从锂离子电池活性正极材料中回收钴的新型闭环生物技术。

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Eva Pakostova, John Graves, Egle Latvyte, Giovanni Maddalena, Louise Horsfall
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引用次数: 0

摘要

近年来,对锂离子电池(LIB)的需求迅速增长。传统的回收策略(基于火法和湿法冶金)会对环境造成破坏,因此需要开发更具可持续性的方法。生物浸出法是一种很有前景的环保方法,它利用微生物来溶解金属。然而,以生物浸出为基础的技术尚未在工业规模上应用于从废锂电池中回收有价金属。为了提高活性阴极材料(钴酸锂;LCO)的金属回收率,我们进行了一系列实验。(i) 使用两种嗜酸性原核生物联合体对≤0.5%的 LCO 进行直接生物浸出,实现了 >80% 的钴和 90% 的锂提取。30 °C时的金属回收率明显低于 45 °C时。(ii) 相反,在使用适应 LCO 水平升高的复合菌群对 3% LCO 进行直接生物浸出过程中,30 °C复合菌群的表现明显优于 45 °C复合菌群,在一步生物浸出过程中分别溶解了 73% 和 93% 的钴和锂,在两步生物浸出过程中分别溶解了 83% 和 99% 的钴和锂。(iii) 经调整的 30°C 联合体被用于低废物闭环系统中的间接沥滤(含 10% 的 LCO)。该过程包括在制酸生物反应器(AGB)中生成硫酸,用生物酸(pH 0.9)浸出 LCO 2-3 周,选择性地将 Co 沉淀为氢氧化物,并将无金属液循环回 AGB。在七个阶段中,共溶解了 58.2% 的钴和 100% 的锂,在每个阶段后,超过 99.9% 的溶解钴以高纯度氢氧化钴的形式被回收。此外,还利用阿拉斯加脱硫弧菌从获得的富钴浸出液中生成了纳米钴颗粒,并优化了钴电积作为一种替代回收技术,从含钴浓度明显低于工业湿法冶金液的生物浸出液中获得了高回收率(碳毡和粗化钢的回收率分别为 91.1% 和 73.6%)。该闭环系统主要由混养古菌 Ferroplasma 和硫氧化细菌 Acidithiobacillus caldus 和 Acidithiobacillus thiooxidans 控制。所开发的系统实现了较高的金属回收率,并提供了适用于电池供应链的高纯度固体产品,同时最大限度地减少了废物的产生以及高浓度溶解金属对浸出原核生物的抑制作用。该系统适合放大应用,并有可能适用于不同的电池化学成分。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A novel closed-loop biotechnology for recovery of cobalt from a lithium-ion battery active cathode material.

In recent years, the demand for lithium-ion batteries (LIBs) has been increasing rapidly. Conventional recycling strategies (based on pyro- and hydrometallurgy) are damaging for the environment and more sustainable methods need to be developed. Bioleaching is a promising environmentally friendly approach that uses microorganisms to solubilize metals. However, a bioleaching-based technology has not yet been applied to recover valuable metals from waste LIBs on an industrial scale. A series of experiments was performed to improve metal recovery rates from an active cathode material (LiCoO2; LCO). (i) Direct bioleaching of ≤0.5 % LCO with two prokaryotic acidophilic consortia achieved >80 % Co and 90 % Li extraction. Significantly lower metal recovery rates were obtained at 30 °C than at 45 °C. (ii) In contrast, during direct bioleaching of 3 % LCO with consortia adapted to elevated LCO levels, the 30 °C consortium performed significantly better than the 45 °C consortium, solubilizing 73 and 93 % of the Co and Li, respectively, during one-step bioleaching, and 83 and 99 % of the Co and Li, respectively, during a two-step process. (iii) The adapted 30°C consortium was used for indirect leaching in a low-waste closed-loop system (with 10 % LCO). The process involved generation of sulfuric acid in an acid-generating bioreactor (AGB), 2-3 week leaching of LCO with the biogenic acid (pH 0.9), selective precipitation of Co as hydroxide, and recirculation of the metal-free liquor back into the AGB. In total, 58.2 % Co and 100 % Li were solubilized in seven phases, and >99.9 % of the dissolved Co was recovered after each phase as a high-purity Co hydroxide. Additionally, Co nanoparticles were generated from the obtained Co-rich leachates, using Desulfovibrio alaskensis, and Co electrowinning was optimized as an alternative recovery technique, yielding high recovery rates (91.1 and 73.6% on carbon felt and roughened steel, respectively) from bioleachates that contained significantly lower Co concentrations than industrial hydrometallurgical liquors. The closed-loop system was highly dominated by the mixotrophic archaeon Ferroplasma and sulfur-oxidizing bacteria Acidithiobacillus caldus and Acidithiobacillus thiooxidans. The developed system achieved high metal recovery rates and provided high-purity solid products suitable for a battery supply chain, while minimizing waste production and the inhibitory effects of elevated concentrations of dissolved metals on the leaching prokaryotes. The system is suitable for scale-up applications and has the potential to be adapted to different battery chemistries.

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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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