TY - JOUR
T1 - Hexagonal perovskite related oxide ion conductor Ba3NbMoO8.5
T2 - phase transition, temperature evolution of the local structure and properties
AU - Chambers, Matthew S.
AU - McCombie, Kirstie S.
AU - Auckett, Josie E.
AU - McLaughlin, Abbie C.
AU - Irvine, John T. S.
AU - Chater, Philip A.
AU - Evans, John S. O.
AU - Evans, Ivana Radosavljevic
N1 - M. S. C. thanks Diamond Light Source and Durham University for a PhD studentship. I. R. E. acknowledges the Royal Society and the Leverhulme Trust for the award of a Senior Research Fellowship (SRF\R1\180040). J. E. A. acknowledges the support of a Newton International Fellowship (NF170809) awarded by The Royal Society.
PY - 2019/11/28
Y1 - 2019/11/28
N2 - Ba3NbMoO8.5 has
recently been demonstrated to exhibit competitive oxide ion conductivity
and to be stable under reducing conditions, making it an excellent
potential electrolyte for solid oxide fuel cells. We report here the
first investigation of the local structure in Ba3NbMoO8.5,
carried out using variable-temperature neutron total scattering and
pair distribution function (PDF) analysis. This work reveals a
significant degree of disorder in the material, even at ambient
conditions, in both the cation and the anion arrangements and suggests
the prevalence of the five-fold Nb/Mo coordination. In addition, high
resolution powder X-ray diffraction data indicate that the
temperature-dependent structural changes in Ba3NbMoO8.5
are due to a first order phase transition, and reveal a previously
unreported effect of thermal history on the room-temperature form of the
material. PDF modelling shows that Ba3NbMoO8.5 has an essentially continuous oxygen distribution in the ab plane at 600 °C which leads to its high oxide-ion conductivity.
AB - Ba3NbMoO8.5 has
recently been demonstrated to exhibit competitive oxide ion conductivity
and to be stable under reducing conditions, making it an excellent
potential electrolyte for solid oxide fuel cells. We report here the
first investigation of the local structure in Ba3NbMoO8.5,
carried out using variable-temperature neutron total scattering and
pair distribution function (PDF) analysis. This work reveals a
significant degree of disorder in the material, even at ambient
conditions, in both the cation and the anion arrangements and suggests
the prevalence of the five-fold Nb/Mo coordination. In addition, high
resolution powder X-ray diffraction data indicate that the
temperature-dependent structural changes in Ba3NbMoO8.5
are due to a first order phase transition, and reveal a previously
unreported effect of thermal history on the room-temperature form of the
material. PDF modelling shows that Ba3NbMoO8.5 has an essentially continuous oxygen distribution in the ab plane at 600 °C which leads to its high oxide-ion conductivity.
U2 - 10.1039/C9TA08378B
DO - 10.1039/C9TA08378B
M3 - Article
SN - 0959-9428
VL - 7
SP - 25503
EP - 25510
JO - Journal of Materials Chemistry
JF - Journal of Materials Chemistry
IS - 44
ER -