Litcius/Paper detail

Integrating pyro- and biohydrometallurgy in a green closed-loop lithium-ion battery recycling approach

Lukas Wiszniewski, Lalropuia Lalropuia, Sabine Spiess, Peter Presoly, K Kremser, Klaus Doschek, Georg M. Guebitz, Zlatko Raonić

2025Journal of environmental chemical engineering11 citationsDOIOpen Access PDF

Abstract

State-of-the-art stand-alone recycling routes for lithium-ion batteries (LIB), such as pyrometallurgy or hydrometallurgy, face significant challenges, including high energy consumption, loss of valuable elements like lithium (Li) and susceptibility to a waste stream with varying cathode chemistry. The present work investigates the comparison of recovery targets when processing synthesized black mass between a standalone biohydrometallurgical process and a combined method, including an upstream pyrometallurgical process. In this approach, black mass undergoes carbothermic reduction in the InduMelt reactor, in which volatile elements like Li are vaporized and extracted via the gas stream, producing a Li-free alloy. Thermodynamic equilibrium calculations using FactSage™ showed the possibility of partial oxidation when using the alloy in an open-loop approach. Within a closed-loop approach, the alloy was pulverized for downstream biohydrometallurgy. Bioleaching experiments using adapted enriched cultures with synthetic pre- and untreated NMC811 and LFP black mass were performed at pulp densities (w/v) of 1 % and 10 %. The highest leaching efficiency of up to 100 % for Nickel (Ni), Manganese (Mn), Cobalt (Co), and Aluminium (Al) was achieved in the 1 % pre-treated experiment. Increasing the pulp density to 10 % reduced the leaching efficiency of these metals to less than 25 % which could be attributed to factors such as the alkaline nature of the black mass, microbial inhibition and passivation due to precipitation. Pyrometallurgical pre-treatment improved metal leaching from NMC by up to 90 %, but had no impact on LFP. To close the materials loop, selective precipitation was applied. • The transfer coefficient for Lithium within pyrometallurgy is as high as 99 %. • Leaching efficiencies of critical elements reached up to 100 % using a combined pyro- and biohydrometallurgical approach. • Partial oxidation can be applied, to use the alloy within an open-loop approach. • The limiting factor for efficient leaching within biohydrometallurgy is the pulp density.

Topics & Concepts

Battery (electricity)Lithium (medication)Lithium-ion batteryAutomotive engineeringIonClosed loopLoop (graph theory)Environmental scienceComputer scienceEngineeringChemistryControl engineeringPhysicsPower (physics)PsychologyMathematicsThermodynamicsOrganic chemistryCombinatoricsPsychiatryExtraction and Separation ProcessesMetal Extraction and BioleachingRecycling and Waste Management Techniques