Srinjoy Datta, Amiya K. Samal, Sayandeep Banerjee, Rajesh K. Srivastava
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A low-angle relationship between the silicate and opaque fabrics and good correlation with magnetic lineation, identified via petrographic studies and shape preferred orientation analyses of multiple oriented thin sections, suggest a primary flow-related magnetic anisotropy for the studied dyke samples. The classic subparallel relationship between the trend of the dyke planes and magnetic fabric of the associated host granites suggests that the radiating geometry of the ca. 2.21 Ga dyke swarm was supported by a favourable pre-existing structural grain of the country rock. We interpret the magma for the studied dyke swarm was fed laterally from a distant plume. It was emplaced as laterally propagating primary dyke fractures as well as injected into the pre-existing subparallel crustal inhomogeneities. 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引用次数: 0
摘要
岩浆岩堤通常是通过未变形地壳的原生水力断裂而形成的,也可能是利用了预先存在的地壳不均匀性,代表了一个大型火成岩矿带的管道系统。东达尔瓦克拉通密集出露了从约 2.37 Ga 到约 1.79 Ga 的几代古新生代岩浆岩堤群。在此,利用岩浆岩堤和相关主花岗岩的磁感应强度各向异性结构数据,研究了约2.21 Ga的Anantapur-Kunigal岩浆岩堤群的NW-W走向的置换系统学,该岩浆岩堤群显示出放射状的几何形状,以了解岩浆流动动力学。硅酸盐和不透明结构之间的低角度关系以及与磁力线的良好相关性(通过岩石学研究和多个定向薄切片的形状优选取向分析确定)表明,所研究的堤坝样本存在与流动相关的主要磁各向异性。堤坝平面的趋势与相关主花岗岩的磁性结构之间典型的近平行关系表明,约 2.21 Ga 的堤坝群的辐射几何形状是由其磁性结构决定的。2.21Ga的堤坝群的放射状几何形状是由原生岩的有利结构纹理支撑的。我们的解释是,所研究的堤坝群的岩浆是从一个遥远的羽流中横向注入的。岩浆以横向扩展的原生堤裂缝形式喷出,并注入到预先存在的次平行地壳不均匀性中。与所有这些推论相印证的是,约 2.21 Ga 的阿南塔普尔-金伯利岩的详细成岩模式。2.21Ga的阿南塔普尔-库尼加尔堤坝群的详细成岩模型。
Contextual relationship between mechanical heterogeneity and dyking: constraints from magma emplacement dynamics of the ca. 2.21 Ga Anantapur–Kunigal mafic dyke swarm, Dharwar Craton, India
Mafic dykes are typically emplaced through primary hydraulic fracturing of undeformed crust or may make use of pre-existing crustal inhomogeneities, representing the plumbing systems of a large igneous province. The Eastern Dharwar Craton has dense exposures of several generations of Paleoproterozoic mafic dyke swarms ranging from ca. 2.37 Ga to ca. 1.79 Ga. Herein, using anisotropy of magnetic susceptibility fabric data of mafic dykes and associated host granites, the emplacement systematics of the NW- to W-trending ca. 2.21 Ga Anantapur–Kunigal dyke swarm, displaying a radiating geometry, have been studied to understand magma flow dynamics. A low-angle relationship between the silicate and opaque fabrics and good correlation with magnetic lineation, identified via petrographic studies and shape preferred orientation analyses of multiple oriented thin sections, suggest a primary flow-related magnetic anisotropy for the studied dyke samples. The classic subparallel relationship between the trend of the dyke planes and magnetic fabric of the associated host granites suggests that the radiating geometry of the ca. 2.21 Ga dyke swarm was supported by a favourable pre-existing structural grain of the country rock. We interpret the magma for the studied dyke swarm was fed laterally from a distant plume. It was emplaced as laterally propagating primary dyke fractures as well as injected into the pre-existing subparallel crustal inhomogeneities. Corroborating all these inferences, a detailed emplacement model for ca. 2.21 Ga Anantapur–Kunigal dyke swarm is also proposed.
期刊介绍:
Geological Magazine, established in 1864, is one of the oldest and best-known periodicals in earth sciences. It publishes original scientific papers covering the complete spectrum of geological topics, with high quality illustrations. Its worldwide circulation and high production values, combined with Rapid Communications and Book Review sections keep the journal at the forefront of the field.
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