Bala Krishnan Ganesan, Megala Moorthy, Yeong-A Kim, Hariharan Dhanasekaran, Jeong-Hyeon Song, Yun-Sung Lee
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引用次数: 0
摘要
钠离子电池被认为是下一代大规模储能应用中锂离子电池的一种具有成本效益和前景的替代品。然而,插层动力学缓慢,稳定性差,影响了其高效应用。近年来,富钠阴极材料作为一种具有高比能和高耐久性的极具发展前景的材料而崭露头角。利用p2型结构的高Na离子迁移率和减少的John-Teller活性Mn位,该富Na阴极的稳定性得到了提高。在这项工作中,我们开发了一种高性能富钠阴极,以氟化氧化锰钠(Na 1.2 Mn 0.8 O 1.5 F 0.5)作为电池正极。在固态电池中分析了相应的结构和电化学性能。极好的阴极结构在10 mA/g时具有178 mAh/g的高比容量。为了进一步发挥其性能,阴极材料与固体电解质和界面改性阳极耦合。固态电池表现出增强的离子存储能力和更好的稳定性。
A Study on Na1.2Mn0.8O1.5F0.5 Na-Rich Cathode Material for High Capacity and Superior Stability Sodium Solid-State Battery
Sodium ion batteries are considered as a cost-effective and promising alternative to lithium-ion batteries for next generation large-scale energy storage applications. However, the sluggish intercalation kinetics and poor stability plagues the efficient applications. Recently, sodium rich cathode materials are emerging as a promising system to retain high specific energy with improved durability. Benefitting from the high Na ion mobility by P2-type structure and reduced John-Teller active Mn site, improved stability has been achieved for this Na-rich cathode. In this work, we developed a high performing Na rich cathode with Sodium Manganese Oxyfluoride ( Na 1.2 Mn 0.8 O 1.5 F 0.5 ) as a battery positive electrode. The corresponding structural and electrochemical performances are analysed in solid-state battery. The highly favourable cathode architecture demonstrated a high specific capacity of 178 mAh/g at 10 mA/g in half-cell configuration. To further harness its performance, the cathode material was coupled with solid-electrolyte and interface modified anode. Solid-state battery demonstrated an enhanced capability towards ion storage and better stability.
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