Reactive co-sputter deposition of Ta-doped tungsten oxide thin films for water splitting application

Reactive co-sputter deposition of Ta-doped tungsten oxide thin films for water splitting application

Abstract This study aimed to investigate the structural, optical, and electronic properties of WO3 thin films modified by Ta-doping, considering their potential application in photoelectrochemical (PEC) water splitting. Due to its unique physical and chemical properties, WO3 films have been commonly...

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Bibliographic Details
Main Authors: Samaneh Jafarpour, Hamid Naghshara
Format: Article
Language:English
Published: Nature Portfolio 2025-03-01
Series:Scientific Reports
Subjects:
WO3
Ta-doping
Photoelectrochemical water splitting
Bandgap
Co-sputtering
Photocurrent
Online Access:https://doi.org/10.1038/s41598-025-92008-6
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Summary:Abstract This study aimed to investigate the structural, optical, and electronic properties of WO3 thin films modified by Ta-doping, considering their potential application in photoelectrochemical (PEC) water splitting. Due to its unique physical and chemical properties, WO3 films have been commonly suggested as a promising photoanode for hydrogen production. However, the wide bandgap and unsuitable band edge positions of WO3 limit its PEC efficiency. Doping have been extensively applied as an effective strategy for bandgap engineering. Here, post-annealed WO3 films with different concentrations of Ta dopant were synthesized via reactive magnetron co-sputtering, while DC and RF sputtering powers were varied with the aim of achieving the desired properties. EDX analysis showed that Ta atoms were doped into WO3 in the range of 0–3.93 at%. As evident from SEM and AFM images, the surface morphology was significantly affected by increasing Ta doping, the formation of a granular structure with well-defined boundaries and increasing surface roughness (1.79–47.94 nm). XRD patterns confirmed that the incorporation of Ta atoms into a monoclinic WO3 improved the crystallinity, especially in the (002) direction. Most importantly, a decrease in the average transparency (92.82–74.27%), an increase in visible absorption, a red shift of the fundamental absorption edge corresponding to a favorable drop in the optical bandgap energy (3.07–2.61 eV) were found with increasing Ta concentration. Notably, the substitution of W6+ ions with Ta dopant (0–3.93 at%) led to an upward shift in the valence band maximum (3.62–3.31 eV) and a downward shift in the conduction band minimum (0.55–0.70 eV). The WO3 photoanode doped with 3.93 at% Ta exhibited the maximum photocurrent density of 0.65 mA/cm2 (at 1 V vs. Ag/AgCl) under simulated sunlight. Furthermore, WO3 photoanode doped with 3.93 at% Ta showed excellent photoresponsivity and slow electron–hole recombination. The obtained results predict the potential of Ta-doping coupled with post-annealing to optimize the structural and optoelectronic properties of sputtered WO3 thin films as photoanode for use in efficient PEC water splitting.
ISSN:2045-2322

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