posted on 2012-01-18, 00:00authored byCharles
Y. Cummings, Frank Marken, Laurence M. Peter, K. G. Upul Wijayantha, Asif A. Tahir
Thin mesoporous films of α-Fe2O3 have
been prepared on conducting glass substrates using layer-by-layer
self-assembly of ca. 4 nm hydrous oxide nanoparticles followed by
calcining. The electrodes were used to study the oxygen evolution
reaction (OER) in the dark and under illumination using in situ potential-modulated
absorption spectroscopy (PMAS) and light-modulated absorption spectroscopy
(LMAS) combined with impedance spectroscopy. Formation of surface-bound
higher-valent iron species (or “surface trapped holes”)
was deduced from the PMAS spectra measured in the OER onset region.
Similar LMAS spectra were obtained at more negative potentials in
the onset region of photoelectrochemical OER, indicating involvement
of the same intermediates. The impedance response of the mesoporous
α-Fe2O3 electrodes exhibits characteristic
transmission line behavior that is attributed to slow hopping of holes,
probably between surface iron species. Frequency-resolved PMAS and
LMAS measurements revealed slow relaxation behavior that can be related
to the impedance response and that indicates that the lifetime of
the intermediates (or trapped holes) involved in the OER is remarkably
long.