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Formation of an electron hole doped film in the α-Fe 2O3 photoanode upon electrochemical oxidation
Type of publication
Peer-reviewed
Publikationsform
Original article (peer-reviewed)
Publication date
2013
Author
Gajda-Schrantz Krisztina, Tymen Simon, Boudoire Florent, Toth Rita, Bora Debajeet K., Calvet Wolfram, Grätzel Michaël, Constable Edwin C., Braun Artur,
Project
Fundamental Aspects of Photocatalysis and Photoelectrochemistry / Basic Research Instrumentation for Functional Characterization
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Original article (peer-reviewed)
Journal
Physical Chemistry Chemical Physics
Volume (Issue)
15(5)
Page(s)
1443 - 1451
Title of proceedings
Physical Chemistry Chemical Physics
DOI
10.1039/c2cp42597a
Abstract
Solar hydrogen generation by water splitting in photoelectrochemical cells (PEC) is an appealing technology for a future hydrogen economy. Hematite is a prospective photoanode material in this respect because of its visible light conjugated band gap, its corrosion stability, its environmentally benign nature and its low cost. Its bulk and surface electronic structure has been under scrutiny for many decades and is considered critical for improvement of efficiency. In the present study, hematite films of nominally 500 nm thickness were obtained by dip-coating on fluorine doped tin oxide (FTO) glass slides and then anodised in 1 molar KOH at 500, 600, and 700 mV for 1, 10, 120 and 1440 minutes under dark conditions. X-ray photoelectron spectra recorded at the Fe 3p resonant absorption threshold show that the eg transition before the Fermi energy, which is well developed in the pristine hematite film, becomes depleted upon anodisation. The spectral weight of the eg peak decreases with the square-root of the anodisation time, pointing to a diffusion controlled process. The speed of this process increases with the anodisation potential, pointing to Arrhenius behaviour. Concomitantly, the weakly developed t2g peak intensity becomes enhanced in the same manner. This suggests that the surface of the photoanode contains Fe2+ species which become oxidized toward Fe3+ during anodisation. The kinetic behaviour derived from the experimental data suggests that the anodisation forms an electron hole doped film on and below the hematite surface. © 2013 the Owner Societies.
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