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High-cycle-fatigue induced continuous grain growth in ultrafine-grained titanium

High-cycle-fatigue induced continuous grain growth in ultrafine-grained titanium
High-cycle-fatigue induced continuous grain growth in ultrafine-grained titanium
The cyclic deformation behaviour and microstructural stability of severe plastic deformation processed bulk nanostructured (ultrafine-grained, UFG) commercially pure cp-Ti were investigated by using in situ neutron diffraction combined with R = −1 high-cycle-fatigue (HCF) loading at room and cryogenic temperatures. The UFG microstructure was created by equal channel angular pressing (ECAP) and multi-direction forging (MDF). A considerable continuous grain growth was revealed by neutron diffraction for MDF cp-Ti fatigued at 25 °C, as opposed to that at −200 °C. The same HCF fatigue loading at 25 °C only caused very limited grain growth for ECAP cp-Ti. Transmission electron microscopy confirmed the grain growth. Further confirmation of the room-temperature HCF fatigue-induced grain growth was obtained by transmission Kikuchi diffraction based analysis. Novel insights into fatigue induced grain growth mechanism in UFG cp-Ti are thus provided: (i) the thermally activated process plays an important role in grain growth during the room-temperature HCF fatigue; (ii) Continuous dynamic recrystallisation is responsible for the grain growth and dislocation slip or twinning is not essential to trigger such a grain growth; (iii) the anisotropic grain growth behaviour in {0002} grain family can be reconciled by accepting that these grains accumulated highly stored energy during initial severe plastic deformation and the subsequent recrystallisation nucleation occurred at these highly deformed regions.
1359-6454
29-42
Zhao, P.
9538129d-f7a6-488a-9041-a4fd5794c95f
Chen, B.
be54a9a8-da2a-4e6f-ae0e-0b076be87daf
Kelleher, J.F.
5b275bcf-858c-43f6-b0c3-2bc236bfc175
Yuan, G.
7ed1d01d-7afd-498a-b96d-1ee5e742c900
Guan, B.
0c087dc1-bcf0-4a6a-b14c-abb7f359fa48
Zhang, X.
a331be93-28f3-4f6a-813a-56cd4f528336
Tu, S.
7503d316-68ff-43d1-8369-a12dfdad0a0b
et al.
Zhao, P.
9538129d-f7a6-488a-9041-a4fd5794c95f
Chen, B.
be54a9a8-da2a-4e6f-ae0e-0b076be87daf
Kelleher, J.F.
5b275bcf-858c-43f6-b0c3-2bc236bfc175
Yuan, G.
7ed1d01d-7afd-498a-b96d-1ee5e742c900
Guan, B.
0c087dc1-bcf0-4a6a-b14c-abb7f359fa48
Zhang, X.
a331be93-28f3-4f6a-813a-56cd4f528336
Tu, S.
7503d316-68ff-43d1-8369-a12dfdad0a0b

Zhao, P., Chen, B. and Kelleher, J.F. , et al. (2019) High-cycle-fatigue induced continuous grain growth in ultrafine-grained titanium. Acta Materialia, 174, 29-42. (doi:10.1016/j.actamat.2019.05.038).

Record type: Article

Abstract

The cyclic deformation behaviour and microstructural stability of severe plastic deformation processed bulk nanostructured (ultrafine-grained, UFG) commercially pure cp-Ti were investigated by using in situ neutron diffraction combined with R = −1 high-cycle-fatigue (HCF) loading at room and cryogenic temperatures. The UFG microstructure was created by equal channel angular pressing (ECAP) and multi-direction forging (MDF). A considerable continuous grain growth was revealed by neutron diffraction for MDF cp-Ti fatigued at 25 °C, as opposed to that at −200 °C. The same HCF fatigue loading at 25 °C only caused very limited grain growth for ECAP cp-Ti. Transmission electron microscopy confirmed the grain growth. Further confirmation of the room-temperature HCF fatigue-induced grain growth was obtained by transmission Kikuchi diffraction based analysis. Novel insights into fatigue induced grain growth mechanism in UFG cp-Ti are thus provided: (i) the thermally activated process plays an important role in grain growth during the room-temperature HCF fatigue; (ii) Continuous dynamic recrystallisation is responsible for the grain growth and dislocation slip or twinning is not essential to trigger such a grain growth; (iii) the anisotropic grain growth behaviour in {0002} grain family can be reconciled by accepting that these grains accumulated highly stored energy during initial severe plastic deformation and the subsequent recrystallisation nucleation occurred at these highly deformed regions.

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More information

Accepted/In Press date: 17 May 2019
e-pub ahead of print date: 21 May 2019
Published date: 25 May 2019

Identifiers

Local EPrints ID: 489904
URI: http://eprints.soton.ac.uk/id/eprint/489904
DOI: doi:10.1016/j.actamat.2019.05.038
ISSN: 1359-6454
PURE UUID: 8c6a49ca-8ec2-4a2f-8c25-bf43f5d656b0
ORCID for B. Chen: ORCID iD orcid.org/0000-0003-1960-080X

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Date deposited: 07 May 2024 16:42
Last modified: 08 May 2024 02:08

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Contributors

Author: P. Zhao
Author: B. Chen ORCID iD
Author: J.F. Kelleher
Author: G. Yuan
Author: B. Guan
Author: X. Zhang
Author: S. Tu
Corporate Author: et al.

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