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Promoting effect of interfacial hole accumulation on photoelectrochemical water oxidation in BiVO4 and Mo-doped BiVO4

Xiaofeng Wu, F. Palacio, Shixin Chang, Marcus Einert, Qingyang Wu, Clément Maheu, Julia Gallenberger, Chuanmu Tian, Kangle Lv, Jan P. Hofmann

2024Advanced Powder Materials22 citationsDOIOpen Access PDF

Abstract

Hole transfer at the semiconductor-electrolyte interface is a key elementary process in (photo)electrochemical (PEC) water oxidation. However, up to now, a detailed understanding of the hole transfer and the influence of surface hole density on PEC water oxidation kinetics is lacking. In this work, we propose a model for the first time in which the surface accumulated hole density in BiVO 4 and Mo-doped BiVO 4 samples during water oxidation can be acquired via employing illumination-dependent Mott-Schottky measurements. Based on this model, some results are demonstrated as below: (1) Although the surface hole density increases when increasing light intensity and applied potential, the hole transfer rate remains linearly proportional to surface hole density on a log-log scale. (2) Both water oxidation on BiVO 4 and Mo-doped BiVO 4 follow first-order reaction kinetics at low surface hole densities, which is in good agreement with literature. (3) We find that water oxidation active sites in both BiVO 4 and Mo-doped BiVO 4 are very likely to be Bi 5+ , which are produced by photoexcited or/and electro-induced surface holes, rather than VO x species or Mo 6+ due to their insufficient redox potential for water oxidation. (4) Introduction of Mo doping brings about higher OER activity of BiVO 4 , as it suppresses the recombination rate of surface holes and increases formation of Bi 5+ . This surface hole model offers a general approach for the quantification of surface hole density in the field of semiconductor photoelectrocatalysis. A surface hole model is proposed to determine the surface hole density in BiVO 4 photoanodes. Besides, the higher OER activity of Mo-doped BiVO 4 originates from its lower surface hole recombination rate. • A model is proposed to determine the surface accumulated hole density in BiVO 4 and Mo-doped BiVO 4 samples during water oxidation. • Water oxidation on BiVO 4 and Mo-doped BiVO 4 follow first-order reaction kinetics. • The higher OER activity of Mo-doped BiVO 4 originates from its lower surface hole recombination rate.

Topics & Concepts

DopingMaterials scienceChemical engineeringChemistryOptoelectronicsEngineeringAdvanced Photocatalysis TechniquesGas Sensing Nanomaterials and SensorsElectronic and Structural Properties of Oxides
Promoting effect of interfacial hole accumulation on photoelectrochemical water oxidation in BiVO4 and Mo-doped BiVO4 | Litcius