Maximizing the Processing of Polymetallic Concentrates via Actinide Separation and Rare Earth Retrieval

IF 1.5 4区工程技术 Q3 METALLURGY & METALLURGICAL ENGINEERING

Mining, Metallurgy & Exploration Pub Date : 2024-05-04 DOI:10.1007/s42461-024-00985-5

Ahmed A. Eliwa, Amal E. Mubark, Ebrahim A. Gawad, Ahmed H. Orabi, Mona M. Fawzy

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Abstract

During the last decades, the growing demand for rare earth elements (REEs) has led to numerous recent studies to recover these elements from various bearing ores and wastes. Therefore, the recovery of REEs from Ras Baroud polymetallic concentrate has been investigated in the current study. Physical beneficiation for the Ras Baroud pegmatite sample was carried out, yielding a concentrate for euxenite (Y), fergusonite (Y), xenotime (Y), monazite (Ce), allanite, thorite, uranothorite, and Hf-zircon, which resulted in raising the concentrations of rare earth elements, Th, Zr, U, and Ti in the sample. Fusion digestion processes with sodium hydroxide were studied using the Conceived Predictive Diagonal (CPD) technique. The three experimental digestion groups proved the dissolution of 99.9, 95.6, 99.9, 52.5, and 0.47% for REEs, Th, U, Ti, and Zr, respectively, under fusion conditions of 723 K, 120 min, 1/1.5 ore/alkali ratio, and − 100-μm particle sizes. Fusion kinetics, isotherms, and thermodynamics were investigated using several suggested models, namely, pseudo reversible first order, uptake general model, and shrinking core model which matched well with the experimental digestion results. Selective recovery of actinide content from REE content of the digested concentrate chloride solutions was accomplished using solvent extraction with di-2-ethyl hexyl phosphoric acid. About 99.9, 99.9, and 4.2% extraction efficiencies for Th, U, and REEs were performed, respectively, using 0.3 mol/L solvent concentration in kerosene as a diluent, 1/2 organic to aqueous ratio, an aqueous pH of 0.2, and 15-min contact time. Thorium and uranium ions were stripped with sulfuric acid solution 2.5 mol/L with 94 and 98% stripping efficiency, respectively. A highly purified REE precipitate was obtained from the raffinate solutions. Zircon mineralization tailings were obtained as a by-product through the alkaline digestion process.

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通过锕系元素分离和稀土回收最大限度地加工多金属精矿

在过去的几十年里，由于对稀土元素（REEs）的需求不断增长，最近开展了大量研究，从各种含稀土元素的矿石和废料中回收这些元素。因此，本研究调查了从拉斯巴鲁德多金属精矿中回收稀土元素的情况。对拉斯-巴鲁德伟晶岩样本进行了物理选矿，得到了埃克森岩（Y）、铁闪长岩（Y）、氙长岩（Y）、独居石（Ce）、绿帘石、透辉石、乌拉诺托石和 Hf- 锆石的精矿，从而提高了样本中稀土元素 Th、Zr、U 和 Ti 的浓度。利用构想预测对角线（CPD）技术研究了氢氧化钠的熔融消解过程。在 723 K、120 分钟、1/1.5 矿石/碱比例和 - 100-μm 粒径的熔融条件下，三个实验消化组分别溶解了 99.9%、95.6%、99.9%、52.5% 和 0.47%的稀土元素、Th、U、Ti 和 Zr。利用几种建议的模型（即伪可逆一阶模型、吸收一般模型和收缩核心模型）研究了聚变动力学、等温线和热力学，这些模型与实验消解结果非常吻合。利用二-2-乙基己基磷酸进行溶剂萃取，从消化后的氯化精矿溶液中的 REE 含量中选择性地回收了锕系元素。以煤油为稀释剂，溶剂浓度为 0.3 摩尔/升，有机物与水的比例为 1/2，水的 pH 值为 0.2，接触时间为 15 分钟，钍、铀和稀土元素的萃取效率分别约为 99.9%、99.9%和 4.2%。用 2.5 摩尔/升的硫酸溶液剥离钍和铀离子，剥离效率分别为 94% 和 98%。从萃取溶液中获得了高度纯化的 REE 沉淀。锆石矿化尾矿是碱性消化工艺的副产品。

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来源期刊

Mining, Metallurgy & Exploration Materials Science-Materials Chemistry

CiteScore

3.50

自引率

10.50%

发文量

177

期刊介绍： The aim of this international peer-reviewed journal of the Society for Mining, Metallurgy & Exploration (SME) is to provide a broad-based forum for the exchange of real-world and theoretical knowledge from academia, government and industry that is pertinent to mining, mineral/metallurgical processing, exploration and other fields served by the Society. The journal publishes high-quality original research publications, in-depth special review articles, reviews of state-of-the-art and innovative technologies and industry methodologies, communications of work of topical and emerging interest, and other works that enhance understanding on both the fundamental and practical levels.