The effect of the photochemical environment on photoanodes for photoelectrochemical water splitting

被引:16
作者
Huang, Xiaoqian [1 ]
Li, Yanfei [2 ]
Gao, Xiaoru [1 ]
Xue, Qihui [1 ]
Zhang, Ruikang [1 ]
Gao, Yuanzhe [1 ]
Han, Zhangang [1 ]
Shao, Mingfei [2 ]
机构
[1] Hebei Normal Univ, Coll Chem & Mat Sci, Hebei Key Lab Organ Funct Mol, Shijiazhuang 050024, Hebei, Peoples R China
[2] Beijing Univ Chem Technol, State Key Lab Chem Resource Engn, Beijing 100029, Peoples R China
来源
DALTON TRANSACTIONS | 2020年 / 49卷 / 35期
基金
中国国家自然科学基金; 北京市自然科学基金;
关键词
CHARGE-TRANSPORT; TIO2; PERFORMANCE; ALPHA-FE2O3;
D O I
10.1039/d0dt01566k
中图分类号
O61 [无机化学];
学科分类号
070301 ; 081704 ;
摘要
Besides photoelectrode materials, realizing the synergy of the photochemical environment and photoelectrodes for high charge carrier utilization is crucial for enhancing the performance of photoelectrochemical (PEC) water splitting systems. However, few researchers have focused on this important aspect. Herein, the effect of the photochemical environment on photoanodes in PEC water splitting, including the redox potential of electrolytes and light direction, is rationally discussed. A combined study of the potential distribution and electrochemical impedance spectroscopy reveals that the low redox potential of electrolytes facilitates the interior charge transfer and surface charge utilization by enlarging the depletion layer. In addition, it is found that the optimum thickness of semiconductors in photoelectrodes is the length of the depletion layer plus diffusion layer.
引用
收藏
页码:12338 / 12344
页数:7
相关论文
共 42 条
[1]  
Bae D., 2014, ENERG ENVIRON SCI, V8, P650
[2]   Back-Illuminated Si-Based Photoanode with Nickel Cobalt Oxide Catalytic Protection Layer [J].
Bae, Dowon ;
Mei, Bastian ;
Frydendal, Rasmus ;
Pedersen, Thomas ;
Seger, Brian ;
Hansen, Ole ;
Vesborg, Peter C. K. ;
Chorkendorff, Ib .
CHEMELECTROCHEM, 2016, 3 (10) :1517-1517
[3]   Steering charge kinetics in photocatalysis: intersection of materials syntheses, characterization techniques and theoretical simulations [J].
Bai, Song ;
Jiang, Jun ;
Zhang, Qun ;
Xiong, Yujie .
CHEMICAL SOCIETY REVIEWS, 2015, 44 (10) :2893-2939
[4]   Understanding charge transport in non-doped pristine and surface passivated hematite (Fe2O3) nanorods under front and backside illumination in the context of light induced water splitting [J].
Bassi, Prince Saurabh ;
Li Xianglin ;
Fang, Yanan ;
Loo, Joachim Say Chye ;
Barber, James ;
Wong, Lydia Helena .
PHYSICAL CHEMISTRY CHEMICAL PHYSICS, 2016, 18 (44) :30370-30378
[5]   Synergistic Effect of Si Doping and Heat Treatments Enhances the Photoelectrochemical Water Oxidation Performance of TiO2 Nanorod Arrays [J].
Chen, Changlong ;
Wei, Yuling ;
Yuan, Guangzheng ;
Liu, Qinglong ;
Lu, Ranran ;
Huang, Xing ;
Cao, Yi ;
Zhu, Peihua .
ADVANCED FUNCTIONAL MATERIALS, 2017, 27 (31)
[6]   Unraveling the Intrinsic Structures that Influence the Transport of Charges in TiO2 Electrodes [J].
Chen, Jiazang ;
Tao, Hua Bing ;
Liu, Bin .
ADVANCED ENERGY MATERIALS, 2017, 7 (23)
[7]   Imaging photogenerated charge carriers on surfaces and interfaces of photocatalysts with surface photovoltage microscopy [J].
Chen, Ruotian ;
Fan, Fengtao ;
Dittrich, Thomas ;
Li, Can .
CHEMICAL SOCIETY REVIEWS, 2018, 47 (22) :8238-8262
[8]   Semiconductor-based photocatalysts for photocatalytic and photoelectrochemical water splitting: will we stop with photocorrosion? [J].
Chen, Sha ;
Huang, Danlian ;
Xu, Piao ;
Xue, Wenjing ;
Lei, Lei ;
Cheng, Min ;
Wang, Rongzhong ;
Liu, Xigui ;
Deng, Rui .
JOURNAL OF MATERIALS CHEMISTRY A, 2020, 8 (05) :2286-2322
[9]   Photoelectrocatalytic Water Splitting: Significance of Cocatalysts, Electrolyte, and Interfaces [J].
Ding, Chunmei ;
Shi, Jingying ;
Wang, Zhiliang ;
Li, Can .
ACS CATALYSIS, 2017, 7 (01) :675-688
[10]   Construct Fe2+ species and Au particles for significantly enhanced photoelectrochemical performance of α-Fe2O3 by ion implantation [J].
He, Dong ;
Song, Xianyin ;
Ke, Zunjian ;
Xiao, Xiangheng ;
Jiang, Changzhong .
SCIENCE CHINA-MATERIALS, 2018, 61 (06) :878-886
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