Lattice Vibrations Change the Solid Solubility of an Alloy at High Temperatures

We develop a method to accurately and efficiently determine the vibrational free energy as a function of temperature and volume for substitutional alloys from first principles. Taking Ti sub(1-x) Al sub(x) N alloy as a model system, we calculate the isostructural phase diagram by finding the global...

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Bibliographic Details
Published in:Physical review letters 2016-11, Vol.117 (20)
Main Authors: Shulumba, Nina, Hellman, Olle, Raza, Zamaan, Alling, Bjorn, Barrirero, Jenifer, Mucklich, Frank, Abrikosov, Igor A, Oden, Magnus
Format: Article
Language:English
Subjects:
Alloy development
Alloy systems
Free energy
Mathematical models
Miscibility gap
Phase diagrams
Solid solubility
Temperature dependence
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Summary:We develop a method to accurately and efficiently determine the vibrational free energy as a function of temperature and volume for substitutional alloys from first principles. Taking Ti sub(1-x) Al sub(x) N alloy as a model system, we calculate the isostructural phase diagram by finding the global minimum of the free energy corresponding to the true equilibrium state of the system. We demonstrate that the vibrational contribution including anharmonicity and temperature dependence of the mixing enthalpy have a decisive impact on the calculated phase diagram of a Ti sub(1-x) Al sub(x) N alloy, lowering the maximum temperature for the miscibility gap from 6560 to 2860 K. Our local chemical composition measurements on thermally aged Ti sub(0.5) Al sub(0.5) N alloys agree with the calculated phase diagram.
ISSN:0031-9007
1079-7114
DOI:10.1103/PhysRevLett.117.205501