The Recycling of End-of-Life Lithium-Ion Batteries and the Phase Characterisation of Black Mass

IF 4.6 Q2 GREEN & SUSTAINABLE SCIENCE & TECHNOLOGY Recycling Pub Date : 2023-07-12 DOI:10.3390/recycling8040059

L. Donnelly, D. Pirrie, M. Power, Ian J. Corfe, J. Kuva, S. Lukkari, Y. Lahaye, Xuan Liu, Q. Dehaine, E. Jolis, A. Butcher

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Abstract

Black mass is the industry term applied to end-of-life (EoL) lithium-ion batteries that have been mechanically processed for potential use as a recycled material to recover the valuable metals present, including cobalt, lithium, manganese, nickel and copper. A significant challenge to the effective processing of black mass is the complexity of the feed material. Two samples of black mass from a European source were analysed using a combination of methods including automated SEM-EDS (AMICS) to characterise and quantify the phases present and particle chemistry. Micro X-CT imaging, overlain onto automated mineralogy images, enabled the 3D morphology of the particles to be determined. Micro-XRF was used to map the copper, nickel, manganese and cobalt-bearing phases. Since Li cannot be detected using SEM-EDS, its abundance was semi-quantified using laser ablation inductively coupled plasma mass spectrometry (LA-ICP-MS). The integration of these complimentary analytical methods allowed for detailed phase characterisation, which may guide the potential hydrometallurgical or pyrometallurgical recycling routes and chemical assaying.

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报废锂离子电池的回收与黑质量的相位表征

黑物质是一个行业术语，适用于报废（EoL）锂离子电池，这些电池经过机械加工，有可能用作回收材料，以回收现有的有价值金属，包括钴、锂、锰、镍和铜。有效处理黑色物质的一个重大挑战是原料的复杂性。使用包括自动SEM-EDS（AMICS）在内的多种方法对来自欧洲的两个黑色物质样本进行分析，以表征和量化存在的相和颗粒化学。微型X-CT成像覆盖在自动化矿物学图像上，能够确定颗粒的3D形态。MicroXRF用于绘制含铜、镍、锰和钴相的图谱。由于使用SEM-EDS无法检测到Li，因此使用激光烧蚀电感耦合等离子体质谱法（LA-ICP-MS）对其丰度进行了半定量。这些互补分析方法的集成允许进行详细的相表征，这可能指导潜在的湿法冶金或火法冶金回收路线和化学分析。

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