期刊
ADVANCED MATERIALS
卷 35, 期 15, 页码 -出版社
WILEY-V C H VERLAG GMBH
DOI: 10.1002/adma.202211182
关键词
bismuth chromates; photocatalysis; semiconductors; water splitting reaction
A novel triclinic-phase bismuth chromate (Bi2CrO6) with wide light-harvesting ranges and suitable band structures has been reported as a promising semiconductor photocatalyst. It exhibits excellent photocatalytic water oxidation and hydrogen production performance under visible light, and can be used to construct a stable visible-light-driven Z-scheme overall water splitting system. This work provides a potential semiconductor material for photocatalytic and photo-electrochemical solar energy conversion with wide-range light harvesting capability.
Photocatalytic water splitting for solar energy conversion remains challenged by the lack of novel semiconductor photocatalysts with paramount parameters including wide light-harvesting ranges and suitable band structures. Here, a novel triclinic-phase bismuth chromate (Bi2CrO6) acting as a semiconductor photocatalyst candidate is reported. Triclinic Bi2CrO6 exhibits a broad absorption range of approximate to 650 nm with a direct bandgap of 1.86 eV and shows a suitable band structure for water splitting. Theoretical simulations of triclinic Bi2CrO6 reveal a high charge mobility, possibly owing to the strong hybridized covalent bonds, large elastic modulus, and small carrier effective mass. The triclinic Bi2CrO6 is demonstrated to work well toward photocatalytic water oxidation and hydrogen production reactions under visible light and match well with its absorption ranges. In particular, it exhibits decent photocatalytic water oxidation performance in the presence of various electron scavengers. Furthermore, the visible-light-driven Z-scheme overall water splitting system is fabricated by coupling triclinic Bi2CrO6 as the oxygen evolution photocatalyst with SrTiO3:Rh as the hydrogen evolution photocatalyst, giving a stable overall water splitting with stoichiometric evolution of H-2 and O-2. This work presents a promising semiconductor material enabling wide-range light harvesting for photocatalytic and photo-electrochemical solar energy conversion.
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