奥帕里努斯粘土砂质面的异质性特征(瑞士蒙特泰里地下岩石实验室)

Stefan Lüth, Florian Steegborn, F. Heberling, T. Beilecke, Dirk Bosbach, G. Deissmann, Horst Geckeis, Claudia Joseph, Axel Liebscher, Volker Metz, Dorothee Rebscher, Karsten Rink, Trond Ryberg, Stephan Schennen
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摘要

本文介绍了一项基于地震层析成像、测井和岩心分析的粘土岩层异质性多学科调查,作为扩散实验的勘测研究。粘土岩层中的扩散实验为放射性核素(RN)在极低导水介质中的扩散迁移提供了重要的实验数据。以前在蒙特泰里地下岩石实验室(Mont Terri)相对均质的奥帕林纳斯粘土页岩岩层中进行的扩散实验,以及对这些实验进行的建模研究都表明,粘土岩可以充分地描述为均质各向异性介质。对于异质性较大的其他岩性来说,这种简化可能并不合适,因此对不同尺度的异质性进行描述非常重要。奥帕利努斯粘土的砂质岩相与鳞片岩相相比,具有明显的异质性,因此我们启动了一项综合特征描述和 RN 扩散研究,以研究异质性特征描述和异质性环境中的后续扩散的各种方法。第一步是钻探两个倾斜的探井,以进入实验地点的边缘。这些钻孔用于获取跨孔层析地震数据集。还采用了光学、自然伽马和反向散射测井技术,并对岩心进行了分析。根据这些调查的综合结果,在所调查的砂质岩层区域内发现了一个厚度约为 1 米的异常较亮层,其上限位于倾斜探井内约 10 米深处。矿物分析表明,整个岩心只有轻微的变化,异常层的石英含量略高,局部方解石含量明显偏高,粘土矿物含量较低。由于粘土含量较低,异常层的特征是天然伽马射线发射减少,中子反向散射增加,这可能表明孔隙率增加。通过各向异性层析成像得出的地震 P 波速度在该层顶部附近显示出最大梯度。从上覆深色岩石基质向该层的过渡被确定为在异质环境中设置示踪剂扩散实验的适当位置。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Characterisation of heterogeneities in the sandy facies of the Opalinus Clay (Mont Terri underground rock laboratory, Switzerland)
This contribution is presenting a multidisciplinary investigation of heterogeneities in a clay rock formation, based on seismic tomography, logging, and core analysis, as a reconnaissance study for a diffusion experiment. Diffusion experiments in clay rock formations provide crucial experimental data on diffusive transport of radionuclides (RN) in extremely low hydraulic conductivity media. Previous diffusion experiments, conducted, e.g. in the Mont Terri underground rock laboratory within the relatively homogeneous shaly facies of Opalinus Clay, and modelling studies of these experiments have demonstrated that the clay rock could sufficiently well be described as a homogeneous anisotropic medium. For other lithofacies, characterised by larger heterogeneity, such simplification may be unsuitable, and the description of heterogeneity over a range of scales will be important. The sandy facies of the Opalinus Clay exhibits a significantly more pronounced heterogeneity compared to the shaly facies, and a combined characterisation and RN diffusion study has been initiated to investigate various approaches of heterogeneity characterisation and subsequent diffusion in a heterogeneous environment. As an initial step, two inclined exploratory boreholes have been drilled to access the margins of the experiment location. These boreholes have been used to acquire a cross-hole tomographic seismic data set. Optical, natural gamma and backscattering logging were applied and rock cores were analysed. The integrated results of these investigations allowed the identification of an anomalous brighter layer within the investigated area of the sandy facies of approximately 1 m thickness and with its upper bound at roughly 10 m depth within the inclined exploratory wells. Mineralogical analyses revealed only slight variations throughout the rock cores and indicated that the anomalous layer exhibited a slightly higher quartz content, and locally significantly higher calcite contents, accompanied by a lower content of clay minerals. The anomalous layer was characterised by reduced natural gamma emissions, due to the lower clay content, and increased neutron backscattering likely indicating an increased porosity. Seismic P-wave velocities, derived from anisotropic tomography, exhibited a maximal gradient near the top of this layer. The transition from the overlaying darker rock matrix into this layer has been identified as an appropriate location for the setup of a tracer diffusion experiment in a heterogeneous environment.
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