Influence of Twinning Texture on the Corrosion Fatigue Behavior of Extruded Magnesium Alloys

doi:10.1007/s40195-020-01124-x

Abstract

Abstract:

Bio-magnesium alloys have received great attention due to their degradability and biocompatibility. Corrosion fatigue failure is a huge challenge in vivo for bio-magnesium alloy implants. Understanding the effects of twinning textures on the corrosion fatigue of magnesium alloys is meaningful for the applications. In the current study, pre-compression strains of 2% and 4% were carried out on extruded rods. The effects of twinning texture on the corrosion performance and corrosion fatigue resistance were investigated. The hydrogen evolution tests indicated that twinning texture enhanced the corrosion resistance of longitudinal cross section by improving uniformity of surface energy. The results of corrosion fatigue tests indicated that the differences in mechanical damage caused by twinning texture dominated the corrosion fatigue behavior under high stress amplitude. The secondary cracks of surface deteriorated the corrosion fatigue resistance of the original specimens under low stress amplitude. The compact corrosion film and the re-passivation of matrix suppressed the hydrogen induced cracking, thereby improving the corrosion fatigue resistance of the pre-compression specimens.

Key words: Magnesium alloy, Corrosion fatigue, Extension twins, Secondary crack

Jiaqi Hu, Qite Li, Hong Gao. Influence of Twinning Texture on the Corrosion Fatigue Behavior of Extruded Magnesium Alloys[J]. Acta Metallurgica Sinica (English Letters), 2021, 34(1): 65-76.

Figures/Tables 12

Fig. 1 Schematic of a pre-compressed sample processing, b corrosion fatigue experimental setup

Fig. 2 Longitudinal cross section microstructure of the specimens examined by EBSD: crystal orientation map in terms of the inverse pole figures for a AR, b PRC2, c PRC4; corresponding pole figures for i AR, ii PRC2, iii PRC4

Fig. 3 a Distribution of basal plane-oriented grains (red region) on the longitudinal cross section of the three investigated specimens, b calculated area fraction of the basal plane-oriented grains in the whole test area

Fig. 4 Uniaxial tensile curves of AR, PRC2 and PRC4 specimens Full size image

Table 1 Tensile properties of the three investigated specimens: AR, PRC2, and PRC4

Specimens	σ_y (MPa)	σ_u (MPa)	δ (%)
AR	205.2 ± 4.1	294.1 ± 3.1	20.7 ± 0.3
PRC2	55.6 ± 2.7	294.0 ± 2.5	19.5 ± 0.3
PRC4	68.0 ± 2.1	302.5 ± 3.8	17.6 ± 0.2

Fig. 5 Hydrogen evolution volume of three investigated specimens immersed in 37 °C PBS solution as a function of immersion time

Fig. 6 Corrosion product layer of three investigated specimens after hydrogen evolution tests: a AR, c PRC2, e PRC4, and the corresponding corrosion surface (without corrosion products): b AR, d PRC2, f PRC4

Fig. 7 a Variations in the strain responses with the number of cycles under different stress amplitudes; b stress-strain hysteresis loops of the 100th cycle under 120 MPa stress amplitudes; c under 65 MPa stress amplitudes

Fig. 8 Variations of the corrosion fatigue lives under the different stress amplitudes for three investigated specimens

Fig. 9 a Variations of the corrosion fatigue lives with the pre-compression deformation strain under 65 MPa stress amplitude and corresponding surfaces after corrosion fatigue tests: b AR specimen, c PRC2 specimen, d PRC4 specimen

Fig. 10 Fracture images (without corrosion products) after corrosion fatigue tests at 65 MPa for a AR specimen, c PRC2 specimen, e PRC4 specimen, and the corresponding crack nucleation region for b AR specimen, d PRC2 specimen, f PRC4 specimen

Fig. 11 Schematic illustration of forming mechanism of corrosion fatigue surface: a AR specimen, b PRC4 specimen

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