压实对硫化氢在 MX-80 膨润土中扩散迁移的影响

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
F. Chowdhury , T.L. Rashwan , P. Mondal , M. Behazin , P.G. Keech , J.S. Sharma , M. Krol
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引用次数: 0

摘要

加拿大深层地质处置库(DGR)的设计包括一个工程屏障系统,在该系统中,高度压实膨润土(HCB)环绕着铜涂层的废旧燃料容器(UFC)。受微生物影响的腐蚀是对 UFC 长期完整性的潜在威胁,因为在厌氧条件下,微生物活动可能会产生硫化氢 (HS-),并通过 HCB 的扩散传输到达 UFC 表面,从而导致铜腐蚀。因此,了解 HS- 在 HCB 中的迁移机制对于准确预测铜的腐蚀裕量至关重要。本研究通过进行穿透扩散实验,研究了 HS- 在干密度为 1070-1615 kg m-3 的 MX-80 膨润土中的迁移行为。在 HS- 扩散后,进行了溴化物(Br-)扩散和拉曼光谱分析,以探讨膨润土与 HS- 相互作用可能引起的物理或矿物学变化。此外,还利用扩展的阿基定律估算了可进入孔隙率ε。在干密度为 1330 和 1070 kg m-3 时,HS- 的有效扩散系数分别为 2.5 × 10-12 m2 s-1 和 5.0× 10-12 m2 s-1。在实验时间范围内(170 天),高致密膨润土(1535-1615 kg m-3)未观察到 HS- 的突破。拉曼光谱结果显示,HS- 与膨润土中的铁发生了反应,并以麦饭石的形式沉淀,因此,HS- 被固定了下来。最后,本研究的结果表明,HS- 向 UFC 的迁移在很大程度上受缓冲材料中可用铁含量和干密度的控制。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Effect of compaction on bisulfide diffusive transport through MX-80 bentonite

Effect of compaction on bisulfide diffusive transport through MX-80 bentonite

Canada's deep geological repository (DGR) design includes an engineered barrier system where highly compacted bentonite (HCB) surrounds the copper-coated used fuel containers (UFCs). Microbial-influenced corrosion is a potential threat to long-term integrity of UFC as bisulfide (HS) may be produced by microbial activities under anaerobic conditions and transported via diffusion through the HCB to reach the UFC surface, resulting in corrosion of copper. Therefore, understanding HS transport mechanisms through HCB is critical for accurate prediction of copper corrosion allowance. This study investigated HS transport behaviour through MX-80 bentonite at dry densities 1070–1615 kg m−3 by performing through-diffusion experiments. Following HS diffusion, bromide (Br) diffusion and Raman spectroscopy analyses were performed to explore possible physical or mineralogical alterations of bentonite caused by interacting with HS. In addition, accessible porosity ε was estimated using extended Archie's law. Effective diffusion coefficient of HS was found 2.5 × 10−12 m2 s−1 and 5.0× 10−12 m2 s−1 for dry densities 1330 and 1070 kg m−3, respectively. No HS breakthrough was observed for highly compacted bentonite (1535–1615 kg m−3) over the experimental timeframe (170 days). Raman spectroscopy results revealed that HS reacted with iron in bentonite and precipitated as mackinawite and, therefore, it was immobilized. Finally, results of this study imply that HS transport towards UFC will be highly controlled by the available iron content and dry density of the buffer material.

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CiteScore
7.20
自引率
4.30%
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