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福建平潭岛火山岩及其板块碰撞构造 被引量:1
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作者 黄玉生 蔡传荣 周虹 《福州大学学报(自然科学版)》 CAS CSCD 1992年第4期99-105,共7页
提出在福建东南沿海地区晚白垩世除了产出有拉张地球动力环境下火山(石帽山群火山岩)和深成(魁岐碱性花岗岩类)产物外,在长乐-南澳断裂带以东的平潭岛还产出有挤压地球动力环境下火山产物.其化学成分和岩系演化趋势显著不同于闽... 提出在福建东南沿海地区晚白垩世除了产出有拉张地球动力环境下火山(石帽山群火山岩)和深成(魁岐碱性花岗岩类)产物外,在长乐-南澳断裂带以东的平潭岛还产出有挤压地球动力环境下火山产物.其化学成分和岩系演化趋势显著不同于闽东南南园组和石帽山群火山岩,为独立的钙碱性角闪石英安岩系.其成因可能与库拉板块沿台湾中央山脉东侧向台湾海峡陆块的俯冲有关.闽东南地区早白垩世挤压环境火山产物(南园组火山岩)和晚自垩世拉张环境火山-深层岩系则可能与燕山早期台湾海峡陆块向闽东南大陆边缘的碰撞俯冲,而在晚白垩世停止俯冲,同时在台湾中央山脉东侧发生的俯冲作用所造成的“弧后扩张”有关. 展开更多
关键词 白垩纪 火山岩 板块碰撞构造
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论板块碰撞运动学研究──以江南和东天山造山带为例 被引量:3
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作者 施央申 舒良树 +1 位作者 郭令智 孙家齐 《高校地质学报》 CAS CSCD 1995年第1期11-21,共11页
板块碰撞构造运动学是80年代以来国际上兴起,至今仍方兴未艾的研究领域。本文运用构造运动学的基本原理,结合近年来在江南和东天山造山带的工作实践,对板块碰撞的地质标志、运动学研究的多项重要内容、韧剪带的成因类型等作了总结... 板块碰撞构造运动学是80年代以来国际上兴起,至今仍方兴未艾的研究领域。本文运用构造运动学的基本原理,结合近年来在江南和东天山造山带的工作实践,对板块碰撞的地质标志、运动学研究的多项重要内容、韧剪带的成因类型等作了总结.最后对江南和东天山造山带的碰撞运动学特征和新认识作了简要介绍。 展开更多
关键词 板块碰撞构造 运动学 江南 造山带 东天山
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东秦岭松树沟蛇绿岩产出的构造环境及其组合层序的厘定 被引量:3
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作者 李先福 鲍世聪 +1 位作者 陈彰瑞 余研 《武汉化工学院学报》 1994年第1期11-16,共6页
在研究东秦岭松树沟蛇绿岩形成的区域构造格架的基础上,利用平衡剖面的理论,重新厘定了该蛇绿岩组合层序。表明它是东秦岭碰撞缝合带内保存较完整、序列较连续的杂岩体,与世界上一些典型蛇绿岩套及现代洋壳-上地幔剖面可进行对比。
关键词 蛇绿混杂岩 板块碰撞构造 岩石组合层序 东秦岭松树沟
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Developing plate tectonics theory from oceanic subduction zones to collisional orogens 被引量:89
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作者 ZHENG YongFei CHEN YiXiang +1 位作者 DAI LiQun ZHAO ZiFu 《Science China Earth Sciences》 SCIE EI CAS CSCD 2015年第7期1045-1069,共25页
Crustal subduction and continental collision is the core of plate tectonics theory. Understanding the formation and evolution of continental collision orogens is a key to develop the theory of plate tectonics. Differe... Crustal subduction and continental collision is the core of plate tectonics theory. Understanding the formation and evolution of continental collision orogens is a key to develop the theory of plate tectonics. Different types of subduction zones have been categorized based on the nature of subducted crust. Two types of collisional orogens, i.e. arc-continent and continent-continent collisional orogens, have been recognized based on the nature of collisional blocks and the composition of derivative rocks. Arc-continent collisional orogens contain both ancient and juvenile crustal rocks, and reworking of those rocks at the post-collisional stage generates magmatic rocks with different geochemical compositions. If an orogen is built by collision between two relatively old continental blocks, post-collisional magmatic rocks are only derived from reworking of the old crustal rocks. Collisional orogens undergo reactivation and reworking at action of lithosphere extension, with inheritance not only in the tectonic regime but also in the geochemical compositions of reworked products(i.e., magmatic rocks). In order to unravel basic principles for the evolution of continental tectonics at the post-collisional stages, it is necessary to investigate the reworking of orogenic belts in the post-collisional regime, to recognize physicochemical differences in deep continental collision zones, and to understand petrogenetic links between the nature of subducted crust and post-collisional magmatic rocks. Afterwards we are in a position to build the systematics of continental tectonics and thus to develop the plate tectonics theory. 展开更多
关键词 crustal subduction continental collision postcollisional reworking MAGMATISM METAMORPHISM continental tectonics
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Mesozoic tectono-magmatic activities in South China:Retrospect and prospect 被引量:79
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作者 MAO JianRen LI ZiLong YE HaiMin 《Science China Earth Sciences》 SCIE EI CAS 2014年第12期2853-2877,共25页
The South China Block was formed through the collisional orogeny between the Cathaysia Block and the Yangtze Block in the Early Neoproterozoic.The northern,western and southern sides of the South China Block were affe... The South China Block was formed through the collisional orogeny between the Cathaysia Block and the Yangtze Block in the Early Neoproterozoic.The northern,western and southern sides of the South China Block were affected by disappearance of the Paleo-Tethyan Ocean during the Paleozoic.The southern and northern sides of the South China Block were respectively collided with the Indo-China Block and North China Block in the latest Paleozoic to form the basic framework of the Eastern China.The Eastern China has been affected by the westward subduction of the Pacific Plate since the Mesozoic.Therefore,the South China Block was influenced by the three major tectonic systems,leading to a superposed compound tectonics.The comparative study of the Mesozoic geology between the South China Block and its surrounding areas suggests that although the Mesozoic South China Block was adjacent to the subduction zone of the western Pacific,no juvenile arc-type crust has been found in the eastern margin.The main Mesozoic geology in South China is characterized by reworking of ancient continental margins to intracontinental tectonics,lacking oceanic arc basalts and continental arc andesites.Therefore,a key to understanding of the Mesozoic geology in South China is to determine the temporal-spatial distribution and tectonic evolution of Mesozoic magmatic rocks in this region.This paper presents a review on the tectonic evolution of the South China Block through summarizing the magmatic rock records from the compressional to extensional tectonic process with the transition at the three juncture zones and using the deformation and geophysic data from the deep part of the South China continental lithosphere.Our attempt is to promote the study of South China’s geology and to make it as a typical target for development of plate tectonic theory. 展开更多
关键词 TECTONICS magmatic rocks magmatic activity continental dynamics South China Block
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Anatomy of composition and nature of plate convergence: Insights for alternative thoughts for terminal India-Eurasia collision 被引量:22
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作者 XIAO WenJiao AO SongJian +7 位作者 YANG Lei HAN ChunMing WAN Bo ZHANG Ji'En ZHANG ZhiYong LI Rui CHEN ZhenYu SONG ShuaiHua 《Science China Earth Sciences》 SCIE EI CAS CSCD 2017年第6期1015-1039,共25页
The pattern and timing of collision between India and Eurasia have long been a major concern of the international community. However, no consensus has been reached hitherto. To explore and resolve the disagreements in... The pattern and timing of collision between India and Eurasia have long been a major concern of the international community. However, no consensus has been reached hitherto. To explore and resolve the disagreements in the Himalayan study,in this paper we begin with the methodology and basic principles for the anatomy of composition and nature of convergent margins,then followed by an effort to conduct a similar anatomy for the India-Eurasia collision. One of the most common patterns of plate convergence involves a passive continental margin, an active continental margin and intra-oceanic basins together with accreted terranes in between. The ultimate configuration and location of the terminal suture zone are controlled by the basal surface of the accretionary wedge, which may show fairly complex morphology with Z-shape and fluctuant geometry. One plausible method to determine the terminal suture zone is to dissect the compositions and structures of active continental margins. It requires a focus on various tectonic elements belonging to the upper plate, such as accretionary wedges, high-pressure(HP)-ultra-high-pressure(UHP) metamorphic rocks, Barrovian-type metamorphic rocks and basement nappes, together with superimposed forearc basins.Such geological records can define the extreme limits and the intervening surface separating active margin from the passive one,thus offering a general sketch for the surface trace of the terminal suture zone often with a cryptic feature. Furthermore, the occurrence of the cryptic suture zone in depth may be constrained by geophysical data, which, in combination with outcrop studies of HP-UHP metamorphic rocks, enables us to outline the terminal suture zone. The southern part of the Himalayan orogen records complicated temporal and spatial features, which are hard to be fully explained by the classic "two-plate-one-ocean" template,therefore re-anatomy of the compositions and nature for this region is necessitated. Taking advantage of the methodology and basic principles of plate convergence anatomy and synthesizing previous studies together with our recent research, we may gain new insights into the evolution of the Himalayan orogeny.(1) The Yarlung-Zangbo ophiolite is composed of multiple tectonic units rather than a single terminal suture zone, and a group of different tectonic units were juxtaposed against each other in the backstop of the Gangdese forearc.(2) The Tethyan Himalayan Sequence(THS) contains mélanges with typical block-in-matrix structures, uniform southwards paleocurrents and age spectra of detrital zircons typical of Eurasia continent. All of these facts indicate that the THS belonged to Eurasia plate before the terminal collision, emplaced in the forearc of the Gangdese arc.(3) The Greater Himalayan Crystalline Complex(GHC) and Lesser Himalayan Sequence(LHS) comprise complex components including eclogites emplaced into the GHC and the upper part of the LHS. Judging from the fact that HP-UHP metamorphic rocks are exhumed and emplaced in the upper plate, the GHC and the upper part of the LHS where eclogite occur should be assigned to the upper plate, lying above the terminal subduction zone surface. It is the very surface along which the continuous subduction of the India subcontinent occurred, therefore acting as the terminal, cryptic suture. From the suture further southward, the bulk rock associations of the LHS and Sub-Himalayan Sequence(Siwalik) show little affinity of mélange, probably belonging to the foreland system of the India plate. By the anatomy of tectonic features of all the tectonic units in the Himalayan orogen as well as the ages of the subduction-accretion related deformation, we conclude that the terminal India-Eurasia collision occurred after 14 Ma, the timing of the metamorphism of the eclogites emplaced into the upper plate. The development of rifts stretching in N-S direction in Tibet and tectonic events with the transition from sinistral to dextral movements in shear zones, such as the Ailaoshan fault in East Tibet, can coordinately reflect the scale and geodynamic influence of the India-Eurasia convergence zone.By conducting a detailed anatomy of the southern Himalayas, we propose a new model for the final collision-accretion of the Himalayan orogeny. Our study indicates that the anatomy of structures, composition, and tectonic nature is the key to a better understanding of orogenic belts, which may apply to all the orogenic belts around the world. We also point out that several important issues regarding the detailed anatomy of the structures, compositions and tectonic nature of the Himalayan orogeny in future. 展开更多
关键词 Himalayan orogen Yarlung-Zangbo ophiolite Tethyan Himalayan Sequence India-Eurasia collision Anatomy of orogeny
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