Research output: Contribution to journal › Review article › peer-review
Direct Recycling of Mixed-Oxide Cathodes: Balancing Cost, Performance and Environmental Trade-Offs. / Beletskii, Evgenii; Evshchik, Elizaveta; Shikhovtseva, Anna; Kolmakov, Valery; Popov, Andrey; Eliseeva, Svetlana; Shmygleva, Lyubov; Gun'ko, Yurii K.; Romanovski, Valentin.
In: Advanced Science, Vol. 13, No. 17, e19076, 23.03.2026.Research output: Contribution to journal › Review article › peer-review
}
TY - JOUR
T1 - Direct Recycling of Mixed-Oxide Cathodes: Balancing Cost, Performance and Environmental Trade-Offs
AU - Beletskii, Evgenii
AU - Evshchik, Elizaveta
AU - Shikhovtseva, Anna
AU - Kolmakov, Valery
AU - Popov, Andrey
AU - Eliseeva, Svetlana
AU - Shmygleva, Lyubov
AU - Gun'ko, Yurii K.
AU - Romanovski, Valentin
PY - 2026/3/23
Y1 - 2026/3/23
N2 - We compare solid-state relithiation (SSR), hydrothermal relithiation (Hydro), molten salt thermochemistry (MST), electro- chemical (EC), and chemical (Chem) methods using harmonized techno-economic (Group I), electrochemical (Group II), and environmental/toxicological (Group III) metrics. SSR/Hydro occupies a leading position in Group I. EC combines low energy (143.0 kJ ⋅g− 1 ) with higher material cost (147.7$ ⋅kg− 1 ) at the laboratory scale, yielding 71.9 pts, while Chem remains competitive (77.8 pts) despite elevated 201.4$ ⋅kg− 1 and moderate energy consumption of 333.7 kJ ⋅g− 1 . In Group II, MST and SSR lead (64.0 and 61.1 pts), followed by Chem, Hydro, and EC. In Group II, Chem/MST shows the best rate capability recovery, EC—cycling stability recovery, MST—capacity recovery. Group III follows the energy consumption track. The CO2 emission declines as follows: EC < Chem < MST < Hydro < SSR, with method toxicity near moderate hazard for SSR/MST/Hydro/EC and highly reactive / highly toxic for Chem. Integrated performance for Groups I–III is close for methods with energy control in the range of 60–65 points (SSR, Hydro, MST, EC), while Chem leads (72.3 points). For Ni-rich cathodes, transferable methods should include a brief high-temperature step. EC/Chem can only be used for mild regeneration.
AB - We compare solid-state relithiation (SSR), hydrothermal relithiation (Hydro), molten salt thermochemistry (MST), electro- chemical (EC), and chemical (Chem) methods using harmonized techno-economic (Group I), electrochemical (Group II), and environmental/toxicological (Group III) metrics. SSR/Hydro occupies a leading position in Group I. EC combines low energy (143.0 kJ ⋅g− 1 ) with higher material cost (147.7$ ⋅kg− 1 ) at the laboratory scale, yielding 71.9 pts, while Chem remains competitive (77.8 pts) despite elevated 201.4$ ⋅kg− 1 and moderate energy consumption of 333.7 kJ ⋅g− 1 . In Group II, MST and SSR lead (64.0 and 61.1 pts), followed by Chem, Hydro, and EC. In Group II, Chem/MST shows the best rate capability recovery, EC—cycling stability recovery, MST—capacity recovery. Group III follows the energy consumption track. The CO2 emission declines as follows: EC < Chem < MST < Hydro < SSR, with method toxicity near moderate hazard for SSR/MST/Hydro/EC and highly reactive / highly toxic for Chem. Integrated performance for Groups I–III is close for methods with energy control in the range of 60–65 points (SSR, Hydro, MST, EC), while Chem leads (72.3 points). For Ni-rich cathodes, transferable methods should include a brief high-temperature step. EC/Chem can only be used for mild regeneration.
KW - battery recycling
KW - environmental impact
KW - lithium-ion battery
KW - relithiation
KW - sustainable development
KW - techno-economic analysis
UR - https://www.mendeley.com/catalogue/b9852938-b165-34b1-be62-4a68404dd4be/
U2 - 10.1002/advs.202519076
DO - 10.1002/advs.202519076
M3 - Review article
C2 - 41698157
VL - 13
JO - Advanced Science
JF - Advanced Science
SN - 2198-3844
IS - 17
M1 - e19076
ER -
ID: 149274994