Microstructure, Mechanical Properties, and Corrosion Behavior of Mg-Al-Ca Alloy Prepared by Friction Stir Processing

doi:10.1007/s40195-021-01300-7

Abstract

Abstract:

Friction stir processing (FSP) was used to modify the microstructure and improve the mechanical properties and corrosion resistance of an Mg-Al-Ca alloy. The results demonstrated that, after FSP, the grain size of the Mg-Al-Ca alloy was decreased from 13.3 to 6.7 μm. Meanwhile, the Al₈Mn₅ phase was broken and dispersed, and its amount was increased. The yield strength and ultimate tensile strength of the Mg-Al-Ca alloy were increased by 17.0% and 10.1%, respectively, due to the combination of fine grain, second phase, and orientation strengthening, while the elongation was slightly decreased. The immersion and electrochemical corrosion rates in 3.5 wt% NaCl solution decreased by 18.4% and 37.5%, respectively, which contributed to grain refinement. However, the stress corrosion cracking (SCC) resistance of the modified Mg-Al-Ca alloy decreased significantly, which was mainly due to the filiform corrosion induced by the Al₈Mn₅ phase. SCC was mainly controlled by anodic dissolution, while the cathodic hydrogen evolution accelerated the SCC process.

Key words: Friction stir processing, Mg-Al-Ca alloy, Second phase, Mechanical properties, Stress corrosion cracking

Wen Wang, Shan-Yong Chen, Ke Qiao, Pai Peng, Peng Han, Bing Wu, Chen-Xi Wang, Jia Wang, Yu-Hao Wang, Kuai-She Wang. Microstructure, Mechanical Properties, and Corrosion Behavior of Mg-Al-Ca Alloy Prepared by Friction Stir Processing[J]. Acta Metallurgica Sinica (English Letters), 2022, 35(5): 703-713.

Figures/Tables 17

Fig. 1 Sampling position and dimensions of the samples used for the microstructure observations, tensile tests, and corrosion experiments (units: mm). AS represents the advancing side, and RS represents the retreating side. PD, TD, and ND represent the processing, transversal, and normal directions, respectively

Fig. 2 Cross-sectional macrostructure of the FSP sample

Fig. 3 Grain morphologies a, b, grain boundaries distributions c, d of BM and FSP samples

Fig. 4 SEM images showing the second phase particles of the a BM, b FSP samples

Fig. 5 Bright field TEM images and EDS maps of the a-c BM, d-f FSP samples

Table 1 Atomic percent of P1 and P2 in Fig. 5a and b, respectively (at.%)

Points	Mg	Al	Mn	Ca	Zn
P1	5.36	54.45	40.00	0.01	0.17
P2	6.51	59.68	33.58	0.06	0.16

Fig. 6 XRD patterns of the BM and FSP samples

Fig. 7 a, b Pole figures, c, d SF distributions of basal slips along the TD for the BM (left) and FSP (right) samples

Fig. 8 Engineering stress-strain curves of the BM and FSP samples

Fig. 9 Corrosion rates of the BM and FSP samples convert from the weight loss

Fig. 10 SEM morphologies after different immersion time: a, d 3 h, b, e 24 h, and c, f 48 h for the BM (first row) and FSP (second row) samples; g, h enlarged diagrams of points a and b in a, d, respectively. i EDS spectra of point c in h

Fig. 11 Potentiodynamic polarization curves of the BM and FSP samples in 3.5 wt% NaCl solution

Table 2 Eb, Ecorr, icorr, and Pi of the BM and FSP samples in 3.5 wt% NaCl solution

Samples	E_b (V)	E_corr (V)	i_corr (mA cm^-2)	P_i (mm y^-1)
BM	- 1.24	- 1.38	3.4 × 10^-3	0.08
FSP	- 1.16	- 1.36	2.2 × 10^-3	0.05

Table 3 SSRT test results and SCC sensitivity indices of BM and FSP samples

Samples	UTS_air (MPa)	ε_air (%)	UTS_sol (MPa)	ε_sol (%)	I_scc (UTS)	I_scc (ε)
BM	274	47.6	220	7.0	0.20	0.85
FSP	277	46.5	197	6.0	0.29	0.87

Fig. 12 Fracture surfaces of the SSRT test samples: a, d in air; b, e in solution for the BM (first row) and FSP (second row) samples; c, f enlarged diagrams of the selected areas in b, e

Fig. 13 UTS and El comparison of Mg-Al-Ca alloys prepared through different SPD technologies

Fig. 14 Schematic illustration of the proposed SCC mechanism of the BM and FSP samples

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