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71.
Tectonics of Precambrian basement of the Tarim craton 总被引:4,自引:0,他引:4
The Altyn Tagh Mountain is the main area where the Precambrian basements of Tarim craton are exposed. There are two ophiolitic
belts in Altyn Tagh: one belt is exposed in the northern margin of Altyn Tagh whose formation age is about (829±60) Ma, the
other is situated along the southern margin of Altyn Tagh and has a formation age of about (1449±270) Ma. This paper proposes
a simple tectonic model for the Precambrian basement of Tarim craton established from ophiolites in Altyn Tagh area. The south
Tarim block had amalgamated with Qaidam block during about 1400-1500 Ma along the present Altyn fault, while the south Tarim-Qaidam
united block was still separated from the north Tarim block by an ocean. The united block of south Tarim and Qaidam collided
with north Tarim block along the zone of high positive anomaly of central Tarim, Hongliugou and Lapeiquan in about 800 Ma.
So since the Sinian (beginning at 800 Ma) there has been an integrated basement for Tarim craton. 相似文献
72.
山东南墅地区孔兹岩系变质矿物的成因及演化 总被引:3,自引:0,他引:3
南墅地区孔兹岩系的变质矿物具有多成因、多世代的特征 ,其经历三阶段五幕的变质作用 ,形成了以Sil+Gt +Cord +Bi +Kf +Pl+Q为代表的共生矿物组合。通过对主要变质矿物成因及演化特征的分析 ,结合温压计估算 ,确定该区孔兹岩系峰期变质作用温度为 70 0~ 75 0℃ ,压力为 0 .6~0 .7GPa ,变质程度达角闪麻粒岩相。确立 pTt轨迹具顺时针演化特点 ,反映一种陆 -陆碰撞造山带式构造演化模式。 相似文献
73.
CHEN Jisheng 《国际泥沙研究》1996,(2)
HYDROPOWERRESOURCESINUPPERYANGTZECHENJisheng(DirectorEmeritus,YangtzeRiverScientificResearchInstitute(YRSRI),23HuangpuRoad,Wu... 相似文献
74.
秦岭祁连山昆仑山构造发展史与南北中国板块的拼合 总被引:1,自引:0,他引:1
按秦岭祁连山昆仑山发展演化,中国大陆的形成可总结为3阶段板块拼贴“焊合”模型即:中元古代至新元古代早期,原始秦昆洋俯冲—消减,塔里木—华北古陆(北中国板块)与华南洋域新生陆壳(南中国板块)拼贴增生,形成原始中国古陆;震旦纪至志留纪,原始中国古陆裂解,秦祁海洋扩张—俯冲—消减,阿拉善—华北板块(北中国板块)与塔里木、柴达木、华南组成的联合板块(南中国板块)缝合统一,形成古中国板块,泥盆纪至三叠纪早期,古特提斯洋俯冲—消减,藏滇板块(基梅里大陆一部分)与古中国板块碰撞拼贴,滨邻古特提斯洋的中国大陆西南缘(秦祁昆地区)全面皱起,造就中国大陆轮廓;中生代以来,板内超长期继承性汇聚和滨西太平洋边缘构造带、新特提斯—喜马拉雅构造叠加、改造,造就现令中国大陆构造、地势。 相似文献
75.
76.
Guochun ZHAO LIU Shuwen Min SUN LI Sanzhong Simon WILDE Xiaoping XIA Jian ZHANG Yanhong HE 《《地质学报》英文版》2006,80(6):790-806
The Trans-North China Orogen (TNCO) was a Paleoproterozic continent-continent collisional belt along which the Eastern and Western Blocks amalgamated to form a coherent North China Craton (NCC). Recent geological, structural, geochemical and isotopic data show that the orogen was a continental margin or Japan-type arc along the western margin of the Eastern Block, which was separated from the Western Block by an old ocean, with eastward-directed subduction of the oceanic lithosphere beneath the western margin of the Eastern Block. At 2550-2520 Ma, the deep subduction caused partial melting of the medium-lower crust, producing copious granitoid magma that was intruded into the upper levels of the crust to form granitoid plutons in the low- to medium-grade granite-greeustone terranes. At 2530-2520 Ma, subduction of the oceanic lithosphere caused partial melting of the mantle wedge, which led to underplating of mafic magma in the lower crust and widespread mafic and minor felsic volcanism in the arc, forming part of the greenstone assemblages. Extension driven by widespread mafic to felsic volcanism led to the development of back-arc and/or intra-arc basins in the orogen. At 2520-2475 Ma, the subduction caused further partial melting of the lower crust to form large amounts of tonalitic-trondhjemitic-granodioritic (TTG) magmatism. At this time following further extension of back-arc basins, episodic granitoid magmatism occurred, resulting in the emplacement of 2360 Ma, -2250 Ma 2110-21760 Ma and -2050 Ma granites in the orogen. Contemporary volcano-sedimentary rocks developed in the back-arc or intra-are basins. At 2150-1920 Ma, the orogen underwent several extensional events, possibly due to subduction of an oceanic ridge, leading to emplacement of mafic dykes that were subsequently metamorphosed to amphibolites and medium- to high-pressure mafic granulites. At 1880-1820 Ma, the ocean between the Eastern and Western Blocks was completely consumed by subduction, and the dosing of the ocean led to the continent-arc-continent collision, which caused large-scale thrusting and isoclinal folds and transported some of the rocks into the lower crustal levels or upper mantle to form granulites or eclogites. Peak metamorphism was followed by exhumation/uplift, resulting in widespread development of asymmetric folds and symplectic textures in the rocks. 相似文献
77.
78.
Influence of surface roughness of the Teflon plates on kinetics of the bubble attachment was studied. Phenomena occurring during collisions of the air bubble, rising in clean water, with Teflon plates, differing only in their surface roughness, were recorded and analysed using a high-speed camera. Variations of the local velocity of the bubble during the collisions and the time of the bubble attachment were determined. It was found that the Teflon surface roughness was the parameter of a crucial importance for the attachment time of the colliding bubble. Depending on degree of the surface roughness the time of the attachment varied by over order of magnitude (from 3 to over 80 ms). In the case the Teflon surfaces having roughness below 1 μm there were recorded four to five “approach–bounce” cycles prior to the bubble attachment. Moreover, after the first collision the rapid pulsations of the bubble shape (within fraction of millisecond) were recorded. For surfaces of roughness ca. 50 μm and larger the attachment always occurred during the first collision—there was no bouncing observed and the time of the attachment was below 3 ms. It was documented that presence of a micro-bubble at the surface facilitated attachment of the colliding bubble. 相似文献
79.
内蒙古大青山北石兰哈达石英闪长岩构造环境讨论 总被引:2,自引:0,他引:2
内蒙古大青山北石兰哈达地区的晚古生代黑云石英闪长岩,1∶20万区域地质调查时将其置于华力西中期第二次侵入体(δο42(2)),现经岩石学、地球化学、同位素年代学研究,认为该石英闪长岩为早二叠世岩浆活动的产物。岩石具高铝、高钾、高钙的特点,A/CNK<1.1,σ在2.05~2.83之间,为高钾钙碱性岩,属I型花岗岩类,产于碰撞后的抬升构造环境。岩石稀土总量偏低,LREE富集,δEu=0.8~1.0,稀土曲线呈右倾平滑型,其物质来源很可能是源于软流圈的玄武质岩浆与元古宙地壳物质混合作用的结果。 相似文献
80.
The Zagros fold-and-thrust belt of SW-Iran is among the youngest continental collision zones on Earth. Collision is thought to have occurred in the late Oligocene–early Miocene, followed by continental shortening. The High Zagros Belt (HZB) presents a Neogene imbricate structure that has affected the thick sedimentary cover of the former Arabian continental passive margin. The HZB of interior Fars marks the innermost part of SE-Zagros, trending NW–SE, that is characterised by higher elevation, lack of seismicity, and no evident active crustal shortening with respect to the outer (SW) parts. This study examines the brittle structures that developed during the mountain building process to decipher the history of polyphase deformation and variations in compressive tectonic fields since the onset of collision. Analytic inversion techniques enabled us to determine and separate different brittle tectonic regimes in terms of stress tensors. Various strike–slip, compressional, and tensional stress regimes are thus identified with different stress fields. Brittle tectonic analyses were carried out to reconstruct possible geometrical relationships between different structures and to establish relative chronologies of corresponding stress fields, considering the folding process. Results indicate that in the studied area, the main fold and thrust structure developed in a general compressional stress regime with an average N032° direction of σ1 stress axis during the Miocene. Strike–slip structures were generated under three successive strike–slip stress regimes with different σ1 directions in the early Miocene (N053°), late Miocene–early Pliocene (N026°), and post-Pliocene (N002°), evolving from pre-fold to post-fold faulting. Tensional structures also developed as a function of the evolving stress regimes. Our reconstruction of stress fields suggests an anticlockwise reorientation of the horizontal σ1 axis since the onset of collision and a significant change in vertical stress from σ3 to σ2 since the late stage of folding and thrusting. A late right-lateral reactivation was also observed on some pre-existing belt-parallel brittle structures, especially along the reverse fault systems, consistent with the recent N–S plate convergence. However, this feature was not reflected by large structures in the HZB of interior Fars. The results should not be extrapolated to the entire Zagros belt, where the deformation front has propagated from inner to outer zones during the younger events. 相似文献