Abstract
P-texture effect on the fatigue crack propagation (FCP) resistance in an Al-Cu-Mg alloy containing a small amount of Ag, is investigated by X-ray diffraction (XRD), scanning electron microscopy (SEM), transmission electron microscopy (TEM) and electron back scattering diffraction (EBSD). Results shows that the high intensity P-texture sheet has lower , lower FCP rate and higher damage tolerance than random texture sheet. Fracture analysis indicates that the striations spacing of high intensity P-texture sheet is much smaller than that of random texture sheet and it has a rougher fatigue fracture surface, which causes a significant roughness induced crack closure (RICC) effect. The calculation results manifest that high intensity P-texture sheet possesses a higher crack closure level reaching 0.73 as compared to random texture sheet (only 0.25). The statistical analysis results reveal the P-grains have large twist angle of 105–170° and tilt angle of 5–60° with neighboring grains, which is similar to Goss-grains. This is the fundamental reason that P-texture sheet has the same FCP resistance and induces fatigue crack deflection as Goss-texture sheet. Additionally, the most {111} slipping planes of P-grains are distributed in the range of 30–50° deviating from transverse direction of the sheet. This results in more {111} slipping planes to participate in cyclic plastic deformation, which is beneficial to reduce fatigue damage accumulation and improve the damage tolerance of Al-Cu-Mg-Ag alloy.
Highlights
Previous researches indicated that the fatigue properties of polycrystalline materials were controlled by co-clusters and second-phase particles, and related to grain structures, such as grain size, boundary and orientation
The objective of the present work is to reveal the effect and mechanism of P-texture on fatigue crack propagation (FCP) behavior with a purpose to establish the relationship between FCP resistance and texture
Earlier work has shown that grain refinement is an effective way to enhance FCP resistance [7,8,9]
Summary
Previous researches indicated that the fatigue properties of polycrystalline materials were controlled by co-clusters and second-phase particles, and related to grain structures, such as grain size, boundary and orientation. Some researchers [1,2,3] have highlighted the influence of Cu-Mg and Mg-Ag co-clusters on the fatigue crack propagation (FCP) of Al-Cu-Mg alloys. Their results revealed large co-clusters were beneficial for improving FCP resistance. The effect of second-phase particles, that is Ω, θ’, T1 phases [2,4,5] on fatigue behavior in aluminum alloys has been examined. These shearable particles gave rise to crack deflection and reduced FCP rates.
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