Epitaxial crystals of Bi2Pt2O7 pyrochlore through the transformation of δ –Bi2O3 fluorite

Bi2Pt2O7 pyrochlore is thought to be one of the most promising oxide catalysts for application in fuel cell technology. Unfortunately, direct film growth of Bi2Pt2O7 has not yet been achieved, owing to the difficulty of oxidizing platinum metal in the precursor material to Pt4+. In this work, in ord...

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Bibliographic Details
Published in:APL materials 2015-03, Vol.3 (3), p.036105-036105-6
Main Authors: Gutiérrez–Llorente, Araceli, Joress, Howie, Woll, Arthur, Holtz, Megan E., Ward, Matthew J., Sullivan, Matthew C., Muller, David A., Brock, Joel D.
Format: Article
Language:English
Subjects:
30 DIRECT ENERGY CONVERSION
MATERIALS SCIENCE
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Summary:Bi2Pt2O7 pyrochlore is thought to be one of the most promising oxide catalysts for application in fuel cell technology. Unfortunately, direct film growth of Bi2Pt2O7 has not yet been achieved, owing to the difficulty of oxidizing platinum metal in the precursor material to Pt4+. In this work, in order to induce oxidation of the platinum, we annealed pulsed laser deposited films consisting of epitaxial δ–Bi2O3 and co-deposited, comparatively disordered platinum. We present synchrotron x-ray diffraction results that show the nonuniform annealed films contain the first epitaxial crystals of Bi2Pt2O7. We also visualized the pyrochlore structure by scanning transmission electron microscopy, and observed ordered cation vacancies in the epitaxial crystals formed in a bismuth-rich film but not in those formed in a platinum-rich film. The similarity between the δ–Bi2O3 and Bi2Pt2O7 structures appears to facilitate the pyrochlore formation. These results provide the only route to date for the formation of epitaxial Bi2Pt2O7.
ISSN:2166-532X
2166-532X
DOI:10.1063/1.4908103