Localized Corrosion of Binary Mg-Ca Alloy in 0.9 wt% Sodium Chloride Solution

doi:10.1007/s40195-015-0361-2

Abstract

Abstract:

To further understand the localized corrosion of magnesium alloy, various in situ electrochemical techniques and ex situ electron microprobe analysis and SEM were used to monitor the corrosion process of Mg-1.0Ca alloy in 0.9 wt% sodium chloride solution. The results indicated that the localized corrosion was accompanied by the formation and thickening of a corrosion product film on the Mg-1.0Ca alloy. A localized corrosion of the alloy initiated selectively on the eutectic micro-constituent zones, then enhanced with the exposure, developed in depth with ring-shaped corrosion products accumulated around and finally formed a volcanic-like pitting. Based on the measurements, an electrochemical corrosion model was proposed accordingly to describe the formation mechanism of the volcanic-like pitting on the alloy in 0.9 wt% sodium chloride solution.

Key words: Magnesium alloy, Corrosion behavior, EIS, Scanning reference electrode technique

Rui-Qing Hou, Chen-Qing Ye, Cheng-Dong Chen, Shi-Gang Dong, Miao-Qiang Lv, Shu Zhang, Jin-Shan Pan, Guang-Ling Song, Chang-Jian Lin. Localized Corrosion of Binary Mg-Ca Alloy in 0.9 wt% Sodium Chloride Solution[J]. Acta Metallurgica Sinica (English Letters), 2016, 29(1): 46-57.

Figures/Tables 11

Fig.1 SEM image on polished alloy surface a and elemental distributions of Ca, Mg and O on the eutectic micro-constituent b (L1, L2 and L3 refer to location 1, location 2 at eutectic micro-constituent and location 3 at matrix sites, respectively; CP means backscattered electron image)

Table 1 EDX results corresponding to the areas marked in Fig.1a

Area	O		Mg		Ca
Area	wt%	at%	wt%	at%	wt%	at%
L1	2.9	4.8	75.6	81.2	21.5	14.0
L2	4.8	7.5	79.4	82.6	15.8	9.9
L3	0.9	1.4	98.6	98.3	0.5	0.3

Fig.2 OCP of Mg-1.0Ca alloy measured during 6 h of exposure in 0.9 wt% sodium chloride solution

Fig.3 Nyquist a and Bode b plots of Mg-1.0Ca alloy in 0.9 wt% sodium chloride solution for 6 h and equivalent circuit used for the spectra fitting c

Table 2 Fitting results from EIS spectra for Mg-1.0Ca alloy in 0.9 wt% sodium chloride solution

Time (h)	R_s (Ω cm²)	R_f (Ω cm²)	CPE_f		R_ct (Ω cm²)	CPE_dl		R_L (Ω cm²)	L (10⁴ H cm²)
Time (h)	R_s (Ω cm²)	R_f (Ω cm²)	Y_f (10^-5 F cm^-2 s ⁿ^-1)	n_f	R_ct (Ω cm²)	Y_ct (10^-3 F cm^-2 s ⁿ^-1)	n_ct	R_L (Ω cm²)	L (10⁴ H cm²)
1	22±4	791±99	2.08±0.23	0.91	542±8	2.41±0.06	0.68	1449±25	2.73±0.09
2	23±4	814±105	2.18±0.08	0.92	567±44	2.71±0.46	0.58	1683±180	3.05±0.90
3	22±3	802±33	2.39±0.05	0.92	592±4	2.44±0.20	0.67	2563±330	5.07±0.24
4	22±3	808±47	2.49±0.08	0.92	552±22	2.47±0.16	0.71	2521±119	6.66±0.50
6	22±3	1044±225	2.40±0.02	0.92	773±179	2.28±0.07	0.62	3703±701	7.23±1.38

Fig.4 In situ optical images of the sample surface after 0 min a, 15 min b, 30 min c, 1 h d, 2 h e, 4 h f of exposure in 0.9 wt% sodium chloride solution

Fig.5 Sequential 3D potential images (4 mm × 4 mm) on the surface of Mg-1.0Ca alloy in 0.9 wt% sodium chloride solution at OCP, obtained after 10 min a, 1 h b, 2 h c, 3 h d, 4 h e and 6 h f exposure

Fig.6 SEM micrographs of the sample surface after the SRET measurement a, high-magnification images of the area with an active spot before b and after c the removal of corrosion products by ultrasound and SEM image of a corroded defect on the Mg-1.0Ca alloy surface d

Fig.7 SEM image a and elemental distribution b of a large active spot on the Mg-1.0Ca alloy surface after the SRET measurement (CP means backscattered electron image)

Fig.8 SEM images and EDX linear analysis before a and after b etching experiment on the eutectic micro-constituent

Fig.9 Schematic diagrams of corrosion process for the Mg-1.0Ca alloy in 0.9 wt% sodium chloride solution

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