The Defect Chemistry of LaMnO3±δ: 4. Defect Model for LaMnO3+δ

The temperature dependence of the relationship between composition and oxygen partial pressure has been described for \(\mathrm{LaMnO}_{3+\delta}\) and \(\mathrm{LaMnO}_{3-\delta}\) on the basis of an assessment of literature data obtained by TGA by several authors. The thermodynamics of defect form

The density of \(\mathrm{La}_{1-x} A_{x} \mathrm{MnO}_{3+\delta}\) was determined for \(x=0,0.15\), \(0.30(A=\mathrm{Ca}, \mathrm{Sr}, \mathrm{Ba})\) and for \(x=0.50(A=\mathrm{Sr})\) using a pycnometer, defect chemical considerations, lattice parameters, and chemical analyses. The oxygen excess in

\(\mathrm{LaMnO}_{3+\delta}\) samples with \(\mathrm{Mn}^{4+}\) content up to \(50 \%\) have been prepared by different methods. The structure of \(\mathrm{LaMnO}_{3+\delta}\) changes from orthorhombic to cubic (via rhombohedral) with increase in the \(\mathrm{Mn}^{4+}\) content. \(\mathrm{LaMnO}_{3

Rhombohedral LaMnO 3 + d powders were successfully synthesized by annealing gel precursors obtained by a polymerized complex method. The average grain size increases with increasing calcination temperature. The zero-field-cooled (ZFC) and field-cooled (FC) magnetization curves indicate that LaMnO 3