Structural and metamorphic architecture of the Zanskar Himalaya, Suru Valley region, NW India: Implications for the evolution of the Himalayan metamorphic core

I.P. Cawood, M. St-Onge, O. Weller, M. P. Searle, D. Waters, T. Ahmad
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Abstract

New 1:50,000-scale geological mapping in the Zanskar Himalaya of NW India, covering 2,400 km2, is integrated with structural and petrographic analysis to document the evolution and key tectonometamorphic relationships within the Himalayan metamorphic core. The integrated dataset constrains the regional three-dimensional geology and relationships between lithostratigraphy, folds, faults, deformation fabrics, metamorphic isograds, and growth of porphyroblasts within the context of five main deformation phases. Following the initial collision of India and Asia, NW−SE-oriented deformation is recorded by D1 (greenschist-facies) fabrics and D2 (greenschist- to amphibolite-facies) fabrics. D2 represents the main tectonometamorphic deformation phase associated with crustal thickening and produced the dominant regional penetrative fabric through crenulation and transposition of D1 fabrics. Thrust-sense D2 fabrics were reactivated during D3 as the Greater Himalayan Sequence was exhumed along the normal-sense Zanskar Shear Zone, which is part of the South Tibetan Detachment System. D3 fabrics, associated with movement on the Zanskar Shear Zone, were temporally continuous with crenulation and mesoscale folding, recording progressive kilometer-scale backfolding and backthrusting toward the NE between the Greater Himalayan Sequence−Tethyan Himalayan Sequence and the adjacent Indus Suture Zone. Finally, D4 and D5 are recorded as kilometer-scale open folding of older planar and linear structures. The orientation of mineral isograd surfaces ranges from subparallel to oblique with respect to D2 planar structural elements. The growth of pelitic and metabasic peak metamorphic phases from greenschist to upper-amphibolite facies is synchronous with or postdates D2 fabrics. D3 fabrics wrap thermal peak porphyroblasts and realign linear mineral phases. Tectonic thinning adjacent to D3 normal faults is documented by reduced structural spacing of isograds and alignment of isograd surfaces parallel to the faults. D4 and D5 structures modify the trace of all regional metamorphic isograds. Collectively, these observations imply that the thermal peak of metamorphism was reached after the main phase of deformation (D2), and predated movement on the Zanskar Shear Zone (D3). The results document numerous classical elements of collisional orogenesis, including implied clockwise P-T paths, polyphase deformation, and a complete Barrovian metamorphic isograd sequence supplemented by complementary metabasic isograds. The Zanskar Himalaya, unlike other areas of the Himalayan metamorphic core, records metamorphic conditions primarily attained following substantial crustal thickening rather than during subsequent decompression and exhumation. The reduced expression and/or discontinuous nature of exhuming fault systems, which produces variable levels of crustal exposure, may account for this lateral heterogeneity across the mountain belt. Deciphering the complex kinematics of continental tectonics requires the integration of observations and data over large length scales and a range of structural levels.
印度西北部苏鲁河谷地区赞斯卡尔喜马拉雅山的构造和变质结构:喜马拉雅山变质核心演化的意义
印度西北部赞斯喀尔喜马拉雅山新绘制的 1:50,000 比例尺地质图覆盖面积达 2,400 平方公里,该图与构造和岩石学分析相结合,记录了喜马拉雅山变质岩核心区的演变和主要构造-变质关系。该综合数据集对区域三维地质以及岩石地层、褶皱、断层、变形结构、变质等距线和斑岩生长之间的关系进行了约束,并将其置于五个主要变形阶段的背景之下。在印度和亚洲最初碰撞之后,D1(绿泥石-成因)构造和 D2(绿泥石-至闪长岩-成因)构造记录了西北-东南向的变形。D2 代表了与地壳增厚相关的主要构造变质变形阶段,并通过 D1 构造的细长化和转位产生了主要的区域穿透构造。在 D3 阶段,由于大喜马拉雅山序列沿着属于藏南剥离系统的正断层--赞斯喀剪切带被抬升,推覆 D2 构造被重新激活。与赞斯喀尔剪切带运动有关的 D3 构造在时间上与褶皱和中尺度褶皱连续,记录了大喜马拉雅山系-泰雅喜马拉雅山系地层与邻近的印度河断裂带之间逐渐向东北方向的千米级反褶和反推。最后,D4 和 D5 记录为老的平面和线性结构的千米级开放褶皱。相对于 D2 平面结构元素,矿物等距面的方向从近平行到倾斜不等。从绿泥石到上闪长岩面的辉长岩和变质峰变质相的生长与 D2 构造同步或晚于 D2 构造。D3 构造包裹了热峰斑岩,并使线性矿物相重新排列。D3 正断层附近的构造减薄,表现为等距线的构造间距减小,等距线表面与断层平行。D4 和 D5 构造改变了所有区域变质等轴线的轨迹。总之,这些观察结果表明,变质作用的热峰值出现在主要变形阶段(D2)之后,并早于赞斯卡剪切带的运动(D3)。这些结果记录了碰撞造山运动的许多经典要素,包括隐含的顺时针 P-T 路径、多相变形和完整的巴罗维变质等位序列,以及补充的新陈代谢等位序列。与喜马拉雅变质核心的其他地区不同,赞斯喀尔喜马拉雅山记录的变质条件主要是在地壳大幅增厚之后达到的,而不是在随后的减压和掘起过程中达到的。掘出断层系统的表达能力减弱和/或不连续,导致地壳暴露程度不同,这可能是整个山脉带横向异质性的原因。要解读大陆构造的复杂运动学,需要综合大长度尺度和各种构造层次的观测结果和数据。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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