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Modelling martensitic transformation in titanium alloys: the influence of temperature and deformation

Modelling martensitic transformation in titanium alloys: the influence of temperature and deformation
Modelling martensitic transformation in titanium alloys: the influence of temperature and deformation

New theory is presented to describe the occurrence of plasticity-induced transitions in titanium alloys. The approach is able to predict the composition dependence of transformation induced plasticity (TRIP), superelasticity, as well as martensite formation upon quenching. Martensite formation in the absence of stress is considered as the result of a competition between elastic strain energy and chemical driving force. Assuming that the formation of martensite is the result of a thermally activated nucleation process followed by athermal growth, a nucleation parameter is postulated to describe the conditions under which martensite is formed upon quenching; the parameter accounts for the ratio between the available thermal energy and an energy barrier for nucleation, suggesting that ω phase is not the main factor controlling martensite inhibition. This nucleation parameter is able to describe, for the first time, martensite occurrence in 130 alloys from the literature, quantifying the martensite start temperature (Ms) reported for 49 alloys with great precision. An empirical parameter ([Fe]eq) is proposed and, when combined with the Ms prediction, it allows to define regions within which TRIP and superelasticity occur. By defining threshold values for the Ms, the [Fe]eq and the nucleation parameter, candidate alloys likely to display TRIP, superelasticity or martensitic transformation upon quenching can be identified. As a result, this method can be adopted to design alloys with tailored plasticity behaviour.

Martensite, Superelasticity, Titanium alloys, TRIP
Bignon, Madeleine
2e0d9953-ed11-4d2b-a928-bd2caa241e04
Bertrand, Emmanuel
a6e4c98a-9dd8-40c7-b167-07a90eaf3251
Tancret, Franck
63962367-3fff-4cfc-a86c-e56a9fb962d2
Rivera-Díaz-del-Castillo, Pedro E.J.
6e0abc1c-2aee-4a18-badc-bac28e7831e2
Bignon, Madeleine
2e0d9953-ed11-4d2b-a928-bd2caa241e04
Bertrand, Emmanuel
a6e4c98a-9dd8-40c7-b167-07a90eaf3251
Tancret, Franck
63962367-3fff-4cfc-a86c-e56a9fb962d2
Rivera-Díaz-del-Castillo, Pedro E.J.
6e0abc1c-2aee-4a18-badc-bac28e7831e2

Bignon, Madeleine, Bertrand, Emmanuel, Tancret, Franck and Rivera-Díaz-del-Castillo, Pedro E.J. (2019) Modelling martensitic transformation in titanium alloys: the influence of temperature and deformation. Materialia, 7, [100382]. (doi:10.1016/j.mtla.2019.100382).

Record type: Article

Abstract

New theory is presented to describe the occurrence of plasticity-induced transitions in titanium alloys. The approach is able to predict the composition dependence of transformation induced plasticity (TRIP), superelasticity, as well as martensite formation upon quenching. Martensite formation in the absence of stress is considered as the result of a competition between elastic strain energy and chemical driving force. Assuming that the formation of martensite is the result of a thermally activated nucleation process followed by athermal growth, a nucleation parameter is postulated to describe the conditions under which martensite is formed upon quenching; the parameter accounts for the ratio between the available thermal energy and an energy barrier for nucleation, suggesting that ω phase is not the main factor controlling martensite inhibition. This nucleation parameter is able to describe, for the first time, martensite occurrence in 130 alloys from the literature, quantifying the martensite start temperature (Ms) reported for 49 alloys with great precision. An empirical parameter ([Fe]eq) is proposed and, when combined with the Ms prediction, it allows to define regions within which TRIP and superelasticity occur. By defining threshold values for the Ms, the [Fe]eq and the nucleation parameter, candidate alloys likely to display TRIP, superelasticity or martensitic transformation upon quenching can be identified. As a result, this method can be adopted to design alloys with tailored plasticity behaviour.

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Accepted/In Press date: 18 June 2019
e-pub ahead of print date: 6 July 2019
Published date: 12 July 2019
Keywords: Martensite, Superelasticity, Titanium alloys, TRIP

Identifiers

Local EPrints ID: 492260
URI: http://eprints.soton.ac.uk/id/eprint/492260
DOI: doi:10.1016/j.mtla.2019.100382
PURE UUID: 0afe3fc8-8dce-4f71-b1bb-54a009290528
ORCID for Pedro E.J. Rivera-Díaz-del-Castillo: ORCID iD orcid.org/0000-0002-0419-8347

Catalogue record

Date deposited: 23 Jul 2024 16:35
Last modified: 24 Jul 2024 02:07

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Contributors

Author: Madeleine Bignon
Author: Emmanuel Bertrand
Author: Franck Tancret
Author: Pedro E.J. Rivera-Díaz-del-Castillo ORCID iD

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