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1.
松潘-甘孜地体内花岗岩锆石SHRIMP U-Pb定年及其构造意义 总被引:36,自引:17,他引:36
松潘-甘孜地体总体上是一个三角状褶皱带,其北侧、东南侧及东侧分别与东昆仑-西秦岭构造带、金沙江构造带及龙门山构造带相邻。地体内几乎全部被三叠系浊积岩所覆盖,其中侵位了很多花岗岩体。显然,这些花岗岩的岩浆特征、来源与侵位时代,对研究松潘-甘孜地体基底性质、构造演化等问题具有重要意义。本文报道利用SHRIMP定年技术对一些花岗岩岩体锆石所进行的精确测年数据。测试结果表明:(1)松潘-甘孜地体内的花岗岩体主要形成于晚三叠世,但岩浆活动可延续到早侏罗世晚期;(2)早期花岗岩浆活动与三叠纪系褶皱变形大致同期,指示这一时期的花岗岩浆的形成可能与三叠系下部大型拆离滑脱构造相关;(3)花岗岩结晶锆石普遍具有浑圆状或不规则状较老的继承锆石核,这些核部继承锆石可能代表花岗岩浆在上升过程中从不同地层内捕获的碎屑锆石,或者是下地壳岩石深熔残留锆石。根据SHRING U-Pb定年,这些继承锆石的年龄分别为二叠纪、加里东期、晚元古代和早元古代。元古代碎屑锆石的存在也可能指示松潘-甘孜地体具前寒武系基底。 相似文献
2.
川西地区热达门石英闪长岩体位于松潘-甘孜造山带北东侧。岩体的LA-ICP MS锆石U-Pb年龄为(206.4±1.4)Ma,侵位于晚三叠世。岩石Si O2含量为50.62%~56.66%,K2O/Na2O为0.32~1.20。铝饱和指数介于0.59~0.86之间,里特曼指数(σ)介于0.40~1.20之间,属于亚碱性准铝质系列岩石。岩体稀土总量∑REE介于81.45×10-6~222.39×10-6,LREE/HREE介于5.38~10.45之间,(La/Yb)N范围为5.98~12.99,δEu为0.66~1.01,δCe为0.81~0.93。岩石地球化学特征显示热达门岩石英闪长岩是在碰撞造山环境下,由岩浆上涌诱发下地壳物质部分熔融而形成的I型花岗岩。 相似文献
3.
Major,trace and rare earth element(REE) concentrations of Late Triassic sediments(finegrained sandstones and mudstones) from Hongcan Well 1 in the NE part of the Songpan-Ganzi Basin, western China,are used to reveal weathering,provenance and tectonic setting of inferred source areas. The Chemical Index of Alteration(CIA) reflects a low to moderate degree of chemical weathering in a cool and somewhat dry climate,and an A-CN-K plot suggests an older upper continental crust provenance dominated by felsic to intermediate igneous rocks of average tonalite composition.Based on the various geochemical tectonic setting discrimination diagrams,the Late Triassic sediments are inferred to have been deposited in a back-arc basin situated between an active continental margin(the Kunlun-Qinling Fold Belt) and a continental island arc(the Yidun Island Arc).The Triassic sediments in the study area underwent a rapid erosion and burial in a proximal slope-basin environment by the petrographic data. while the published flow directions of Triassic lurbidites in the Aba-Zoige region was not supported Yidun volcanic arc source.Therefore,we suggest that the Kunlun-Qinling tcrrane is most likely to have supplied source materials to the northeast part of the Songpan-Ganzi Basin during the Late Triassic. 相似文献
4.
Tectonostratigraphic and geochronologic constraints on evolution of the northeast Paleotethys from the Songpan-Ganzi complex, central China 总被引:1,自引:0,他引:1
Amy L. Weislogel 《Tectonophysics》2008,451(1-4):331-345
The Middle to Late Triassic deep-water deposits that form the Songpan-Ganzi complex (SGC) of central China comprise an estimated ~ 2.0 × 106 km3 of detrital material that accumulated in the northeasternmost branch of the Paleotethys. A review of existing data demonstrates significant spatial and temporal variations in the stratigraphic and petrologic character of these turbidites. These variations are used to divide the complex into different depocenters: a northeastern depocenter (SGC-NE), a eastern–central depocenter (SGC-EC) and a northwestern depocenter (SGC-NW). Turbidite strata of the SGC-NE and SGC-EC zones of the Songpan-Ganzi complex are linked to the collision of the North China and South China blocks, whereas turbidite strata of the SGC-NW area are likely to be more closely affiliated with evolution of the Kunlun deformation belt. To test the validity of the Songpan-Ganzi stratigraphic framework and interpretations of its tectonostratigraphic evolution, sixty-eight U–Pb zircon ages were determined from five samples of felsic intrusive igneous rock, two samples from felsic plutonic rock of the adjacent Yidun arc complex, and one sample of volcanic rock interbedded with Middle Triassic turbidites of the SGC using the Sensitive High Resolution Ion Microprobe-Reverse Geometry (SHRIMP-RG). Together these data indicate primarily Late Triassic (~ 214–211 Ma) felsic magmatism in the SGC, with some indication of magmatic activity beginning as early as Middle Triassic (220 Ma). Zircon ages from the Yidun arc complex support Middle–Late Triassic magmatism from 225–215 Ma, prior to deformation of the SGC, suggesting deformation of the SGC was not related to subduction of the SGC substrate southwestward beneath the Yidun arc. Inherited Neoproterozoic (880–740 Ma) zircon ages found in two samples from the SGC-EC indicate either inheritance of zircon crystals from the surrounding SGC turbidite strata or possibly involvement of South China basement during crustal thickening and magma genesis. 相似文献
5.
笔者在松潘-甘孜地体下仓界地区发现了晚三叠世基性岩,对其开展了岩相学、地球化学、斜锆石U-Pb年代学等研究。该基性岩由玄武岩和辉绿岩组成,均为钙碱性系列,蚀变较强,形成时代为208.0±7.0 Ma。岩石La/Nb值为1.13~1.95,La/Ta值为7.96~25.79,TiO2含量为1.51%~2.22%,Zr/Nb值为11.35~16.33,指示岩浆源自岩石圈地幔与软流圈地幔的混合源区。根据(Yb/Sm)P-(Tb/Yb)P模型计算结果,推测下仓界基性岩可能源于软流圈物质诱发岩石圈地幔尖晶石-石榴子石过渡相(石榴子石约占0~25%)发生约5%的部分熔融。岩石中发现捕获的古老斜锆石,轻稀土元素富集,重稀土元素亏损,Nb、Ta和Ti元素弱亏损。结合区域地质资料,认为松潘-甘孜地体应该具有陆壳基底,其晚三叠世(<211 Ma)的构造环境为碰撞后的板内伸展环境。 相似文献
6.
川西里伍式富铜矿位于扬子地台西缘和松潘-甘孜造山带接合带的江浪穹窿中。矿体大体上呈层状-似层状或透镜状。前期的矿床地质特征调查及矿相学研究结果表明,里伍铜矿的矿体至少经历了两期富集过程:早期硫化物构造变形特征明显,成典型的条带状构造,而晚期的矿化不具变形特征,主要呈块状、团块-浸染状及脉状矿构造叠加改造于前者之上。本文对里伍和中咀矿床中早期条带状黄铜矿进行了Re-Os同位素定年,获得一个良好的等时线年龄为343±11 Ma(n=4,2σ),初始~(187)Os/~(188)Os比值为~2.37。本文据此认为里伍式富铜矿早期成矿事件始于早石炭世,明显晚于赋矿围岩——元古界里伍岩群,该时期的成矿物质主要来源于大陆上地壳。 相似文献
7.
The Deep Geophysical Structure of the Middle Section of the Longmen Mountains Tectonic Belt and its Relation to the Wenchuan Earthquake 总被引:1,自引:0,他引:1
Investigation of the deep geophysical structure of the Longmen Mountains tectonic belt and its relation to the Wenchuan Earthquake is important for the study of earthquakes. By using magnetotelluric sounding profiles of the Luqu–Zhongjiang and Anxian–Suining; seismic sounding profiles of the Sichuan Maowen–Chongqing Gongtan, the Qinghai Huashi Gorge–Sichuan Jianyang, and the Batang–Zizhong; and magnetogravimetric data of the Longmen Mountains region, the deep geophysical structure of the Songpan–Ganzi block, the western Sichuan foreland basin, and the Longmen Mountains tectonic belt and their relation was discussed. The eastward extrusion of the Qinghai–Tibet Plateau thrusts the Songpan–Ganzi block upon the Yangtze block, which obstructs the eastward movement of the Qinghai–Tibet Plateau. The Maoxian–Wenchuan, Beichuan–Yingxiu, and Anxian–Guanxian faults of the Longmen Mountains fault belt dip to northwest with different dip angles and gradually converge in the deeper parts. Geophysical structure suggests that an intracrustal low-velocity, low-resistivity, and high-conductivity layer is common between the middle and upper crust west of the Longmen Mountains tectonic belt but not in the upper Yangtze block. The Sichuan Basin has a thick low-resistance sedimentary layer on a stable high-resistance basement; moreover, there are secondary paleohighs and depression structures at the lower part of the western Sichuan foreland basin with characteristic of high magnetic anomalies, whereas the Songpan–Ganzi block has a high resisitivity cover of upper crust and continues to a low-resistance layer. Considering the Longmen Mountains tectonic belt as the boundary, there are Bouguer gravity anomalies of "one belt between two zones." Thus, we infer that there is a corresponding relation between the inferred crystalline basement of the Songpan block and the underlying basin basement of the Longmen Mountains fault belt. Furthermore, there may be an extensive ancient Yangtze block, which is west of the Ruoergai block. In addition, the crust–mantle ductile shear zone under the Longmen Mountains tectonic belt is the main fault, whereas the Beichuan–Yingxiu and Anxian–Guanxian faults at the surface are earthquake faults. The Wenchuan Ms 8.0 earthquake might be attributed to the collision of the Yangtze block and the Qinghai–Tibet Plateau. The eastward obduction of the eastern edge of the Qinghai–Tibet Plateau and eastward subduction of its deeper part under the influence of the collision of the Indian, Pacific, and Philippine Plates with the Eurasia Plate might have caused the Longmen Mountains tectonic belt to cut the Moho and extend to the middle and upper crust; thus, creating high stress concentration and rapid energy release zone. 相似文献
8.
通过对近年的区域地质调查成果总结,认为松潘-甘孜造山带西部碰撞结合带在古生代经历了三个重要的发展时期:早古生代先后形成金沙江裂陷槽和理塘裂陷槽;晚古生代中晚期形成金沙江洋和理塘裂谷;晚古代生代末期至中三叠世早期,金沙江洋关闭,理塘洋形成,二者是相互关联的。 相似文献
9.
以构造动力学演化为主线,从拉张与挤压的辩证关系出发,提出了川渝地区构造动力学演化经历了挤压-区域拉张-陆隆伸展-再挤压的构造动力学演化过程;川渝地区在T3-J2期间为盆岭耦合构造格局,在当时山岭与盆地之间过渡的斜坡带前缘(大致相当于理县至都江堰地域),出现印支、燕山期滑覆构造,表现为山岭斜坡前缘逆冲叠瓦状断层与紧闭甚至倒转、平卧褶皱的出现;J3以来,构造动力学背景由伸展转变为挤压,形成基底卷入的厚皮构造,龙门山迅速崛起,四川盆地最终定型,形成现今见到的松潘甘孜高原-龙门山-四川盆地构成的盆山耦合构造格局。 相似文献
10.
本文根据INDEPTH-Ⅳ剖面所做的地质?地球物理探测所取得的资料,进行综合研究,提出了一个新的昆仑山造山模式,论述了:(1)在早二叠世松潘—甘孜洋向昆仑—柴达木地块下俯冲使地块南缘形成陆缘弧和弧后拉张区,使昆仑—柴达木地块在持续碰撞挤压过程中,分别形成了造山带与古近—新近纪盆地的不同构造演化特征;(2)昆仑地段老结晶基底在地块对挤中不断向上抬升成山,同时又受到强烈剥蚀,使老结晶基底及深成岩呈现在地表;南昆仑地块则沿昆仑地块中央断裂向北逆冲到北昆仑地块之上,断裂深10 km;昆仑地块没有发生向北逆冲推覆到柴达木地块上;(3)昆仑地块地壳增厚主要发生在中地壳(6.2~6.6 km/s),是中基性岩石层的增厚;(4)柴达木盆地作为昆仑弧弧后拉张地带,随昆仑造山隆升而下沉,新生界陆相沉积达12~14 km厚,由“沉积”与“挤入”两个作用造成了地壳增厚;结晶基底发生断陷形成新裂谷,裂谷宽度约12 km,深度约4 km,导电带显示裂谷通过断裂与深部发生热流体联系;(5)再次确定了,柴达木盆地莫霍界面深52 km,昆仑山的莫霍界面深65~70 km,莫霍界面台阶位于格尔木附近(185 km距离处);(6)松潘—甘孜地体复理石层厚度为10~14 km,其下面的6.2~6.3 km/s 均匀速度层(同时有高导电性显示)是本地块所特有,推测为残留洋壳的堆积,约15 km厚;浅层通过古近—新近系风火山推覆系增厚,另在中地壳部位挤入了15 km厚岩层;(7)否定了亚洲岩石圈地幔向柴达木地块地幔岩石圈之下俯冲的模式,提出印度大陆地幔岩石圈从高喜马拉雅下拆离成两层,并沿高原地壳底部向北伸展,直到中祁连山之下,成为高原南北对挤过程中岩石圈地幔长度调节的新方式? 相似文献