Comparison of Hydro- and Biohydrometallurgical Extraction of Metals from Waste Li-Ion Batteries of Cell Phone

In the present study, the black residual powders of waste Li-ion batteries were treated with citric, malic, and a combination of these acids for chemical extraction of multimetals. Among the treatments, 0.75 M malic + 0.75 M citric acid was found to be better than either 1.5 M citric acid or 1.5 M m...

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Bibliographic Details
Published in:Journal of sustainable metallurgy 2019-06, Vol.5 (2), p.250-261
Main Authors: Khatri, Bhumika R., Tipre, Devayani R., Dave, Shailesh R.
Format: Article
Language:English
Subjects:
Bacterial leaching
Citric acid
Consortia
Copper
Density
Earth and Environmental Science
Environment
Lithium-ion batteries
Malic acid
Metallic Materials
Nickel
Optimization
Organic chemistry
Reaction time
Rechargeable batteries
Research Article
Solubilization
Sustainable Development
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Summary:In the present study, the black residual powders of waste Li-ion batteries were treated with citric, malic, and a combination of these acids for chemical extraction of multimetals. Among the treatments, 0.75 M malic + 0.75 M citric acid was found to be better than either 1.5 M citric acid or 1.5 M malic acid for 20 g L −1 pulp density at 90 °C. Bioleaching studies were carried out by Leptospirillum ferriphilum -dominated consortium using the two-step process, which resulted in 1.2–1.8-fold higher metal extractions compared to a one-step process. At optimal pH 2.0, Cu–Zn–Ni solubilization was 85 ± 2%, while Co and Li extractions were 97.2% and 33.96%, respectively, after 2–6 days with 10 g L −1 pulp density. When 9 g L −1 initial ferrous iron concentration was used, Cu–Zn–Ni–Co extractions were 92 ± 7%, whereas Li solubilization attained 37.74% within 2–8 days. Optimization of the bioleaching process resulted in 1.7–2.7-fold increase in metal extractions. Studies at 10, 50, and 100 g L −1 pulp densities showed that metal extraction operational time increased as the pulp density was increased, and the obtained extractions ranged between 83 and 40% for Cu, 93 and 54% for Zn, 91 and 27% in the case of Ni, 99 and 17% Co and Li extractions were 44 and 13%. For the spent medium at 10, 50, and 100 g L −1 pulp densities, Cu extraction ranged between 52 and 33%, Zn extractions between 78 and 39%, Ni extractions between 73 and 25%, Co extractions between 58 and 16%, and Li extractions between 22 and 5% within 4–6 days of reaction time. Presence of the consortium had a beneficial influence on the extraction of all the metals studied.
ISSN:2199-3823
2199-3831
DOI:10.1007/s40831-019-00223-z