基于RS、GIS的东喜马拉雅南迦巴瓦峰地区断裂构造的定量研究

东喜马拉雅南迦巴瓦峰地区地质构造十分复杂,对该区板块缝合带的空间位置问题,长期以来,一直认为沿雅鲁藏布江呈弧形展布。笔者以ETM+为主要信息源,以遥感与GIS为技术支撑,对南峰地区的断裂构造进行了详细的遥感解译分析,从构造统计分析的角度对断裂构造进行定量研究,从分维值及趋势值的空间分布及变化特征分析,认为缝合带的南东段、北段大致沿雅鲁藏布江展布,而北西段位于雅鲁藏布江的北西侧,沿东久-米林(断裂带)展布,这也与近几年来开展了1∶25万区域地质调查获得的新认识相一致。     

藏北尼玛地区白垩纪岩浆岩对班公湖-怒江缝合带演化的制约

班公湖-怒江缝合带及其两侧广泛分布白垩纪岩浆岩,这些岩浆活动记录了班公湖-怒江特提斯洋俯冲至闭合以及拉萨-羌塘板块碰撞过程.为了约束该缝合带在早-晚白垩世的演化过程,本文对缝合带中段尼玛地区花岗岩进行岩相学、地球化学、锆石年代学和Hf同位素研究.尼玛北部虾别错花岗岩侵入到中生代地层中,发育石英闪长质包体.锆石U-Pb定...     

大陆碰撞构造剖析

 首先对青藏高原分布的蛇绿岩带的地质特征进行剖析,认为这些蛇绿岩是陆内裂谷环境产出的初始洋壳而不是大陆缝合线。然后对喜马拉雅山系的构造特征及其造山体制加以讨论,认为以喜马拉雅山系作为碰撞造山的样板并无地质事实的根据,而是一种想当然的臆说,后来也得不到参验。结论:碰撞造山带在大陆是不存在的,是看不到的。     

内蒙古苏尼特左旗南两类花岗岩同位素年代学及其构造意义

内蒙古北部索伦缝合带（索伦-苏尼特左旗-锡林浩特）被多数中外学者认为是西伯利亚板块南缘和华北板块北缘的最终缝合带,本文选择该缝合带上苏尼特左旗南两类花岗岩-与俯冲有关和与碰撞有关的岩浆岩（分别叫弧岩浆岩和碰撞岗岩）进行同位素年代学研究,结果表明：（1）弧岩浆活动有两期,分别约为490Ma和310Ma(锆石U-Pb,SHRIMP);碰撞花岗岩的侵位年代在230-250Ma(Rb-Sr全岩和锆石U-Pb);（2）根据本文新的年代学数据,索伦缝合带的最终缝合时间可能是在230-310Ma,这显然不同于国内多数学者坚持的“晚泥盆世碰撞”模式;而Sengor等推测的“晚二又开展碰撞”模式与本文数据一致。     

Seismic anisotropy beneath Dronning Maud Land, Antarctica, revealed by shear wave splitting

Shear wave splitting analyses have been carried out using teleseismic data from broad-band seismograph stations deployed at temporary and permanent locations in Dronning Maud Land (DML), Antarctica. In most cases, the observed anisotropy can be related to major tectonic events that formed the present-day Antarctic continent. We rule out an anisotropic contribution from recent asthenospheric flow. At the Russian base Novolazarevskaya near the coast in central DML, waveform inversion suggests a two-layer model where the fast direction of the upper layer is oriented parallel to Archean fabrics in the lithosphere, whereas the anisotropy of the lower layer is interpreted to have been created during the Jurassic Gondwana break-up. Recordings at the South African base Sanae IV, however, show enigmatic results. For narrow backazimuthal segments, splitting parameters show strong variations together with a multitude of isotropic measurements, indicative of complex scattering that cannot be explained by simple one- or two-layer anisotropic models. In the interior of the continent, the data are consistent with single-layer anisotropy, but show significant spatial variations in splitting parameters. A set of temporary stations across the Heimefront shear zone in western DML yield splitting directions that we interpret as frozen anisotropy from Proterozoic assembly of the craton. An abrupt change in fast axis direction appears to mark a suture between the Grunehogna craton, a fragment of the Kalahari–Kaapvaal craton in southern Africa and the Mesoproterozoic Maudheim Province.     

Geology and geochemistry of the Bingdaban ophiolitic mélange in the boundary fault zone on the northern Central Tianshan Belt,and its tectonic implications

The properties and tectonic significance of the fault bound zone on the northern margin of the Central Tianshan belt are key issues to understand the tectonic framework and evolutionary history of the Tianshan Orogenic Belt. Based on the geological and geochemical studies in the Tianshan orogenic belt, it is suggested that the ophiolitic slices found in the Bingdaban area represent the remaining oceanic crust of the Early Paleozoic ocean between the Hazakstan and Zhungaer blocks. Mainly composed of basalts, gabbros and diabases, the ophiolites were overthrust onto the boundary fault between the Northern Tianshan and Central Tianshan belts. The major element geochemistry is characterized by high TiO₂ (1.50%–2.25%) and MgO (6.64%–9.35%), low K₂O (0.06%–0.41%) and P₂O₅ (0.1%–0.2%), and Na₂O>K₂O as well. Low ΣREE and depletion in LREE indicate that the original magma was derived from a depleted mantle source. Compared with a primitive mantle, the geochemistry of the basalts from the Bingdaban area is featureded by depletion in Th, U, Nb, La, Ce and Pr, and unfractionated in HFS elements. The ratios of Zr/Nb, Nb/La, Hf/Ta, Th/Yb and Hf/Th are similar to those of the typical N-MORB. It can be interpreted that the basalts in the Bingdaban area were derived from a depleted mantle source, and formed in a matured mid-oceanic ridge setting during the matured evolutionary stage of the Northern Tianshan ocean. In comparison with the basalts, the diabases from the Bingdaban area show higher contents of Al₂O₃, ΣREE and HFS elements as well as unfractionated incompatible elements except Cs, Rb and Ba, and about 10 times the values of the primitive mantle. Thus, the diabases are thought to be derived from a primitive mantle and similar to the typical E-MORB. The diabases also have slight Nb depletion accompanying no apparent Th enrichment compared with N-MORB. From studies of the regional geology and all above evidence, it can be suggested that the diabases from the Bingdaban area were formed in the mid-oceanic ridge of the Northern Tianshan ocean during the initial spreading stage. Supported by the Major State Research Program of PRC (Grant No. 2001CB409801), the National Natural Science Foundation of China (Grant Nos. 40472115 and 40234041) and the State Research Program of China Geological Survey (Grant No. 2001130000-22)     

新疆东准噶尔塔克扎勒—麦钦乌拉古缝合线的确定

本文通过构造分析及岩石学、地球化学研究,证实塔克扎勒—麦钦乌拉存在一条蛇绿混杂岩带,表现为在构造变形的砂泥质基质中分布若干个洋脊型和洋岛型的蛇绿岩碎块。该带两侧地壳厚度明显不同,大陆边缘增生方向相反,该带还是一条早古生代的生物群落界线,早石炭世两侧岛弧有较大的纬度差异(20°以上)。因此,塔克扎勒—麦钦乌拉蛇绿混杂岩带是古准噶尔大洋闭合的残骸,代表了西伯利亚板块和塔里木板块碰撞的缝合线构造带。     

雅鲁藏布江缝合带日喀则群的蛇绿岩质海底扇及其板块构造意义

沿雅鲁藏布江缝合带分布的日喀则群(K_2TK)砂泥质细粒复理石中发育着一种独特的沉积单元——蛇绿岩质砂砾质海底扇。这些扇体规模小,内扇和中扇相序典型。无论是内扇还是中扇,水道都特别发育,而且水道游荡作用明显。盛行砂砾质高密度浊流和粘性碎屑流沉积,沉积物粒度粗,含大量卵石级以上的粗碎屑,具有近源、快速堆积的特点。其碎屑组分为世界现代和古代海底扇沉积所罕见,主要是蛇绿岩碎屑,并含少量岛弧火山-岩浆岩碎屑和老地层的碎屑。这些扇体具有活动边缘型海底扇的典型特征,但又有其特殊性,它们发育在雅鲁藏布洋盆闭合、印度板块与藏北板块开始碰撞时的残留复理石盆地边缘。板块碰撞导致蛇绿岩质杂岩体和洋壳物质逆冲、抬升形成一个外弧造山带。该外弧造山带成为这些扇体的主要物源区。同时,强烈的逆掩和纳布作用也可将部分岛弧岩和老地层带到残留盆地边缘,一起作为来源母岩。     

青藏高原比如地体与措勤地体相对古构造位置判别

本文采用蚀源区判别图解QFL和QpLsLv、微量元素图解Th -Co -Zr/10、常量元素图解K2O/Na2O -SiO2 和野外地质实测剖面等方法 ,对比如、措勤地体的构造演化进行了分析。发现并证实了在T3-J1 以前比如地体位于措勤地体的北部 :J2 -3 时随着班—恕缝合带的拉张 ,比如地体开始右旋向东滑动 :一直延续到J3-K1 时 ,班—怒缝合带闭合 ,比如地体才就位于目前位置。最后应用1/ZTR指数推测了比如地体在J2 -3 时滑移点的大致位置 (E90°49,N31°34)。