Rational design of electrocatalysts for simultaneously promoting bulk charge separation and surface charge transfer in solar water splitting photoelectrodes
2018
Hu, Yingfei | Wu, Yangqing | Feng, Jianyong | Huang, Huiting | Zhang, Chunchen | Qian, Qinfeng | Fang, Tao | Xu, Jun | Wang, Peng | Li, Zhaosheng | Zou, Zhigang
For a photoanode, a large overpotential for water oxidation, which limits the solar-to-hydrogen efficiency, may be caused by slow water oxidation kinetics and the recombination of photo-induced electrons and holes. Herein, taking flat and thin BiVO₄ photoanodes as an example, the composite AgOₓ/NiOₓ electrocatalyst was found to promote not only the water oxidation kinetics, but also the bulk charge separation. As a result, the surface charge injection efficiency (ηᵢₙⱼ) and the bulk charge separation efficiency (ηₛₑₚ) of BiVO₄ photoanodes were improved by the composite AgOₓ/NiOₓ electrocatalyst. Photo-assisted electrochemical impedance spectroscopy (EIS) was employed to illustrate the significantly reduced surface charge transfer resistance of the BiVO₄/AgOₓ/NiOₓ sample at the interface between the photoanode surface and the electrolyte. Analysis of the surface potential changes obtained from photo-assisted Kelvin probe force microscopy (KPFM) revealed that the surface photovoltage (SPV) of the BiVO₄/AgOₓ/NiOₓ photoanode is higher than those of BiVO₄/AgOₓ and BiVO₄/NiOₓ, representing its large band bending region for bulk charge separation. The open circuit photovoltage (OCP) measurements also demonstrated the superior charge separation ability of the BiVO₄/AgOₓ/NiOₓ photoanode. The possible working mechanism is that one component of the composite AgOₓ/NiOₓ electrocatalyst may stabilize the high valence states of the other metal ions, which is beneficial for the formation of water oxidation active sites and the extension of the band bending region.
Показать больше [+] Меньше [-]Ключевые слова АГРОВОК
Библиографическая информация
Эту запись предоставил National Agricultural Library