Kinetics and Thermodynamics Study of Ammonia Leaching on Spent LMR-NMC Battery Cathodes
Indra Perdana(1*), Muhammad Irfan Rahman(2), Doni Riski Aprilianto(3), Himawan Tri Bayu Murti Petrus(4), Divita Hayyu Kinanti(5)
(1) Sustainable Mineral Processing Research Group, Department of Chemical Engineering, Faculty of Engineering, Universitas Gadjah Mada, Jl. Grafika No. 2, Yogyakarta 55281, Indonesia
(2) Sustainable Mineral Processing Research Group, Department of Chemical Engineering, Faculty of Engineering, Universitas Gadjah Mada, Jl. Grafika No. 2, Yogyakarta 55281, Indonesia
(3) Sustainable Mineral Processing Research Group, Department of Chemical Engineering, Faculty of Engineering, Universitas Gadjah Mada, Jl. Grafika No. 2, Yogyakarta 55281, Indonesia
(4) Sustainable Mineral Processing Research Group, Department of Chemical Engineering, Faculty of Engineering, Universitas Gadjah Mada, Jl. Grafika No. 2, Yogyakarta 55281, Indonesia
(5) Sustainable Mineral Processing Research Group, Department of Chemical Engineering, Faculty of Engineering, Universitas Gadjah Mada, Jl. Grafika No. 2, Yogyakarta 55281, Indonesia
(*) Corresponding Author
Abstract
The recycling of spent lithium NMC-type batteries, widely used in electric vehicles, presents a challenge due to manganese content, which complicates metal separation and purification. This study explored a selective leaching process using ammonia to recover metals from high-manganese-content LMR-NMC cathodes. By adjusting the (NH4)2SO4 reagent concentration to 1–2 M and maintaining the temperature between 50–80 °C, the recovery rates of lithium, nickel and cobalt metals were enhanced, leaving manganese primarily as residue in the form of Mn(OH)₂ and (NH4)2Mn(SO4)2. A kinetics model, integrating an equilibrium-shrinking core model with a modified temperature-dependent Arrhenius approach, accurately simulates the metal recovery. The activation energies of the forward leaching reactions of Li, Ni, and Co were respectively (1.4331±0.0036)×105, (1.5494±0.0034)×105, and (1.5743±0.0040)×105 J/mol, while those for the backward reactions were (5.3307±0.0041)×105, (2.4753±0.0093)×105, and (1.6289±0.0092)×105 J/mol, respectively. The leaching mechanism was found to be exothermic, which allows maximum recovery at low temperatures. The findings highlight ammonia’s effectiveness as a selective leachant, significantly reducing manganese in the leaching solution, and streamlining nickel and cobalt separation, thus enhancing the recycling process’s efficiency and sustainability.
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[1] da Silva Lima, L., Quartier, M., Buchmayr, A., Sanjuan-Delmás, D., Laget, H., Corbisier, D., Mertens, J., and Dewulf, J., 2021, Life cycle assessment of lithium-ion batteries and vanadium redox flow batteries-based renewable energy storage systems, Sustainable Energy Technol. Assess., 46, 101286.
[2] Yoshio, M., Brodd, R.J., and Kozawa, A., 2009, Lithium-Ion Batteries: Science and Technologies, Springer, New York, US.
[3] Yu, D., Huang, Z., Makuza, B., Guo, X., and Tian, Q., 2021, Pretreatment options for the recycling of spent lithium-ion batteries: A comprehensive review, Miner. Eng., 173, 107218.
[4] Zhang, W., Xu, C., He, W., Li, G., and Huang, J., 2018, A review on management of spent lithium ion batteries and strategy for resource recycling of all components from them, Waste Manage. Res., 36 (2), 99–112.
[5] Zeng, X., Li, J., and Ren, Y., 2012, Prediction of various discarded lithium batteries in China, 2012 IEEE International Symposium on Sustainable Systems and Technology (ISSST), Boston, MA, US, 16-18 May 2012.
[6] Kang, D.H.P., Chen, M., and Ogunseitan, O.A., 2013, Potential environmental and human health impacts of rechargeable lithium batteries in electronic waste, Environ. Sci. Technol., 47 (10), 5495–5503.
[7] Zheng, X., Zhu, Z., Lin, X., Zhang, Y., He, Y., Cao, H., and Sun, Z., 2018, A mini-review on metal recycling from spent lithium ion batteries, Engineering, 4 (3), 361–370.
[8] Baum, Z.J., Bird, R.E., Yu, X., and Ma, J., 2022, Lithium-ion battery recycling—Overview of techniques and trends, ACS Energy Lett., 7 (2), 712–719.
[9] Islam, M.T., and Iyer-Raniga, U., 2022, Lithium-ion battery recycling in the circular economy: A review, Recycling, 7 (3), 33.
[10] Anonymous, 2019, Recycle spent batteries, Nat. Energy, 4 (4), 253–253.
[11] Jin, S., Mu, D., Lu, Z., Li, R., Liu, Z., Wang, Y., Tian, S., and Dai, C., 2022, A comprehensive review on the recycling of spent lithium-ion batteries: Urgent status and technology advances, J. Cleaner Prod., 340, 130535.
[12] Free, M.L., 2022, Hydrometallurgy: Fundamentals and Applications, Springer, Cham, Switzerland.
[13] Guimarães, L.F., Botelho Junior, A.B., and Espinosa, D.C.R., 2022, Sulfuric acid leaching of metals from waste Li-ion batteries without using reducing agent, Miner. Eng., 183, 107597.
[14] Chen, W.S., and Ho, H.J., 2018, Recovery of valuable metals from lithium-ion batteries NMC cathode waste materials by hydrometallurgical methods, Metals, 8 (5), 321.
[15] Xuan, W., de Souza Braga, A., Korbel, C., and Chagnes, A., 2021, New insights in the leaching kinetics of cathodic materials in acidic chloride media for lithium-ion battery recycling, Hydrometallurgy, 204, 105705.
[16] Xuan, W., Otsuki, A., and Chagnes, A., 2019, Investigation of the leaching mechanism of NMC 811 (LiNi0.8Mn0.1Co0.1O2) by hydrochloric acid for recycling lithium ion battery cathodes, RSC Adv., 9 (66), 38612–38618.
[17] Peng, C., Liu, F., Wang, Z., Wilson, B.P., and Lundström, M., 2019, Selective extraction of lithium (Li) and preparation of battery grade lithium carbonate (Li2CO3) from spent Li-ion batteries in nitrate system, J. Power Sources, 415, 179–188.
[18] Zhuang, L., Sun, C., Zhou, T., Li, H., and Dai, A., 2019, Recovery of valuable metals from LiNi0.5Co0.2Mn0.3O2 cathode materials of spent Li-ion batteries using mild mixed acid as leachant, Waste Manage., 85, 175–185.
[19] Zheng, X., Gao, W., Zhang, X., He, M., Lin, X., Cao, H., Zhang, Y., and Sun, Z., 2017, Spent lithium-ion battery recycling – Reductive ammonia leaching of metals from cathode scrap by sodium sulphite, Waste Manage., 60, 680–688.
[20] Ku, H., Jung, Y., Jo, M., Park, S., Kim, S., Yang, D., Rhee, K., An, E.M., Sohn, J., and Kwon, K., 2016, Recycling of spent lithium-ion battery cathode materials by ammoniacal leaching, J. Hazard. Mater., 313, 138–146.
[21] Liu, X., Huang, K., Xiong, H., and Dong, H., 2023, Ammoniacal leaching process for the selective recovery of value metals from waste lithium-ion batteries, Environ. Technol., 44 (2), 211–225.
[22] Meng, K., Cao, Y., Zhang, B., Ou, X., Li, D., Zhang, J., and Ji, X., 2019, Comparison of the ammoniacal leaching behavior of layered LiNixCoyMn1–x–yO2 (x = 1/3, 0.5, 0.8) cathode materials, ACS Sustainable Chem. Eng., 7 (8), 7750–7759.
[23] Ning, P., Meng, Q., Dong, P., Duan, J., Xu, M., Lin, Y., and Zhang, Y., 2020, Recycling of cathode material from spent lithium ion batteries using an ultrasound-assisted DL-malic acid leaching system, Waste Manage., 103, 52–60.
[24] Munir, H., Srivastava, R.R., Kim, H., Ilyas, S., Khosa, M.K., and Yameen, B., 2020, Leaching of exhausted LNCM cathode batteries in ascorbic acid lixiviant: A green recycling approach, reaction kinetics and process mechanism, J. Chem. Technol. Biotechnol., 95 (8), 2286–2294.
[25] Li, L., Lu, J., Ren, Y., Zhang, X.X., Chen, R.J., Wu, F., and Amine, K., 2012, Ascorbic-acid-assisted recovery of cobalt and lithium from spent Li-ion batteries, J. Power Sources, 218, 21–27.
[26] Refly, S., Floweri, O., Mayangsari, T.R., Aimon, A.H., and Iskandar, F., 2021, Green recycle processing of cathode active material from LiNi1/3Co1/3Mn1/3O2 (NCM 111) battery waste through citric acid leaching and oxalate co-precipitation process, Mater. Today: Proc., 44, 3378–3380.
[27] Mishra, D., Kim, D.J., Ralph, D.E., Ahn, J.G., and Rhee, Y.H., 2008, Bioleaching of metals from spent lithium ion secondary batteries using Acidithiobacillus ferrooxidans, Waste Manage., 28 (2), 333–338.
[28] Huang, T., Liu, L., and Zhang, S., 2019, Recovery of cobalt, lithium, and manganese from the cathode active materials of spent lithium-ion batteries in a bio-electro-hydrometallurgical process, Hydrometallurgy, 188, 101–111.
[29] Moosakazemi, F., Ghassa, S., Jafari, M., and Chelgani, S.C., 2023, Bioleaching for recovery of metals from spent batteries – A review, Miner. Process. Extr. Metall. Rev., 44 (7), 511–521.
[30] Mustika, P.C.B.W., Suryanaga, E.C., Perdana, I., Sutijan, S., Astuti, W., Petrus, H.T.B.M., and Prasetya, A., 2023, Optimization of lithium separation from NCA leachate solution: Investigating the impact of feed concentration, pressure, and complexing agent concentration, ASEAN J. Chem. Eng., 23 (3), 343–359.
[31] Nitta, N., Wu, F., Lee, J.T., and Yushin, G., 2015, Li-ion battery materials: Present and future, Mater. Today, 18 (5), 252–264.
[32] Houache, M.S.E., Yim, C.H., Karkar, Z., and Abu-Lebdeh, Y., 2022, On the current and future outlook of battery chemistries for electric vehicles—Mini review, Batteries, 8 (7), 70.
[33] Schmuch, R., Wagner, R., Hörpel, G., Placke, T., and Winter, M., 2018, Performance and cost of materials for lithium-based rechargeable automotive batteries, Nat. Energy, 3 (4), 267–278.
[34] Smith, A.J., Smith, S.R., Byrne, T., Burns, J.C., and Dahn, J.R., 2012, Synergies in blended LiMn2O4 and Li[Ni1/3Co1/3Mn1/3]O2 positive electrodes, J. Electrochem. Soc., 159 (10), A1696.
[35] Meng, F., Liu, Q., Kim, R., Wang, J., Liu, G., and Ghahreman, A., 2020, Selective recovery of valuable metals from industrial waste lithium-ion batteries using citric acid under reductive conditions: Leaching optimization and kinetic analysis, Hydrometallurgy, 191, 105160.
[36] Refly, S., Floweri, O., Mayangsari, T.R., Sumboja, A., Santosa, S.P., Ogi, T., and Iskandar, F., 2020, Regeneration of LiNi1/3Co1/3Mn1/3O2 cathode active materials from end-of-life lithium-ion batteries through ascorbic acid leaching and oxalic acid coprecipitation processes, ACS Sustainable Chem. Eng., 8 (43), 16104–16114.
[37] Gao, W., Song, J., Cao, H., Lin, X., Zhang, X., Zheng, X., Zhang, Y., and Sun, Z., 2018, Selective recovery of valuable metals from spent lithium-ion batteries – Process development and kinetics evaluation, J. Cleaner Prod., 178, 833–845.
[38] Liu, B., Huang, J., Song, J., Liao, K., Si, J., Wen, B., Zhou, M., Cheng, Y., Gao, J., and Xia, Y., 2022, Direct recycling of spent LiNi0.5Co0.2Mn0.3O2 cathodes based on single oxalic acid leaching and regeneration under mild conditions assisted by lithium acetate, Energy Fuels, 36 (12), 6552–6559.
[39] Semenov, N.N., 1958, Some Problems of Chemical Kinetics and Reactivity, Pergamon Press, London, UK.
[40] Setiawan, H., Petrus, H.T.B.M., and Perdana, I., 2019, Reaction kinetics modeling for lithium and cobalt recovery from spent lithium-ion batteries using acetic acid, Int. J. Miner. Metall. Mater., 26 (1), 98–107.
[41] Kohout, J., 2021, Modified Arrhenius equation in materials science, chemistry and biology, Molecules, 26 (23), 7162.
[42] Smith, I.W.M., 2008, The temperature-dependence of elementary reaction rates: Beyond Arrhenius, Chem. Soc. Rev., 37 (4), 812–826.
[43] Julien, C.M., and Massot, M., 2003, Lattice vibrations of materials for lithium rechargeable batteries I. Lithium manganese oxide spinel, Mater. Sci. Eng., B, 97 (3), 217–230.
[44] Lin, Y., Zhao, S., Qian, J., Xu, N., Liu, X.Q., Sun, L.B., Li, W., Chen, Z., and Wu, Z., 2020, Petal cell-derived MnO nanoparticle-incorporated biocarbon composite and its enhanced lithium storage performance, J. Mater. Sci., 55 (5), 2139–2154.
[45] Essehli, R., Sabri, S., El-Mellouhi, F., Aïssa, B., Ben Yahia, H., Altamash, T., Khraisheh, M., Amhamed, A., and El Bali, B., 2020, Single crystal structure, vibrational spectroscopy, gas sorption and antimicrobial properties of a new inorganic acidic diphosphates material (NH4)2Mg(H2P2O7)2·2H2O, Sci. Rep., 10 (1), 8909.
[46] Zheng, R., Wang, W., Dai, Y., Ma, Q., Liu, Y., Mu, D., Li, R., Ren, J., and Dai, C., 2017, A closed-loop process for recycling LiNixCoyMn1–x–yO2 from mixed cathode materials of lithium-ion batteries, Green Energy Environ., 2 (1), 42–50.
[47] Di Vincenzo, A., and Floriano, M.A., 2020, Elucidating the influence of the activation energy on reaction rates by simulations based on a simple particle model, J. Chem. Educ., 97 (10), 3630–3637.
[48] Laurendeau, N.M., 2005, Statistical Thermodynamics: Fundamentals and Applications, Cambridge University Press, Cambridge, UK.
[49] Lafuente, B., Downs, R.T., Yang, H., and Stone, N., 2015, “The Power of Databases: The RRUFF Project” in Highlights in Mineralogical Crystallography, Eds. Armbruster, T., and Danisi, R.M., De Gruyter, Berlin, Germany.
DOI: https://doi.org/10.22146/ijc.93312
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