Deep eutectic solvents (DESs) have garnered attention in Li-ion battery (LIB) recycling due to their declared eco-friendly attributes and adjustable metal dissolution selectivity, offering a promising avenue for recycling processes. However, DESs currently lack competitiveness compared to mineral acids, commonly used in industrial-scale LIB recycling. Current research primarily focuses on optimizing DES formulation and experimental conditions to maximize metal dissolution yields in standalone leaching experiments. While achieving yields comparable to traditional leaching systems is important, extensive DES reuse is vital for overall recycling feasibility. To achieve this, evaluating the metal dissolution mechanism can assist in estimating DES consumption rates and assessing process makeup stream costs. The selection of appropriate metal recovery and DES regeneration strategies is essential to enable subsequent reuse over multiple cycles. Finally, decomposition of DES components should be avoided throughout the designed recycling process, as by-products can impact leaching efficiency and compromise the safety and environmental friendliness of DES. In this review, these aspects are emphasized with the aim of directing research efforts away from simply pursuing the maximization of metal dissolution efficiency, towards a broader view focusing on the application of DES beyond the laboratory scale.Extensive reuse of deep eutectic solvent should be ensured when applied in the Li-ion battery recycling process. In each key step of recycling, including metal dissolution, recovery, and DES regeneration, decomposition and consumption occur, hindering DES reuse and thus undermining the feasibility of the entire recycling process. image
Addressing the Reuse of Deep Eutectic Solvents in Li‐Ion Battery Recycling: Insights into Dissolution Mechanism, Metal Recovery, Regeneration and Decomposition / Svärd, Michael; Ma, Chunyan; Forsberg, Kerstin; Schiavi, Pier Giorgio. - In: CHEMSUSCHEM. - ISSN 1864-5631. - 2024:(2024), pp. 1-22. [10.1002/cssc.202400410]
Addressing the Reuse of Deep Eutectic Solvents in Li‐Ion Battery Recycling: Insights into Dissolution Mechanism, Metal Recovery, Regeneration and Decomposition
Schiavi, Pier Giorgio
Ultimo
2024
Abstract
Deep eutectic solvents (DESs) have garnered attention in Li-ion battery (LIB) recycling due to their declared eco-friendly attributes and adjustable metal dissolution selectivity, offering a promising avenue for recycling processes. However, DESs currently lack competitiveness compared to mineral acids, commonly used in industrial-scale LIB recycling. Current research primarily focuses on optimizing DES formulation and experimental conditions to maximize metal dissolution yields in standalone leaching experiments. While achieving yields comparable to traditional leaching systems is important, extensive DES reuse is vital for overall recycling feasibility. To achieve this, evaluating the metal dissolution mechanism can assist in estimating DES consumption rates and assessing process makeup stream costs. The selection of appropriate metal recovery and DES regeneration strategies is essential to enable subsequent reuse over multiple cycles. Finally, decomposition of DES components should be avoided throughout the designed recycling process, as by-products can impact leaching efficiency and compromise the safety and environmental friendliness of DES. In this review, these aspects are emphasized with the aim of directing research efforts away from simply pursuing the maximization of metal dissolution efficiency, towards a broader view focusing on the application of DES beyond the laboratory scale.Extensive reuse of deep eutectic solvent should be ensured when applied in the Li-ion battery recycling process. In each key step of recycling, including metal dissolution, recovery, and DES regeneration, decomposition and consumption occur, hindering DES reuse and thus undermining the feasibility of the entire recycling process. imageFile | Dimensione | Formato | |
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