Abstract:Currently, the electric vehicle industry is expanding rapidly, leading to challenges in the large-scale retirement and resource recovery of lithium-ion batteries. The black mass from spent LiFePO4 batteries has a complex composition. In this study, an acid-free leaching process based on sodium persulfate was developed to treat the black mass. This method achieves selective lithium recovery and enables cathode material regeneration. Key parameters were optimized via single-factor experiments. At ambient temperature, lithium could be selectively leached from the complex black mass by adjusting the leaching time to 40 min, the LiFePO4/Na2S2O8 molar ratio to 2.0:1.2, and the solid-liquid ratio to 50 g/L. A lithium leaching efficiency of 86.4% was achieved, while the dissolution of Fe, Cu, and Al was minimized. Notably, temperatures above 35 ℃ led to a substantial increase in the leaching rates of Cu and Al, and temperatures ≥65 ℃ promoted the dissolution of Fe. Therefore, ambient temperature operation saves energy and ensures leaching selectivity. The mechanism was investigated using multiple characterization techniques. X-ray diffraction (XRD) revealed that the majority of LiFePO4 was converted into FePO4, following the reaction: 2LiFePO4 + Na2S2O8 → 2FePO4 + Li2SO4 + Na2SO4. Fourier transform infrared spectroscopy (FTIR) showed characteristic peak shifts and a new peak corresponding to the bending vibration of the  group. Scanning electron microscopy (SEM) images demonstrated that the graphite and LiFePO4 particle structures were preserved after leaching, confirming the mildness of the process. Based on the shrinking-core model, the incomplete lithium leaching was attributed to in-situ retained FePO4, which obstructed the contact between Na2S2O8 and internal LiFePO4. After impurity removal and leachate concentration, lithium was precipitated using a saturated Na2CO3 solution. High-purity Li2CO3 was obtained through purification. Regenerated LiFePO4 (RLFP) was prepared via carbothermal reduction using recycled Li2CO3 and FePO4 as raw materials, with 20% glucose added as the carbon source, followed by roasting at 700 ℃ for 10 h under an N2 atmosphere. RLFP exhibited properties comparable to those of commercial LiFePO4 (CLFP): XRD confirmed its standard crystal phase; X-ray photoelectron spectroscopy (XPS) verified that Fe was in the Fe2+ valence state; and Raman spectroscopy showed distinct D and G peaks with an ID/IG ratio< 1, indicating a high degree of graphitization. Electrochemical tests demonstrated that RLFP delivered a specific discharge capacity exceeding 155 mA·h/g at 0.1 C and maintained a capacity retention of 99.2% after 100 charge-discharge cycles at 0.5 C. Our mild, acid-free, and short-flow leaching and regeneration strategy enables efficient selective lithium recovery from black mass and the regeneration of high-performance LiFePO4. This work offers a practical pathway for the recycling of spent LiFePO4 batteries and demonstrates promising potential for industrial-scale applications. Close-