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Paving the road toward the use of β-Fe2O3 in solar water splitting: Raman identification, phase transformation and strategies for phase stabilization

Ningsi Zhang, Xin Wang, Jianyong Feng, Huiting Huang, Yongsheng Guo, Zhaosheng Li, Zhigang Zou

2020National Science Review57 citationsDOIOpen Access PDF

Abstract

Abstract Although β-Fe2O3 has a high theoretical solar-to-hydrogen efficiency because of its narrow band gap, the study of β-Fe2O3 photoanodes for water splitting is elusive as a result of their metastable nature. Raman identification of β-Fe2O3 is theoretically and experimentally investigated in this study for the first time, thus clarifying the debate about its Raman spectrum in the literature. Phase transformation of β-Fe2O3 to α-Fe2O3 was found to potentially take place under laser and electron irradiation as well as annealing. Herein, phase transformation of β-Fe2O3 to α-Fe2O3 was inhibited by introduction of Zr doping, and β-Fe2O3 was found to withstand a higher annealing temperature without any phase transformation. The solar water splitting photocurrent of the Zr-doped β-Fe2O3 photoanode was increased by 500% compared to that of the pure β-Fe2O3 photoanode. Additionally, Zr-doped β-Fe2O3 exhibited very good stability during the process of solar water splitting. These results indicate that by improving its thermal stability, metastable β-Fe2O3 film is a promising photoanode for solar water splitting.

Topics & Concepts

MetastabilityRaman spectroscopyWater splittingMaterials sciencePhotocurrentAnnealing (glass)DopingPhase (matter)Thermal stabilityBand gapOptoelectronicsChemical engineeringChemistryOpticsPhotocatalysisMetallurgyPhysicsEngineeringOrganic chemistryCatalysisBiochemistryIron oxide chemistry and applicationsArsenic contamination and mitigation