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High-temperature mass spectrometric study of the thermodynamic properties in the Sm2O3-ZrO2-HfO2 system. / Kablov, Eugene N.; Stolyarova, Valentina L.; Vorozhtcov, Viktor A.; Lopatin, Sergey I.; Shugurov, Sergey M.; Shilov, Andrey L.; Karachevtsev, Fedor N.

In: Rapid Communications in Mass Spectrometry, Vol. 36, No. 7, e9238, 15.04.2022, p. e9238.

Research output: Contribution to journalArticlepeer-review

Harvard

Kablov, EN, Stolyarova, VL, Vorozhtcov, VA, Lopatin, SI, Shugurov, SM, Shilov, AL & Karachevtsev, FN 2022, 'High-temperature mass spectrometric study of the thermodynamic properties in the Sm2O3-ZrO2-HfO2 system', Rapid Communications in Mass Spectrometry, vol. 36, no. 7, e9238, pp. e9238. https://doi.org/10.1002/rcm.9238, https://doi.org/10.1002/rcm.9238

APA

Kablov, E. N., Stolyarova, V. L., Vorozhtcov, V. A., Lopatin, S. I., Shugurov, S. M., Shilov, A. L., & Karachevtsev, F. N. (2022). High-temperature mass spectrometric study of the thermodynamic properties in the Sm2O3-ZrO2-HfO2 system. Rapid Communications in Mass Spectrometry, 36(7), e9238. [e9238]. https://doi.org/10.1002/rcm.9238, https://doi.org/10.1002/rcm.9238

Vancouver

Kablov EN, Stolyarova VL, Vorozhtcov VA, Lopatin SI, Shugurov SM, Shilov AL et al. High-temperature mass spectrometric study of the thermodynamic properties in the Sm2O3-ZrO2-HfO2 system. Rapid Communications in Mass Spectrometry. 2022 Apr 15;36(7):e9238. e9238. https://doi.org/10.1002/rcm.9238, https://doi.org/10.1002/rcm.9238

Author

Kablov, Eugene N. ; Stolyarova, Valentina L. ; Vorozhtcov, Viktor A. ; Lopatin, Sergey I. ; Shugurov, Sergey M. ; Shilov, Andrey L. ; Karachevtsev, Fedor N. / High-temperature mass spectrometric study of the thermodynamic properties in the Sm2O3-ZrO2-HfO2 system. In: Rapid Communications in Mass Spectrometry. 2022 ; Vol. 36, No. 7. pp. e9238.

BibTeX

@article{63731a007f3f4db68c23eed99fb7114f,
title = "High-temperature mass spectrometric study of the thermodynamic properties in the Sm2O3-ZrO2-HfO2 system",
abstract = "Rationale: The Sm2O3-ZrO2-HfO2 system is a promising base for the development of a wide spectrum of new refractory materials. Reliable data on thermodynamic properties in this system are of significant importance for planning the preparation and application of high-temperature ceramics. Especially, they can be useful for calculation of the unknown phase equilibria in this system. Methods: The thermodynamic properties of the Sm2O3-ZrO2-HfO2 system were studied by the high-temperature mass spectrometric method. The samples in the system under consideration synthesized by the solid-state method were vaporized from a tungsten twin effusion cell using a MS-1301 magnetic sector mass spectrometer. Ionization of the vapor species effusing from the cell was carried out by electrons at an energy of 25 eV. Results: It was shown that, at temperatures below 2500 K, the main vapor species over the ceramics based on the Sm2O3-ZrO2-HfO2 system were SmO, Sm, and O corresponding to vapor composition over pure Sm2O3. The SmO, Sm, and O partial vapor pressures over the samples and the Sm2O3 activities were obtained in the temperature range 2319–2530 K. This allowed the excess Gibbs energy values to be determined. For comparison, the excess Gibbs energies in the Sm2O3-ZrO2-HfO2 system were also calculated by the semi-empirical Kohler, Toop, Redlich-Kister, and Wilson methods and optimized by the statistical thermodynamic Generalized Lattice Theory of Associated Solutions (GLTAS). Conclusions: The thermodynamic data calculated by the semi-empirical approaches at 2423 K were shown to be lower than the experimental values. However, the Toop and Wilson methods were found to be useful for evaluation of the excess Gibbs energy values at the Sm2O3 mole fraction less and higher than 0.32, respectively. The self-consistent thermodynamic description of the Sm2O3-ZrO2-HfO2 system was derived at high temperatures by optimization of the experimental results using the GLTAS.",
keywords = "THERMAL BARRIER COATINGS, PHYSICOCHEMICAL PROPERTIES, ZIRCONIA, CERAMICS, HAFNIA, SM2O3-Y2O3-HFO(2)SYSTEM",
author = "Kablov, {Eugene N.} and Stolyarova, {Valentina L.} and Vorozhtcov, {Viktor A.} and Lopatin, {Sergey I.} and Shugurov, {Sergey M.} and Shilov, {Andrey L.} and Karachevtsev, {Fedor N.}",
note = "Publisher Copyright: {\textcopyright} 2021 John Wiley & Sons Ltd.",
year = "2022",
month = apr,
day = "15",
doi = "10.1002/rcm.9238",
language = "English",
volume = "36",
pages = "e9238",
journal = "Rapid Communications in Mass Spectrometry",
issn = "0951-4198",
publisher = "Wiley-Blackwell",
number = "7",

}

RIS

TY - JOUR

T1 - High-temperature mass spectrometric study of the thermodynamic properties in the Sm2O3-ZrO2-HfO2 system

AU - Kablov, Eugene N.

AU - Stolyarova, Valentina L.

AU - Vorozhtcov, Viktor A.

AU - Lopatin, Sergey I.

AU - Shugurov, Sergey M.

AU - Shilov, Andrey L.

AU - Karachevtsev, Fedor N.

N1 - Publisher Copyright: © 2021 John Wiley & Sons Ltd.

PY - 2022/4/15

Y1 - 2022/4/15

N2 - Rationale: The Sm2O3-ZrO2-HfO2 system is a promising base for the development of a wide spectrum of new refractory materials. Reliable data on thermodynamic properties in this system are of significant importance for planning the preparation and application of high-temperature ceramics. Especially, they can be useful for calculation of the unknown phase equilibria in this system. Methods: The thermodynamic properties of the Sm2O3-ZrO2-HfO2 system were studied by the high-temperature mass spectrometric method. The samples in the system under consideration synthesized by the solid-state method were vaporized from a tungsten twin effusion cell using a MS-1301 magnetic sector mass spectrometer. Ionization of the vapor species effusing from the cell was carried out by electrons at an energy of 25 eV. Results: It was shown that, at temperatures below 2500 K, the main vapor species over the ceramics based on the Sm2O3-ZrO2-HfO2 system were SmO, Sm, and O corresponding to vapor composition over pure Sm2O3. The SmO, Sm, and O partial vapor pressures over the samples and the Sm2O3 activities were obtained in the temperature range 2319–2530 K. This allowed the excess Gibbs energy values to be determined. For comparison, the excess Gibbs energies in the Sm2O3-ZrO2-HfO2 system were also calculated by the semi-empirical Kohler, Toop, Redlich-Kister, and Wilson methods and optimized by the statistical thermodynamic Generalized Lattice Theory of Associated Solutions (GLTAS). Conclusions: The thermodynamic data calculated by the semi-empirical approaches at 2423 K were shown to be lower than the experimental values. However, the Toop and Wilson methods were found to be useful for evaluation of the excess Gibbs energy values at the Sm2O3 mole fraction less and higher than 0.32, respectively. The self-consistent thermodynamic description of the Sm2O3-ZrO2-HfO2 system was derived at high temperatures by optimization of the experimental results using the GLTAS.

AB - Rationale: The Sm2O3-ZrO2-HfO2 system is a promising base for the development of a wide spectrum of new refractory materials. Reliable data on thermodynamic properties in this system are of significant importance for planning the preparation and application of high-temperature ceramics. Especially, they can be useful for calculation of the unknown phase equilibria in this system. Methods: The thermodynamic properties of the Sm2O3-ZrO2-HfO2 system were studied by the high-temperature mass spectrometric method. The samples in the system under consideration synthesized by the solid-state method were vaporized from a tungsten twin effusion cell using a MS-1301 magnetic sector mass spectrometer. Ionization of the vapor species effusing from the cell was carried out by electrons at an energy of 25 eV. Results: It was shown that, at temperatures below 2500 K, the main vapor species over the ceramics based on the Sm2O3-ZrO2-HfO2 system were SmO, Sm, and O corresponding to vapor composition over pure Sm2O3. The SmO, Sm, and O partial vapor pressures over the samples and the Sm2O3 activities were obtained in the temperature range 2319–2530 K. This allowed the excess Gibbs energy values to be determined. For comparison, the excess Gibbs energies in the Sm2O3-ZrO2-HfO2 system were also calculated by the semi-empirical Kohler, Toop, Redlich-Kister, and Wilson methods and optimized by the statistical thermodynamic Generalized Lattice Theory of Associated Solutions (GLTAS). Conclusions: The thermodynamic data calculated by the semi-empirical approaches at 2423 K were shown to be lower than the experimental values. However, the Toop and Wilson methods were found to be useful for evaluation of the excess Gibbs energy values at the Sm2O3 mole fraction less and higher than 0.32, respectively. The self-consistent thermodynamic description of the Sm2O3-ZrO2-HfO2 system was derived at high temperatures by optimization of the experimental results using the GLTAS.

KW - THERMAL BARRIER COATINGS

KW - PHYSICOCHEMICAL PROPERTIES

KW - ZIRCONIA

KW - CERAMICS

KW - HAFNIA

KW - SM2O3-Y2O3-HFO(2)SYSTEM

UR - http://www.scopus.com/inward/record.url?scp=85126546599&partnerID=8YFLogxK

UR - https://www.mendeley.com/catalogue/7fe7c1d4-5d9f-31cb-90cc-262689cf3022/

U2 - 10.1002/rcm.9238

DO - 10.1002/rcm.9238

M3 - Article

AN - SCOPUS:85126546599

VL - 36

SP - e9238

JO - Rapid Communications in Mass Spectrometry

JF - Rapid Communications in Mass Spectrometry

SN - 0951-4198

IS - 7

M1 - e9238

ER -

ID: 92753535