Thermodynamic description of the Gd2O3-Y2O3-HfO2 and La2O3-Y2O3-HfO2 systems at high temperatures

Шилов, А. Л.; Stolyarova, V. L.; Vorozhtcov, Viktor A.; Лопатин, С. И.

doi:10.1016/j.calphad.2019.03.001

Cited by 13 publications

(11 citation statements)

References 9 publications

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“…The results obtained in the present study by the Knudsen effusion mass spectrometric method at 2373 K were optimized using the Barker‐Guggenheim generalized theory of associated solutions (GLTAS), which was applied earlier for modeling of the thermodynamic properties in the La 2 O 3 ‐Y 2 O 3 ‐HfO 2 and Gd 2 O 3 ‐Y 2 O 3 ‐HfO 2 systems . As was already discussed, the activities of components in these systems could be considered as temperature independent, and therefore in all these studies the excess chemical potentials of components were calculated from the measured component activities at a uniform temperature of 2500 K and optimization was performed using the same lattice basic model.…”

Section: Resultsmentioning

confidence: 99%

Vaporization and thermodynamics of ceramics in the Sm₂O₃‐Y₂O₃‐HfO₂ system

Каблов

Stolyarova

Vorozhtcov

et al. 2020

Rapid Comm Mass Spectrometry

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Rationale The Sm2O3‐Y2O3‐HfO2 system holds promise for applications in the sphere of high‐temperature technologies, particularly the development of ultra‐high‐temperature ceramics. However, the reliability of refractory materials is dependent on the possible selective vaporization of their components leading to changes in their physicochemical properties. Thus, information about vaporization processes and thermodynamic properties of ceramics based on the Sm2O3‐Y2O3‐HfO2 system may be of importance for the production of high‐temperature materials as well as for the prediction of the physicochemical properties of ultra‐high‐temperature ceramics. Methods The Knudsen effusion mass spectrometric method was used, with an MS‐1301 magnetic mass spectrometer equipped with a tungsten twin effusion cell used to examine the samples in the Sm2O3‐Y2O3‐HfO2 system. Electron ionization of vapor species effusing from the cell was carried out at an ionization energy of 25 eV. Results It was shown that at a temperature of 2373 K, selective vaporization of Sm2O3 and Y2O3 occurred in the samples of the Sm2O3‐Y2O3‐HfO2 system, with the main vapor species being SmO, Sm, YO, and O. The partial pressures of these vapor species were obtained by the ion current comparison method. The Sm2O3 activities in the Sm2O3‐Y2O3‐HfO2 system were determined and allowed the evaluation of the excess Gibbs energies at 2373 K. The direction of change of the condensed phase of the samples because of selective vaporization of the components was examined. Conclusions The Sm2O3‐Y2O3‐HfO2 system was characterized by negative deviations from the ideal behavior at 2373 K. The excess Gibbs energies evaluated in the present study were approximated using the Redlich‐Kister representation and visualized in the form of curves of constant values in the concentration triangle. The data obtained in the Sm2O3‐Y2O3‐HfO2 system were optimized using the Barker‐Guggenheim theory of associated solutions.

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Section: Resultsmentioning

confidence: 99%

Vaporization and thermodynamics of ceramics in the Sm₂O₃‐Y₂O₃‐HfO₂ system

Каблов

Stolyarova

Vorozhtcov

et al. 2020

Rapid Comm Mass Spectrometry

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“…The integral thermodynamic functions in a ternary system can be derived from the activity data for only one component using the Generalized Lattice Theory of Associated Solutions (GLTAS) also known as the Barker‐Guggenheim approach 29,30 . This approach was successfully applied to optimization and analysis of the results of investigation of a series of binary and ternary systems including hafnate systems 10,14,15 . Modeling of the thermodynamic properties of the melts and solid solutions is based on interpolation of the experimental dependences of the chemical potentials μ i or the Gibbs energies Δ G on the composition.…”

Section: Discussion and Modelingmentioning

confidence: 99%

“…In the modeling of the essentially nonideal Gd 2 O 3 -ZrO 2 -HfO 2 system, the experimental data on gadolinium oxide alone (Table 5) are insufficient for unambiguous optimization of all η AB μν values. Therefore, the values of the energy parameters, which had been fixed already in our earlier studies, 10,15,31 were substituted into system (14) to reduce the number of variables.…”

Section: Discussion and Modelingmentioning

confidence: 99%

“…A search for new compositions of the zirconia‐hafnia ceramics stabilized by rare earth oxides is interesting, first of all, in view of the advantages they may provide when used as materials for thermal barrier coatings 1–6 and for casting moulds and cores in the production of gas turbine engine blades 7–9 . Investigation of the thermodynamic properties of the Gd 2 O 3 ‐ZrO 2 ‐HfO 2 ceramics in addition to the data obtained earlier for the systems containing yttrium, lanthanum, and samarium oxides as stabilizing components 10–16 will contribute greatly to the thermodynamic database significant for discovery and analysis of compositions with higher operational temperatures and thermal resistance, better durability, and stability of performance. The experimental results were obtained by the Knudsen effusion mass spectrometric method that provides information on the vapor composition over the samples under study and partial pressures of the vapor species thereby allowing the determination of the thermodynamic activities of components in the system.…”

Section: Introductionmentioning

confidence: 96%

“…obtained earlier for the systems containing yttrium, lanthanum, and samarium oxides as stabilizing components [10][11][12][13][14][15][16] will contribute greatly to the thermodynamic database significant for discovery and analysis of compositions with higher operational temperatures and thermal resistance, better durability, and stability of performance. The experimental results were obtained by the Knudsen effusion mass spectrometric method that provides information on the vapor composition over the samples under study and partial pressures of the vapor species thereby allowing the determination of the thermodynamic activities of components in the system.…”

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Mass spectrometric study and modeling of the thermodynamic properties in the Gd₂O₃‐ZrO₂‐HfO₂ system at high temperatures

Каблов

Шилов

Stolyarova

et al. 2022

Rapid Comm Mass Spectrometry

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Rationale: Materials based on the Gd 2 O 3 -ZrO 2 -HfO 2 system are promising for a wide range of high-temperature technological applications, such as for obtaining thermal barrier coatings in the aviation and space industry, as well as advanced materials in nuclear power applications. Experimental studies of the ceramics based on this system by the Knudsen effusion mass spectrometric method provides such valuable information as the vapor composition over the samples and enables derivation of the thermodynamic functions.Methods: Samples of ceramics in the Gd 2 O 3 -ZrO 2 -HfO 2 system were synthesized and analyzed by X-ray fluorescence and diffraction techniques. The vaporization processes and partial pressures of the vapor species over the samples were obtained by the high-temperature mass spectrometric method using the ion current comparison method. The derived thermodynamic functions were optimized within the Generalized Lattice Theory of Associated Solutions (GLTAS) approach.Results: At the temperature of 2600 K, the GdO, ZrO, ZrO 2 , HfO, and O vapor species were found over the samples, but only for the GdO and ZrO species were accurate experimental data on the partial pressures obtained. In all the ceramic samples, the Gd 2 O 3 activity was determined. On this experimental basis, modeling within the GLTAS approach was performed. It allowed the evaluation of the Gd 2 O 3 , ZrO 2 , and HfO 2 activities in the system under study and a rough approximation of the excess Gibbs energy as a function of composition to be obtained.Conclusions: At 2600 K the Gd 2 O 3 -ZrO 2 -HfO 2 system is characterized by negative deviations of its thermodynamic properties from the ideal behavior. Consistency of the obtained modeling results indicate reasonable uniformity of the energy parameters of the lattice model derived in calculations of the hafnia-containing oxide systems, which may be used in further modeling of multicomponent systems. | INTRODUCTIONA search for new compositions of the zirconia-hafnia ceramics stabilized by rare earth oxides is interesting, first of all, in view of the advantages they may provide when used as materials for thermal barrier coatings 1-6 and for casting moulds and cores in the production of gas turbine engine blades. [7][8][9] Investigation of the thermodynamic properties of the Gd 2 O 3 -ZrO 2 -HfO 2 ceramics in addition to the data

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High‐temperature Mass Spectrometric Study and Modeling of the Thermodynamic Properties of the TiO₂‐SiO₂‐ZrO₂ System

Shilov,

Stolyarova,

Lopatin

et al. 2024

ChemistrySelect

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Development of the advanced materials based on the TiO2‐SiO2‐ZrO2 system is hindered by lack of the information on its thermodynamic properties and phase equilibria. In the present study, the samples in the TiO2‐SiO2‐ZrO2 system were prepared by solid‐state synthesis and analyzed by X‐ray microanalysis, fluorescence, and diffraction techniques. The thermodynamic properties in this system were evaluated by Knudsen effusion mass spectrometric (KEMS) method and optimized within the generalized lattice theory of associated solutions (GLTAS). The main vapor species over the silica‐containing samples vaporized from the tungsten cell at the temperature 1973 K were SiO, O, WO2, and WO3. The vapor over the samples in the TiO2‐ZrO2 system at 2356 K was composed mainly of TiO, TiO2, O, WO2, and WO3. The activity of components in the samples and the partial pressures of the identified vapor species were determined. At 1973 K, the TiO2‐SiO2‐ZrO2 system is characterized by positive deviations from the ideality. The observed weak dependence of the SiO2 activity on the SiO2 content suggests the presence of a broad field of immiscibility on the phase diagram in the concentration range 40–100 mol . % SiO2. The thermodynamic data on the TiO2‐SiO2‐ZrO2 system obtained by KEMS can be of great value for calculation of the phase equilibria.

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Thermodynamic description of the Gd2O3-Y2O3-HfO2 and La2O3-Y2O3-HfO2 systems at high temperatures

Cited by 13 publications

References 9 publications

Vaporization and thermodynamics of ceramics in the Sm₂O₃‐Y₂O₃‐HfO₂ system

Vaporization and thermodynamics of ceramics in the Sm₂O₃‐Y₂O₃‐HfO₂ system

Mass spectrometric study and modeling of the thermodynamic properties in the Gd₂O₃‐ZrO₂‐HfO₂ system at high temperatures

High‐temperature Mass Spectrometric Study and Modeling of the Thermodynamic Properties of the TiO₂‐SiO₂‐ZrO₂ System

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Thermodynamic description of the Gd2O3-Y2O3-HfO2 and La2O3-Y2O3-HfO2 systems at high temperatures

Cited by 13 publications

References 9 publications

Vaporization and thermodynamics of ceramics in the Sm2O3‐Y2O3‐HfO2 system

Vaporization and thermodynamics of ceramics in the Sm2O3‐Y2O3‐HfO2 system

Mass spectrometric study and modeling of the thermodynamic properties in the Gd2O3‐ZrO2‐HfO2 system at high temperatures

High‐temperature Mass Spectrometric Study and Modeling of the Thermodynamic Properties of the TiO2‐SiO2‐ZrO2 System

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Vaporization and thermodynamics of ceramics in the Sm₂O₃‐Y₂O₃‐HfO₂ system

Vaporization and thermodynamics of ceramics in the Sm₂O₃‐Y₂O₃‐HfO₂ system

Mass spectrometric study and modeling of the thermodynamic properties in the Gd₂O₃‐ZrO₂‐HfO₂ system at high temperatures

High‐temperature Mass Spectrometric Study and Modeling of the Thermodynamic Properties of the TiO₂‐SiO₂‐ZrO₂ System