J. Priscilla Grace, Y. Kaliprasad and Surendra K. Martha
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引用次数: 0
Abstract
Lithium–sulfur batteries (LSBs) offer a distinctive advantage over traditional Li-ion batteries with a higher theoretical capacity (1675 mA h g−1) and energy density (2600 W h kg−1). This study focuses on an inexpensive graphite recycled from the spent LIBs as a promising sulfur host for developing sustainable LSBs. A recycled reduced graphene oxide–sulfur (RRGO-S) composite was cast onto a 3D-carbon fiber (CF) electrode (RRGO-S@CF). The flexible and lightweight RRGO-S@CF electrodes at 500 mA g−1 delivered an initial discharge capacity of 552 mA h g−1, and there was no capacity loss in its initial five cycles, maintaining a stable capacity of 390 mA h g−1 till 300 cycles with 73% capacity retention. At a higher current density of 1.675 A g−1, it delivered an improved capacity of 417 mA h g−1. The enhanced electrochemical performance was due to the favorable interaction between the RRGO and lithium polysulfides, reducing the active material loss and polysulfide dissolution. The 3D-CF and RRGO offer a conductive network and Li-ion transport with electrolyte wettability, thereby improving the sulfur utilization and overall electrochemical performance in LSBs. This approach demonstrates the construction of recycled materials from the spent LIBs as an inexpensive source to meet the growing energy demand in the practical development of LSBs.
与传统锂离子电池相比,锂硫电池具有更高的理论容量(1675 mA h g−1)和能量密度(2600 W h kg−1)。本研究的重点是从废lib中回收的廉价石墨作为开发可持续lbs的有前途的硫宿主。将回收的还原氧化石墨烯-硫(RRGO-S)复合材料浇铸在3d碳纤维(CF)电极上(RRGO-S@CF)。柔性轻质RRGO-S@CF电极在500 mA g−1下的初始放电容量为552 mA h g−1,并且在最初的5次循环中没有容量损失,在300次循环中保持390 mA h g−1的稳定容量,容量保留率为73%。在1.675 a g−1的电流密度下,其容量提高到417 mA h g−1。电化学性能的提高是由于RRGO与多硫化锂之间良好的相互作用,减少了活性物质的损失和多硫化物的溶解。3D-CF和RRGO提供导电网络和具有电解质润湿性的锂离子传输,从而提高了硫的利用率和lsb的整体电化学性能。这种方法表明,从废lib中回收材料的构建是一种廉价的来源,可以满足lsdb实际开发中不断增长的能源需求。
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