Abstract
In this study, Bi2S3 sensitive layer has been grown on the surface of WO3 nanoplate arrays via an in situ approach. The characterization of samples were carried out using scanning electron microscopy (SEM), transmission electron microscopy (TEM), X-ray diffraction (XRD) and ultraviolet–visible absorption spectroscopy (UV-vis). The results show that the Bi2S3 layer is uniformly formed on the surface of WO3 nanoplates and less interfacial defects were observed in the interface between the Bi2S3 and WO3. More importantly, the Bi2S3/WO3 films as photoanodes for photoelectrochemical (PEC) cells display the enhanced PEC performance compared with the Bi2S3/WO3 films prepared by a sequential ionic layer adsorption reaction (SILAR) method. In order to understand the reason for the enhanced PEC properties, the electron transport properties of the photoelectrodes were studied by using the transient photocurrent spectroscopy and intensity modulated photocurrent spectroscopy (IMPS). The Bi2S3/WO3 films prepared via an in situ approach have a greater transient time constant and higher electron transit rate. This is most likely due to less interfacial defects for the Bi2S3/WO3 films prepared via an in situ approach, resulting in a lower resistance and faster carrier transport in the interface between WO3 and Bi2S3.
Highlights
The limited supply of energy and global climate change caused by burning fossil fuels are two serious challenges faced by humans in the future
The Bi2WO6 was formed on WO3 nanoplate by a simple soaking and calcined process
The S2− can be generated by the decomposition of thiourea, and the Bi2WO6 will react with the S2− to form the Bi2S3 on the surface of WO3 nanoplates[53]
Summary
The depiction of the fabrication process for Bi2S3/WO3 films by in-situ growth method and surface morphology change of sample for each step are shown in Figs 1 and 2, respectively. The Bi2S3/WO3 prepared films by in-situ growth method were denoted as i-Bi2S3/WO3 photoelectrodes Their PEC performances were recorded in the same condition. The average transient time constant (τt) of photoelectrodes can be calculated and obtained from the transient photocurrent plots by using the kinetic equations as follows[58,59,60,61]: D
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