Interplay between lattice distortions, vibrations and phase stability in NbMoTaW high entropy alloys

F.H.W. Kormann; Marcel H.F. Sluiter

doi:10.3390/e18080403

Interplay between lattice distortions, vibrations and phase stability in NbMoTaW high entropy alloys

F.H.W. Kormann^*, Marcel H.F. Sluiter

^*Corresponding author for this work

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63 Citations (Scopus)

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Abstract

Refractory high entropy alloys (HEA), such as BCC NbMoTaW, represent a promising materials class for next-generation high-temperature applications, due to their extraordinary mechanical properties. A characteristic feature of HEAs is the formation of single-phase solid solutions. For BCC NbMoTaW, recent computational studies revealed, however, a B2(Mo,W;Nb,Ta)-ordering at ambient temperature. This ordering could impact many materials properties, such as thermodynamic, mechanical, or diffusion properties, and hence be of relevance for practical applications. In this work, we theoretically address how the B2-ordering impacts thermodynamic properties of BCC NbMoTaW and how the predicted ordering temperature itself is affected by vibrations, electronic excitations, lattice distortions, and relaxation energies.

Original language	English
Article number	403
Number of pages	7
Journal	Entropy: international and interdisciplinary journal of entropy and information studies
Volume	18
Issue number	8
DOIs	https://doi.org/10.3390/e18080403
Publication status	Published - 2016

Keywords

Density functional theory
High entropy alloy
Lattice distortions
Ordering
Vibrations

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entropy-18-00403-v2Final published version, 1.15 MBLicence: CC BY

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AU - Kormann, F.H.W.

AU - Sluiter, Marcel H.F.

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N2 - Refractory high entropy alloys (HEA), such as BCC NbMoTaW, represent a promising materials class for next-generation high-temperature applications, due to their extraordinary mechanical properties. A characteristic feature of HEAs is the formation of single-phase solid solutions. For BCC NbMoTaW, recent computational studies revealed, however, a B2(Mo,W;Nb,Ta)-ordering at ambient temperature. This ordering could impact many materials properties, such as thermodynamic, mechanical, or diffusion properties, and hence be of relevance for practical applications. In this work, we theoretically address how the B2-ordering impacts thermodynamic properties of BCC NbMoTaW and how the predicted ordering temperature itself is affected by vibrations, electronic excitations, lattice distortions, and relaxation energies.

AB - Refractory high entropy alloys (HEA), such as BCC NbMoTaW, represent a promising materials class for next-generation high-temperature applications, due to their extraordinary mechanical properties. A characteristic feature of HEAs is the formation of single-phase solid solutions. For BCC NbMoTaW, recent computational studies revealed, however, a B2(Mo,W;Nb,Ta)-ordering at ambient temperature. This ordering could impact many materials properties, such as thermodynamic, mechanical, or diffusion properties, and hence be of relevance for practical applications. In this work, we theoretically address how the B2-ordering impacts thermodynamic properties of BCC NbMoTaW and how the predicted ordering temperature itself is affected by vibrations, electronic excitations, lattice distortions, and relaxation energies.

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KW - Vibrations

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Interplay between lattice distortions, vibrations and phase stability in NbMoTaW high entropy alloys

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