材料科学
电解质
电极
水溶液
钠
盐(化学)
离子
锂离子电池的纳米结构
无机化学
化学工程
电化学
能量密度
储能
工程物理
冶金
有机化学
化学
物理化学
物理
工程类
功率(物理)
量子力学
作者
Zhiyin Yang,Ailun Huang,Cheng‐Wei Lin,Bradley C. Kroes,Xueying Chang,Maher F. El-Kady,Yuzhang Li,Richard B. Kaner
标识
DOI:10.1021/acsami.4c15832
摘要
High Resolution Image Download MS PowerPoint Slide Aqueous sodium-ion batteries (SIBs) are gradually being recognized as viable solutions for large-scale energy storage because of their inherent safety as well as low cost. However, despite recent advancements in water-in-salt electrolyte technologies, the challenge of identifying anode materials with sufficient specific capacity persists, complicating the wider adoption of these batteries. This study introduces an innovative and straightforward approach for synthesizing vanadium oxide laser-scribed graphene (VO x -LSG) composites, which function as effective anode materials in aqueous sodium-ion batteries. By combining a rapid laser-scribing technique with precise thermal control, the method not only allows for changing the morphology of the vanadium oxide, but also tuning its oxidation state. This is achieved while embedding these electrochemically active particles within a highly conductive graphene scaffold. When paired with a Prussian blue-based cathode (Na 1.88 Mn[Fe(CN) 6 ] 0.97 ) in a concentrated NaClO 4 -based aqueous electrolyte, the battery’s charge storage mechanism is found to be largely surface-controlled, leading to exceptional rate performance. The full cell demonstrates specific capacities of 128 mA h/ [email protected] A/g and 65.6 mA h/g@1 A/g, with an energy density of 47.7 W h/kg, outperforming many existing aqueous sodium-ion batteries. This strategy offers a promising path forward for integrating efficient, eco-friendly, and low-cost anode materials into large energy storage devices and systems.
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