Geochemical reactions altering the mineralogical and multiscale pore characteristics of uranium-bearing reservoirs during CO2 + O2 in situ leaching
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W. Wang | Lixin Zhao | X. Qi | Q. Niu | B. Sun | Xuebin Su | Zhongmin Ji | Lanlan Tian | Xingyu Zhou | Jianhui Zhang | Genmao Zhou | Qizhi Wang
[1] Gun Huang,et al. Influence of Acid Treatment on Pore Structure and Fractal Characterization of a Tight Sandstone: A Case Study from Wudun Sag, Dunhuang Basin , 2022, Acta Geologica Sinica - English Edition.
[2] Shicheng Zhang,et al. CO2–brine–rock interactions altering the mineralogical, physical, and mechanical properties of carbonate-rich shale oil reservoirs , 2022, Energy.
[3] Zhanxue Sun,et al. Blockage and uranium migration via CO2 + O2 leaching within autoclave: a test study from Mengqiguer deposit in Yili Basin, Northwest of China , 2022, Journal of Radioanalytical and Nuclear Chemistry.
[4] D. Elsworth,et al. Nanoscale mechanical property variations concerning mineral composition and contact of marine shale , 2022, Geoscience Frontiers.
[5] Y. Ju,et al. Micro-nano-scale pore stimulation of coalbed methane reservoirs caused by hydraulic fracturing experiments , 2022, Journal of Petroleum Science and Engineering.
[6] Wei Wang,et al. Mineral Composition and Full-Scale Pore Structure of Qianjiadian Sandstone-Type Uranium Deposits: Application for In Situ Leaching Mining , 2022 .
[7] Mingyi Chen,et al. Responses of multi-scale microstructures, physical-mechanical and hydraulic characteristics of roof rocks caused by the supercritical CO2-water-rock reaction , 2022 .
[8] J. Liu,et al. Improved uranium leaching efficiency from low-permeability sandstone using low-frequency vibration in the CO2+O2 leaching process , 2021, Journal of Rock Mechanics and Geotechnical Engineering.
[9] Yun Yang,et al. Quantifying the impact of mineralogical heterogeneity on reactive transport modeling of CO2 + O2 in-situ leaching of uranium , 2021, Acta Geochimica.
[10] Xiaohan Wang,et al. Hydrogeology Response to the Coordinated Mining of Coal and Uranium: A Transparent Physical Experiment , 2021, Geofluids.
[11] Jiangfeng Yang,et al. Determination of shale macroscale modulus based on microscale measurement: a case study concerning multiscale mechanical characteristics , 2021, Petroleum Science.
[12] Bing Sun,et al. Fractal kinetic characteristics of uranium leaching from low permeability uranium-bearing sandstone , 2021, Nuclear Engineering and Technology.
[13] Wei Wang,et al. A small-scale experimental study of CO2 enhanced injectivity methods of the high-rank coal , 2021, Petroleum Science.
[14] Bing Sun,et al. Pore structure evolution characteristics of sandstone uranium ore during acid leaching , 2021, Nuclear Engineering and Technology.
[15] G. Cui,et al. Geochemical reactions and their influence on petrophysical properties of ultra-low permeability oil reservoirs during water and CO2 flooding , 2021 .
[16] Xuehai Fu,et al. Determinations of the multifractal characteristics of the pore structures of low-, middle-, and high-rank coal using high-pressure mercury injection , 2021 .
[17] Jianfeng Wu,et al. Reactive transport numerical modeling of CO2+O2 in-situ leaching in sandstone-type uranium ore , 2021, SCIENTIA SINICA Technologica.
[18] Wei Wang,et al. Changes of Multiscale Surface Morphology and Pore Structure of Mudstone Associated with Supercritical CO2-Water Exposure at Different Times , 2021 .
[19] W. Wang,et al. Experimental study on the softening effect and mechanism of anthracite with CO2 injection , 2021 .
[20] Jing Zhang,et al. 3D characterization of porosity and minerals of low-permeability uranium-bearing sandstone based on multi-resolution image fusion , 2020, Nuclear Science and Techniques.
[21] L. Wen,et al. Investigation of the CO2 Flooding Behavior and Its Collaborative Controlling Factors , 2020 .
[22] Shicheng Zhang,et al. Pore structure alteration induced by CO2–brine–rock interaction during CO2 energetic fracturing in tight oil reservoirs , 2020 .
[23] Yiyu Lu,et al. Changes in Pore Structure of Dry-hot Rock with Supercritical CO2 Treatment , 2020 .
[24] Wei Wang,et al. Study on the anisotropic permeability in different rank coals under influences of supercritical CO2 adsorption and effective stress and its enlightenment for CO2 enhance coalbed methane recovery , 2020 .
[25] Xia-Ting Feng,et al. Preliminary study on the feasibility of co-exploitation of coal and uranium , 2019, International Journal of Rock Mechanics and Mining Sciences.
[26] Bing Sun,et al. Fractal characteristics of uranium‐bearing sandstone structure and their effects on acid leaching , 2019, Energy Science & Engineering.
[27] L. Xin,et al. Pore Fractal Characteristics of Lignite at Different Temperatures Based on Mercury Intrusion Test , 2019, Geotechnical and Geological Engineering.
[28] Jienan Pan,et al. Fractal study of adsorption-pores in pulverized coals with various metamorphism degrees using N2 adsorption, X-ray scattering and image analysis methods , 2019, Journal of Petroleum Science and Engineering.
[29] Shiqi Liu,et al. Experimental study of permeability changes and its influencing factors with CO2 injection in coal , 2019, Journal of Natural Gas Science and Engineering.
[30] Wei Yu,et al. Fractal characteristics of low-permeability gas sandstones based on a new model for mercury intrusion porosimetry , 2018, Journal of Natural Gas Science and Engineering.
[31] Lixin Zhao,et al. Mineral alteration and pore-plugging caused by acid in situ leaching: a case study of the Wuyier uranium deposit, Xinjiang, NW China , 2018, Arabian Journal of Geosciences.
[32] Yanhai Chang,et al. Shale pore size classification: An NMR fluid typing method , 2018, Marine and Petroleum Geology.
[33] Li Chen,et al. Pore scale study of multiphase multicomponent reactive transport during CO2 dissolution trapping , 2018 .
[34] L. Cao,et al. The adsorption-swelling and permeability characteristics of natural and reconstituted anthracite coals , 2017 .
[35] Jienan Pan,et al. The evolution and formation mechanisms of closed pores in coal , 2017 .
[36] C. Zou,et al. Fractal analysis of high rank coal from southeast Qinshui basin by using gas adsorption and mercury porosimetry , 2017 .
[37] Pengfei Zhang,et al. Characterization of shale pore system: A case study of Paleogene Xin'gouzui Formation in the Jianghan basin, China , 2017 .
[38] J. Saunders,et al. Potential aquifer vulnerability in regions down-gradient from uranium in situ recovery (ISR) sites. , 2016, Journal of environmental management.
[39] Y. Liu,et al. Fractal Analysis of Shale Pore Structure of Continental Gas Shale Reservoir in the Ordos Basin, NW China , 2016 .
[40] Xu Gen-f. Analysis of the main technological parameters of CO_2+O_2 in situ leaching uranium and problems by chemical precipitation blocking , 2014 .
[41] S. Bauer,et al. Geochemical modelling of CO2–water–rock interactions in a potential storage formation of the North German sedimentary basin , 2013 .
[42] Erich A Schneider,et al. Recovery of Uranium from Seawater: A Review of Current Status and Future Research Needs , 2013 .
[43] Liu Wei-ping. Laboratory test of neutral leaching of a uranium ore in Inner Mongolia , 2013 .
[44] H. Shao,et al. Effects of salinity and the extent of water on supercritical CO2-induced phlogopite dissolution and secondary mineral formation. , 2011, Environmental science & technology.
[45] Wei-dong Sun,et al. The genesis of sandstone‐type uranium deposits in the Ordos Basin, NW China: constraints provided by fluid inclusions and stable isotopes , 2009 .
[46] Boming Yu,et al. On the Physical Properties of Apparent Two‐Phase Fractal Porous Media , 2009 .
[47] Xuehai Fu,et al. Fractal classification and natural classification of coal pore structure based on migration of coal bed methane , 2005 .
[48] Rakesh Kumar,et al. STUDY ON SOME FACTORS AFFECTING THE RESULTS IN THE USE OF MIP METHOD IN CONCRETE RESEARCH , 2003 .
[49] D. H. Everett,et al. Manual of Symbols and Terminology for Physicochemical Quantities and Units, Appendix II: Definitions, Terminology and Symbols in Colloid and Surface Chemistry , 1972 .