Hydrometallurgical recycling of lithium-ion batteries by reductive leaching with sodium metabisulphite

Vieceli, Nathália; Nogueira, Carlos A.; Guimarães, Carlos Henrique; Pereira, M.F.C.; Durão, F.; Margarido, F.

doi:10.1016/j.wasman.2017.09.032

Cited by 143 publications

(31 citation statements)

References 37 publications

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“…Recently, a great deal of research has been devoted to the leaching process of waste Li-ion battery scraps with different types of mineral acids like HCl (Guo et al, 2016), H3PO4 (Chen et al, 2017), H2SO4 (Pagnanelli et al, 2016) and organic acids including citric acid (Zheng et al, 2016), malic acid (Li et al, 2010) and lactic acid (Li et al, 2017). Moreover, the leaching efficiency of cobalt and lithium has also been shown to increase with the use of additional reducing agents like H2O2 (Pagnanelli et al, 2017b), Na2S2O5 (Vieceli et al, 2018), NaHSO3 (Meshram et al, 2016), D-glucose (Granata et al, 2012) as well as ascorbic acid (Li et al, 2012). (Meshram et al, 2016) 35.8 a 1 M H2SO4 + 5% (v/v) H2O2 50 14.1 3.1 79 94 - (Meshram et al, 2016) 44.2 a 4 M H2SO4 + 10% (v/v) H2O2 100 42.0 5.3 95 96 - (Chen et al, 2011) 54.0 a 2 M H2SO4 + 5% (v/v) H2O2 50 26.7 3.2 99 99 - (Sun and Qiu, 2011a) 35.8 a 1 M H2SO4 + 7.5 M NaHSO3 50 15.2 3.0 85 93 - (Meshram et al, 2016) 35.4 a 3 M H2SO4 + 0.25 M Na2S2O3 66 23.1 2.4 99 99 50 (Wang et al, 2012) 41.5 a 0.34 M H3PO4 + 2% (v/v) H2O2 8 3.2 0.4 95 95 - (Pinna et al, 2017) 54.0 a 0.1 M Citric + 0.02 M ascorbic 2 0.9 0.1 80 100 - (Nayaka et al, 2015) 54.0 a 0.5 M glycine + 0.02 M ascorbic 2 1.0 0.1 95 95 - (Nayaka et al, 2016a) 55.0 a 1.25 M ascorbic acid 25 13.1 1.6 95 99 - (Li et al, 2012) -2 M H2SO4 + 4% H2O2 66 32.7 2.3 97 97 65 (Nayl et al, 2017) 52.0 a 1 M H2SO4 + 0.02 M glucose 35 16.0 1.5 88 92…”

Section: Introductionmentioning

confidence: 99%

Selective reductive leaching of cobalt and lithium from industrially crushed waste Li-ion batteries in sulfuric acid system

et al. 2018

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Recycling of valuable metals from secondary resources such as waste Li-ion batteries (LIBs) has recently attracted significant attention due to the depletion of high-grade natural resources and increasing interest in the circular economy of metals. In this article, the sulfuric acid leaching of industrially produced waste LIBs scraps with 23.6% cobalt (Co), 3.6% lithium (Li) and 6.2% copper (Cu) was investigated. The industrially produced LIBs scraps were shown to provide higher Li and Co leaching extractions compared to dissolution of corresponding amount of pure LiCoO. In addition, with the addition of ascorbic acid as reducing agent, copper extraction showed decrease, opposite to Co and Li. Based on this, we propose a new method for the selective leaching of battery metals Co and Li from the industrially crushed LIBs waste at high solid/liquid ratio (S/L) that leaves impurities like Cu in the solid residue. Using ascorbic acid (CHO) as reductant, the optimum conditions for LIBs leaching were found to be T = 80 °C, t = 90 min, [HSO] = 2 M, [CHO] = 0.11 M and S/L = 200 g/L. This resulted in leaching efficiencies of 95.7% for Li and 93.8% for Co, whereas in contrast, Cu extraction was only 0.7%. Consequently, the proposed leaching method produces a pregnant leach solution (PLS) with high Li (7.0 g/L) and Co (44.4 g/L) concentration as well as a leach residue rich in Cu (up to 12 wt%) that is suitable as a feed fraction for primary or secondary copper production.

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Section: Introductionmentioning

confidence: 99%

Selective reductive leaching of cobalt and lithium from industrially crushed waste Li-ion batteries in sulfuric acid system

et al. 2018

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“…Apart from the references cited above, other research groups worked on various optimization of the sulfuric acid process by changing process parameters such as adding sonication to the leaching step [132,133], or replacing the reducing agent [134][135][136]. Other publications are summarized in Table S1 in Supplementary Information [137][138][139][140][141][142][143][144].…”

Section: Sulfate Systemmentioning

confidence: 99%

Progress and Status of Hydrometallurgical and Direct Recycling of Li-Ion Batteries and Beyond

et al. 2020

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An exponential market growth of Li-ion batteries (LIBs) has been observed in the past 20 years; approximately 670,000 tons of LIBs have been sold in 2017 alone. This trend will continue owing to the growing interest of consumers for electric vehicles, recent engagement of car manufacturers to produce them, recent developments in energy storage facilities, and commitment of governments for the electrification of transportation. Although some limited recycling processes were developed earlier after the commercialization of LIBs, these are inadequate in the context of sustainable development. Therefore, significant efforts have been made to replace the commonly employed pyrometallurgical recycling method with a less detrimental approach, such as hydrometallurgical, in particular sulfate-based leaching, or direct recycling. Sulfate-based leaching is the only large-scale hydrometallurgical method currently used for recycling LIBs and serves as baseline for several pilot or demonstration projects currently under development. Conversely, most project and processes focus only on the recovery of Ni, Co, Mn, and less Li, and are wasting the iron phosphate originating from lithium iron phosphate (LFP) batteries. Although this battery type does not dominate the LIB market, its presence in the waste stream of LIBs causes some technical concerns that affect the profitability of current recycling processes. This review explores the current processes and alternative solutions to pyrometallurgy, including novel selective leaching processes or direct recycling approaches.

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“…However, precautions and safety measurements should be taken prior dismantling the spent Li-batteries. Even the spent LiBs contain residual voltage and can produce strong heat and flames due to self-ignition (because of residual charge) and internal short circuit (Nan, Han, & Zuo, 2005;Vieceli et al, 2018). Therefore, precautionary steps like (i) refrigeration using NaCl or water, (ii) cryogenic activities like immersion in liquid nitrogen for 4-6 min and (iii) promoting short circuit and discharging the batteries using electric iron powder were proposed in the literature (Li, Wang, & Xu, 2016;Vieceli et al, 2018).…”

Section: Li-ion Batteriesmentioning

confidence: 99%

Recent advances on hydrometallurgical recovery of critical and precious elements from end of life electronic wastes - a review

Sethurajan

Hullebusch

Fontana

et al. 2019

Critical Reviews in Environmental Science and Technology

238

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Waste electrical and electronic equipment (WEEE) contains economically significant levels of precious, critical metals and rare earth elements, apart from base metals and other toxic compounds. Recycling and recovery of critical elements from WEEEs using a cost-effective technology are now one of the top priorities in metallurgy due to the rapid depletion of their natural resources. More than 150 publications on WEEE management, leaching and recovery of metals from WEEE were reviewed in this work, with special emphasize on the recent research (2015-2018). This paper summarizes the recent progress regarding various hydrometallurgical processes for the leaching of critical elements from WEEEs. Various methodologies and techniques for critical elements selective recovery (using ionic liquids, solvent extraction, electrowinning, adsorption, and precipitation) from the WEEEs leachates are discussed. Future prospects regarding the use of WEEEs as secondary resources for critical raw materials and its technoeconomical and commercial beneficiaries are discussed.

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Hydrometallurgical recycling of lithium-ion batteries by reductive leaching with sodium metabisulphite

Cited by 143 publications

References 37 publications

Selective reductive leaching of cobalt and lithium from industrially crushed waste Li-ion batteries in sulfuric acid system

Selective reductive leaching of cobalt and lithium from industrially crushed waste Li-ion batteries in sulfuric acid system

Progress and Status of Hydrometallurgical and Direct Recycling of Li-Ion Batteries and Beyond

Recent advances on hydrometallurgical recovery of critical and precious elements from end of life electronic wastes - a review

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