Separation and Purification Technology, Journal Year: 2024, Volume and Issue: unknown, P. 130125 - 130125
Published: Oct. 1, 2024
Language: Английский
Published: Jan. 15, 2025
Language: Английский
Citations
10
Journal of Industrial and Engineering Chemistry, Journal Year: 2024, Volume and Issue: 140, P. 47 - 64
Published: May 27, 2024
Language: Английский
Citations
17
Green Chemistry, Journal Year: 2024, Volume and Issue: 26(13), P. 7656 - 7717
Published: Jan. 1, 2024
This review introduces the structure and failure mechanism of lithium-ion batteries, followed by a systematic summary recycling techniques, including direct, hydrometallurgical, pyrometallurgical recovery.
Language: Английский
Citations
14
The Science of The Total Environment, Journal Year: 2024, Volume and Issue: 951, P. 175459 - 175459
Published: Aug. 20, 2024
Language: Английский
Citations
10
Journal of Energy Chemistry, Journal Year: 2024, Volume and Issue: unknown
Published: Nov. 1, 2024
Language: Английский
Citations
9
Environmental Science & Technology, Journal Year: 2024, Volume and Issue: 58(43), P. 19486 - 19500
Published: Oct. 18, 2024
Recycling spent lithium-ion batteries offers a sustainable solution to reduce ecological degradation from mining and mitigate raw material shortages price volatility. This study investigates using electrodialysis with selective bipolar ion-exchange membranes establish circular economy for batteries. An experimental data set of over 1700 ion concentration measurements across five current densities, two compositions, three pH levels supports the techno-economic analysis. Selective (SED) isolates lithium ions battery leachates, yielding 99% Li-pure retentate 68.8% retention, achieving relative ionic fluxes up 2.41 Li+ transition metal cations selectivity 5.64 monovalent cations. Bipolar membrane (BMED) converts LiCl into high-purity LiOH HCl, essential remanufacturing reducing acid consumption via recycling. High densities leakage, leakage as low 0.03%, though hydronium hydroxide in BMED remains high at 11–20%. Our analysis projects production costs between USD 1.1 3.6 per kilogram, significantly lower than prices. Optimal SED conditions are identified, emphasizing need control proton transport improve cobalt–lithium separation enhance cost efficiency.
Language: Английский
Citations
8
ACS Sustainable Chemistry & Engineering, Journal Year: 2024, Volume and Issue: 12(23), P. 8780 - 8791
Published: May 29, 2024
The traditional lithium-ion battery (LIB) recycling method is inseparable from the application of chemical reagents such as acid and alkali, so efficient green valuable metal recovery technology invaluable. Moreover, current development environmentally friendly capacitive deionization (CDI) has been limited by field desalination. This work proposes a reagent-free for spent LIB cathode materials, which realizes lithium leaching ions into ultrapure water through CDI reverse application. Lithium in solution can be recovered evaporation crystallization form LiOH·H2O. Studies have shown that process unidirectional selectivity Li+. capacity LiNixCoyMn1–x–yO2 (NCM) materials reach 42.95 mg/g, but other elements (Ni, Co, Mn) was 0 mg/g. content recycled material after experiment reduced 90%, used precursor preparation fresh NCM materials. Meanwhile, under action voltage, arrangement bulk graphite crystals anode electrode changes disordered to orderly layered, reused system or high-value prelithium production batteries. expands new without using any alkali reagents, conducive sustainable environment.
Language: Английский
Citations
6
Chemical Engineering Journal, Journal Year: 2024, Volume and Issue: 497, P. 154573 - 154573
Published: Aug. 5, 2024
Language: Английский
Citations
6
Journal of Colloid and Interface Science, Journal Year: 2024, Volume and Issue: 677, P. 140 - 150
Published: Aug. 10, 2024
Language: Английский
Citations
6
Separation and Purification Technology, Journal Year: 2025, Volume and Issue: unknown, P. 131918 - 131918
Published: Feb. 1, 2025
Language: Английский
Citations
0