Slip and fatigue crack formation processes in an α/β titanium alloy in relation to crystallographic texture on different scales

Bridier, Florent; Villechaise, Patrick; Méndez, J.

doi:10.1016/j.actamat.2008.04.036

Cited by 332 publications

(147 citation statements)

References 14 publications

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“…The localized slip following slip off on the basal plane must be activated in the recrystallized α grain for the microcrack growth, where the shear stress to the basal plane should act at the microcrack tip. 16) Bridier et al 15) suggested that the origin of fatal crack on basal plane required a combination of a high Schmid factor in addition to high elastic stiffness, including a high tensile stress normal to the basal plane, although the detected α grains with microcracks showed the basal Schmid factor in the range of 0.15-0.45. Therefore, thin β platelets which were aligned between the recrystallized α grain and the recovered α grain were responsible for the microcrack generation to form {0001} tansgranular facet in the recrystallized α grains as follows:…”

Section: Microcracks In β Platelets and Their Growth In αmentioning

confidence: 99%

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Analysis of Subsurface Fatigue Crack Generation in Ti–Fe–O Alloy at Low Temperature

Umezawa

Koga

2018

ISIJ Int.

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Subsurface microcracks developed in the Ti-Fe-O cross-rolled material were characterized in order to clarify the subsurface fatigue crack initiation. A considerable amount of microcracks in β platelets were detected. The {0001} transgraular microcracks in α grains predominantly generated at the β grain boundary between recovered α grain and recrystallized α grain, and grew into the recrystallized α grain along the basal plane, although the microcracks at the twist boundary of α grains and at the α-β interface were occasionally detected. Stress concentration around the microcrack in β platelets may assist the microcrack initiation on basal plane (transgranular facet) in neighboring α grain due to a combination of the shear stress and tensile stress normal to the basal plane at α-β boundary. The {0001} transgraular microcracks growth and/or coalescence occurred with the assistance of shear stress on prismatic plane such as {1010} steps.

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Section: Microcracks In β Platelets and Their Growth In αmentioning

confidence: 99%

“…15) According to the full constraints model analysis, the relaxation under the simple shear mode was easier than that under the tension mode. 16) The localized basal slip on {0001} under the simple shear mode may assist the growth of microcrack.…”

Section: Introductionmentioning

confidence: 99%

Analysis of Subsurface Fatigue Crack Generation in Ti–Fe–O Alloy at Low Temperature

Umezawa

Koga

2018

ISIJ Int.

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“…M max shows an increase of 0.941 relative to M at the same axis in Type 1. There are two sets of five independent slip systems for minimum work at the axis listed in Table 2 16,18) so that the f01 1 10gh11 2 20i is geometrically hard to operate. In Types 2-4, therefore, the restrictions of other slip systems result in the operation of f01 1 10gh11 2 20i because of their higher CRSSs.…”

Section: Discussionmentioning

confidence: 99%

“…16,18) In this regime, M is comparatively high regardless of the secondary slip systems' operation, and the number of active f01 1 10gh11 2 20i is mostly the same (Fig. 8).…”

Section: Dominant Deformation Modes In Primary Slip Sys-mentioning

confidence: 99%

Slip Deformation Analysis Based on Full Constraints Model for α-Titanium Alloy at Low Temperature

Morita

Umezawa

2011

Mater. Trans.

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The effects of restricted slip conditions on both the Taylor factor and plastic work rate under the condition of tensile yielding have been analyzed in -titanium alloys at low temperatures, using the full constraints model. The role of secondary slip systems, i.e., the hai basal slip and hc þ ai pyramidal slip, was clarified, when the hai prismatic slip was dominant. Although no influence of secondary slip conditions on the Taylor factor was detected, the plastic work rate was sensitive to the operating secondary slip systems. When the basal system was chosen as the secondary slip system, the plastic work rate increased in all tensile axes, especially around h0001i. In addition, no basal slip operation decreased the plastic strain energy. The plastic work rate was the highest along the h0001i tensile axis, and the operation of the hc þ ai pyramidal slip was necessary to achieve plastic deformation along c axis. High elastic strain energy, therefore, must accumulate to a high level around h0001i, because the pyramidal slip is hardly active owing to its very high critical resolved shear stress.

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“…Moreover, both plastic and elastic deformations coexist in polycrystalline specimens, since the operation depends on the crystal orientation. In the stage 2), regardless of whether the origin of transgranular cracking is slip-off (slip localization) [7] or microcracking [8] on a crystal plane, the plastic deformation on the facet plane hardly yields and the elastic field normal to the facet plane has to accumulate. Table 1 represents crystallographic characterization of the transgranular facet at subsurface crack initiation sites in the references [3,7,[9][10][11][12][13][14][15][16].…”

Section: Introductionmentioning

confidence: 99%

Analyses of heterogeneous deformation and subsurface fatigue crack generation in alpha titanium alloy at low temperature

Umezawa¹,

Morita

Yuasa

et al. 2014

AIP Conference Proceedings

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Critical experiments and analyses at cryogenic temperature to promote a better understanding of mechanical properties in high-strength alloys AIP Conference Proceedings 1574, 327 (2014) Abstract. Subsurface crack initiation in high-cycle fatigue has been detected as {0001} transgranular facet in titanium alloys at low temperature. The discussion on the subsurface crack generation was reviewed. Analyses by neutron diffraction and full constraints model under tension mode as well as crystallographic identification of the facet were focused. The accumulated tensile stress along <0001> may be responsible to initial microcracking on {0001} and the crack opening.

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Slip and fatigue crack formation processes in an α/β titanium alloy in relation to crystallographic texture on different scales

Cited by 332 publications

References 14 publications

Analysis of Subsurface Fatigue Crack Generation in Ti–Fe–O Alloy at Low Temperature

Analysis of Subsurface Fatigue Crack Generation in Ti–Fe–O Alloy at Low Temperature

Slip Deformation Analysis Based on Full Constraints Model for α-Titanium Alloy at Low Temperature

Analyses of heterogeneous deformation and subsurface fatigue crack generation in alpha titanium alloy at low temperature

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Slip and fatigue crack formation processes in an α/β titanium alloy in relation to crystallographic texture on different scales

Cited by 332 publications

References 14 publications

Analysis of Subsurface Fatigue Crack Generation in Ti–Fe–O Alloy at Low Temperature

Analysis of Subsurface Fatigue Crack Generation in Ti–Fe–O Alloy at Low Temperature

Slip Deformation Analysis Based on Full Constraints Model for &alpha;-Titanium Alloy at Low Temperature

Analyses of heterogeneous deformation and subsurface fatigue crack generation in alpha titanium alloy at low temperature

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Slip Deformation Analysis Based on Full Constraints Model for α-Titanium Alloy at Low Temperature