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Hu, Q.*; Wang, Q.*; Zhao, C.*; Zhang, T.*; 舘 幸男; 深津 勇太
no journal, ,
Fine-grained and clay-rich mudrocks play an important role in the long-term performance of a geological repository for storing high-level nuclear wastes and petroleum production in shale formations. However, low-permeability mudrocks whose pores are poorly interconnected are known to have anomalous diffusion properties that strongly impact long-term net diffusion. The complex pore structure involving predominantly nano-sized pore space is related to compaction and diagenesis from the maturation process of organic matter-rich mudrocks at deep depths, leading to a much smaller effective porosity which could be further partitioned by water- or oil-wet pore networks. Working with shallow clayey sediments of Wakkanai formation around Horonobe underground research center in Hokkaido of Japan and Opalinus clay of Mt. Terri Underground Research Laboratory in Switzerland, as well as various deep shales (Barnett, Eagle Ford and Wolfcamp from Texas, Bakken from North Dakota), using a wide range of sample sizes, this multi-approach and -scale work utilizes a complementary suite of approaches for pore structure characterization (e.g., helium pycnometry, mercury intrusion porosimetry, small angle/X-ray neutron scattering, field emission-scanning electron microscopy), gas diffusion and liquid (including water-, oil-, and bi-wetting) imbibition involving custom-designed tracer recipe followed with micro-scale mapping with laser ablation-ICP-MS. The experimental results show that deep mudrocks has a much smaller effective porosity than the total porosity (as a result of poor pore connectivity) and associated diffusion coefficient, and the effective porosity and diffusion coefficients are also dependent upon the sample sizes used in the measurement.
Wang, Q. M.*; Hu, Q.*; Zhao, C.*; Zhang, T.*; 深津 勇太; 舘 幸男
no journal, ,
Fluid flow and chemical transport in porous media are the macroscopic consequences of pore structure, which integrates geometry (e.g., pore size and surface area, pore-size distribution) and topology (e.g., pore connectivity). Low-permeability geological media whose pores are poorly interconnected will exhibit the characteristics of anomalous diffusion and sample size-dependent effective porosity, which will strongly impact long-term net diffusion and retention of radionuclides in geological repository settings. A suite of experimental approaches is utilized to study the microscopic pore structure and macroscopic fluid flow and chemical transport for a range of natural rocks (such as clay/shale, crystalline rock, salt), in addition to clay minerals. With a particular focus on quantifying the presence and magnitude of isolated pores for a reduced effective porosity in low-permeability geomedia, the integrated methodologies for basic properties and pore structure characterization include X-ray diffraction, thin section petrography, grain size distribution, water immersion porosimetry, mercury intrusion porosimetry, nitrogen physisorption, scanning electron microscopy, X-ray computed tomography, and (ultra-)small angle neutron (or X-ray) scattering. In addition, custom-designed gas diffusion, tracer recipe involving a range of anionic and cationic chemicals with subsequent analyses by laser ablation and inductively coupled plasma-mass spectrometry, along with batch sorption, column transport, and imbibition tests were conducted for coupled effects of pore structure and chemical retention/transport.
Hu, Q.*; Wang, Q. M.*; Zhao, C.*; Zhang, T.*; Iltaf, H.*; 舘 幸男; 深津 勇太
no journal, ,
Fine-grained and clay-rich mudrocks play an important role in the long-term performance of a geological repository for storing high-level nuclear wastes and petroleum production in shale formations. However, low-permeability mudrocks whose pores are poorly interconnected are known to have anomalous diffusion properties that strongly impact long-term net diffusion. The complex pore structure involving predominantly nano-sized pore space is related to compaction and diagenesis from the maturation process of organic matter-rich mudrocks at deep depths, leading to a much smaller effective porosity. Working with various clay minerals, shallow clayey sediments of Wakkanai formation around Horonobe URL in Japan and Opalinus clay of Mt. Terri URL in Switzerland, as well as various deep shales (Barnett, Eagle Ford and Wolfcamp from Texas), using a wide range of sample sizes, this multi-approach and -scale work utilizes a complementary suite of techniques for pore structure characterization (e.g., mercury intrusion porosimetry, small angle X-ray/neutron scattering, scanning electron microscopy), gas diffusion, batch sorption and column transport. The experimental results show that deep mudrocks has a much poor pore connectivity than the shallow ones, and the effective porosity, diffusion coefficients, sorption coefficients are also dependent upon the sample sizes used in the measurement.