Haschke S, Zhuo Y, Schlicht S, Barr M, Kloth R, Dufond ME, Santinacci L, Bachmann J (2019)
Publication Type: Journal article, Original article
Publication year: 2019
Book Volume: 6
Article Number: 1801432
Journal Issue: 3
A conductive SnO2 layer and small quantities of IrO2 surface cocatalyst enhance the catalytic efficiency of nanoporous Fe2O3 electrodes in the oxygen evolution reaction at neutral pH. Anodic alumina templates are therefore coated with thin layers of SnO2, Fe2O3, and IrO2 by atomic layer deposition. In the first step, the Fe2O3 electrode is modified with a conductive SnO2 layer and submitted to different postdeposition thermal treatments in order to maximize its catalytic performance. The combination of steady-state electrolysis, electrochemical impedance spectroscopy, X-ray crystallography, and X-ray photoelectron spectroscopy demonstrates that catalytic turnover and e(-) extraction are most efficient if both layers are amorphous in nature. In the second step, small quantities of IrO2 with extremely low iridium loading of 7.5 mu g cm(-2) are coated on the electrode surface. These electrodes reveal favorable long-term stability over at least 15 h and achieve maximized steady-state current densities of 0.57 +/- 0.05 mA cm(-2) at eta = 0.38 V and pH 7 (1.36 +/- 0.10 mA cm(-2) at eta = 0.48 V) in dark conditions. This architecture enables charge carrier separation and reduces the photoelectrochemical water oxidation onset by 300 mV with respect to pure Fe2O3 electrodes of identical geometry.
APA:
Haschke, S., Zhuo, Y., Schlicht, S., Barr, M., Kloth, R., Dufond, M.E.,... Bachmann, J. (2019). Enhanced Oxygen Evolution Reaction Activity of Nanoporous SnO2/Fe2O3/IrO2 Thin Film Composite Electrodes with Ultralow Noble Metal Loading. Advanced Materials Interfaces, 6(3). https://doi.org/10.1002/admi.201801432
MLA:
Haschke, Sandra, et al. "Enhanced Oxygen Evolution Reaction Activity of Nanoporous SnO2/Fe2O3/IrO2 Thin Film Composite Electrodes with Ultralow Noble Metal Loading." Advanced Materials Interfaces 6.3 (2019).
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