Ab initio modeling of TWIP and TRIP effects in β‑Ti alloys

David Holec; Johann Grillitsch; José L. Neves; David Obersteiner; Thomas Klein

doi:10.1557/s43578-025-01657-w

Ab initio modeling of TWIP and TRIP effects in β‑Ti alloys

David Holec
, Johann Grillitsch
, José L. Neves
, David Obersteiner
, Thomas Klein

Lehrstuhl für Metallkunde (420)

Austrian Institute of Technology, Ranshofen

Publikation: Beitrag in Fachzeitschrift › Artikel › Forschung › Begutachtung

Abstract

Abstract: Transformations in bcc-β, hcp-α, and the ω phases of Ti alloys are studied using density functional theory for pure Ti and Ti alloyed with Al, Si, V, Cr, Fe, Cu, Nb, Mo, and Sn. The β-stabilization caused by alloying Si, Fe, Cr, and Mo was observed, but the most stable phase appears between the β and the α phases, corresponding to the martensitic α′′ phase. Next, the {112}⟨111¯⟩ bcc twins are separated by a positive barrier, which further increases by alloying w.r.t. pure Ti. The {332}⟨113¯⟩ twinning yields negative barriers for all species but Mo and Fe. This is because the transition state is structurally similar to the α phase, which is preferred over the β phase for the majority of alloying elements. Lastly, the impact of alloying on twin boundary energies is discussed. These results may serve as design guidelines for novel Ti-based alloys with specific application areas.

Originalsprache	Englisch
Seiten (von - bis)	2376-2387
Seitenumfang	12
Fachzeitschrift	Journal of materials research (JMR)
Jahrgang	2025
Ausgabenummer	Volume 40, Issue 16
DOIs	https://doi.org/10.1557/s43578-025-01657-w
Publikationsstatus	Elektronische Veröffentlichung vor Drucklegung. - 4 Aug. 2025

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Publisher Copyright:
© The Author(s) 2025.

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abstract = "Abstract: Transformations in bcc-β, hcp-α, and the ω phases of Ti alloys are studied using density functional theory for pure Ti and Ti alloyed with Al, Si, V, Cr, Fe, Cu, Nb, Mo, and Sn. The β-stabilization caused by alloying Si, Fe, Cr, and Mo was observed, but the most stable phase appears between the β and the α phases, corresponding to the martensitic α′′ phase. Next, the \{112\}⟨111¯⟩ bcc twins are separated by a positive barrier, which further increases by alloying w.r.t. pure Ti. The \{332\}⟨113¯⟩ twinning yields negative barriers for all species but Mo and Fe. This is because the transition state is structurally similar to the α phase, which is preferred over the β phase for the majority of alloying elements. Lastly, the impact of alloying on twin boundary energies is discussed. These results may serve as design guidelines for novel Ti-based alloys with specific application areas.",

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T1 - Ab initio modeling of TWIP and TRIP effects in β‑Ti alloys

AU - Holec, David

AU - Grillitsch, Johann

AU - Neves, José L.

AU - Obersteiner, David

AU - Klein, Thomas

N1 - Publisher Copyright: © The Author(s) 2025.

PY - 2025/8/4

Y1 - 2025/8/4

N2 - Abstract: Transformations in bcc-β, hcp-α, and the ω phases of Ti alloys are studied using density functional theory for pure Ti and Ti alloyed with Al, Si, V, Cr, Fe, Cu, Nb, Mo, and Sn. The β-stabilization caused by alloying Si, Fe, Cr, and Mo was observed, but the most stable phase appears between the β and the α phases, corresponding to the martensitic α′′ phase. Next, the {112}⟨111¯⟩ bcc twins are separated by a positive barrier, which further increases by alloying w.r.t. pure Ti. The {332}⟨113¯⟩ twinning yields negative barriers for all species but Mo and Fe. This is because the transition state is structurally similar to the α phase, which is preferred over the β phase for the majority of alloying elements. Lastly, the impact of alloying on twin boundary energies is discussed. These results may serve as design guidelines for novel Ti-based alloys with specific application areas.

AB - Abstract: Transformations in bcc-β, hcp-α, and the ω phases of Ti alloys are studied using density functional theory for pure Ti and Ti alloyed with Al, Si, V, Cr, Fe, Cu, Nb, Mo, and Sn. The β-stabilization caused by alloying Si, Fe, Cr, and Mo was observed, but the most stable phase appears between the β and the α phases, corresponding to the martensitic α′′ phase. Next, the {112}⟨111¯⟩ bcc twins are separated by a positive barrier, which further increases by alloying w.r.t. pure Ti. The {332}⟨113¯⟩ twinning yields negative barriers for all species but Mo and Fe. This is because the transition state is structurally similar to the α phase, which is preferred over the β phase for the majority of alloying elements. Lastly, the impact of alloying on twin boundary energies is discussed. These results may serve as design guidelines for novel Ti-based alloys with specific application areas.

KW - Ductility

KW - Phase transformation

KW - Simulation

KW - Ti

KW - Twins

UR - https://www.scopus.com/pages/publications/105012436310

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DO - 10.1557/s43578-025-01657-w

M3 - Article

SN - 0884-2914

VL - 2025

SP - 2376

EP - 2387

JO - Journal of materials research (JMR)

JF - Journal of materials research (JMR)

IS - Volume 40, Issue 16

ER -