Journal
ENERGY & FUELS
Volume 35, Issue 11, Pages 9623-9634Publisher
AMER CHEMICAL SOC
DOI: 10.1021/acs.energyfuels.1c00179
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Recent research has shown that utilizing a WO3/BiFeO3 n-p heterojunction device for photo-electrochemical water splitting can achieve excellent performance, largely due to the built-in potential at the heterojunction interface and the ferroelectric-assisted photocatalytic behavior of BiFeO3.
Storing sunlight energy in chemical bonds by water splitting or carbon dioxide reduction grabs a vast majority of interest in recent years. The race for improving the photo-electrochemical (PEC) water splitting performance has been raised mostly by investigating heterojunction semiconductors. In this article, the WO3/BiFeO3 n-p heterojunction device is deposited via sol-gel spin coating, and the PEC water splitting of the device is compared to those of each counterpart. The monoclinic-phase WO3 film without any impurity with granular morphology and a band gap of 3.00 eV is synthesized. The BiFeO3 film is also synthesized through three different methods to reach phase purity and a band gap of 2.15 eV. PEC measurements demonstrate that the WO3/BiFeO3 heterojunction reveals an onset potential of 0.25 V and a photocurrent density of 35.2 mA/cm(2) at 2 V versus Ag/AgCl, which is far better than those of individual components. These properties result from not only built-in potential at the interface of the n-p heterojunction but also from abnormal ferroelectric-assisted photocatalytic behavior of BiFeO3 on the surface and from porous morphology of the film. Moreover, the WO3/BiFeO3 represents long-lasting photostability. The n-p heterojunction properly enhances the carrier lifetime by appropriate band alignment formation, confirmed by photoluminescence spectroscopy and electrochemicalspectroscopy.
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