Thermodynamic modeling of the Fe−Zn system using exponential temperature dependence for the excess Gibbs energy

Thermodynamic modeling of the Fe−Zn system using exponential temperature dependence for the excess Gibbs energy

The Fe-Zn binary system was re−modeled using exponential equation Li=hi•exp(-T/τi) (i=0,1,2…) to describe the excess Gibbs energy of the solution phases and intermetallic compounds with large homogeneities. A self-consistent set of thermodynamic parameters is obtained and the calculated phase di...

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Bibliographic Details
Main Authors: Tang Y., Yuan X., Du Y., Xiong W.
Format: Article
Language:English
Published: Technical Faculty, Bor 2011-01-01
Series:Journal of Mining and Metallurgy. Section B: Metallurgy
Subjects:
Fe−Zn system
miscibility gap
excess Gibbs energy
thermodynamic modelling
Online Access:http://www.doiserbia.nb.rs/img/doi/1450-5339/2011/1450-53391101001T.pdf
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spelling doaj-f9b3e08e460a4624ad85f0757fc5d3f62020-11-24T20:45:27ZengTechnical Faculty, BorJournal of Mining and Metallurgy. Section B: Metallurgy1450-53392011-01-0147111010.2298/JMMB1101001TThermodynamic modeling of the Fe−Zn system using exponential temperature dependence for the excess Gibbs energyTang Y.Yuan X.Du Y.Xiong W.The Fe-Zn binary system was re−modeled using exponential equation Li=hi•exp(-T/τi) (i=0,1,2…) to describe the excess Gibbs energy of the solution phases and intermetallic compounds with large homogeneities. A self-consistent set of thermodynamic parameters is obtained and the calculated phase diagrams and thermodynamic properties using the exponential equation agree well with the experimental data. Compared with previous assessments using the linear equation to describe the interaction parameters, the artificial miscibility gap at high temperatures was removed. In addition, the calculated thermodynamic properties of the liquid phase were more reasonable than those resulting from all the previous calculations. The present calculations yield noticeable improvements to the previous calculations. http://www.doiserbia.nb.rs/img/doi/1450-5339/2011/1450-53391101001T.pdfFe−Zn systemmiscibility gapexcess Gibbs energythermodynamic modelling
collection DOAJ
language English
format Article
sources DOAJ
author Tang Y.
Yuan X.
Du Y.
Xiong W.
spellingShingle Tang Y.
Yuan X.
Du Y.
Xiong W.
Thermodynamic modeling of the Fe−Zn system using exponential temperature dependence for the excess Gibbs energy
Journal of Mining and Metallurgy. Section B: Metallurgy
Fe−Zn system
miscibility gap
excess Gibbs energy
thermodynamic modelling
author_facet Tang Y.
Yuan X.
Du Y.
Xiong W.
author_sort Tang Y.
title Thermodynamic modeling of the Fe−Zn system using exponential temperature dependence for the excess Gibbs energy
title_short Thermodynamic modeling of the Fe−Zn system using exponential temperature dependence for the excess Gibbs energy
title_full Thermodynamic modeling of the Fe−Zn system using exponential temperature dependence for the excess Gibbs energy
title_fullStr Thermodynamic modeling of the Fe−Zn system using exponential temperature dependence for the excess Gibbs energy
title_full_unstemmed Thermodynamic modeling of the Fe−Zn system using exponential temperature dependence for the excess Gibbs energy
title_sort thermodynamic modeling of the fe−zn system using exponential temperature dependence for the excess gibbs energy
publisher Technical Faculty, Bor
series Journal of Mining and Metallurgy. Section B: Metallurgy
issn 1450-5339
publishDate 2011-01-01
description The Fe-Zn binary system was re−modeled using exponential equation Li=hi•exp(-T/τi) (i=0,1,2…) to describe the excess Gibbs energy of the solution phases and intermetallic compounds with large homogeneities. A self-consistent set of thermodynamic parameters is obtained and the calculated phase diagrams and thermodynamic properties using the exponential equation agree well with the experimental data. Compared with previous assessments using the linear equation to describe the interaction parameters, the artificial miscibility gap at high temperatures was removed. In addition, the calculated thermodynamic properties of the liquid phase were more reasonable than those resulting from all the previous calculations. The present calculations yield noticeable improvements to the previous calculations.
topic Fe−Zn system
miscibility gap
excess Gibbs energy
thermodynamic modelling
url http://www.doiserbia.nb.rs/img/doi/1450-5339/2011/1450-53391101001T.pdf
work_keys_str_mv AT tangy thermodynamicmodelingofthefeznsystemusingexponentialtemperaturedependencefortheexcessgibbsenergy
AT yuanx thermodynamicmodelingofthefeznsystemusingexponentialtemperaturedependencefortheexcessgibbsenergy
AT duy thermodynamicmodelingofthefeznsystemusingexponentialtemperaturedependencefortheexcessgibbsenergy
AT xiongw thermodynamicmodelingofthefeznsystemusingexponentialtemperaturedependencefortheexcessgibbsenergy
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