Aluminum Removal from Rare Earth Chloride Solution through Regulated Hydrolysis via Electrochemical Method

Due to the coexistence of Al3+ and RE3+ and their similar properties, the separation of aluminum from rare earths is difficult. In this study, selective precipitation was used to separate aluminum from rare earth chloride solution via electrochemical regulated hydrolysis. By controlling the current...

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Bibliographic Details
Published inSeparations Vol. 11; no. 5; p. 149
Main Authors Zhu, Yaoyao, Li, Jian, Xie, Dongyue, Zhang, Hui, Li, Man, Xu, Binfeng, Zhang, Xuxia, Xie, Yangyang, Qi, Tao
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.05.2024
Subjects
Aluminum
Aluminum oxide
Chemical tests and reagents
Chloride
Chlorides
Current density
Efficiency
electrochemical
Electrodes
Electron microscopes
Energy consumption
Hydrolysis
Hydroxides
Hydroxyl ions
Innovations
Leachates
Methods
Morphology
Power supply
rare earth
Rare earth compounds
Rare earth elements
Reagents
regulated hydrolysis
Separation
Solvent extraction processes
Sulfuric acid
Temperature
China
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Summary:Due to the coexistence of Al3+ and RE3+ and their similar properties, the separation of aluminum from rare earths is difficult. In this study, selective precipitation was used to separate aluminum from rare earth chloride solution via electrochemical regulated hydrolysis. By controlling the current density and electrolytic time, the rate of hydroxyl ion production was regulated, and the selective separation of rare earth and aluminum was realized according to the different precipitation sequences. By altering the temperature, current density, pH value, and other parameters, the separation performance of aluminum from rare earth in mixed rare earth chloride systems was systematically investigated. The removal rate of aluminum reached 88.35%, and the loss rate of rare earth was only 5.99% under optimized conditions. Compared with traditional neutralization hydrolysis, the new process showed higher efficiency and lower rare earth loss rate. Furthermore, a kinetic analysis of aluminum precipitation revealed that the reaction adhered to pseudo-first order kinetics. Additionally, the precipitate obtained via separation and filtration was amorphous alumina hydroxide with a small amount of rare earth attached. No reagent was consumed for the new process, which was more efficient and cleaner, providing a new idea for removing aluminum impurities from rare earth solutions.
ISSN:2297-8739
2297-8739
DOI:10.3390/separations11050149