posted on 2017-07-21, 00:00authored byDennis
P. Chen, Joerg C. Neuefeind, Kallum M. Koczkur, David L. Bish, Sara E. Skrabalak
(GaN)1–x(ZnO)x (GZNO) is capable of visible-light
driven water splitting,
but its bandgap at x ≤ 0.15 (>2.7 eV) results
in poor visible-light absorption. Unfortunately, methods to narrow
its bandgap by incorporating higher ZnO concentrations are accompanied
by extensive Urbach tailing near the absorption-edge, which is indicative
of structural disorder or chemical inhomogeneities. We evaluated whether
this disorder is intrinsic to the bond-length distribution in GZNO
or is a result of defects introduced from the loss of Zn during nitridation.
Here, the synthesis of GZNO derived from layered double hydroxide
(LDH) precursors is described which minimizes Zn loss and chemical
inhomogeneities and enhances visible-light absorption. The average
and local atomic structures of LDH-derived GZNO were investigated
using X-ray and neutron scattering and are correlated with their oxygen
evolution rates. An isotope-contrasted neutron-scattering experiment
was conducted in conjunction with reverse Monte Carlo (RMC) simulations.
We showed that a bond-valence bias in the RMC refinements reproduces
the short-range ordering (SRO) observed in structure refinements using
isotope-contrasted neutron data. The findings suggest that positional
disorder of cation–anion pairs in GZNO partially arises from
SRO and influences local bond relaxations. Furthermore, particle-based
oxygen evolution reactions (OERs) in AgNO3 solution reveal
that the crystallite size of GZNO correlates more than positional
disorder with oxygen evolution rate. These findings illustrate the
importance of examining the local structure of multinary photocatalysts
to identify dominant factors in particulate-based photodriven oxygen
evolution.