Seminar Nasional Teknik Kimia "Kejuangan"

Recovery of valuable metals from spent lithium iron phosphate (LiFePO₄) batteries are quite challenging because it needs a lot of process. The recycling of these spent batteries can avoid environment contamination from the waste, meanwhile the valuable metallic components in the batteries including lithium can be treated as a resource for potential recovery of lithium. Low concentration of sulfuric acid (H₂SO₄) as a leachant and hydrogen peroxide (H₂O₂) as an oxidant, was used to leach elements from cathode materials of spent LiFePO₄ batteries that mainly contained Li, Fe and P. Li could be selectively leached into the solution and while Fe and P was assumed to remain in the residue. The significant effects of acid concentration, solid-liquid ratio, reaction temperature and reaction time on the leaching rate are determined. Under the optimum conditions of 0.1 M H₂SO_4, 2 vol% H₂O_2, S/L ratio of 75g/L, 60 °C and 60 min, the leaching efficiency determined were 74.74% for Li and 0.99% for Fe. A leaching mechanism of shrinking-core model with diffusion through product layer control was proposed. It was found that the apparent activation energy was 12.69 kJ mol^-1 as calculated by the Arrhenius equation together with an enthalpy (∆H) of 10 kJ mol^-1 and an entropy (∆S) of -264.54 Jmol^-1K^-1.

Aaltonen M, Peng C, Wilson BP, Lundstrom M. Leaching of Metals from Spent Lithium-Ion Batteries †. Recycling 2017; 2: 20.

Ebrahimzade H, Khayati GR, Schaffie M. Leaching kinetics of valuable metals from waste Li-ion batteries using neural network approach. Journal of Material Cycles and Waste Management 2018; 20: 2117–2129.

Gaines L. Lithium-ion battery recycling processes: Research towards a sustainable course ☆. Sustainable Materials and Technologies 2018; 17; e00068.

Han B, Altansukh B, Haga K, Takasaki Y, Shibayama A. Leaching and kinetic study on pressure oxidation of chalcopyrite in H2SO4 solution and the effect of pyrite on chalcopyrite leaching. Journal of Sustainable Metallurgy 2017.

Hidalgo T, Kuhar L, Beinlich A, Putnis A. Kinetic study of chalcopyrite dissolution with iron (III) chloride in methanesulfonic acid. Minerals Engineering 2018; 125(May): 66–74.

Levenspiel O. Chemical reaction engineering. John Wiley & Sons. 1998: 566-586.

Li H, Xing S, Liu Y, Li F, Guo H, Kuang G. Recovery of lithium, iron, and phosphorus from spent LiFePO4 batteries using stoichiometric sulfuric acid leaching system. ACS Sustainable Chem. Eng. 2017; 5: 8017–8024.

Li L, Bian Y, Zhang X, Yao Y, Xue Q, Fan E, Wu F, Chen R. A green and effective room-temperature recycling process of LiFePO4 cathode materials for lithium-ion batteries 2019; 85: 437–444.

Meshram P, Pandey BD, Mankhand TR. Hydrometallurgical processing of spent lithium ion batteries (LIBs) in the presence of a reducing agent with emphasis on kinetics of leaching. Chemical Engineering Journal 2015; 281: 418–427.

Wang W, Wu Y. An overview of recycling and treatment of spent LiFePO4 batteries in China. Resources, Conservation & Recycling 2017; 127 (100): 233–243.

Yang Y, Meng X, Cao H, Lin X, Liu C, Sun Y, Zhang Y, Sun Z. Selective recovery of lithium from spent lithium iron phosphate batteries: A sustainable process. Green Chemistry 2018; DOI: 10.1039/C7GC03376A.

Yuan L, Wang Z, Zhang W, Hu X, Chen J, Huang Y. Development and challenges of LiFePO4 cathode material for lithium-ion batteries. Energy & Environmental Science 2011; 4: 269–284.

Yuliusman, Fajaryanto R, Nurqomariah A, Silvia. Acid leaching and kinetics study of cobalt recovery from spent lithium-ion batteries with nitric acid. 3rd i-TREC 2018; 67: 1–6.

Zhang W, Xu C, He W, Li G. A review on management of spent lithium ion batteries and strategy for resource recycling of all components from them 2018; 36 (2): 99–112.