2008
DOI: 10.1007/s11661-008-9633-z
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Microstructural Influences on Very-High-Cycle Fatigue-Crack Initiation in Ti-6246

Abstract: The fatigue behavior of an alpha + beta titanium alloy, Ti-6Al-2Sn-4Zr-6Mo, has been characterized in the very-high-cycle fatigue (VHCF) regime using ultrasonic-fatigue (20 kHz) techniques. Stress levels (r max ) of 40 to 60 pct of the yield strength of this alloy have been examined. Fatigue lifetimes in the range of 10 6 to 10 9 cycles are observed, and fatigue cracks initiate from both surface and subsurface sites. This study examines the mechanisms of fatiguecrack formation by quantifying critical microstru… Show more

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Cited by 152 publications
(100 citation statements)
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“…4), while some of the specimens failed from internal initiation sites under maximum stresses of 860 MPa or lower. Further details on the microstructure, experimental methods, results, and analysis are provided in [37,[39][40][41]54], which served as the backbone of the results to be presented below. residual-stress-free electropolished surfaces.…”
Section: Materials and Experimental Methodsmentioning
confidence: 99%
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“…4), while some of the specimens failed from internal initiation sites under maximum stresses of 860 MPa or lower. Further details on the microstructure, experimental methods, results, and analysis are provided in [37,[39][40][41]54], which served as the backbone of the results to be presented below. residual-stress-free electropolished surfaces.…”
Section: Materials and Experimental Methodsmentioning
confidence: 99%
“…In this approach, the lifetime distribution was modeled as a superposition of the probability densities of the crack-growth-dominated lifetime (Type I) and the crack-initiation-dominated, mean lifetime (Type II). The underlying initiation and cracking mechanisms for this material have been reported elsewhere, and a key factor in the fatigue variability of this material was microtexture [40][41][42][54][55][56]. The total lifetime density was represented by:…”
Section: Modeling Bimodal Fatiguementioning
confidence: 96%
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“…1,2) The subsurface fatigue crack initiation sites in near-α and α-β type titanium alloys commonly appear crystallographic transgranular facet or facets. [1][2][3][4][5][6][7][8] Mostly the facets formed on or near the {0001} basal plane regardless their inclination to the principal stress axis. Dislocation movement in α phase is restricted on the primary slip plane and fairly planar so that dislocation arrays on {01 1 0} < 11 2 0 > are piled-up in the vicinity of grain boundaries and a local stress concentration generates near α grain boundary.…”
Section: Introductionmentioning
confidence: 99%
“…Crack initiation transition from surface to sub-surface/internal pores and inclusions have been reported to occur during giga-cycle fatigue testing [45,57]. In addition, texture can affect fatigue crack initiation in Ni-based superalloys and Ti alloys [58][59][60][61]. Clustered grains can act more like a single grain exhibiting similar crystallographic orientation and enable slip across low angle grain boundaries, thereby creating the possibility for slip to occur easier over longer distances, resulting in dislocation pile-ups and stress concentrations at grain boundaries.…”
Section: Fatigue 15mentioning
confidence: 99%