Electrochemical Behavior of Passive Films Formed on the Surface of Coarse-, Fine- and Ultra-fine-Grained AA1050 Based on a Modified PDM

doi:10.1007/s40195-016-0429-7

Abstract

Abstract:

Electrochemical impedance spectroscopy (EIS) and Mott-Schottky analysis were carried out to evaluate the electrochemical behavior of the passive films formed on the surface of coarse-grained (CG), fine-grained (FG) and ultra-fine-grained (UFG) 1050 Al alloy (AA1050) samples in alkaline media (pH value of 8.0) based on a modification of point defect model (PDM). The EIS results revealed that the polarization resistance increased from about 22.71-120.33 kΩ cm² for UFG sample when compared to CG sample (annealed sample). The semiconductor properties of the passive films formed on CG, FG and UFG AA1050 samples in the test solution were investigated by employing Mott-Schottky analysis in conjunction with PDM. The results indicated that donor densities were in the range of 2.19 × 10²¹-0.61 × 10²¹ cm^-3 and decreased with grain refinement. Finally, all electrochemical tests showed that the electrochemical behavior of AA1050 alloy was improved by decreasing the grain size, mainly due to the formation of thicker and less defective oxide films.

Key words: AA1050 alloy, Grain refinement, Ultra-fine grain (UFG), Passive film, Mott-Schottky

Seyed Omid Gashti, Arash Fattah-alhosseini, Yousef Mazaheri. Electrochemical Behavior of Passive Films Formed on the Surface of Coarse-, Fine- and Ultra-fine-Grained AA1050 Based on a Modified PDM[J]. Acta Metallurgica Sinica (English Letters), 2016, 29(7): 629-637.

Figures/Tables 13

Table 1 Composition of AA1050 was used in this work (in wt%)

Fe	Si	Mg	Mn	Ti	V	Zn	Al
0.35	0.04	0.02	0.01	0.01	0.01	0.01	Bal.

Fig. 1 Effect of grain refinement on dislocation density and hardness of AA1050 samples

Fig. 2 Optical micrograph of annealed AA1050 before severe plastic deformation method

Fig. 3 TEM micrograph and corresponding SAED pattern of UFG AA1050 sample

Fig. 4 Open-circuit potential a, potentiodynamic polarization b curves of CG, FG and UFG AA1050 samples in test solution (pH value of 8)

Table 2 Calculated data of potentiodynamic polarization plots of CG, FG and UFG AA1050 samples in test solution

Sample	E_corr (V_Ag/AgCl)	i_corr (10^-6 A cm^-2)	i_pass (10^-5 A cm^-2)
CG	-0.493	2.0	6.5
FG	-0.474	1.0	3.2
UFG	-0.460	0.5	1.7

Fig. 5 Nyquist plots a, bode plots b of CG, FG and UFG AA1050 samples in test solution (pH value of 8)

Fig. 6 Kramers-Kronig transformation of the EIS data obtained for CG a, FG b, UFG c AA1050 samples in test solution (pH value of 8)

Fig. 7 Equivalent electrical circuit was proposed for modeling experimental EIS data

Table 3 Variations in the impedance parameters of CG, FG and UFG samples

Parameter	CG sample		FG sample		UFG sample
Parameter	Value	Estimated error	Value	Estimated error	Value	Estimated error
R_s (Ω cm²)	262	1.113	286	2.112	270	2.095
R_p (kΩ cm²)	22.71	1.562	86.94	2.801	120.33	2.712
Y₀ (μΩ^-1 sⁿ cm^-2)	53.01	1.607	23.65	1.955	13.44	2.225
C_dl (μF cm^-2)	57.90	1.607	29.98	1.955	14.84	2.225
n	0.810	0.597	0.744	0.693	0.786	0.678
χ²	0.023	-	0.047	-	0.065	-

Fig. 8 Mott-Schottky plots of CG a, FG b, UFG c AA1050 samples in test solution (pH value of 8)

Fig. 9 Modified PDM for passivation of AA1050 in test solution (pH value of 8.0), where \(V_{\text{Al}}^{3 - }\) is aluminum vacancy on the aluminum sublattice of the passive film, \({\text{Al}}_{i}^{3 + }\) is interstitial aluminum, \({\text{Al}}_{\text{Al}}\) is aluminum cation on the aluminum sublattice of the passive film, \(V_{\text{O}}^{2 + }\) is oxygen vacancy on the oxygen sublattice of the passive film, \({\text{O}}_{\text{O}}\) is oxygen anion on the oxygen sublattice of the passive film, \({\text{Al}}^{3 + } \left( {\text{aq}} \right)\) is aluminum cation in solution

Table 4 Variations of the donor density [ND (1021 cm-3)] of CG, FG and UFG AA1050 samples extracted from Mott-Schottky plots slopes

CG sample	FG sample	UFG sample
2.19 ± 0.3	1.29 ± 0.2	0.61 ± 0.2

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