Phase Stability Behaviour of Rare Earth Orthovanadates under High Pressure

Rare earth-doped ceria thin films are currently thoroughly studied to be used in miniaturized solid oxide cells, memristive devices and gas sensors. The employment in such different application fields derives from the most remarkable property of this material, namely ionic conductivity, occurring through the mobility of oxygen ions above a certain threshold temperature. This feature is in turn limited by the association of defects, which hinders the movement of ions through the lattice. In addition to these issues, ionic conductivity in thin films is dominated by the presence of the film/substrate interface, where a strain can arise as a consequence of lattice mismatch. A tensile strain, in particular, when not released through the occurrence of dislocations, enhances ionic conduction through the reduction of activation energy. Within this complex framework, high pressure X-ray diffraction investigations performed on the bulk material are of great help in estimating the bulk modulus of the material, and hence its compressibility, namely its tolerance toward the application of a compressive/tensile stress. In this review, an overview is given about the correlation between structure and transport properties in rare earth-doped ceria films, and the role of high pressure X-ray diffraction studies in the selection of the most proper compositions for the design of thin films.

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High-pressure synthesis of REB5O8(OH)2 (RE = Ho, Er, Tm)

Zeitschrift für Naturforschung B ◽

10.1515/znb-2020-0180 ◽

2020 ◽

Vol 0 (0) ◽

Author(s):

Michael Zoller ◽

Hubert Huppertz

Keyword(s):

High Pressure ◽

Rare Earth ◽

Ir Spectroscopy ◽

Earth Metal ◽

Monoclinic Space Group ◽

X Ray Diffraction ◽

X Ray ◽

Structure Solution ◽

Pressure Synthesis ◽

The Rare Earth

AbstractThe rare earth oxoborates REB5O8(OH)2 (RE = Ho, Er, Tm) were synthesized in a Walker-type multianvil apparatus at a pressure of 2.5 GPa and a temperature of 673 K. Single-crystal X-ray diffraction data provided the basis for the structure solution and refinement. The compounds crystallize in the monoclinic space group C2 (no. 5) and are composed of a layer-like structure containing dreier and sechser rings of corner sharing [BO4]5− tetrahedra. The rare earth metal cations are coordinated between two adjacent sechser rings. Further characterization was performed utilizing IR spectroscopy.

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High pressure phase transition and elastic properties of covalent heavy rare-earth Antimonides

Journal of Molecular Modeling ◽

10.1007/s00894-011-0980-0 ◽

2011 ◽

Vol 17 (12) ◽

pp. 3057-3062 ◽

Cited By ~ 1

Author(s):

Purvee Bhardwaj ◽

Sadhna Singh

Keyword(s):

Phase Transition ◽

High Pressure ◽

Rare Earth ◽

Elastic Properties ◽

High Pressure Phase ◽

Heavy Rare Earth ◽

High Pressure Phase Transition ◽

Pressure Phase

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Phase Stability of Iron Nitride Fe4N at High Pressure—Pressure-Dependent Evolution of Phase Equilibria in the Fe–N System

Materials ◽

10.3390/ma14143963 ◽

2021 ◽

Vol 14 (14) ◽

pp. 3963

Author(s):

Marius Holger Wetzel ◽

Tina Trixy Rabending ◽

Martin Friák ◽

Monika Všianská ◽

Mojmír Šob ◽

...

Keyword(s):

High Pressure ◽

Phase Equilibria ◽

Phase Stability ◽

Polymorphic Transition ◽

Ex Situ ◽

Stable Phase ◽

Iron Nitride ◽

Phase System ◽

Target Composition ◽

Heat Treated

Although the general instability of the iron nitride γ′-Fe4N with respect to other phases at high pressure is well established, the actual type of phase transitions and equilibrium conditions of their occurrence are, as of yet, poorly investigated. In the present study, samples of γ′-Fe4N and mixtures of α Fe and γ′-Fe4N powders have been heat-treated at temperatures between 250 and 1000 °C and pressures between 2 and 8 GPa in a multi-anvil press, in order to investigate phase equilibria involving the γ′ phase. Samples heat-treated at high-pressure conditions, were quenched, subsequently decompressed, and then analysed ex situ. Microstructure analysis is used to derive implications on the phase transformations during the heat treatments. Further, it is confirmed that the Fe–N phases in the target composition range are quenchable. Thus, phase proportions and chemical composition of the phases, determined from ex situ X-ray diffraction data, allowed conclusions about the phase equilibria at high-pressure conditions. Further, evidence for the low-temperature eutectoid decomposition γ′→α+ε′ is presented for the first time. From the observed equilibria, a P–T projection of the univariant equilibria in the Fe-rich portion of the Fe–N system is derived, which features a quadruple point at 5 GPa and 375 °C, above which γ′-Fe4N is thermodynamically unstable. The experimental work is supplemented by ab initio calculations in order to discuss the relative phase stability and energy landscape in the Fe–N system, from the ground state to conditions accessible in the multi-anvil experiments. It is concluded that γ′-Fe4N, which is unstable with respect to other phases at 0 K (at any pressure), has to be entropically stabilised in order to occur as stable phase system. In view of the frequently reported metastable retention of the γ′ phase during room temperature compression experiments, energetic and kinetic aspects of the polymorphic transition γ′⇌ε′ are discussed.

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