K. Subramanyan, M. Akshay, Yun‐Sung Lee, V. Aravindan
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引用次数: 10
摘要
废旧锂离子电池通过提取和再利用阳极活性材料石墨,通过一种简单而有效和可扩展的技术作为钠离子电池(SIB)的阳极,有效地回收利用。通过溶剂- co -插层工艺,回收的石墨(RG)半电池获得了>120 mAh g - 1的容量。进行了原位阻抗来评估电解液在延长循环中的稳健性。采用碳包覆的Na3V2(PO4)3阴极对RG的性能进行了评价,在100次循环后,RG的容量保持率为78%。此外,在- 10至40°C范围内,研究了全电池的温度依赖性性能,在此范围内,它表现出出色的低温性能。在环境温度条件下,全电池的能量密度为78 Wh kg - 1。SIB活性材料的回收将降低每千瓦时的成本,并作为一种绿色技术处理废旧锂离子电池。
Na‐Ion Battery with Graphite Anode and Na3V2(PO4)3 Cathode via Solvent‐Co‐Intercalation Process
Spent Li‐ion batteries are efficiently recycled by extracting and reusing the anode active material, graphite, through a simple yet effective and scalable technique as anode for the sodium‐ion battery (SIB). The recovered graphite (RG) half‐cell rendered a capacity of >120 mAh g−1 via the solvent‐co‐intercalation process. An in situ impedance is performed to assess the robustness of the electrolyte for the extended cycling. The performance of RG is evaluated in a full‐cell with carbon‐coated Na3V2(PO4)3 cathode, which exhibits capacity retention of 78% after 100 cycles. In addition, a temperature dependence performance of the full‐cell is studied from −10 to 40 °C, where it exhibits outstanding low‐temperature performance. The full‐cell provides an energy density of 78 Wh kg−1 at ambient temperature conditions. Recovery of active materials for SIB will drive down the cost/kWh and act as a green technology to dispose of spent Li‐ion batteries.
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