What does this research mean for the field?

The experimentally determined thermodynamic properties of the La2O3–FeO system differ significantly from existing NUCLEA database calculations, necessitating a new optimization of phase equilibria using the CALPHAD approach. Novelty: ClaimNovelty.CONTRADICTORY. Consensus alignment: ConsensusAlignment.CHALLENGES_CONSENSUS.

What question did this study set out to answer?

The research aims to analyze the thermodynamic properties of the La2O3–Fe2O3 system at high temperatures.

March 29, 2026

High-Temperature Thermodynamic Study of the La2O3–Fe2O3 System: Experiment and Modeling

Key Points

The research aims to analyze the thermodynamic properties of the La2O3–Fe2O3 system at high temperatures.
Conducted high-temperature mass-spectrometric investigations up to 1840 K.
Identified vapor species including Fe, O2, and FeO at elevated temperatures.
Measured atomic iron partial pressure across a temperature range of 1647–1840 K.
Utilized Redlich–Kister and Wilson polynomials to analyze FeO activity dependencies.
Assessed thermodynamic properties against values from the NUCLEA database.
Oxygen was the primary gas phase component at temperatures between 900 and 1600 K.
Fe, O2, and FeO became significant as temperatures approached 1650 K.
Achievements in defining FeO activity versus concentration dependencies indicated differences with previously calculated values.
The study underscores the need for optimizing phase equilibria using the CALPHAD method.

Abstract

This paper presents a high-temperature mass-spectrometric investigation of the thermodynamic properties of melts in the La2O3–Fe2O3 system at temperatures up to 1840 K. At the initial vaporization stage at temperatures from 900 to 1600 K, oxygen was the major component of the gas phase. As the temperature increased to 1650 K, Fe, O2, and FeO vapor species were identified over the studied samples. The atomic iron partial pressure determined as a function of temperature in the range 1647–1840 K both over the samples of the system under study and over pure Fe2O3 was used to determine the FeO activity and the molar enthalpy of mixing of iron oxide. The derived FeO activity versus concentration dependencies in the La2O3–FeO system were described by the Redlich–Kister and Wilson polynomials and in terms of the generalized lattice theory of associated solutions (GLTAS). The resulting thermodynamic description of the La2O3–FeO system differed from the thermodynamic values calculated using the NUCLEA database, which indicates the necessity for a new optimization of phase equilibria in the system under consideration using the CALPHAD approach.

Mark Helpful

Bookmark

Relay