 相似文献