ZnO nanowire arrays with <i>in situ</i> sequentially self-assembled vertically oriented CdS nanosheets as superior photoanodes for photoelectrochemical water splitting

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Abstract

High-density CdS nanosheets were vertically self-assembled on ZnO nanowire arrays, forming a photoanode with superior performance toward water splitting.

Abstract

The performance of photoelectrochemical (PEC) water splitting, a highly promising strategy for solar to hydrogen energy conversion, is greatly restricted by the photoanode reaction. For the first time, high-density CdS nanosheets have been in situ grown on ZnO nanowire arrays with a vertical orientation via a sequential self-assembly approach. The obtained hierarchical and hybrid nanostructured array delivers a photocurrent density of 9.10 mA cm ⁻² at 1.23 V ( versus the reversible hydrogen electrode) and a maximum photoconversion efficiency of 3.72%, both of which are among the highest reported for ZnO-based photoanodes. The superior PEC performance is primarily due to the CdS nanosheet layer greatly increasing visible light absorption, enhancing charge separation, and facilitating charge transfer and transport. This work not only develops a facile, mild, and economical strategy to in situ self-assemble quantum NSs on ZnO NWAs for application as high-performance photoanodes toward PEC water splitting, but also sheds light on the mechanisms for both the formation and the performance enhancement of ZnO NWAs assembled with vertically oriented CdS NSs.

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CdS-Based photocatalysts

Lei Cheng, Quanjun Xiang, Yulong Liao … (2018)

The review summarizes the recent progress in the synthesis, fundamental properties, morphology, photocatalytic applications and challenges of CdS-based photocatalysts. To solve the problem of the global energy shortage and the pollution of the environment, in recent years, semiconductor photocatalytic technology that converts solar energy into chemical fuel has been widely studied. Regarding semiconductor-based photocatalysts, CdS has attracted extensive attention due to its relatively narrow bandgap for visible-light response and sufficiently negative potential of the conduction band edge for the reduction of protons. Studies have shown that CdS-based photocatalysts possess excellent photocatalytic performance in terms of solar-fuel generation and environmental purification. This critical review presents the recent advances and progress in the design and synthesis of various CdS and CdS-based photocatalysts. The basic physical and chemical properties of CdS and the related growth mechanism have been briefly summarized. Moreover, the applications of CdS-based photocatalysts have been discussed such as in photocatalytic hydrogen production, reduction of CO 2 to hydrocarbon fuels and degradation of pollutants. Finally, a brief perspective on the challenges and future directions for the development of CdS and CdS-based photocatalysts are also presented.