Microstructural Investigation of Discarded NdFeB Magnets After Low-Temperature Hydrogenation

IF 2.5 3区 材料科学 Q3 GREEN & SUSTAINABLE SCIENCE & TECHNOLOGY Journal of Sustainable Metallurgy Pub Date : 2024-06-26 DOI:10.1007/s40831-024-00873-8
Alireza Habibzadeh, Mehmet Ali Kucuker, Öznur Çakır, Mertol Gökelma
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Abstract

Due to continuously increasing demand and limited resources of rare-earth elements (REEs), new solutions are being sought to overcome the supply risk of REEs. To mitigate the supply risk of REEs, much attention has recently been paid to recycling. Despite the more common recycling methods, including hydrometallurgical and pyrometallurgical processes, hydrogen processing of magnetic scrap (HPMS) is still in the development stage. Magnet-to-magnet recycling via hydrogenation of discarded NdFeB magnets provides a fine powder suitable for the production of new magnets from secondary sources. One of the crucial aspects of HPMS is the degree of recovery of the magnetic properties, as the yield efficiency can easily reach over 95%. The amount, morphology, and distribution of the Nd-rich phase are the key parameters to achieve the excellent performance of the magnet by isolating the matrix grain. Therefore, a better insight into the microstructure of the matrix grains and the Nd-rich phase before and after hydrogenation is essential. In this study, a low-temperature hydrogenation process in the range of room temperature to 400 °C was conducted as the first step to recycle NdFeB magnets from discarded hard disk drives (HDDs), and the hydrogenated powder was characterized by electron microscopy and X-ray diffraction. The results show that there are three different morphologies of the Nd-rich phase, which undergo two different transformations through oxidation and hydride formation. While at lower temperatures (below 250 °C) the degree of pulverization is higher and the experimental evidence of hydride formation is less clear, at higher temperatures the degree of pulverization decreases. The formation of neodymium hydride at higher temperatures prevents further oxidation of the Nd-rich phase due to its high stability.

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低温氢化后废弃钕铁硼磁体的微观结构研究
由于稀土元素(REEs)的需求持续增长而资源有限,人们正在寻求新的解决方案来克服稀土元素的供应风险。为了降低稀土元素的供应风险,最近人们开始关注回收利用问题。尽管有了更常见的回收方法,包括湿法冶金和火法冶金工艺,但磁性废料的氢处理(HPMS)仍处于开发阶段。通过氢化废弃的钕铁硼磁铁进行磁铁到磁铁的回收利用,可提供适用于利用二次资源生产新磁铁的细粉。HPMS 的一个关键方面是磁性能的恢复程度,因为产量效率可以轻松达到 95% 以上。富钕相的数量、形态和分布是通过分离基体晶粒实现磁体优异性能的关键参数。因此,更好地了解氢化前后基体晶粒和富钕相的微观结构至关重要。在本研究中,首先在室温至 400 ℃ 范围内进行了低温氢化处理,以回收废弃硬盘驱动器(HDD)中的钕铁硼磁体,并通过电子显微镜和 X 射线衍射对氢化粉末进行了表征。结果表明,富钕相有三种不同的形态,它们通过氧化和氢化物形成发生了两种不同的转变。在较低温度下(低于 250 °C),粉化程度较高,氢化物形成的实验证据不太明显;而在较高温度下,粉化程度降低。在较高温度下形成的氢化钕因其高稳定性而阻止了富钕相的进一步氧化。
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来源期刊
Journal of Sustainable Metallurgy
Journal of Sustainable Metallurgy Materials Science-Metals and Alloys
CiteScore
4.00
自引率
12.50%
发文量
151
期刊介绍: Journal of Sustainable Metallurgy is dedicated to presenting metallurgical processes and related research aimed at improving the sustainability of metal-producing industries, with a particular emphasis on materials recovery, reuse, and recycling. Its editorial scope encompasses new techniques, as well as optimization of existing processes, including utilization, treatment, and management of metallurgically generated residues. Articles on non-technical barriers and drivers that can affect sustainability will also be considered.
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