Effect of Al Content on the Corrosion Behavior of Extruded Dilute Mg-Al-Ca-Mn Alloy

doi:10.1007/s40195-022-01451-1

Abstract

Abstract:

The microstructure, extrusion texture and corrosion behavior of extruded dilute Mg-Al-Ca-Mn alloy with different Al contents were investigated. The corrosion rate of the alloy was more sensitive to the Fe impurities. The 1.2 wt% Al showed the lowest corrosion rate, which was mainly attributed to the weakening of the cathode effect caused by the increase of the Al and the decrease of the Fe in the precipitated phase. Refined grains, stronger basal surface texture and higher corrosion potential deriving from the higher Al content of the matrix also further enhanced the corrosion resistance of the matrix.

Key words: Dilute magnesium alloys, Corrosion behavior, Al content, Fe impurity, Second phase

Bao-Chang Liu, Shuai Zhang, Hong-Wei Xiong, Wen-Hao Dai, Yin-Long Ma. Effect of Al Content on the Corrosion Behavior of Extruded Dilute Mg-Al-Ca-Mn Alloy[J]. Acta Metallurgica Sinica (English Letters), 2023, 36(1): 77-90.

Figures/Tables 19

Table 1 Chemical composition of the dilute Mg-Al-Ca-Mn alloy sheets

Specimens	Chemical composition (wt%)
Specimens	Al	Ca	Mn	Fe	Cu	Ni	Si	Mg
A04	0.44	0.29	0.52	0.0093	0.0015	0.0009	0.0285	Bal.
A08	0.86	0.30	0.49	0.0085	0.0013	0.0009	0.0237	Bal.
A12	1.18	0.30	0.46	0.0086	0.0019	0.0008	0.0159	Bal.

Fig. 1 Optical microscope images of the microstructure of dilute Mg-Al-Ca-Mn alloy: a A04, b A08, c A12

Fig. 2 X-ray diffraction pattern of A04, A08, and A12 of dilute Mg-Al-Ca-Mn alloy

Fig. 3 SEM images and EDS analysis of the microstructure of dilute Mg-Al-Ca-Mn alloy: a A04, b A08, c A12, d typical precipitation phase line scan analysis

Table 2 EDS analysis of phases in Fig. 3a-c

Spectrum points	Chemical composition (at.%)
Spectrum points	Mg	Al	Mn	Fe	O	Ca	Fe/Al + Mn + Fe
1	57.61	9.38	15.91	2.81	9.84	-	0.1
2	57.02	10.99	18.29	3.07	5.98	-	0.095
3	93.98	-	-	-	5.55	0.47	-
4	58.46	13.79	17.62	2.98	4.09	-	0.087
5	58.32	14.94	18.68	2.68	2.46	-	0.074
6	88.65	4.64	3.78	0.76	1.61	-	0.083
7	6.84	50.03	35.45	1.17	6.51	-	0.014
8	93.38	1.36	0.32	0.16	4.77	-	0.087
9	30.17	36.46	26.05	0.64	6.68	-	0.01
10	26.14	40.77	26.08	1.21	5.80	-	0.018

Fig. 4 EBSD results obtained from three samples and grain size distribution histograms: a A04; b A08; c A12

Fig. 5 The (0001)/(10-10) pole figures of the three samples: a A04; b A08; c A12

Fig. 6 OCP of the dilute Mg-Al-Ca-Mn alloy for 7200 s and the surface state of the immersed sample in 3.5 wt% NaCl

Fig. 7 a A schematic polarization curve of extruded dilute Mg-Al-Ca-Mn alloy, b polarization curve of extruded dilute Mg-Al-Ca-Mn alloys after immersion in 3.5 wt% NaCl at 25?±?1 °C

Table 3 Values of Ecorr and Icorr extracted from the polarization curves of A04, A08 and A12 in 3.5 wt% NaCl at 25?±?1 °C

Alloy	E_corr (V _SCE)	i_corr (μA/cm²)	β_a (mV/dec)	β_c (mV/dec)	R_pi (Ω cm²)	Corrosion rate (mm/y)
A04	-1.671	885.23	58.8	-304.4	35.75	20.22
A08	-1.669	316.65	51.7	-171.4	101.52	7.23
A12	-1.655	212.54	58.8	-179.5	178.65	4.86

Fig. 8 Hydrogen evolution rates as a function of immersion time of A04, A08, and A12 specimens in 3.5 wt% NaCl at 25?±?1 °C at a 7 d, b 12 h

Fig. 9 Average mass loss rate of A04, A08, and A12 specimens in 3.5 wt% NaCl at 25?±?1 °C

Table 4 Converted annual corrosion rate (evaluated from the weight loss rate) for A04, A08 and A12 specimens in 3.5 wt% NaCl at 25?±?1 °C

Alloy	A04	A08	A12
Corrosion rate (mm/y)	15.239 ± 1.074	12.967 ± 1.576	8.477 ± 0.827

Fig. 10 Macromorphologies of A04, A08 and A12 samples after immersed in 3.5 wt% NaCl solutions for 7 d

Fig. 11 Typical corrosion morphologies of dilute Mg-Al-Ca-Mn alloys after immersion testing for 2 h and 7 d in 3.5 wt% NaCl at 25?±?1 °C: a,d A04; b,e A08; c,f A12

Fig. 12 X-ray diffraction patterns of dilute Mg–Al–Ca–Mn alloy immersed in 3.5 wt% NaCl at 25?±?1 °C for 1 h

Fig. 13 Electrochemical impedance spectra (EIS) plots of dilute Mg-Al-Ca-Mn alloys in 3.5 wt% NaCl at a,b 10 min, c,d 2 h

Table 5 Fitting results for EIS in 3.5 wt% NaCl at 25?±?1 °C

Sample	R_s		Y_0dl		n_dl	R_t		Y_0f		n_f	R_f
Sample	(Ω cm²)		(Ω⁻¹ cm⁻² sⁿ)		n_dl	(Ω cm²)		(Ω⁻¹ cm⁻² sⁿ)		n_f	(Ω cm²)
A04-10 min	15.8		1.596E-4		0.989	38.76		3.306E-2		0.757	26.92
A08-10 min	15.07		8.32E-5		0.998	39.47		3.10E-2		0.700	28.54
A12-10 min	15.29		3.857E-5		1	52.67		2.437 E-2		0.593	27.74
A04-2 h	15.19		3.472E-5		0.865	74.22		2.797E-3		0.808	107.00
A08-2 h	15.45		1.963E-5		0.905	116.90		2.366E-3		0.755	141.4
A12-2 h	14.62		1.361E-5		0.951	151.40		2.406E-3		0.685	132.20
Sample		R_p		C_dl			C_f		d_f
Sample		(Ω cm²)		(μF cm⁻²)			(μF cm⁻²)		(cm)
A04-10 min		81.48		1.509E-4			2.502E-2		1.344E-11
A08-10 min		83.08		8.220E-5			2.051E-2		1.640E-11
A12-10 min		95.7		3.857E-5			1.392E-2		2.416E-11
A04-2 h		196.41		1.410E-5			2.055E-3		1.637E-10
A08-2 h		273.75		1.064E-5			1.689E-3		1.989E-10
A12-2 h		298.22		9.930E-6			1.349E-3		2.493E-10

Fig. 14 a Changes in Al content, Mn content, impurity Fe content and Fe atomic ratio in Al-Mn phase of dilute Mg-Al-Ca-Mn alloys, b corrosion rate vs. Fe atomic ratio in Al-Mn phase of dilute Mg-Al-Ca-Mn alloys

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