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1.
晚新生代中国东部大陆边缘的构造活动主要集中于东海东缘。中新世以来菲律宾海板块俯冲、冲绳海槽弧后张裂、台湾弧-陆碰撞等一系列重大构造过程,塑造了现今琉球沟-弧-盆体系、台湾碰撞造山带和南海东北部的构造-地貌格局。本文基于对重磁和多道地震资料的解译,并结合前人研究成果,恢复了冲绳海槽构造演化史,阐明了冲绳海槽弧后张裂和台湾弧-陆碰撞之间的关系。在此基础上,重建了中新世以来欧亚板块、菲律宾海板块、南海板块之间的相互作用过程模型。本研究有助于进一步理解板块汇聚背景下东亚大陆边缘深部动力-热力过程对浅部构造格局变迁的制约和影响。 相似文献
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台湾东部海岸山脉对弧陆碰撞的响应 总被引:1,自引:0,他引:1
台湾岛位于欧亚板块和菲律宾海板块的交界处,处在马尼拉海沟和琉球海沟两个方向相对的俯冲带的转换位置.由于从中新世以来吕宋岛弧与欧亚大陆斜向碰撞(弧陆碰撞)形成了今日台湾构造格局,特有的构造地质环境和正在进行中的块体增生使其成为地质学家的研究热点.针对吕宋岛弧海岸山脉段对弧陆碰撞的响应,本文综述了近年来海岸山脉年代学、地球化学、构造地质和利吉混杂岩等方面的研究成果,对海岸山脉的快速隆升和剥蚀特征进行了总结,并在此基础上指出了目前海岸山脉地质研究工作中存在的主要问题,提出今后的研究方向应集中在利吉混杂岩的形成机制、花东海盆洋壳性质和利用海岸山脉凝灰岩进行弧陆碰撞发展过程研究等几个方面. 相似文献
3.
约距今2200万年的新近纪中新世早期,菲律宾洋板块斜向俯冲插入欧亚陆板块之下,在板块碰接带的两侧进行不同的地质演化。海沟、火山岛弧、弧后盆地是板块构造理论中洋板块与陆板块碰接时在碰接带附近产生的构造地貌,即“沟、弧、盆系”。菲律宾洋板块俯冲于欧亚陆板块之下到更新世后期(距今约20万年),其构造地貌由洋到陆为大洋-硫球海沟-台湾火山岛弧-弧后盆(边缘海)-中国大陆,其中海沟以东至大陆为东海大陆架。 相似文献
4.
南海是西太平洋海域最大的边缘海,然而南海扩张终结后动力学过程研究仍较为薄弱.通过构造变革界面识别、褶皱冲断带沉积记录等方面的系统研究,揭示南海南部和东部陆缘在南海后扩张期的演化历程.研究表明南海南部和东部边缘经历了多个微板块从俯冲到碰撞的演变历程,形成了陆-陆碰撞、弧-陆碰撞、洋-弧俯冲等多个特征迥异的板块边界.南海南部陆缘属于古南海俯冲拖曳构造区,婆罗洲西北沙捞越-曾母地块率先碰撞,随后经历了婆罗洲东北沙巴-南沙地块碰撞、西南巴拉望-卡加延岛弧碰撞.南部多个微板块碰撞导致古南海呈剪刀式从西向东逐渐关闭和消亡,总体形成了以微地块碰撞、深海槽发育和造山带前缘巨厚沉积充填为特色的碰撞陆缘.东部陆缘属于菲律宾海俯冲-碰撞构造区,南海东部洋壳自中新世开始向菲律宾海板块俯冲,弧-陆碰撞仅局限于东部陆缘南北两端.澳洲-印度板块、菲律宾海板块与欧亚板块相互作用控制了南海边缘海闭合过程,南海正在进行的关闭过程主要集中在东缘和南缘,东缘呈现了以南海洋壳消亡为特征的闭合过程,而南缘则呈现以微陆块碰撞为特征的古南海闭合过程.显然,南部后扩张期陆缘演变可为边缘海闭合过程研究提供极佳的范例,同时对我国海洋权益保护和南海大陆边缘动力学研究具有重要意义. 相似文献
5.
台湾岛是吕宋岛弧(相当于菲律宾海板块西缘)与中国大陆边缘(属于欧亚板块)强烈碰撞的结果。这一碰撞带位于马尼拉海沟俯决带的北部延伸。沿此带,南海盆地向东一东南俯冲到吕宋岛弧之下。向北,强烈的俯冲与激烈碰撞之间的变化是递变发展的。相反,在台湾东部,碰撞带与Ryukyu活动边缘之界线十分清析。后者与菲律宾西部海盆地向西北方向上的欧亚大陆边缘下的俯冲作用有关。对于台湾东、南部这两个关键区的构造研究是1984年10月—11月R/V Jean-Char(?)ot “Pop_2”号勘察的主要目的。分别在20°15′N和21°45′N之间对马尼拉俯冲带的北端以 相似文献
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7.
台湾造山带是中新世晚期以来相邻菲律宾海板块往北西方向移动,导致北吕宋岛弧系统及弧前增生楔与欧亚大陆边缘斜碰撞形成的。目前该造山带仍在活动,虽然规模很小,但形成了多数大型碰撞造山带中的所有构造单元,是研究年轻造山系统的理想野外实验室,为理解西太平洋弧-陆碰撞过程和边缘海演化提供了一个独特的窗口。本文总结了二十一世纪以来对台湾造山带的诸多研究进展,讨论了其构造单元划分及演化过程。我们将台湾造山带重新划分为6个构造单元,由西至东分依次为:(1)西部前陆盆地;(2)中央山脉褶皱逆冲带;(3)太鲁阁带;(4)玉里-利吉蛇绿混杂岩带;(5)纵谷磨拉石盆地;(6)海岸山脉岛弧系统。其中,西部前陆盆地为6.5Ma以来伴随台湾造山带的隆升剥蚀形成沉积盆地。中央山脉褶皱逆冲带为新生代(57~5.3Ma)欧亚大陆东缘伸展盆地沉积物由于弧-陆碰撞受褶皱、逆冲及变质作用改造形成的。太鲁阁带是造山带中的古老陆块,主要记录中生代古太平洋俯冲在欧亚大陆活动边缘形成的岩浆、沉积和变质岩作用。玉里-利吉蛇绿混杂岩带和海岸山脉岛弧系统分别为中新世中期(~18Ma)以来南中国海板块向菲律宾海板块之下俯冲形成的岛弧和弧前增生楔,其中玉里混杂岩中有典型低温高压变质作用记录,变质年龄为11~9Ma;岛弧火山作用的主要时限为9.2~4.2Ma。纵谷磨拉石盆地记录1.1Ma以来的山间盆地沉积。台湾造山带的构造演化可划分为4个阶段:(a)古太平洋板块俯冲与欧亚大陆边缘增生阶段(200~60Ma);(b)欧亚大陆东缘伸展和南中国海扩张阶段(60~18Ma);(c)南中国海俯冲阶段(18~4Ma);(d)弧-陆碰撞阶段(<6Ma)。台湾弧-陆碰撞造山带是一个特殊案例,其弧-陆碰撞并不伴随着弧-陆之间的洋盆消亡,而是由于北吕宋岛弧及弧前增生楔伴随菲律宾海板块运动向西北方走滑,仰冲到欧亚大陆边缘,形成现今的台湾造山带。 相似文献
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琉球弧前盆地位于菲律宾海板块北部与欧亚板块汇聚部位,发育于琉球海沟北部增生楔与琉球岛弧之间,是典型“沟-弧-盆”体系的组成单元。现利用多道地震资料,首次建立琉球弧前盆地的层序地层格架,分析其新生代层序地层特征,阐明弧前盆地沉积充填演化过程,并探讨各盆地主要物源。通过地震剖面解释分析,表明:①始新世为岛弧变质基底沉积期,晚渐新世晚期-早中新世阶段发育残余伸展盆地基底沉积,属于浅海环境,主要受岩浆活动影响,发育火山碎屑岩相;②中中新世-第四纪时期是弧前盆地的主体沉积期,盆地从半深海沉积环境向深海环境过渡,发育典型深海沉积相,局部为火山碎屑岩相;中中新世时北部的南琉球群岛是弧前盆地主要物源区;晚中新世至第四纪时期,台湾岛东北部陆区成为对该弧前盆地贡献最大的物源区,而南琉球群岛的物源供给量降为次要地位。该研究结果是对琉球岛弧及周缘构造控盆作用研究的拓展,并对台湾岛陆地与东部海域“源-汇”系统研究有重要的指导意义。 相似文献
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台湾造山带位于欧亚板块和菲律宾海板块交界处, 由于两板块斜向聚合作用, 使得台湾造山带构造极其复杂并具有分段性: 南部尚处于碰撞造山初期, 而北部已处于碰撞后期, 构造环境已从挤压转变为张裂。前人利用三维砂箱模型对造山带进行研究时, 主要关注于斜向聚合作用对造山带的影响, 较少考虑到冲绳海槽张裂作用。本文在前人基础上通过添加砂纸带机器模拟张裂作用, 探讨挤压-张裂同时作用下砂体的变形模式, 解释台湾造山带北部—琉球地区的构造现象。通过分析实验图像和粒子图像测量(PIV)数据, 并与地震剖面、GPS速度场测量和古地磁数据进行对比后认为: 台湾岛北部顺时针旋转主要与斜向汇聚作用有关; 宜兰平原东西至东北—西南向的运动, 及南北有别的运动模式主要与冲绳海槽张裂作用有关; 琉球地区形貌主要受控于俯冲的菲律宾海板块形状, 在斜向聚合作用下造成地层褶皱和挤压。之后在由东向西发展的弧后伸展作用下, 形成冲绳海槽东宽西窄的凹陷区及一系列正断层, 并伴随琉球岛弧的顺时针旋转。 相似文献
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南海北部与台湾海峡地区自晚白垩世至新生代,经历了由挤压性大陆边缘向伸展性大陆边缘的转化,这一伸展性质除台湾海峡地区由于后期弧陆碰撞封闭而转化成带有挤压性的前陆盆地外,其余部分一直保持着伸展性质,但它不是被动式陆缘而是活动性陆缘的一部分,其主要依据是整个南海这一时期处于印度板块,菲律宾板块与欧亚板块的相互挤压和活动大陆边缘之中,其岩浆活动除有陆缘裂谷型火山岩外,尚有活动陆缘的火山岩,南海是一个活动陆 相似文献
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西太平洋边缘构造带是地球上规模最大最复杂的板块边界,以台湾和马鲁古海为界,自北往南大致可以分为3段。北段是典型的沟-弧-盆体系,千岛海盆、日本海盆及冲绳海槽均为典型的弧后扩张盆地。中段菲律宾岛弧构造带为双向俯冲带,构造复杂,新生代经历大的位移和重组,使得欧亚大陆边缘的南海、苏禄海和苏拉威西海成因存在很大的争议。南段新几内亚—所罗门构造带是太平洋板块、印度—澳大利亚及欧亚板块共同作用的结果,既有不同阶段的俯冲、碰撞,也有大规模的走滑与弧后的扩张,其间既有新扩张的海盆,又有正在俯冲消亡的海盆。台湾岛处于枢纽部位,欧亚板块在此被撕裂,南部欧亚大陆边缘南海洋壳沿马尼拉海沟俯冲于菲律宾岛弧之下,而北部菲律宾海洋壳沿琉球海沟俯冲欧亚大陆之下。马鲁古海是西太平洋板块边界又一转折点,马鲁古海板块往东下插于哈马黑拉之下,往西下插于桑义赫弧,形成反U形双向俯冲汇聚带,其洋壳板块已基本全部消失,致使哈马黑拉弧与桑义赫弧形成弧-弧碰撞。 相似文献
12.
Located at the end of the northern Manila Trench,the Hengchun Peninsula is the latest exposed part of Taiwan Island,and preserves a complete sequence of accretionary deep-sea turbidite sandstones.Combined with extensive field observations,a’source-to-sink’approach was employed to systematically analyze the formation and evolutionary process of the accretionary prism turbidites on the Hengchun Peninsula.Lying at the base of the Hengchun turbidites are abundant mafic normal oceanic crust gravels with a certain degree of roundness.The gravels with U-Pb ages ranging from 25.4 to23.6 Ma are underlain by hundreds-of-meters thickness of younger deep-sea sandstone turbidites with interbedded gravels.This indicates that large amounts of terrigenous materials from both the’Kontum-Ying-Qiong’River of Indochina and the Pearl River of South China were transported into the deep-water areas of the northern South China Sea during the late Miocene and further eastward in the form of turbidity currents.The turbidity flow drastically eroded and snatched mafic materials from the normal South China Sea oceanic crust along the way,and subsequently unloaded large bodies of basic gravel-bearing sandstones to form turbidites near the northern Manila Trench.With the Philippine Sea Plate drifting clockwise to the northwest,these turbidite successions eventually migrated and,since the Middle Pleistocene,were exposed as an accretionary prism on the Hengchun Peninsula. 相似文献
13.
A synthesis of the geologic evolution of Taiwan 总被引:2,自引:0,他引:2
C.S. Ho 《Tectonophysics》1986,125(1-3)
The island arc of Taiwan is composed of Cenozoic geosynclinal sediments more than 10,000 m thick, lying on a pre-Tertiary metamorphic basement. Pleistocene to Miocene andesitic islands surround the main island and are related mostly to arc magmatism. The Penghu Island Group in the Taiwan Strait is covered with Pleistocene flood basalt. Neogene shallow marine clastic sediments are exposed mainly in the western foothills with Pleistocene andesitic extrusives at the northern tip and the northeastern offshore islands. A thick sequence of Paleogene to Miocene argillitic to slaty metaclastic rocks underlies the western Central Range and forms the immediate sedimentary cover on the pre-Tertiary metamorphic complex to the east, which represents an older Mesozoic arc-trench system. The Coastal Range in eastern Taiwan is a Neogene andesitic magmatic arc, including also a large variety of volcaniclastic and turbiditic sediments. Cenozoic Taiwan is the site of arc-continent collision where the Luzon arc on the Philippine Sea plate overrides the Chinese continental margin on the Eurasian plate. East and northeast of Taiwan, the polarity of subduction changes whereby the oceanic Philippine Sea plate is subducting beneath the Ryukyu arc system on the Eurasian plate. Continent-arc collision in Taiwan island is anomalous and may occur in a broad belt of deformation rather than along a well-defined plate boundary or subduction zone. 相似文献
14.
E. Barrier 《Tectonophysics》1985,115(1-2)
The active Taiwan orogen is the product of a two stage collision, that included first the collision of the Hengchun ridge, an accretionary wedge, with the Chinese continental margin, and second the collision of the Luzon trough and volcanic arc, from the Philippine Sea plate, with the Central Range of Taiwan. During the first stage, the strength of the continental margin induced a decrease of the convergence rate that controlled the final Central Range orientation and induced the second stage of the collision. Taking into account the kinematics of the plate interaction, a reconstruction of the Taiwan collision during the last 4 Ma is proposed. 相似文献
15.
How was Taiwan created? 总被引:4,自引:0,他引:4
Since the beginning of formation of proto-Taiwan during late Miocene (9 Ma), the subducting Philippine (PH) Sea plate moved continuously through time in the N307° direction at a 5.6 cm/year velocity with respect to Eurasia (EU), tearing the Eurasian plate. Strain states within the EU crust are different on each side of the western PH Sea plate boundary (extensional in the Okinawa Trough and northeastern Taiwan versus contractional for the rest of Taiwan Island). The B feature corresponds to the boundary between the continental and oceanic parts of the subducting Eurasian plate and lies in the prolongation of the ocean–continent boundary of the northern South China Sea. Strain rates in the Philippines to northern Taiwan accretionary prism are similar on each side of B (contractional), though with different strain directions, perhaps in relation with the change of nature of the EU slab across B. Consequently, in the process of Taiwan mountain building, the deformation style was probably not changing continuously from the Manila to the Ryukyu subduction zones. The Luzon intra-oceanic arc only formed south of B, above the subducting Eurasian oceanic lithosphere. North of B, the Luzon arc collided with EU simultaneously with the eastward subduction of a portion of EU continental lithosphere beneath the Luzon arc. In its northern portion, the lower part of the Luzon arc was subducting beneath Eurasia while the upper part accreted against the Ryukyu forearc. Among the consequences of such a simple geodynamic model: (i) The notion of continuum from subduction to collision might be questioned. (ii) Traces of the Miocene volcanic arc were never found in the southwestern Ryukyu arc. We suggest that the portion of EU continental lithosphere, which has subducted beneath the Coastal Range, might include the Miocene Ryukyu arc volcanoes formed west of 126°E longitude and which are missing today. (iii) The 150-km-wide oceanic domain located south of B between the Luzon arc and the Manila trench, above the subducting oceanic EU plate (South China Sea) was progressively incorporated into the EU plate north of B. 相似文献
16.
As a result of oblique collision, the Taiwan orogen propagates southward. The Hengchun peninsula in the southern tip of the Taiwan Central Range, preserving the youngest, the least deformed and the most complete accretionary prism sequences, allows therefore better understanding of the tectonic evolution of Taiwan orogen. On the Hengchun peninsula, four main stages of paleostress can be recognized by the analysis of brittle tectonics. After recording the first two stages of paleostress, rocks of the Hengchun peninsula (the Hengchun block) have undergone both tilting and counterclockwise rotation of about 90°. The structural boundaries of this rotated Hengchun block are: the Kenting Mélange zone in the southwest, the Fongkang Fault in the north, and a submarine backthrust in the east. The angle of this rotation is principally calculated by the paleomagnetic analysis data and a physical model experiment. Through a systematic back-tilting and back-rotating restoration, the original orientations of the four paleostress stages of Hengchun peninsula are recognized. They are, from the ancient to the recent, a NW–SE extension, a combination of NW–SE transtension and NE–SW transpression, a NE–SW compression, and finally a combination of NE–SW transtension and NW–SE transpression. This result can be explained by a phenomenon of stress axes permutation, instead of a complex polyphase tectonism. This stress axes permutation is caused by the horizontal compression increase accompanying the propagation of the accretionary prism. Combining the tectonic and paleomagnetic data with paleocurrent and stratigraphic data enables us to reconstruct the tectonic evolution of the Hengchun peninsula. This reconstruction corresponds to the deformation history of a continental margin basin, from its opening to its intense deformation in the accretionary prism. 相似文献
17.
《China Geology》2018,1(4):477-484
Lichi mélange, located in the southern coastal range, eastern Taiwan, China, is a typical tectonic mélange of the plate’s boundary zone between the Eurasian Plate and the Philippine Sea Plate. It formed during the collision of the Luzon arc with the Eurasian Continent (arc-continent collision). It is composed of sandstone and/or mudstone matrix and many kinds and sizes of rock fragments, including some sedimentary rocks, volcanic rocks and a few metamorphic rocks. The serpentinite is one of the common fragments in the Lichi mélange. By the petrographic characteristics and the zircon U-Pb chronology analyses, protolith of the serpentinite is peridotite, the age is 17.7 ± 0.5 Ma. Taking the tectonic background into account, it is inferred that the serpentinite (serpentinised peridotite) come from the forearc basin (the North Luzon Trough) and was taken into the mélange by a second thrust westwards. The origin of the serpentinite in Lichi mélange is helpful to understand the formation of the Lichi mélange and can provide reliable detailed information for the study of the arc-continent collision orogenic activity in and offshore Taiwan. 相似文献
18.
Kirk McIntosh Yosio Nakamura T.-K. Wang R.-C. Shih Allen Chen C.-S. Liu 《Tectonophysics》2005,401(1-2):23-54
We have used combined onshore and offshore wide-angle seismic data sets to model the velocity structure of the Taiwan arc–continent collision along three cross-island transects. Although Taiwan is well known as a collisional orogen, relatively few data have been collected that reveal the deeper structure resulting from this lithospheric-scale process. Our southern transect crosses the Hengchun Peninsula of southernmost Taiwan and demonstrates characteristics of incipient collision. Here, 11-km-thick, transitional crust of the Eurasian plate (EUP) subducts beneath a large, rapidly growing accretionary prism. This prism also overrides the N. Luzon forearc to the east as it grows. Just west of the arc axis there is an abrupt discontinuity in the forearc velocity structure. Because this break is accompanied by intense seismicity, we interpret that the forearc block is being detached from the N. Luzon arc and Philippine Sea plate (PSP) at this point. Our middle transect illustrates the structure of the developing collision. Steep and overturned velocity contours indicate probable large-scale thrust boundaries across the orogen. The leading edge of the coherent PSP appears to extend to beneath the east coast of Taiwan. Deformation of the PSP is largely limited to the remnant N. Luzon arc with no evidence of crustal thickening to the east in the Huatung basin. Our northern transect illustrates slab–continent collision—the continuing collision of the PSP and EUP as the PSP subducts. The collisional contact is below 20 km depths along this transect NE of Hualien. This transect shows elements of the transition from arc–continent collision to Ryukyu arc subduction. Both of our models across the Central Range suggest that the Paleozoic to Mesozoic basement rocks there may have been emplaced as thick, coherent thrust sheets. This suggests a process of partial continental subduction followed by intra-crustal detachment and buoyancy-aided exhumation. Although our models provide previously unknown structural information about the Taiwan orogen, our data do not define the deepest orogenic structure nor the structure of western Taiwan. Additional seismic (active and passive), geologic, and geodynamic modeling work must be done to fully define the structure, the active deformation zones, and the key geodynamic process of the Taiwan arc–continent collision. 相似文献