Aerosol Deposition of CuFeO2 Photocathode Coatings for Hydrogen Production

IF 3.2 3区材料科学 Q2 MATERIALS SCIENCE, COATINGS & FILMS Journal of Thermal Spray Technology Pub Date : 2024-07-02 DOI:10.1007/s11666-024-01798-0

Alessia Bruera, Andreas Elsenberg, Mauro Borghi, Giulia Dolcetti, Giovanni Bolelli, Frank Gärtner, Mauricio Schieda, Thomas Klassen, Luca Lusvarghi

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Abstract

Photoelectrochemical (PEC) water splitting is a viable route for green hydrogen generation. In PEC cells, the electrodes are coated with suitable semiconductor materials, which absorb the sunlight, generating charge carriers that are used to split water molecules into H₂ and O₂. CuFeO₂ is one promising photocathode material for water splitting. However, its performance is limited by electron/hole pairs recombination within the film and at the film/substrate interface. Aerosol deposition (AD) can be employed to minimize charge recombination by spraying dense, thin films and by establishing a good back-contact interface. In this study, CuFeO₂ powders were synthesized through a conventional solid-state technique and sprayed by AD under varied parameter sets. The effect of particle size distributions, carrier gas, gas pressure and substrate temperature was investigated. The best spraying parameter set was then tuned to obtain thin coatings (< 1 µm). Single-particle deformation and coatings microstructure were investigated by scanning electron microscopy. Optical properties of CuFeO₂ films were analyzed by UV–Vis spectroscopy, while photoelectrochemical performances were estimated through amperometry tests under simulated sunlight. The results of this research show that CuFeO₂ photocathodes can be successfully manufactured by AD. Their performance can be optimized by adjusting coating thickness and by annealing in air.

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气溶胶沉积用于制氢的 CuFeO2 光阴极涂层

光电化学（PEC）水分裂是一种可行的绿色制氢方法。在光电化学电池中，电极上涂有合适的半导体材料，这些材料吸收太阳光，产生电荷载流子，用于将水分子分裂成 H2 和 O2。CuFeO2 是一种很有前途的水分裂光电阴极材料。然而，其性能受到薄膜内部和薄膜/基底界面上电子/空穴对重组的限制。气溶胶沉积（AD）可通过喷涂致密的薄膜和建立良好的背接触界面来最大限度地减少电荷重组。本研究采用传统固态技术合成了 CuFeO2 粉末，并在不同参数设置下通过 AD 进行喷涂。研究了粒度分布、载气、气体压力和基底温度的影响。然后调整最佳喷涂参数集，以获得薄涂层（< 1 µm）。通过扫描电子显微镜研究了单颗粒变形和涂层的微观结构。紫外可见光谱分析了 CuFeO2 薄膜的光学特性，模拟阳光下的安培测试则评估了其光电化学性能。研究结果表明，CuFeO2 光电阴极可通过 AD 成功制造。通过调整涂层厚度和在空气中退火，可以优化它们的性能。

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来源期刊

Journal of Thermal Spray Technology 工程技术-材料科学：膜

CiteScore

5.20

自引率

25.80%

发文量

198

审稿时长

2.6 months

期刊介绍： From the scientific to the practical, stay on top of advances in this fast-growing coating technology with ASM International''s Journal of Thermal Spray Technology. Critically reviewed scientific papers and engineering articles combine the best of new research with the latest applications and problem solving. A service of the ASM Thermal Spray Society (TSS), the Journal of Thermal Spray Technology covers all fundamental and practical aspects of thermal spray science, including processes, feedstock manufacture, and testing and characterization. The journal contains worldwide coverage of the latest research, products, equipment and process developments, and includes technical note case studies from real-time applications and in-depth topical reviews.