可持续回收钕的方法分析

Kalani Periyapperuma, Laura Sanchez-Cupido, J. Pringle, C. Pozo‐Gonzalo
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引用次数: 5

摘要

钕(Nd)是最重要的稀土金属之一,因为它具有卓越的性能,在绿色能源技术中起着至关重要的作用,如风力涡轮机和电动汽车。一些关键用途包括手机和硬盘驱动器等技术应用中的永磁体,以及镍金属氢化物电池。需求持续增长,但储备严重有限,这使其持续供应面临风险。从报废产品中恢复是解决可用性挑战的最有趣的方法之一。这一观点集中于从永磁体和可充电电池中回收Nd的不同方法,涵盖了最发达的工艺,湿法冶金和火法冶金,并特别关注使用高度电化学稳定介质(如离子液体)的电沉积。在所有离子液体化学中,只有磷离子液体得到了深入的研究,探讨了温度、电沉积电位、盐浓度、添加剂(如水)和溶剂化对电沉积质量和数量的影响。最后,讨论了研究新型离子液体化学的重要性,以及离子液体中其他金属杂质对镀层组成或离子液体稳定性的影响。这为该领域未来的工作指明了重要方向,以实现有效和选择性地回收钕的重要目标,以克服日益严峻的供应问题。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Analysis of Sustainable Methods to Recover Neodymium
Neodymium (Nd) is one of the most essential rare-earth metals due to its outstanding properties and crucial role in green energy technologies such as wind turbines and electric vehicles. Some of the key uses includes permanent magnets present in technological applications such as mobile phones and hard disk drives, and in nickel metal hydride batteries. Nd demand is continually growing, but reserves are severely limited, which has put its continued availability at risk. Nd recovery from end-of-life products is one of the most interesting ways to tackle the availability challenge. This perspective concentrates on the different methods to recover Nd from permanent magnets and rechargeable batteries, covering the most developed processes, hydrometallurgy and pyrometallurgy, and with a special focus on electrodeposition using highly electrochemical stable media (e.g., ionic liquids). Among all the ionic liquid chemistries, only phosphonium ionic liquids have been studied in-depth, exploring the impact of temperature, electrodeposition potential, salt concentration, additives (e.g., water) and solvation on the electrodeposition quality and quantity. Finally, the importance of investigating new ionic liquid chemistries, as well as the effect of other metal impurities in the ionic liquid on the deposit composition or the stability of the ionic liquids are discussed. This points to important directions for future work in the field to achieve the important goal of efficient and selective Nd recovery to overcome the increasingly critical supply problems.
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