Xinhui Zhang, Aiping Wu, Dongxu Wang, Ying Xie, Aleksandr I. Gubanov, Gennadiy A. Kostin, Chungui Tian
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引用次数: 0
摘要
双过渡金属间隙化合物(btmic)在水电解中具有广阔的应用前景。以前的btmic通常由不规则粒子组成。在这里,这项工作展示了新型1D Co6Mo6C基异质结纳米线(1D Co/Co6Mo6C)的合成,其直径约为50 nm,长径比约为20,用于高效水电解。一个有趣的生长过程基于热分解“挤压”PMo12(磷钼酸)/ZIF‐67(沸石咪唑酸框架‐67)立方体前驱体。这种“挤压”生长与Mo种对Co种的隔离作用有关。一系列的实验和理论计算表明,Co和Mo的相互调节优化了电子结构,加速了H2O的解离和H+的还原动力学。此外,纳米线为电子转移和反应物的传递提供了途径。因此,1D Co/Co6Mo6C在1 m KOH条件下具有较高的析氢反应(η10为31 mV)和析氧反应(η10为210 mV)活性。基于1D Co/Co6Mo6C的电解电池需要1.43 V的低电压才能驱动10 mA cm−2。该催化剂在1 m磷酸盐缓冲盐水溶液中也表现出良好的HER性能,在电流密度>;42 mA cm - 2时超过Pt/C。
1D Co6Mo6C-Based Heterojunctional Nanowires from Pyrolytically “Squeezing” PMo12/ZIF-67 Cubes for Efficient Overall Water Electrolysis
The bi-transition-metal interstitial compounds (BTMICs) are promising for water electrolysis. The previous BTMICs are usually composed of irregular particles. Here, this work shows the synthesis of novel 1D Co6Mo6C-based heterojunction nanowires (1D Co/Co6Mo6C) with diameters about 50 nm and a length-to-diameter ratio about 20 for efficient water electrolysis. An interesting growth process based on pyrolytically “squeezing” PMo12 (Phosphomolybdic acid)/ZIF-67 (Zeolitic Imidazolate Framework-67) cube precursor is demonstrated. The “squeezing” growth is related to the role of Mo species for isolating Co species. A series of tests and theoretical calculation show the mutual regulation of Co and Mo to optimize the electronic structure, accelerating H2O dissociation and the reduction kinetics of H+. Additionally, the nanowires provide pathways for electron transfer and the transmission of reactants. Consequently, the 1D Co/Co6Mo6C exhibits high activity for hydrogen evolution reaction (η10 of 31 mV) and oxygen evolution reaction (η10 of 210 mV) in 1 m KOH. The electrolytic cell based on 1D Co/Co6Mo6C requires a low voltage of 1.43 V to drive 10 mA cm−2. The catalyst also exhibits good HER performance in 1 m phosphate-buffered saline solution, exceeding Pt/C at a current density >42 mA cm−2.
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