Phase morphology, variants and crystallography of alloy microstructures in cold dwell fatigue

•The Stroh model was revisited for the anisotropic rate dependence in hexagonal metals.•In rogue grain combination, basal slip activation gives higher cold creep.•Of the Ti alloy microstructures, multi-variant basketweave inhibits cold creep most.•Multi-variant basketweave inhibits dwell fatigue by...

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Published inInternational journal of fatigue Vol. 113; pp. 324 - 334
Main Authors Zhang, Zhen, Dunne, Fionn P.E.
Format Journal Article
LanguageEnglish
Published Kidlington Elsevier Ltd 01.08.2018
Elsevier BV
Subjects
Basketweave
Burgers orientation relationship
Cold dwell fatigue
Creep
Creep (materials)
Crystallography
Dependence
Dislocations
Kinematics
Load shedding
Low temperature resistance
Materials creep
Materials fatigue
Metal fatigue
Microscale kinematic confinement
Microstructure
Morphology
Slip
Stress relaxation
Titanium alloy
Titanium alloys
Titanium base alloys
Variants
Titanium alloy
Variants
Creep
Basketweave
Microscale kinematic confinement
Cold dwell fatigue
Burgers orientation relationship
Online AccessGet full text
ISSN0142-1123
1879-3452
DOI10.1016/j.ijfatigue.2018.03.030

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Abstract •The Stroh model was revisited for the anisotropic rate dependence in hexagonal metals.•In rogue grain combination, basal slip activation gives higher cold creep.•Of the Ti alloy microstructures, multi-variant basketweave inhibits cold creep most.•Multi-variant basketweave inhibits dwell fatigue by microscale kinematic confinement. This paper examines microscale crystal slip accumulation, cold creep, and stress redistribution (load shedding) related to dwell fatigue in a range of α–β Ti alloy microstructures. The role of basal slip and prism slip is evaluated in load shedding in a rogue grain combination. The results enrich the Stroh dislocation pile up interpretation of dwell by accounting for the anisotropic rate dependence of differing slip systems together with morphology. Microstructural morphology has been found to play an essential role in cold creep and load shedding in dwell fatigue. Basketweave structures with multiple α variants have been shown to give the lowest load shedding for which the mechanistic explanation is that the β lath structures provide multiple, small-scale α variants which inhibit creep and hence stress relaxation, thus producing more uniform, diffuse stress distributions across the microstructure through microscale kinematic confinement, imposed by multi (α)-to-single (β) BOR relations (i.e. multiple α variants sharing the same parent β grain). The critical consequence of this is that alloys typically having multi-variant basketweave structure (e.g. Ti-6246), remain free of dwell fatigue debit whereas those alloys associated with globular colony structures (e.g. Ti-6242) suffer significant dwell debit. This understanding is important in microstructural design of titanium alloys for resisting cold dwell fatigue.
AbstractList •The Stroh model was revisited for the anisotropic rate dependence in hexagonal metals.•In rogue grain combination, basal slip activation gives higher cold creep.•Of the Ti alloy microstructures, multi-variant basketweave inhibits cold creep most.•Multi-variant basketweave inhibits dwell fatigue by microscale kinematic confinement. This paper examines microscale crystal slip accumulation, cold creep, and stress redistribution (load shedding) related to dwell fatigue in a range of α–β Ti alloy microstructures. The role of basal slip and prism slip is evaluated in load shedding in a rogue grain combination. The results enrich the Stroh dislocation pile up interpretation of dwell by accounting for the anisotropic rate dependence of differing slip systems together with morphology. Microstructural morphology has been found to play an essential role in cold creep and load shedding in dwell fatigue. Basketweave structures with multiple α variants have been shown to give the lowest load shedding for which the mechanistic explanation is that the β lath structures provide multiple, small-scale α variants which inhibit creep and hence stress relaxation, thus producing more uniform, diffuse stress distributions across the microstructure through microscale kinematic confinement, imposed by multi (α)-to-single (β) BOR relations (i.e. multiple α variants sharing the same parent β grain). The critical consequence of this is that alloys typically having multi-variant basketweave structure (e.g. Ti-6246), remain free of dwell fatigue debit whereas those alloys associated with globular colony structures (e.g. Ti-6242) suffer significant dwell debit. This understanding is important in microstructural design of titanium alloys for resisting cold dwell fatigue.
This paper examines microscale crystal slip accumulation, cold creep, and stress redistribution (load shedding) related to dwell fatigue in a range of α–β Ti alloy microstructures. The role of basal slip and prism slip is evaluated in load shedding in a rogue grain combination. The results enrich the Stroh dislocation pile up interpretation of dwell by accounting for the anisotropic rate dependence of differing slip systems together with morphology. Microstructural morphology has been found to play an essential role in cold creep and load shedding in dwell fatigue. Basketweave structures with multiple α variants have been shown to give the lowest load shedding for which the mechanistic explanation is that the β lath structures provide multiple, small-scale α variants which inhibit creep and hence stress relaxation, thus producing more uniform, diffuse stress distributions across the microstructure through microscale kinematic confinement, imposed by multi (α)-to-single (β) BOR relations (i.e. multiple α variants sharing the same parent β grain). The critical consequence of this is that alloys typically having multi-variant basketweave structure (e.g. Ti-6246), remain free of dwell fatigue debit whereas those alloys associated with globular colony structures (e.g. Ti-6242) suffer significant dwell debit. This understanding is important in microstructural design of titanium alloys for resisting cold dwell fatigue.
Author Dunne, Fionn P.E.
Zhang, Zhen
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Keywords Titanium alloy
Variants
Creep
Basketweave
Microscale kinematic confinement
Cold dwell fatigue
Burgers orientation relationship
Language English
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Snippet •The Stroh model was revisited for the anisotropic rate dependence in hexagonal metals.•In rogue grain combination, basal slip activation gives higher cold...
This paper examines microscale crystal slip accumulation, cold creep, and stress redistribution (load shedding) related to dwell fatigue in a range of α–β Ti...
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SubjectTerms Basketweave
Burgers orientation relationship
Cold dwell fatigue
Creep
Creep (materials)
Crystallography
Dependence
Dislocations
Kinematics
Load shedding
Low temperature resistance
Materials creep
Materials fatigue
Metal fatigue
Microscale kinematic confinement
Microstructure
Morphology
Slip
Stress relaxation
Titanium alloy
Titanium alloys
Titanium base alloys
Variants
Title Phase morphology, variants and crystallography of alloy microstructures in cold dwell fatigue
URI https://dx.doi.org/10.1016/j.ijfatigue.2018.03.030
https://www.proquest.com/docview/2088804593
Volume 113
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