Geological conditions and fluid flow history that lead to the development of large clastic dykes in basins: A case study from Kushiro, Japan

IF 2.8 2区地球科学 Q2 GEOSCIENCES, MULTIDISCIPLINARY

Basin Research Pub Date : 2024-10-21 DOI:10.1111/bre.70002

Shuji Tamamura, Takuma Murakami, Katsuhiko Kaneko, Tetsuro Yoneda, Tsutomu Sato, Jun Aizawa, Hiroyuki Matsumoto, Kagemi Uchida, Yoshiaki Suzuki, Toshifumi Igarashi

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Abstract

Large clastic dykes (the Harutori-Taro and Harutori-Jiro dykes) and smaller dykes are exposed in the underground Kushiro Coal Mine (KCM), Japan. This study examines these dykes as a case study to investigate the geological conditions and fluid flow history that lead to the development of large clastic dykes in basins. The composition of the dykes indicates the Beppo and/or Harutori formations as their parent unit. Crystallite size distribution (CSD) analysis reveals Ostwald ripening of the kaolinite in the kaolinitised feldspar from the dykes, suggesting stagnant conditions in the parent unit before the dyke was formed. In contrast, smectite CSDs and the high carbonate content of the dykes suggest that large volumes of fluid flowed through the dykes along the established hydraulic gradient, which was triggered by the breaking of the upper seal. The isotopic and chemical compositions of the calcite and aragonite in the dykes, with moderate siderite and rhodochrosite content, indicate the fluid was a warm (>30°C) mixture of freshwater and saltwater, which was transferred from deeper levels of the parent unit towards the crest of an anticline. Immediately after sand injection, the semi-closed system of the parent unit near the root of the large dyke was transformed into a major flow channel for overpressurised fluids. Subsequently, a large volume of fluid flowed along the vertical conduit (or dyke) over a long period of time (>1 Myr), which removed fluid from a widespread area (i.e., several hundred square kilometres) of the basin. The results show that thin parent units, poor lateral continuity of the upper seal, and spatially heterogeneous overpressurisation do not preclude the formation of large dykes.

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导致盆地中大型碎屑岩堤发育的地质条件和流体流动历史：日本钏路的案例研究

日本钏路煤矿（KCM）地下出露了大型碎屑岩堤（Harutori-Taro 堤和 Harutori-Jiro 堤）和小型堤坝。本研究以这些堤坝为案例，探讨了导致盆地中大型碎屑岩堤坝形成的地质条件和流体流动历史。这些堤坝的成分表明，其母体单元是别府和/或晴通层。晶体尺寸分布（CSD）分析显示，堤坝中的高岭石化长石中的高岭石发生了奥斯特瓦尔德熟化，这表明在堤坝形成之前，母岩单元处于停滞状态。与此相反，堤坝中的钠长石CSD和高碳酸盐含量表明，大量流体沿着已形成的水力梯度流经堤坝，上封层的破裂引发了流体的流动。堤坝中方解石和文石的同位素和化学成分以及适度的菱铁矿和红柱石含量表明，流体是淡水和盐水的温热（30°C）混合物，从母体单元的较深层流向反斜坡的坡顶。注砂后，大堤根部附近母岩单元的半封闭系统立即变成了超压流体的主要流道。随后，大量流体在很长一段时间（1 Myr）内沿着垂直导管（或堤坝）流动，将流体从盆地的广泛区域（即几百平方公里）带走。研究结果表明，母岩单位薄、上封层横向连续性差以及空间异质超压并不妨碍大型堤坝的形成。

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来源期刊

Basin Research 地学-地球科学综合

CiteScore

7.00

自引率

9.40%

发文量

审稿时长

>12 weeks

期刊介绍： Basin Research is an international journal which aims to publish original, high impact research papers on sedimentary basin systems. We view integrated, interdisciplinary research as being essential for the advancement of the subject area; therefore, we do not seek manuscripts focused purely on sedimentology, structural geology, or geophysics that have a natural home in specialist journals. Rather, we seek manuscripts that treat sedimentary basins as multi-component systems that require a multi-faceted approach to advance our understanding of their development. During deposition and subsidence we are concerned with large-scale geodynamic processes, heat flow, fluid flow, strain distribution, seismic and sequence stratigraphy, modelling, burial and inversion histories. In addition, we view the development of the source area, in terms of drainage networks, climate, erosion, denudation and sediment routing systems as vital to sedimentary basin systems. The underpinning requirement is that a contribution should be of interest to earth scientists of more than one discipline.