Abstract
Hydrogen generation from renewable energy sources will play a key role in the concerted endeavor to constrain climate change. One environmentally friendly route, powered by sunlight, is the photoelectrochemical water splitting cell (PEC). This technology employs electrodes coated with thin films of semiconductor materials to capture light and generate charge carriers that directly drive the water splitting reaction. Bismuth vanadate is a promising metal oxide semiconductor, as it absorbs visible light, and is abundant, non-toxic and cost-effective. The present study investigates the formation of bismuth vanadate thin films by the aerosol deposition (AD) method. Operating with layer formation at room temperature, AD offers advantages over other routes for the fabrication of photoactive thin film coatings, as no binders or sintering processes need to be applied. Furthermore, compared to traditional cold spraying, micrometer-sized particles can be used, resulting in coatings with thicknesses below 1 µm. Additionally, the lower kinetic energy of the feedstock powder particles enables the use of delicate substrates, such as FTO-coated glass, expanding the range of possible PEC device configurations. The process parameters explored in this study had considerable influence on the resulting coating microstructure, which in turn showed a significant impact on the photoelectrochemical performance.
Highlights
The analysis of world climate data and its correlation to human activity shows that the use of fossil fuels must be reduced drastically in order to restrict emissions of greenhouse gases to a minimum
According to laser scattering analysis, the as-received BiVO4 powder used for aerosol deposition (AD) coatings (AE1) (Fig. 3a) had particle sizes of d10 = 0.4 lm, d50 = 4.0 lm and d90 = 9.1 lm
Both samples were sprayed at the same AD conditions using a 10-mm slit nozzle and a carrier gas flow of 10 l/min as standard parameter set for AD
Summary
The analysis of world climate data and its correlation to human activity shows that the use of fossil fuels must be reduced drastically in order to restrict emissions of greenhouse gases to a minimum. Akedo in the 1990s (Ref 12-14), AD is a solvent-free solid state kinetic spraying method for the deposition of small-sized ceramic particles onto various substrate materials, usually operating at room temperature. At present, it provides solutions for a wide field of applications (Ref [12, 15,16,17]). Fluorine-doped tin oxide (FTO)-coated glass substrates are widely used when investigating material systems for photoelectrochemical applications, since they can be integrated into a wide range of device configurations They can be implemented with backside illumination, which, in the case of electron-transport limited absorbers such as BiVO4, allows more photogenerated electrons to reach the back contact, minimizing recombination losses. During the PEC experiments, the potential was cycled three to five times from the OCP to 1.8 V versus RHE (1.5 V versus RHE with added Na2SO3) and back operating at a scan rate of 25 mVs-1
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