电池(电)
材料科学
纳米颗粒
碳纤维
化学工程
兴奋剂
纳米技术
光电子学
复合材料
工程类
复合数
功率(物理)
物理
量子力学
作者
Hyung Wook Choi,Hongdae Lee,Jun Lu,Seok Bin Kwon,Dong In Jeong,Beum Jin Park,Jiwon Kim,Bong Kyun Kang,Gun Jang,Dae Ho Yoon,Ho Seok Park
摘要
Abstract Herein, we have designed a highly active and robust trifunctional electrocatalyst derived from Prussian blue analogs, where Co 4 N nanoparticles are encapsulated by Fe embedded in N‐doped carbon nanocubes to synthesize hierarchically structured Co 4 N@Fe/N–C for rechargeable zinc–air batteries and overall water‐splitting electrolyzers. As confirmed by theoretical and experimental results, the high intrinsic oxygen reduction reaction, oxygen evolution reaction, and hydrogen evolution reaction activities of Co 4 N@Fe/N–C were attributed to the formation of the heterointerface and the modulated local electronic structure. Moreover, Co 4 N@Fe/N–C induced improvement in these trifunctional electrocatalytic activities owing to the hierarchical hollow nanocube structure, uniform distribution of Co 4 N, and conductive encapsulation by Fe/N–C. Thus, the rechargeable zinc–air battery with Co 4 N@Fe/N–C delivers a high specific capacity of 789.9 mAh g −1 and stable voltage profiles over 500 cycles. Furthermore, the overall water electrolyzer with Co 4 N@Fe/N–C achieved better durability and rate performance than that with the Pt/C and IrO 2 catalysts, delivering a high Faradaic efficiency of 96.4%. Along with the great potential of the integrated water electrolyzer powered by a zinc–air battery for practical applications, therefore, the mechanistic understanding and active site identification provide valuable insights into the rational design of advanced multifunctional electrocatalysts for energy storage and conversion.
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