Phase equilibria in the Y–Ba–Fe–O system

“…The phase equilibria in the 1/2Y 2 O 3 –1/2Fe 2 O 3 system were discussed in detail in our recent paper . Two single‐phase complex oxides were confirmed to exist at 1373 K in air: YFeO 3 with the orthorhombically distorted perovskite structure (sp.…”

“…A comparison of 1/2Y 2 O 3 –MO–1/2Fe 2 O 3 phase diagrams for M = Ca and M = Sr (present work) shows that phase equilibria in the Ca‐ and Sr containing systems are generally similar, although the homogeneity ranges of solid solutions are wider for the latter system. In contrast, the substitution of Ba for Sr completely changes the phase equilibria due to the increased size difference between Ba 2+ and Y 3+ ions = 1.61−1.075 = 0.535 Å …”

“…The information concerning small‐sized rare earth‐ or yttrium‐based ferrites is limited, although undoped strontium ferrite and yttrium ferrite have been the objects of wide‐ranging studies as magnetic and membrane materials in the last few decades . The wide variety of specific features of phase formation in the related systems and significant differences in the phase diagrams of these systems require detailed study of each system, in particular Y 2 O 3 –SrO–Fe 2 O 3 .…”

“…Summarizing the aforementioned data, one can conclude that the phase equilibria in the Y 2 O 3 –SrO–Fe 2 O 3 system are unclear, and the available information about the homogeneity range in a Sr x Y 1− x FeO 3−δ solid solution is contradictory (the values of x = 0.25 and 0.5 obtained in [] lie outside of the range 0.71 ≤ x ≤ 0.91 reported in []). Therefore, the aims of present work are: (a) the determination of homogeneity ranges and the crystal structure of the solid solutions formed in the 1/2Y 2 O 3 –SrO–1/2Fe 2 O 3 system; (b) the characterization of oxygen content in the obtained solid solutions and determination of its changes with temperature; (c) the determination of thermal expansion for the obtained solid solutions; (d) establishing the phase equilibria in the 1/2Y 2 O 3 –SrO–1/2Fe 2 O 3 system and a comparison of the obtained phase diagram with the related 1/2Ln 2 O 3 –SrO–1/2Fe 2 O 3 (Ln = Nd, La) and 1/2Y 2 O 3 –MO–1/2Fe 2 O 3 (M = Ca, Ba) systems.…”

Phase equilibria, structure, oxygen nonstoichiometry, and thermal expansion of oxides in the 1/2Y₂O₃–SrO–1/2Fe₂O₃ system

“…The phase equilibria in the 1/2Y 2 O 3 –1/2Fe 2 O 3 system were discussed in detail in our recent paper . Two single‐phase complex oxides were confirmed to exist at 1373 K in air: YFeO 3 with the orthorhombically distorted perovskite structure (sp.…”

“…A comparison of 1/2Y 2 O 3 –MO–1/2Fe 2 O 3 phase diagrams for M = Ca and M = Sr (present work) shows that phase equilibria in the Ca‐ and Sr containing systems are generally similar, although the homogeneity ranges of solid solutions are wider for the latter system. In contrast, the substitution of Ba for Sr completely changes the phase equilibria due to the increased size difference between Ba 2+ and Y 3+ ions = 1.61−1.075 = 0.535 Å …”

“…The information concerning small‐sized rare earth‐ or yttrium‐based ferrites is limited, although undoped strontium ferrite and yttrium ferrite have been the objects of wide‐ranging studies as magnetic and membrane materials in the last few decades . The wide variety of specific features of phase formation in the related systems and significant differences in the phase diagrams of these systems require detailed study of each system, in particular Y 2 O 3 –SrO–Fe 2 O 3 .…”

“…Summarizing the aforementioned data, one can conclude that the phase equilibria in the Y 2 O 3 –SrO–Fe 2 O 3 system are unclear, and the available information about the homogeneity range in a Sr x Y 1− x FeO 3−δ solid solution is contradictory (the values of x = 0.25 and 0.5 obtained in [] lie outside of the range 0.71 ≤ x ≤ 0.91 reported in []). Therefore, the aims of present work are: (a) the determination of homogeneity ranges and the crystal structure of the solid solutions formed in the 1/2Y 2 O 3 –SrO–1/2Fe 2 O 3 system; (b) the characterization of oxygen content in the obtained solid solutions and determination of its changes with temperature; (c) the determination of thermal expansion for the obtained solid solutions; (d) establishing the phase equilibria in the 1/2Y 2 O 3 –SrO–1/2Fe 2 O 3 system and a comparison of the obtained phase diagram with the related 1/2Ln 2 O 3 –SrO–1/2Fe 2 O 3 (Ln = Nd, La) and 1/2Y 2 O 3 –MO–1/2Fe 2 O 3 (M = Ca, Ba) systems.…”

Phase equilibria, structure, oxygen nonstoichiometry, and thermal expansion of oxides in the 1/2Y₂O₃–SrO–1/2Fe₂O₃ system

“…Since earlier Ba 3 SmFe 2 O 7.5 was obtained in argon 31 or in air but at significantly higher temperature, 32 we have checked the possibility for Ba 3 SmFe 2 O 7.5 synthesis at 1100°C in air.…”

Phase equilibria and stability of intermediate phases in the Sm₂O₃–BaO–Fe₂O₃ system

Fluorine-doped barium cobaltite perovskite membrane for oxygen separation and syngas production