posted on 2014-05-07, 00:00authored byLena Trotochaud, Samantha
L. Young, James K. Ranney, Shannon W. Boettcher
Fe plays a critical,
but not yet understood, role in enhancing
the activity of the Ni-based oxygen evolution reaction (OER) electrocatalysts.
We report electrochemical, in situ electrical, photoelectron
spectroscopy, and X-ray diffraction measurements on Ni1–xFex(OH)2/Ni1–xFexOOH
thin films to investigate the changes in electronic properties, OER
activity, and structure as a result of Fe inclusion. We developed
a simple method for purification of KOH electrolyte that uses precipitated
bulk Ni(OH)2 to absorb Fe impurities. Cyclic voltammetry
on rigorously Fe-free Ni(OH)2/NiOOH reveals new Ni redox
features and no significant OER current until >400 mV overpotential,
different from previous reports which were likely affected by Fe impurities.
We show through controlled crystallization that β-NiOOH is less
active for OER than the disordered γ-NiOOH starting material
and that previous reports of increased activity for β-NiOOH
are due to incorporation of Fe-impurities during the crystallization
process. Through-film in situ conductivity measurements
show a >30-fold increase in film conductivity with Fe addition,
but
this change in conductivity is not sufficient to explain the observed
changes in activity. Measurements of activity as a function of film
thickness on Au and glassy carbon substrates are consistent with the
hypothesis that Fe exerts a partial-charge-transfer activation effect
on Ni, similar to that observed for noble-metal electrode surfaces.
These results have significant implications for the design and study
of Ni1–xFexOOH OER electrocatalysts, which are the fastest measured OER
catalysts under basic conditions.