Modifying of Graphite Recovering From the Industrial Diamond Remainders as Value-Added Cathode Material for High-Performance Aqueous Zinc-Ion Batteries
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Abstract
To meet the future development of high-performance aqueous zinc ion batteries (AZIBs) with high energy density, low cost, and excellent cycle stability, an innovative strategy is developed to treat diamond residue graphite and integrate nanostructured MnO2 onto its surface via simple hydrothermal and heat treatment methods. In the MnO2@MG composite, the presence of modified graphite (MG) restricts the degree of freedom of MnO2 growth, resulting in the formation of smaller MnO2 structures and avoiding the accumulation and aggregation of MnO2, which helps to improve the interface charge transport of composite electrodes. Meanwhile, the MG could effectively slow the structural collapse of MnO2 during charging/discharging and improve the conductivity of MnO2. Based on the synergistic core–shell structure, the AZIBs employing MnO2@MG exhibit superior capacity (332.0 mA h g−1 at 100 mA g−1 over 300 cycles), excellent rate capabilities (208.1 mA h g−1 at 500 mA g−1), and outstanding cycling performance (48.1% capacity retention after 2000 cycles) at high current density. This work demonstrates the successful and large-scale conversion of industrial diamond residue graphite into a high-performance cathode of AZIBs.
为了满足高性能、高能量密度、低成本、高循环稳定性的水性锌离子电池(AZIBs)的未来发展,提出了一种创新的策略,即通过简单的水热和热处理方法处理金刚石渣石墨,并将纳米结构的MnO2集成到其表面。在MnO2@MG复合材料中,改性石墨(MG)的存在限制了MnO2生长的自由度,导致MnO2结构的形成更小,避免了MnO2的积累和聚集,有助于提高复合电极的界面电荷输运。同时,MG能有效减缓MnO2在充放电过程中的结构崩塌,提高MnO2的电导率。基于协同核壳结构,采用MnO2@MG的AZIBs在高电流密度下表现出优异的容量(100 mA g−1超过300次循环时为332.0 mA h g−1),优异的倍率能力(500 mA g−1时为208.1 mA h g−1)和出色的循环性能(2000次循环后容量保持率为48.1%)。这项工作证明了工业金刚石渣石墨成功和大规模转化为高性能azib阴极。
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