A Review of Opportunities and Methods for Recovery of Rhodium from Spent Nuclear Fuel during Reprocessing

IF 0.5 Q4 NUCLEAR SCIENCE & TECHNOLOGY

Journal of Nuclear Engineering and Radiation Science Pub Date : 2023-07-18 DOI:10.3390/jne4030034

B. Hodgson, J. Turner, Alistair F. Holdsworth

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Abstract

Rhodium is one of the scarcest, most valuable, and useful platinum group metals, a strategically important material relied on heavily by automotive and electronics industries. The limited finite natural sources of Rh and exponentially increasing demands on these supplies mean that new sources are being sought to stabilise supplies and prices. Spent nuclear fuel (SNF) contains a significant quantity of Rh, though methods to recover this are purely conceptual at this point, due to the differing chemistry between SNF reprocessing and the methods used to recycle natural Rh. During SNF reprocessing, Rh partitions between aqueous nitric acid streams, where its speciation is complex, and insoluble fission product waste streams. Various techniques have been investigated for Rh recovery during SNF reprocessing for over 50 years, including solvent extraction, ion exchange, precipitation, and electrochemical methods, with tuneable approaches such as impregnated composites and ionic liquids receiving the most attention recently, assisted by more the comprehensive understanding of Rh speciation in nitric acid developed recently. The quantitative recovery of Rh within the SNF reprocessing ecosystem has remained elusive thus far, and as such, this review discusses the recent developments within the field, and strategies that could be applied to maximise the recovery of Rh from SNF.

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乏核燃料后处理中回收铑的机会和方法综述

铑是最稀有、最有价值和最有用的铂族金属之一，是汽车和电子工业高度依赖的重要战略材料。Rh的自然资源有限，对这些供应的需求呈指数增长，这意味着人们正在寻求新的资源来稳定供应和价格。乏核燃料(SNF)含有大量的Rh，但由于SNF后处理与回收天然Rh的方法之间的化学性质不同，目前回收这些Rh的方法纯粹是概念性的。在SNF后处理过程中，Rh在其形态复杂的硝酸水溶液流和不溶性裂变产物废物流之间划分。50多年来，人们对SNF后处理过程中Rh的回收方法进行了各种研究，包括溶剂萃取、离子交换、沉淀法和电化学方法，其中浸渍复合材料和离子液体等可调方法最近受到了最广泛的关注，这得益于近年来对硝酸中Rh形态形成的更全面的了解。到目前为止，在SNF后处理生态系统中Rh的定量回收仍然难以捉摸，因此，本文讨论了该领域的最新发展，以及可用于最大限度地从SNF中回收Rh的策略。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Nuclear Engineering and Radiation Science NUCLEAR SCIENCE & TECHNOLOGY-

CiteScore

1.30

自引率

0.00%

发文量

期刊介绍： The Journal of Nuclear Engineering and Radiation Science is ASME’s latest title within the energy sector. The publication is for specialists in the nuclear/power engineering areas of industry, academia, and government.