Alkaline in-situ leaching of uranium in low-permeability sandstone: An experimental study using online low field nuclear magnetic resonance (LF-NMR) spectroscopy on multiphase response

IF 4.8 2区材料科学 Q1 METALLURGY & METALLURGICAL ENGINEERING

Hydrometallurgy Pub Date : 2024-01-26 DOI:10.1016/j.hydromet.2024.106269

Tong Zhang , Haitao Zhang , Xin Yang , Junlin Mao , Xuebin Su , Yang Liu , Guoliang Zhou , Zhizheng Xie

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引用次数: 0

Abstract

Uranium leaching was influenced by multiphase flow and geological structure during in-situ recovery of uranium (ISRU). In this study, the characteristics of multiphase flow and pore structure responding to the alkaline ISRU was investigated, using a real-time triaxial coupling nuclear magnetic resonance experiment system. The component of leaching solute, flow regime and pore structure evolution was monitored online through the T₂ spectrum and magnetic resonance imaging (MRI), and corresponding coupling correlation of uranium recovery and pore conductivity was analyzed. The result demonstrates that the uranium sandstone was composed of micropore (1–10 ms), mesopore (10–100 ms), and macropore (>100 ms) corresponding to different relaxation times (ms). The uranium migration was mainly dominated by mesopore, and mineral dissolution and precipitation were influenced by micropore and macropore. Uranium recovery based on colloidal tetravalent and hexavalent uranium particles was exponentially correlated with the volume of leaching solution passed through the solute (solid phase/pores) and slightly contributed by the seal pore and matrix-bearing uranium. The physical migration, mineral dissolution, carbonate precipitation, and alternation by reactive transport occurred and was influenced by the hydrodynamic pressure. The dissolution of U, Ca, and Si experienced a dynamic period (0–5 PV), buffer period (5–37 PV), transition period (37–200 PV), and stable period (200–319 PV); peak concentration of U occurred at 5 PV, and 73.4% of uranium was recovered in the scope of 0–37 PV. Here, 1 PV represents the sample pore volume of 3.95 cm³. The porosity and permeability were enlarged under the influence of the chemical dissolution and physical migration, but decreased with the precipitation of CaCO₃ and SiO₂ colloids. Permeability and porosity exhibited a positive correlation with the volume of solution passed through in the range of 0–100 PV, but a negative correlation was observed in the range of 100–319 PV. The findings provide significant insight into ISRU engineering practice.

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低渗透性砂岩中铀的碱性原位沥滤：利用在线低场核磁共振 (LF-NMR) 光谱对多相反应的实验研究

在铀原位回收（ISRU）过程中，铀浸出受到多相流和地质结构的影响。本研究利用实时三轴耦合核磁共振实验系统，研究了碱性 ISRU 反应的多相流和孔隙结构特征。通过 T2 光谱和磁共振成像（MRI）对浸出溶质成分、流动机制和孔隙结构演变进行了在线监测，并分析了铀回收率和孔隙电导率的相应耦合相关性。结果表明，铀砂岩由微孔（1-10 ms）、中孔（10-100 ms）和大孔（100 ms）组成，对应不同的弛豫时间（ms）。铀的迁移主要受中孔的影响，而矿物的溶解和沉淀则受微孔和大孔的影响。基于胶体四价铀和六价铀颗粒的铀回收率与通过溶质（固相/孔隙）的浸出液体积呈指数关系，密封孔隙和基质含铀的影响较小。物理迁移、矿物溶解、碳酸盐沉淀和反应迁移交替发生，并受到流体动力压力的影响。铀、钙和硅的溶解经历了动态期（0-5 PV）、缓冲期（5-37 PV）、过渡期（37-200 PV）和稳定期（200-319 PV）；铀的峰值浓度出现在 5 PV，73.4%的铀在 0-37 PV 范围内被回收。这里，1 PV 表示样品孔隙体积为 3.95 立方厘米。孔隙率和渗透率在化学溶解和物理迁移的影响下增大，但随着 CaCO3 和 SiO2 胶体的沉淀而减小。在 0-100 PV 范围内，渗透率和孔隙率与溶液通过量呈正相关，但在 100-319 PV 范围内呈负相关。这些发现为 ISRU 工程实践提供了重要启示。

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来源期刊

Hydrometallurgy 工程技术-冶金工程

CiteScore

9.50

自引率

6.40%

发文量

144

审稿时长

3.4 months

期刊介绍： Hydrometallurgy aims to compile studies on novel processes, process design, chemistry, modelling, control, economics and interfaces between unit operations, and to provide a forum for discussions on case histories and operational difficulties. Topics covered include: leaching of metal values by chemical reagents or bacterial action at ambient or elevated pressures and temperatures; separation of solids from leach liquors; removal of impurities and recovery of metal values by precipitation, ion exchange, solvent extraction, gaseous reduction, cementation, electro-winning and electro-refining; pre-treatment of ores by roasting or chemical treatments such as halogenation or reduction; recycling of reagents and treatment of effluents.