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1.
宋维宇 《海洋地质与第四纪地质》2012,(2):77-83
莺歌海盆地位于印支半岛与南海北部大陆边缘交接区,复杂的地质构造背景使其形成演化的动力学机制成为国内外研究的焦点。综合新的区域资料,对影响莺歌海盆地发育的区域构造演化特征进行了系统分析,认为新生代以来印度板块与欧亚板块的碰撞造成印支板块的逃逸构造,以及印支板块的顺时针旋转,红河断裂带新生代的变形机制,直接或间接地控制了莺歌海盆地的形成与演化。在此背景条件下,莺歌海盆地新生代以来的构造演化经历了3个阶段,即左旋走滑-伸展裂陷阶段、地壳韧性伸展-热沉降阶段和加速沉降阶段。 相似文献
2.
红河断裂带及其邻区的震源机制解特征及其反映的断裂活动分段性 总被引:2,自引:0,他引:2
对红河断裂带及其邻区219个地震的相关数据进行震源机制解分析,阐述了红河断裂带不同区段的地震分布特征及其地震类型的差异性,结合对研究区区域深部动力学条件的分析,从地震发生及其深部动力学特征分析红河断裂带活动的分段性特征,取得如下新认识:(1)红河断裂带北西段由于受印-藏碰撞影响而显现出挤压应力场特征,断裂活动具有逆断特征和局部拉张应力场下的正断特征;(2)中段作为华南亚板块与印支亚板块之间的主体剪切活动带,显现剪切应力场特征,断裂以剪切活动为主;(3)南东段在断裂带右旋走滑的基础上,受到深部物质抬升、岩石圈拉伸减薄的影响,而表现出张扭应力场性质,断裂活动显现张扭特征. 相似文献
3.
莺歌海盆地构造演化动力学机制探讨 总被引:1,自引:0,他引:1
莺歌海盆地是在印支地块与华南地块缝合线上发展起来的新生代沉积盆地,其奇特的地质现象与复杂的动力学背景是国内外学者研究的热点。关于其形成机制,目前主要有四种观点:"中国东部裂陷式"观点、"左旋走滑"观点、"右旋走滑"观点、"先左旋后右旋"观点。通过对该盆地区域地质背景、盆地构造几何学、运动学及沉积学综合分析,认为莺歌海盆地形成演化受印-藏碰撞、太平洋板块俯冲以及地幔上涌的影响,主要经历了古新世—早渐新世左旋拉分、晚渐新世—中新世热沉降、上新世—第四纪右旋拉分三个阶段。 相似文献
4.
红河活动断裂带在南海西北部的反映 总被引:6,自引:0,他引:6
红河断裂带是一条走滑的活动断裂带,它控制着南海西北部的构造活动,也控制着莺歌海盆地的形成和演化。根据南海西北部中穿过莺歌海盆地的地震剖面和历史资料进行解释,结果表明,莺歌海盆地的形成可分3个阶段:自50MaB.P.开始,沿红河断裂带的左旋错动和在印支地块的顺时针旋转的应力作用下,形成了莺歌海盆地的雏形;24MaB.P.之后在左旋压扭应力场作用下,形成了盆地西北部的反转构造;5MaB.P.之后发生了右旋错动,盆地内快速沉降,发育巨厚沉积层。根据盆地内最老和最新的沉积中心之间的距离,推测沿红河断裂带的左旋位错约200km。该断裂带发展到现代,其活动性大为减弱,曾发生10次小于5级地震。 相似文献
5.
南海晚新生代构造运动与天然气水合物资源 总被引:6,自引:0,他引:6
南海在新生代经历过两次海底扩张产生了南海洋盆.南海北部和南部原来都是被动大陆边缘,但北部在晚新生代由于菲律宾海板块与欧亚板块在台湾地区发生了碰撞,使陆缘遭受到北西向挤压,在陆缘上产生了北西向左旋走滑活动,我们命名此次构造活动为东沙运动;南部陆缘在早中新世末由于南移的南沙地块与婆罗洲地块发生了碰撞,加上此时北移的菲律宾海板块在明都洛岛地区与欧亚板块发生碰撞,以及南部的东南苏拉威西地块与西北苏拉威西地块发生碰撞,在南海南部产生了挤压构造,我们命名此次构造运动为南沙运动.这两次新生代的构造运动改变了南北陆缘的性质,北部陆缘有人因此称之为准被动陆缘,而南部陆缘的南部则变成了挤压边缘.南海南北陆缘在晚新生代受到的挤压活动,对油气成藏和天然气水合物的形成有重要的推动作用,因为挤压活动有利于流体的流动,进而在适当的地方形成油气藏和天然气水合物. 相似文献
6.
南海莺歌海盆地形成机制的物理模拟 总被引:2,自引:3,他引:2
莺歌海盆地位于印支板块和华南板块的拼接带,红河断裂带的海上延伸带上,构造演化十分复杂,由于盆地沉积厚度巨大,泥流体底辟发充,肝震勘探难以直接揭示盆地内部深层的构造面貌,因而对盆地形成与构造演化的认识存在明显的分歧,利用常用的三维比例沙箱模型,对盆地的形成机制进行了物理模拟,结果表明莺歌海盆地的形成可分3个阶段,自50MaB.P,或更早开始,在沿红洒断裂带带伸分量的左旋错动和印支地块的顺时针旋转的联合应力场作用下,形成了莺歌海盆地的断陷格架,大约21MaB.P.之后在纯左旋错动阶段叠加了压扭应力场,形成了盆地西北部的反转构造,约5MaB.P.之后发生右旋错动,带来了盆地内新一轮的快速沉积,根据盆地内最老和最新的沉积中心之间的距离,推测沿红河断裂带的左行位错约200km. 相似文献
7.
《海洋地质与第四纪地质》2017,(6)
南海北部莺歌海盆地为新生代沉积盆地,地处欧亚板块、太平洋板块和印度-澳大利亚板块交汇处,构造位置独特,复杂的地质构造现象使其形成演化的动力学机制成为国内外研究的热点。同一类型盆地具有相似的构造、沉降、沉积演化历史与成因机制。莺歌海盆地与渭河盆地均位于多板块交汇处,存在长期相对快速沉积、沉降及构造演化迁移等典型走滑型盆地特征。在明确渭河盆地成因机制的基础上,对比两盆地构造、沉降及沉积演化历史,结合莺歌海盆地特殊的构造位置及南海扩张的构造背景,分析得出:莺歌海盆地形成演化和印度-澳大利亚板块与青藏板块碰撞、印支板块逃逸及自身旋转、华南板块向东挤出及太平洋板块俯冲关系密切,受多板块构造活动影响较大,新生代以来先后依次经历左旋走滑、伸展—热沉降—右旋走滑、伸展三大成盆演化期。另外,与渭河盆地相比,莺歌海盆地发育有高温、高压及泥底辟等特殊地质现象,主要受控于热沉降阶段,与渐新世以来(33~15Ma)南海扩张事件具有重要关系。 相似文献
8.
红河断裂带的新生代变形机制及莺歌海盆地的实验证据 总被引:30,自引:4,他引:30
红河断裂带是印藏碰撞过程中,印支地块被顺时针旋转挤出的走滑变形带。莺歌海盆地发育于红河断裂带海上延伸带上。根据莺歌海盆地和相邻的NE向琼东南盆地在晚中新世前(5.5Ma B.P.)独立的构造发育和差异的沉降特点,认为红河断裂不可能穿越莺琼盆地界限向北东延伸,而越东断裂和中建南断裂很可能是红河断裂的延续。莺歌海盆地成盆机制的物理模拟结合红河断裂带陆上的变形特征、年代学证据与青藏高原隆升过程的研究,参考莺歌海盆地模拟过程中不同应力场下沉降中心的长轴方向,我们推断红河断裂带新生代的演化大致分4个阶段:(1)50-38Ma B.P.期间的缓慢平移运动;(2)38—25MaB.P.期间的快速左行走滑运动;(3)25—5Ma B.P.期间的左行走滑逐渐停止阶段;(4)5Ma B.P.后的右行走滑阶段。 相似文献
9.
中国东部中朝与华南(或扬子)板块在晚二叠世—三叠纪期间碰撞形成大别-苏鲁超高压造山带,这一碰撞结合带过黄海在朝鲜半岛的延伸方式一直是国内外学者关注的焦点。通过梳理近年关于这一板块边界划分问题的最新研究成果,发现多数成果趋向于认为京畿地块及其以南地区仍属中朝板块,苏鲁造山带并未延伸至整个朝鲜半岛。结合郯庐断裂带中生代活动特征及下扬子区弧形构造的成因分析,支持板块碰撞的嵌入模式,并对嵌入模式的边界带进行了新的修订,即朝鲜半岛大多归属中朝板块,仅京畿地块西南局部归属扬子板块东延。郯庐断裂南段与朝鲜半岛Jooggaryeong断裂在黄海海域的延伸分别为下扬子向中朝板块嵌入的转换边界,两者具有相似的演化特征。印支期这两条断裂为碰撞的转换断裂,燕山期又发生了走滑活动,并向北延伸分叉。 相似文献
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11.
The East Vietnam Boundary Fault Zone (EVBFZ) forms the seaward extension of the Red River Shear Zone and interacted with the extensional rift systems in basins along the Central Vietnamese continental margin. The structural outline of the central Vietnamese margin and the timing of deformation are therefore fundamental to understanding the development of the South China Sea and its relation to Indochinese escape tectonism and the India-Eurasia collision. This study investigates the structural and stratigraphic evolution of the Central Vietnamese margin in a regional tectonic perspective based on new 2-D seismic and well data. The basin fill is divided into five major Oligocene to Recent sequences separated by unconformities. Deposition and the formation of unconformities were closely linked with transtension, rifting, the opening of the South China Sea and Late Neogene uplift and denudation of the eastern flank of Indochina. The structural outline of the Central Vietnamese margin favors a hybrid tectonic model involving both escape and slab-pull tectonics. Paleogene left-lateral transtension over the NNW-striking EVBFZ, occurred within the Song Hong Basin and the Quang Ngai Graben and over the Da Nang Shelf/western Phu Khanh Basin, related to the escape of Indochina. East of the EVBFZ, Paleogene NE-striking rifting prevailed in the outer Phu Khanh Basin and the Hoang Sa Graben fitting best with a prevailing stress derived from a coeval slab-pull from a subducting proto-South China Sea beneath the southwest Borneo – Palawan region. Major rifting terminated near the end of the Oligocene. However, late stage rifting lasted to the Early Miocene when continental break-up and seafloor spreading commenced along the edge of the outer Phu Khanh Basin. The resulting transgression promoted Lower and Middle Miocene carbonate platform growth on the Da Nang Shelf and the Tri Ton High whereas deeper marine conditions prevailed in the central part of the basins. Partial drowning and platform retreat occurred after the Middle Miocene due to increased siliciclastic input from the Vietnamese mainland. As a result, siliciclastic, marine deposition prevailed offshore Central Vietnam during the Pliocene and Pleistocene. 相似文献
12.
The Malay Basin is located offshore West Malaysia in the South China Sea, within north central region of 1st order Sunda Block. The basin developed partly as a result of tectonic collisions and strike-slip shear of the Southeast Asia continental slabs, as the Indian Plate collided into Eurasia, and subsequent extrusion of lithospheric blocks towards Indochina. The Sunda Block epicontinental earliest rift margins were manifested by the Palaeogene W–E rift valleys, which formed during NW–SE sinistral shear of the region. Later Eocene NW–SE dextral shear of (2nd order) Indochina Block against East Malaya Block rifted open a 3rd order Malay Basin. Developed within it is a series of 4th order N–S en-echelon ridges and grabens. The grabens and some ridges, sequentially, host W–E trending 5th order folds of later compressional episodes. The Malay Basin Ridge and Graben Model explains the multi-phased structural deformation which started with, the a) Pre-Rift Palaeo/Mesozoic crystalline/metamorphic Basement, b) Synrift phase during Paleogene, c) Fast Subsidence from Late Oligocene to Middle Miocene, d) Compressional inversion of first Sunda fold during Late Miocene, and e) Basin Sag during Plio-Pleistocene with mild compressional episodes. The subsequent Mio-Pliocene folding history of Malay Basin is connected to the collision of Sunda Block against subducting Indian–Australian Plate. This Neogene Sunda tectonics, to some degree after the cessation of South China Sea spreading, is due to the diachronous collision along the 1st order plate margins between SE Asia and Australia. 相似文献
13.
Weilin Zhu Yuchi Cui Lei Shao Peijun Qiao Peng Yu Jianxiang Pei Xinyu Liu Hao Zhang 《海洋学报(英文版)》2021,40(2):13-28
The pre-Cenozoic northern South China Sea(SCS) Basin basement was supposed to exist as a complex of heterogeneous segments, divided by dozens of N-S faulting. Unfortunately, only the Hainan Island and the northeastern SCS region were modestly dated while the extensive basement remains roughly postulated by limited geophysical data. This study presents a systematic analysis including U-Pb geochronology, elemental geochemistry and petrographic identification on granite and meta-clastic borehole samples from several key areas. Constrained from gravity-magnetic joint inversion, this interpretation will be of great significance revealing the tectono-magmatic evolution along the southeastern margin of the Eurasian Plate. Beneath the thick Cenozoic sediments, the northern SCS is composed of a uniform Mesozoic basement while the Precambrian rocks are only constricted along the Red River Fault Zone. Further eastern part of the northern SCS below the Cenozoic succession was widely intruded by granites with Jurassic-to-early Cretaceous ages. Further western part, on the other hand, is represented by meta-sedimentary rocks with relatively sporadic granite complexes. To be noted,the western areas derived higher-degree and wider metamorphic zones, which is in contrast with the lowerdegree and narrower metamorphic belt developed in the eastern region. Drastic collisions between the Indochina Block and South China continent took place since at least late Triassic, resulting in large-scale suturing and deformation zones. At the westernmost part of the northern SCS, the intracontinental amalgamation with closure of the Meso-Tethys has caused fairly stronger and broader metamorphism. One metamorphic biotite granite is located on the suturing belt and yields a Precambrian U-Pb age. It likely represents the relict from the ancient Gondwana supercontinent or its fringes. Arc-continental collision between the Paleo-Pacific and the southeast China Block, on the other hand, results in a relatively narrow NE–SW trending metamorphic belt during the late Mesozoic. Within the overall geological setting, the Cenozoic SCS oceanic basin was subsequently generated from a series of rifting and faulting processes along the collisional-accretionary continental margin. 相似文献
14.
Cuimei Zhang Zhenfeng Wang Zhipeng Sun Zhen Sun Jianbao Liu Zhangwen Wang 《Marine Geophysical Researches》2013,34(3-4):309-323
Located at the intersection between a NW-trending slip system and NE-trending rift system in the northern South China Sea, the Qiongdongnan Basin provides key clues for us to understand the proposed extrusion of the Indochina Block along with Red River Fault Zone and extensional margins. In this paper we for the first time systematically reveal the striking structural differences between the western and eastern sector of the Qiongdongnan Basin. Influenced by the NW-trending slip faults, the western Qiongdongnan Basin developed E–W-trending faults, and was subsequently inverted at 30–21 Ma. The eastern sector was dominated by faults with NE orientation before 30 Ma, and thereafter with various orientations from NE, to EW and NW during the period 30–21 Ma; rifting display composite symmetric graben instead of the composite half graben or asymmetric graben in the west. The deep and thermal structures in turn are invoked to account for such deformation differences. The lithosphere of the eastern Qiongdongnan Basin is very hot and thinned because of mantle upwelling and heating, composite symmetric grabens formed and the faults varied with the basal plate boundary. However, the Southern and Northern Uplift area and middle of the central depression is located on normal lithosphere and formed half grabens or simple grabens. The lithosphere in the western sector is transitional from very hot to normal. Eventually, the Paleogene tectonic development of the Qiongdongnan Basin may be summarized into three stages with dominating influences, the retreat of the West Pacific subduction zone (44–36 Ma), slow Indochina block extrusion together with slab-pull of the Proto-South China Sea (36–30 Ma), rapid Indochina block extrusion together with the South China Sea seafloor spreading (30–21 Ma). 相似文献
15.
利用SEABAT8111多波束系统在南海西南部珊瑚礁区海域进行地形地貌探测,同时还进行了单道和多道地球物理调查。探测表明该区珊瑚礁礁体的活动断裂主要有NE、NW、SN向3组。NE向断裂主要分布在岛礁区内,是晚燕山期南海第一次海底扩张时形成的断裂系,强烈活动于晚白垩世—始新世,晚第三纪以来继承性活动,以张剪性断裂为主,现今活动性中等至弱。NW向断裂主要分布在曾母盆地,以张剪性断裂为主,切割至基底,强烈活动于渐新世至上新世,构成了曾母盆地的主要张裂期,第四纪仍有活动,均为弱活动断裂。SN向断裂主要有南海西部的滨海断裂带,它是南海SN向扩张时期的转换断层,具张剪性,为中活动断裂,是南海西南部珊瑚礁区活动性较强的断裂,该断裂带历史上曾有火山活动和地震活动的记录。 相似文献
16.
印度-欧亚板块碰撞对南海形成的影响研究: 一种数值模拟方法 总被引:2,自引:0,他引:2
中国南海新生代处于欧亚板块、印度-澳大利亚板块和太平洋板块相互作用的交汇处,其形成演化受三大板块复杂动力学过程和相互间作用所制约,尤其是中始新世印度板块同欧亚板块之间的“硬”碰撞及随后的楔入的影响.利用FLAC软件对该次碰撞对南海形成效应进行了模拟,模拟结果表明在模型东-东南边界为自由边界和考虑太平洋向欧亚板块的俯冲作用的支持应力边界条件两种情形下,均能引起构造物质或地幔流向南东、南逃逸,在南海地区产生足够的侧向挤出和南北向的剪切,从而在该地区导致广泛的南北向拉张,这些极有利于南海的打开. 相似文献
17.
珠江口盆地的形成与南海的构造演化 总被引:2,自引:0,他引:2
南海地块在中生代早期与华南大陆边缘发生了一次陆陆碰撞,这一碰撞形成了研究地区中生代近EW向为主的构造格局,珠江口盆地及整个南海的演化都是在南海地块各块体裂离华南陆缘后发生的。盆地自晚白垩世以来,先后经历了不同构造方向的两期张裂阶段及张裂后沉降阶段。 相似文献