Wüstite (Fe1−xO) – Thermodynamics and crystal growth

Maki Hamada; Steffen Ganschow; Detlef Klimm; George Serghiou; Hans-Josef Reichmann; Matthias Bickermann

doi:10.1515/znb-2022-0071

Wüstite (Fe1−xO) – Thermodynamics and crystal growth

Maki Hamada, Steffen Ganschow^*, Detlef Klimm, George Serghiou, Hans-Josef Reichmann, Matthias Bickermann

^*Corresponding author for this work

School of Engineering

Research output: Contribution to journal › Article › peer-review

Abstract

Iron(II) oxide, wüstite, is the iron oxide with the lowest oxygen content. Under ambient conditions it is metastable for two reasons: (1) it undergoes eutectoid decomposition to Fe and Fe3O4 below ≈570° C, and (2) depending on temperature, it is thermodynamically stable only for very low oxygen partial pressures, down to below 10−20 bar. Hence, for the growth of single crystals from the melt, the growth atmosphere must contain reducing components to keep the oxygen partial pressure on the required low level. With Ar/CO2/CO mixtures this aim can be reached. It is shown experimentally and by thermodynamic calculation, that the grown crystals contain carbon inclusions. Theoretically it is shown that wüstite crystals without carbon inclusions could be grown in humid N2/H2 mixtures. First experiments are presented in this article, but a further adjustment of experimental parameters is required.

Original language	English
Pages (from-to)	463-468
Number of pages	6
Journal	Zeitschrift fur naturforschung section b-A journal of chemical sciences
Volume	77
Issue number	6
Early online date	25 May 2022
DOIs	https://doi.org/10.1515/znb-2022-0071
Publication status	Published - 27 Jun 2022

Keywords / Materials (for Non-textual outputs)

crystal growth
inclusions
iron oxide
thermodynamic equilibrium

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title = "W{\"u}stite (Fe1−xO) – Thermodynamics and crystal growth",

abstract = "Iron(II) oxide, w{\"u}stite, is the iron oxide with the lowest oxygen content. Under ambient conditions it is metastable for two reasons: (1) it undergoes eutectoid decomposition to Fe and Fe3O4 below ≈570° C, and (2) depending on temperature, it is thermodynamically stable only for very low oxygen partial pressures, down to below 10−20 bar. Hence, for the growth of single crystals from the melt, the growth atmosphere must contain reducing components to keep the oxygen partial pressure on the required low level. With Ar/CO2/CO mixtures this aim can be reached. It is shown experimentally and by thermodynamic calculation, that the grown crystals contain carbon inclusions. Theoretically it is shown that w{\"u}stite crystals without carbon inclusions could be grown in humid N2/H2 mixtures. First experiments are presented in this article, but a further adjustment of experimental parameters is required.",

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T1 - Wüstite (Fe1−xO) – Thermodynamics and crystal growth

AU - Hamada, Maki

AU - Ganschow, Steffen

AU - Klimm, Detlef

AU - Serghiou, George

AU - Reichmann, Hans-Josef

AU - Bickermann, Matthias

PY - 2022/6/27

Y1 - 2022/6/27

N2 - Iron(II) oxide, wüstite, is the iron oxide with the lowest oxygen content. Under ambient conditions it is metastable for two reasons: (1) it undergoes eutectoid decomposition to Fe and Fe3O4 below ≈570° C, and (2) depending on temperature, it is thermodynamically stable only for very low oxygen partial pressures, down to below 10−20 bar. Hence, for the growth of single crystals from the melt, the growth atmosphere must contain reducing components to keep the oxygen partial pressure on the required low level. With Ar/CO2/CO mixtures this aim can be reached. It is shown experimentally and by thermodynamic calculation, that the grown crystals contain carbon inclusions. Theoretically it is shown that wüstite crystals without carbon inclusions could be grown in humid N2/H2 mixtures. First experiments are presented in this article, but a further adjustment of experimental parameters is required.

AB - Iron(II) oxide, wüstite, is the iron oxide with the lowest oxygen content. Under ambient conditions it is metastable for two reasons: (1) it undergoes eutectoid decomposition to Fe and Fe3O4 below ≈570° C, and (2) depending on temperature, it is thermodynamically stable only for very low oxygen partial pressures, down to below 10−20 bar. Hence, for the growth of single crystals from the melt, the growth atmosphere must contain reducing components to keep the oxygen partial pressure on the required low level. With Ar/CO2/CO mixtures this aim can be reached. It is shown experimentally and by thermodynamic calculation, that the grown crystals contain carbon inclusions. Theoretically it is shown that wüstite crystals without carbon inclusions could be grown in humid N2/H2 mixtures. First experiments are presented in this article, but a further adjustment of experimental parameters is required.

KW - crystal growth

KW - inclusions

KW - iron oxide

KW - thermodynamic equilibrium

U2 - 10.1515/znb-2022-0071

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SN - 0932-0776

VL - 77

SP - 463

EP - 468

JO - Zeitschrift fur naturforschung section b-A journal of chemical sciences

JF - Zeitschrift fur naturforschung section b-A journal of chemical sciences

IS - 6

ER -

Wüstite (Fe1−xO) – Thermodynamics and crystal growth

Abstract

Keywords / Materials (for Non-textual outputs)

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