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Main Authors: Wang, Ligen, Burkmann, Konrad, Ushakov, Sergey V., Wang, Edric X., Matteucci, Jared, Scheuermann, Mara, Melnitschuk, Erik, Glaum, Robert, Xu, Hongwu, Opila, Elizabeth J., Navrotsky, Alexandra, Hong, Qi-Jun
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2510.16654
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author Wang, Ligen
Burkmann, Konrad
Ushakov, Sergey V.
Wang, Edric X.
Matteucci, Jared
Scheuermann, Mara
Melnitschuk, Erik
Glaum, Robert
Xu, Hongwu
Opila, Elizabeth J.
Navrotsky, Alexandra
Hong, Qi-Jun
author_facet Wang, Ligen
Burkmann, Konrad
Ushakov, Sergey V.
Wang, Edric X.
Matteucci, Jared
Scheuermann, Mara
Melnitschuk, Erik
Glaum, Robert
Xu, Hongwu
Opila, Elizabeth J.
Navrotsky, Alexandra
Hong, Qi-Jun
contents Rare earth oxide-phosphates (REOPs) form a largely unexplored family of refractory lanthanides and yttrium compounds with general formula RExOy(PO4)z. They are of interest for applications ranging from thermal barrier coatings to catalysts and magnetic materials. At least four REOPs phases were experimentally identified with RE/P ratios from 7:3 to 6:1, however the structures were solved only for 3:1 phases (RE3O3(PO4)). In this work we report the structure for the 7:3 phases (RE7O6(PO4)3) derived by ab initio analysis of models based on previously reported oxide-vanadate analogues. The most stable structures for all 7:3 REOPs were found to be isotypic, adopting monoclinic symmetry with space group P21/c. The structures were validated by comparison of their powder X-ray diffraction patterns to those of synthesized La, Pr, Nd, Sm, Eu, Gd and Tb 7:3 phases (Rietveld refinement for all except Tb). Ab initio analysis of thermodynamic stability showed that all 7:3 REOPs are unstable at 0 K toward decomposition to REPO4 and RE3PO7 or RE2O3. The entropy contribution stabilizes RE7O6(PO4)3 phases for light rare earth elements above 1000 K, however, starting with Dy, computationally predicted stabilization temperature is higher than estimated melting points of RE7O6(PO4)3, which is consistent with observed synthesis pattern.
format Preprint
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institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Structure and stability of 7:3 rare earth oxide-phosphates: a combined ab initio and experimental study
Wang, Ligen
Burkmann, Konrad
Ushakov, Sergey V.
Wang, Edric X.
Matteucci, Jared
Scheuermann, Mara
Melnitschuk, Erik
Glaum, Robert
Xu, Hongwu
Opila, Elizabeth J.
Navrotsky, Alexandra
Hong, Qi-Jun
Materials Science
Rare earth oxide-phosphates (REOPs) form a largely unexplored family of refractory lanthanides and yttrium compounds with general formula RExOy(PO4)z. They are of interest for applications ranging from thermal barrier coatings to catalysts and magnetic materials. At least four REOPs phases were experimentally identified with RE/P ratios from 7:3 to 6:1, however the structures were solved only for 3:1 phases (RE3O3(PO4)). In this work we report the structure for the 7:3 phases (RE7O6(PO4)3) derived by ab initio analysis of models based on previously reported oxide-vanadate analogues. The most stable structures for all 7:3 REOPs were found to be isotypic, adopting monoclinic symmetry with space group P21/c. The structures were validated by comparison of their powder X-ray diffraction patterns to those of synthesized La, Pr, Nd, Sm, Eu, Gd and Tb 7:3 phases (Rietveld refinement for all except Tb). Ab initio analysis of thermodynamic stability showed that all 7:3 REOPs are unstable at 0 K toward decomposition to REPO4 and RE3PO7 or RE2O3. The entropy contribution stabilizes RE7O6(PO4)3 phases for light rare earth elements above 1000 K, however, starting with Dy, computationally predicted stabilization temperature is higher than estimated melting points of RE7O6(PO4)3, which is consistent with observed synthesis pattern.
title Structure and stability of 7:3 rare earth oxide-phosphates: a combined ab initio and experimental study
topic Materials Science
url https://arxiv.org/abs/2510.16654