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DOI: 10.1039/A703731G (Paper) Reference Section for: J. Mater. Chem., 1997, 7, 2513-2517

Oxidation mechanism and valence states of copper and manganese in tetragonal CuMn2O4

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Bernard Gillot, Stephane Buguet and Etienne Kester

Abstract

With the view of determining the ionic configuration in tetragonal CuMn2O4 spinels prepared between 850 and 930 °C, the valence states of copper and manganese and the oxidation mechanism of these compounds have been determined by XPS, FTIR spectroscopy analyses and DTG measurements. For unoxidized samples, XPS spectroscopy analysis shows a predominately monovalent copper located in tetrahedral sites. Divalent copper in octahedral sites is also present, but at a lower level. Similar results are obtained for oxidized samples. FTIR data, upon oxidation of Cu and Mn ions below 500 °C, confirm the formation of a metastable spinel phase Cu1.5Mn1.5O4 with a 1:3 ordering on the octahedral sublattice. A quantitative analysis by DTG mainly based on the difference of reactivity of Cu and Mn ions allows measurement of the content of each cation and determination of the ionic configuration.

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