Lattice Disorder and Oxygen Migration Pathways in Pyrochlore and Defect-Fluorite Oxides

Frederick P. Marlton, Zhaoming Zhang, Yuanpeng Zhang, Thomas E. Proffen, Chris D. Ling, Brendan J. Kennedy

Research output: Contribution to journalArticlepeer-review

33 Scopus citations

Abstract

Atomic-scale disorder plays an important role in the chemical and physical properties of oxide materials. The structural flexibility of pyrochlore-type oxides allows for crystal-chemical engineering of these properties. Compositional modification can push pyrochlore oxides toward a disordered defect-fluorite structure with anion Frenkel pair defects that facilitate oxygen migration. The local structure of the long-range average cubic defect-fluorite was recently claimed to consist of randomly arranged orthorhombic weberite-type domains. In this work, we show, using low-temperature neutron total-scattering experiments, that this is not the case for Zr-rich defect-fluorites. By analyzing data from the pyrochlore/defect-fluorite Y2Sn2-xZrxO7 series using a combination of neutron pair distribution function and big-box modelling, we have differentiated and quantified the relationship between anion sub-lattice disorder and Frenkel defects. These details directly influence the energy landscape for oxygen migration and are crucial for simulations and design of new materials with improved properties.

Original languageEnglish
Pages (from-to)1407-1415
Number of pages9
JournalChemistry of Materials
Volume33
Issue number4
DOIs
StatePublished - Feb 23 2021

Funding

F.P.M., C.D.L., and B.J.K. acknowledge financial support from the Australian Research Council Discovery Project DP190101862.

FundersFunder number
Australian Research CouncilDP190101862

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