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蛇绿岩与产于增生楔中的蛇绿岩碎片记录了大洋岩石圈形成、俯冲、消亡等造山作用的全过程信息;是解剖造山带与探讨造山作用的重要研究对象.本文重点阐述蛇绿岩的继承性构造(形成于大洋岩石圈形成阶段:洋?陆过渡带型(ocean-continental transition,简称OCT)、洋中脊型(快速扩张脊的Penrose型与慢速扩张的洋底核杂岩型)、supra-subduction-zone(SSZ)型三个基本端元)与造山就位构造(构造就位于造山带阶段:仰冲就位与俯冲刮铲)的特征、区别及其地质意义.强调蛇绿岩形成的“生而不同”与构造就位的“死也有别”;讨论了蛇绿岩两阶段的特征、时代的大地构造配置,呼吁关注蛇绿岩构造就位阶段俯冲流体的叠加作用,其可能导致最终就位在造山带中的蛇绿岩大部分都具有SSZ型特征.最后,结合中亚造山带南部主要蛇绿岩的特征,对未来中亚造山带蛇绿岩研究提出一些思考与展望;指出未来研究应注重对有限洋盆或小洋盆的厘定,关注OCT成因蛇绿岩的识别与研究,重视山弯构造与走滑断裂对蛇绿岩带现今产出的控制与改造作用. 相似文献
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内蒙古索伦山地区出露蛇绿岩,其研究对探讨古亚洲洋演化具有重要意义。对内蒙古索伦山地区蛇绿岩进行了系统的调查和研究,探讨了其就位机制与时限。 结合索伦山蛇绿岩地质特征和区域地质背景综合分析,认为研究区蛇绿岩组合包括地幔与洋壳组分。索伦山地区蛇绿岩存在较为完整的蛇绿岩组合模式,出露地幔岩石组合为蛇纹石化纯橄榄岩、蛇纹石化二辉-方辉橄榄岩、橄榄辉石岩和硅化碳酸盐化蚀变超基性岩(风化壳)等。蛇绿岩组合中洋壳组分为辉长岩、辉绿岩、玄武岩和硅质岩。蛇绿岩就位机制划分为4种,即碰撞仰冲型、增生底垫型、俯冲剥离型和角流型。其中,俯冲剥离型就位机制表现为岩石组合齐全完整的特征,产出形态为岩块、岩片,其中岩块、岩片与基质为构造断层接触;在俯冲带近大陆一侧常形成岛弧岩浆岩等特征。索伦山蛇绿岩地质特征与俯冲剥离型就位机制特征完全相符,故索伦山蛇绿岩就位机制大致为洋中脊俯冲剥离型。根据大洋岩石圈形成之后在10 Ma之内就位这一原则,结合索伦山地区辉长岩SHRIMP锆石U Pb年龄为(2807±53) Ma,认为索伦山蛇绿岩就位时限在270 Ma左右。 相似文献
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第32届国际地质大会反映了近年来造山带和蛇绿岩研究的最新成果。太古代与年轻造山带对比研究表明决定造山带几何特征的主要因素是它们与同造山及造山期后的伸展构造体制的响应方式。进一步分析了中新元古代罗得利亚超大陆的形成与裂解机理。分析了晚前寒武纪-古生代造山作用过程及可能模式。造山带形成后其深部表露、抬升和剥蚀过程与气候及环境演变有紧密的关系,是当前及今后地球科学的重要研究领域。蛇绿岩的岩浆成因并不能用一种简单的模式来解释,研究表明蛇绿岩岩浆具多成因。提出了蛇绿岩套的双离散侵位模式、多米诺旋转侵位模式、俯冲快速折返就位模式。对比表明特提斯及环太平洋蛇绿岩的来源、演化及就位特征具明显的多样性。 相似文献
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蛇绿岩及蛇绿岩构造侵位 总被引:3,自引:0,他引:3
高坪仙 《前寒武纪研究进展》2000,23(4):250-256
已有研究实例阐明了蛇绿岩产出的构造环境及构造侵位机制的多样性,其中发育完整的蛇绿岩套具有与现代大洋岩石圈剖面相似的四层结构模式,它们形成于洋中脊扩张构造环境。由于构造运动使蛇绿岩套肢解,构造侵位于大陆造山带缝合线地带,沿断裂构造以构造岩片和构造昆杂岩产出。蛇绿岩提供了洋壳形成和破坏的重要证据,蛇绿岩带和古缝合线是确定造山带中古洋盆存在及陆块边界的直接标志。 相似文献
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已有研究实例阐明了蛇绿岩产出的构造环境及构造侵位机制的多样性 ,其中发育完整的蛇绿岩套具有与现代大洋岩石圈剖面相似的四层结构模式 ,它们形成于洋中脊扩张构造环境。由于构造运动使蛇绿岩套肢解 ,构造侵位于大陆造山带缝合线地带 ,沿断裂构造以构造岩片和构造混杂岩产出。蛇绿岩提供了洋壳形成和破坏的重要证据 ,蛇绿岩带或古缝合线是确定造山带中古洋盆存在及陆块边界的直接标志 相似文献
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青海天峻南山蛇绿岩的地质特征及其形成环境 总被引:3,自引:0,他引:3
青海天峻南山蛇绿岩为本次1:5万区调中首次发现,从其中地质特征,岩石化学及地球化学特征反映出陆内裂谷扩张的早石炭世小洋盆构造环境,它的发现对于重新认识宗务隆造山地质属性,地球动力学机制,与祁连造山带,柴达木地块的构造关系以及研究古特提斯洋演化提供了新的依据。 相似文献
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完达山增生造山带(也被称之为那丹哈达地体)位于东北亚大陆边缘,与俄罗斯远东地区的锡霍特-阿林增生造山带相连,它们共同构成环太平洋造山带的重要组成部分,是中国北方唯一的中生代海相沉积建造出露区。这些增生造山带的形成与古太平洋的俯冲增生作用密切相关,其中包括外来地体、微小陆块、岛弧、洋壳、海山、大洋高原、蛇绿岩等复杂的地质块体。传统的岩石地层填图方法在研究区不合适,无法反映杂岩属性。因此,在传统野外地质调查方法的基础上,采用针对造山带非史密斯地层填图方法,这将对本地区的地质工作有重要的意义。 相似文献
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K. Wakita 《Journal of Asian Earth Sciences》2000,18(6)
The geology of Cretaceous accretionary–collision complexes in central Indonesia is reviewed in this paper. The author and his colleagues have investigated the Cretaceous accretionary–collision complexes by means of radiolarian biostratigraphy and metamorphic petrology, as well as by geological mapping. The results of their work has revealed aspects of the tectonic development of the Sundaland margin in Cretaceous time. The Cretaceous accretionary–collision complexes are composed of various tectonic units formed by accretionary or collision processes, forearc sedimentation, arc volcanism and back arc spreading. The tectonic units consist of chert, limestone, basalt, siliceous shale, sandstone, shale, volcanic breccia, conglomerate, high P/T and ultra high P metamorphic rocks and ultramafic rocks (dismembered ophiolite). All these components were accreted along the Cretaceous convergent margin of the Sundaland Craton. In the Cretaceous, the southeastern margin of Sundaland was surrounded by a marginal sea. An immature volcanic arc was developed peripherally to this marginal sea. An oceanic plate was being subducted beneath the volcanic arc from the south. The oceanic plate carried microcontinents which were detached fragments of Gondwanaland. Oceanic plate subduction caused arc volcanism and formed an accretionary wedge. The accretionary wedge included fragments of oceanic crust such as chert, siliceous shale, limestone and pillow basalt. A Jurassic shallow marine allochthonous formation was emplaced by the collision of continental blocks. This collision also exhumed very high and ultra-high pressure metamorphic rocks from the deeper part of the pre-existing accretionary wedge. Cretaceous tectonic units were rearranged by thrusting and lateral faulting in the Cenozoic era when successive collision of continental blocks and rotation of continental blocks occurred in the Indonesian region. 相似文献
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柴北缘赛坝沟增生杂岩组成与变形特征 总被引:1,自引:0,他引:1
柴北缘构造带由高压-超高压变质岩、蛇绿岩、增生杂岩、火山-岩浆弧及前寒武纪中-高级变质岩共同构成。该构造带内的"滩间山群"岩石组合与构造属性复杂,其岩性包括中基性火山岩、碎屑沉积岩以及超基性岩和中酸性侵入岩,普遍遭受低绿片岩相变质作用和强烈构造变形。结合区域资料和地质填图结果,综合分析认为该构造带东段赛坝沟地区的"滩间山群"由火山-岩浆弧、增生杂岩、蛇绿岩三个不同构造单元岩石组成。其中增生杂岩主要是一套深海-半深海沉积组合,夹玄武岩、灰岩、硅质岩等块体,自南而北总体呈现出来自洋壳、海山和海沟环境的大洋板块地层的岩石组合特征,同时呈现与日本西南部增生杂岩极为相似的岩石组合类型。该套组合构造变形强烈,主要表现为2期构造变形。其中第一期构造变形(D1)主要表现为双冲构造和同斜紧闭褶皱,断层和褶皱轴面主体倾向为NE,形成于大洋俯冲阶段;第二期构造变形(D2)主要表现为不对称褶皱和S-C组构,可能是晚期柴达木与祁连地块发生陆-陆碰撞过程中形成的,形成时间为440~400Ma。空间上,该增生杂岩与出露于其北侧的蛇绿岩、火山-岩浆弧共同构成了相对完整的沟-弧系统,指示了寒武-奥陶纪时期,柴北缘地区曾发生古洋盆向北俯冲造山作用。 相似文献
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Toshiyuki Kurihara Kazuhiro Tsukada Shigeru Otoh Kenji Kashiwagi Minjin Chuluun Dorjsuren Byambadash Bujinlkham Boijir Sersmaa Gonchigdorj Manchuk Nuramkhan Masakazu Niwa Tetsuya Tokiwa Gen’ya Hikichi Takafumi Kozuka 《Journal of Asian Earth Sciences》2009,34(2):209-225
Recent mapping projects undertaken in Central Mongolia have revealed the widespread occurrence of radiolarian chert within a Paleozoic accretionary complex. We present the results of the first detailed tectonostratigraphic and radiolarian biostratigraphic investigations of the Gorkhi Formation in the Khangai–Khentei belt of the Central Asian Orogenic Belt.The Gorkhi Formation consists of sandstone shale, alternating sandstone and shale of turbidite affinity and chert with small amounts of siliceous shale, basalt, limestone, and clast-bearing mudstone. Radiolarian chert that is completely devoid of terrigenous clastic material is commonly associated with underlying basalt (sedimentary contact) and with conformably overlying siliceous shale and turbidite deposits. The tectonic stacking of basalt–chert and chert–turbidite successions is the most remarkable structural feature of the formation.The recovery of moderately well-preserved radiolarians and conodonts from red chert led to the recognition of four radiolarian assemblages that have a combined age range from the latest Silurian (Pridolian) to the Late Devonian (Frasnian). No age control exists for the siliceous shale, shale, and sandstone, although they are considered to be latest Devonian or slightly younger on the basis of stratigraphic relationships with underlying chert.The Gorkhi Formation has previously been interpreted as a thick sedimentary basin deposit overlying an unexposed Archean–Neoproterozoic basement; however, the stratigraphy within individual tectonic slices clearly corresponds to that of an ocean plate stratigraphy of an accretionary complex generated by the trenchward movement of an oceanic plate. From the lowermost to uppermost units, the stratigraphy comprises ocean floor basalt, pelagic deep-water radiolarian chert, hemipelagic siliceous shale, and terrigenous turbidite deposits. The biostratigraphic data obtained in the present study provide corroborating evidence for the existence of an extensive deep-water ocean that enabled the continuous sedimentation of pelagic chert over a period of nearly 50 million years. These data, together with structural data characterized by tectonic repetition of the stratigraphy, indicate that these rocks formed as an accretionary wedge along an active continental margin, possibly that of the Angara Craton. The mid-oceanic chert was probably deposited in the Northern Hemisphere portion of the Paleo–Pacific Ocean that faced the Angara Craton and the North China–Tarim blocks. Thus, we propose that subduction–accretion processes along the Paleo–Pacific rim played an important role in the accretionary growth of the active continental margin of the Angara Craton, directly influencing the evolution of the Central Asian Orogenic Belt. 相似文献
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The Kiselyovka–Manoma accretionary complex formed at the end of the Early Cretaceous during subduction of the Pacific oceanic plate underneath the Khingan–Okhotsk active continental margin along the east of Eurasia. It is composed of Jurassic–Early Cretaceous oceanic chert, siliceous mudstone, and limestone that include a significant amount of basic volcanic rocks. The known and newly obtained data on the petrogeochemistry of the Jurassic and Early Cretaceous basalt from various parts of the accretionary complex are systemized in the paper. Based on the comprehensive analysis of these data, the possible geodynamic settings of the basalt are considered. The petrogeochemical characteristics provide evidence for the formation of basalt in different parts of the oceanic floor within the spreading ridge, as well as on oceanic islands far from the ridge. The basalts of oceanic islands are mostly preserved in the accretionary complex. The compositional variations of the basalts may be controlled by the different thickness of the oceanic lithosphere on which they formed. This is explained by the varying distances of the lithosphere from the spreading zone. 相似文献
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Permian greenstones in the Jurassic Mino–Tamba accretionary complex, southwest Japan, are divided into three distinct series on the basis of their geological occurrence, mineralogy, and geochemistry. A low-Ti series (LTS) is associated with Lower Permian chert and limestone, and is the most voluminous of the three series. The LTS shows slightly more enriched geochemical and isotopic characteristics than MORB. A transition series (TS) is mainly associated with Lower Permian chert, and has more enriched geochemical signatures than MORB. Its isotopic characteristics are divided into enriched and depleted types. A high-Ti series (HTS) occurs as sills and hyaloclastites within Middle Permian chert and as dikes intruding the TS. Some HTS rocks have high MgO contents. The HTS is characterized by enrichment in incompatible trace elements and an isotopic composition comparable to HIMU-type basalt. The geochemistry of the voluminous LTS is similar to that of the oceanic basalt series of the Kerguelen plateau, suggesting production by partial melting of a shallow mantle plume head below thick oceanic lithosphere in Early Permian time. We infer that the TS formed simultaneously at the margins of the mantle plume head. In contrast, the HTS may have resulted from partial melting of a deep mantle plume tail in Middle Permian time. Permian greenstones in the Mino–Tamba belt may have thus formed by superplume activity in an intra-oceanic setting. Given the presence of two known contemporary continental flood basalt provinces (Siberia and Emeishan) and some accreted oceanic plateau basalts, the vast magmatism of the Mino–Tamba oceanic plateau suggests a large-scale superplume pulse in Permian time. Accretion of oceanic plateaux may have played an important role in the growth of continental margins and island arcs in Japan and elsewhere in the circum-Pacific region. 相似文献
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前人关于南澜沧江构造带团梁子岩组的时代和构造属性有不同的认识.对景谷地区的团梁子岩组的物质组成、锆石年代学和地球化学进行了系统研究.团梁子岩组是一套强变形、弱变质的构造地层,主要由深海洋盆泥质岩和近岛弧碎屑岩构成,夹杂有洋中脊型玄武岩、硅质岩等岩块.2件变沉积岩样品的锆石U-Pb年龄结果显示其原岩时代分别不早于272±2 Ma和259±1 Ma.侵入团梁子岩组的安山玢岩锆石U-Pb年龄为244±1 Ma.团梁子岩组的变玄武岩岩块属于低钾拉斑玄武岩系列,具有典型的N-MORB地球化学特征.综合团梁子岩组的岩石组合特征和原岩性质,认为其很可能是一套晚古生代俯冲增生杂岩.团梁子岩组和南澜沧江构造带内其他洋盆相残余物质指示南澜沧江构造带是一条古特提斯结合带,代表存在于晚古生代的弧后小洋盆,而非宽阔的大洋. 相似文献
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《Gondwana Research》2010,17(3-4):587-608
Plume-related oceanic magmatism form oceanic islands, seamounts and plateaus (hereafter “seamounts” or “paleoseamounts”), which are important features in geological history. The accretion of oceanic seamounts to active continental margins significantly contributed to the formation of the continental crust. This paper reviews occurrences of Late Neoproterozoic–Mesozoic seamounts of the Paleo-Asian and Paleo-Pacific oceans, which are hosted by accretionary complexes (ACs) of Russian Altai, East Kazakhstan, Mongolia, Russian Far East and Japan. The paleoseamounts commonly consist of Ti–LREE–Nb-enriched plume-related basalts (OIB-type or intraplate basalts) capped with massive limestone and associated with other units of oceanic plate stratigraphy (OPS): oceanic floor basalts (MORB), pelagic chert, epiclastic slope facies, etc. The paper presents available geochemical data on the plume-related basalts including the first geochemical data on the Middle Paleozoic OIB-type basalts of the Paleo-Asian Ocean hosted by the Ulaanbaatar AC of Mongolia. An emphasis is made for the structural setting of OPS units, specific geochemical features of intraplate basalts, problems of their identification, and distinguishing from magmatic units of a different origin such as MORB, island-arc and back-arc basalts. Finally, we propose a continuous, though periodical, evolution of the Pacific superplume-related magmatism, which can be more reliably proved by studying Middle Paleozoic OPS units hosted by ACs of Mongolia and Tien Shan, and discuss prospects of future studies. 相似文献
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Pacific superplume-related oceanic basalts hosted by accretionary complexes of Central Asia, Russian Far East and Japan 总被引:5,自引:0,他引:5
I. Yu. Safonova A. Utsunomiya S. Kojima S. Nakae O. Tomurtogoo A.N. Filippov K. Koizumi 《Gondwana Research》2009,16(3-4):587-608
Plume-related oceanic magmatism form oceanic islands, seamounts and plateaus (hereafter “seamounts” or “paleoseamounts”), which are important features in geological history. The accretion of oceanic seamounts to active continental margins significantly contributed to the formation of the continental crust. This paper reviews occurrences of Late Neoproterozoic–Mesozoic seamounts of the Paleo-Asian and Paleo-Pacific oceans, which are hosted by accretionary complexes (ACs) of Russian Altai, East Kazakhstan, Mongolia, Russian Far East and Japan. The paleoseamounts commonly consist of Ti–LREE–Nb-enriched plume-related basalts (OIB-type or intraplate basalts) capped with massive limestone and associated with other units of oceanic plate stratigraphy (OPS): oceanic floor basalts (MORB), pelagic chert, epiclastic slope facies, etc. The paper presents available geochemical data on the plume-related basalts including the first geochemical data on the Middle Paleozoic OIB-type basalts of the Paleo-Asian Ocean hosted by the Ulaanbaatar AC of Mongolia. An emphasis is made for the structural setting of OPS units, specific geochemical features of intraplate basalts, problems of their identification, and distinguishing from magmatic units of a different origin such as MORB, island-arc and back-arc basalts. Finally, we propose a continuous, though periodical, evolution of the Pacific superplume-related magmatism, which can be more reliably proved by studying Middle Paleozoic OPS units hosted by ACs of Mongolia and Tien Shan, and discuss prospects of future studies. 相似文献
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CHAN Lung Sang 《《地质学报》英文版》2019,93(Z2):9-9
Many ophiolite complexes like those of Oman and New Caledonia represent fragments of ancient oceanic crust and upper mantle generated at supra‐subduction zone environments and have been obducted onto the adjacent rifted continental margin together with the accretionary complexes and intra‐oceanic arcs. The Lajishan ophiolite complexes in the Qilian orogenic belt along the NE edge of the Tibet‐Qinghai Plateau are one of several ophiolites situated to the south of the Central Qilian block. Our geological mapping and petrological investigations suggest that the Lajishankou ophiolite complex consists of serpentinite, wehrlite, pyroxenite, gabbro, dolerite, and pillow and massive basalts that occur in a series of elongate fault‐bounded slices. An accretionary complex composed mainly of basalt, radiolarian chert, sandstone, mudstone, and mélange lies structurally beneath the ophiolite complex. The Lajishankou ophiolite complex and accretionary complex were emplaced onto the Qingshipo Formation of the Central Qilian block which shows features typical of turbidites deposited in a deep‐water environment of passive continental margin. Our geochemical and geochronological studies indicate that the mafic rocks in the Lajishankou ophiolite complex can be categorized into three distinct groups: massive island arc tholeiites, 509 Ma back‐arc dolerite dykes, and 491 Ma pillow basaltic and dolerite slices that are of seamount origin in a back‐arc basin. The ophiolite and accretionary complex constitute a Cambrian‐early Ordovician trench‐arc system within the South Qilian belt during the early Paleozoic southward subduction of the South Qilian Ocean prior to Early Ordovician obduction of this system onto the Central Qilian block. 相似文献