Abstract

The passivity and protective nature of the passive films are essentially related to ionic and electronic transport processes, which are controlled by the optical and electronic properties of passive films. In this study, the electrochemical behavior of passive films anodically formed on AISI 304 stainless steel in sulfuric acid solution has been examined using electrochemical impedance spectroscopy. AISI 304 in sulphuric acid solution is characterized by high interfacial impedance, thereby illustrating its high corrosion resistance. Results showed that the interfacial impedance and the polarization resistance () initially increase with applied potential, within the low potential passive. However, at a sufficiently high potential passive ( V), the interfacial impedance and the polarization resistance decrease with increasing potential. An electrical equivalent circuit based on the impedance analysis, which describes the behavior of the passive film on stainless steel more satisfactorily than the proposed models, is presented.

1. Introduction

Stainless steel possesses high corrosion resistance due to its ability to spontaneously form stable passive oxides in air and aqueous solutions. These oxides, which in many cases are no thicker than a few nanometers [13], act as a reactivity barrier between the metal and the environment. The electrochemical polarization method, including anodic passivation, enhances the preferential dissolution of iron into solution and the enrichment of chromium in the passive film, and hence this method is effective for increasing stability, compaction, and corrosion resistance of the passive films [4, 5]. The corrosion reaction rate, that is, the anodic current density of anodic films, is lowered by several orders of magnitude than that of naturally grown oxide films. The chemical composition, the structure, and the thickness of electrochemically formed passive films on stainless steel change not only with environment but especially with passivation potential [69].

Over the recent years, most of the modern descriptions of passive films are based on the concepts presented by Macdonald and coworkers [1015] in the point defect model (PDM). The PDM assumes that the transport of matter through the film takes place via ionic point defects. This transport is necessary for any growth of the film. The presence of point defects also provides a path for the cations formed from the substrate metal to pass through the film into the solution. Point defects are formed and annihilated in reactions proceeding at the metal/film and film/solution interfaces. The rates of these reactions and of the defect transport determine to a great extent the electrical and electrochemical properties of the film [1618].

Electrochemical impedance spectroscopy (EIS) has been widely used for studying the electrochemical mechanisms occurring on the electrodes. EIS data can be used to establish an equivalent electrical circuit model for the electrochemical processes of electrodes. The various elements in this equivalent circuit are related to the metal/film and film/solution interfaces and the phenomena occurring inside the passive film [19, 20]. EIS measurements make it possible to obtain some information on the mechanism, establishing a theoretical transfer function and developing the passive film growth model [21, 22].

AISI 304 stainless steel is the most popular alloy, used extensively because of its good corrosion resistance; its passive films have been the subject of many investigations. In spite of the relatively large amount of research on the electrical properties of passive films anodically formed, however, few papers have been published on a systematic study of the impedance behavior. The great complexity of the metal/passive film/electrolyte system of stainless steels makes the clarification of the passive film difficult. In this work, EIS measurements were made in a large range of frequencies in order to get more information on the passive film electrochemically grown on AISI 304 stainless steel/solution properties.

2. Experimental Procedures

Specimens were cut from 1 cm diameter rods of AISI 304 stainless steel; the chemical composition (%, wt.): Cr 18.1, Ni 8.7, Mn 1.1, Si 0.47, C 0.08, S 0.002, and balance Fe. The samples were placed in stainless steel sacks and were annealed in inert environment (Ar gas) to eliminate the cold work effect due to cutting process. The annealing was preformed at 1050°C for 90 min followed by water quenching. The pretreatment applied on specimens consisted of mechanical polishing using emery papers up to 1200 grade, degreasing and rinsing in distilled water. A three-electrode cell featuring a Pt counter electrode and a saturated calomel electrode (SCE) was employed. All the potential values in the text are relative to the SCE. The solution (0.5 M H2SO4) was prepared from analytical grade 97% H2SO4 and distilled water. Prior to each experiment, the working electrode was catholically polarized at −1.2 V for 5 min.

Impedance investigations were performed using an EG&G Model 273A potentiostat/galvanostat controlled by a personal computer at ambient temperature (23–25°C). Passive films on AISI 304 stainless steel were formed potentiostatically at DC potentials selected based on the passive region of anodic curve for 1 h and then EIS measurements were done. Each electrochemical measurement was repeated at least three times. An excitation voltage of 10 mV (peak-to-peak) and an applied frequency ranging from 100 kHz to 10 mHz have been used. All the potential values in the text are relative to the SCE. For EIS data modeling and curve-fitting method, Z-View2 impedance software “Equivalent Circuit” was used. This program is based on the method of nonlinear least squares, which allows nonideal electrochemical behavior to be modeled.

3. Results and Discussion

3.1. Experimental Results

The electrochemical behavior of the anodic passive films on AISI 304 stainless steel in 0.5 M H2SO4 has been evaluated by means of impedance measurements. For this purpose, passive films on stainless steel electrode were formed potentiostatically at DC potentials selected based on the passive region of anodic curve for 1 h and then EIS measurements were done. The potential of 0.8 V corresponds to the upper limit of the passive region, which also corresponds to the beginning of the transpassive region. Typical Nyquist and Bode plots for anodic oxide films are presented in Figure 1. Bode plots have been added for the representation of the impedance spectra because the magnitude of the impedance at low frequencies is several orders of magnitude higher than that at high frequencies, and thus high-frequency features are difficult to discern in a Nyquist plot. In the frequency range of measurement, all impedance spectra have the same features.

Figure 2 indicates that the impedance magnitude at low frequencies initially increases with film formation potential, within the low passive potential. However, at a sufficiently high passive potential ( V) the impedance magnitude decreases with increasing potential. The high impedance values in this low-frequency region can be associated with the presence of the barrier layer of the passive film.

3.2. The Physical and Mathematical Models of the Metal/Passive Film/Solution System

For many years, a great number of mechanisms and models have been put forward through the research and analysis of the EIS of different systems. Among these models, the six main ones are as follows.

Model A
The interface resistance and the capacitance are simply paralleled to represent the passive electrode system [2326].When measuring the impedance of the actual system, the obtained capacitance sometimes may deviate from the “pure capacitance”. Therefore, a constant phase element () is introduced for the fitting to replace capacitor . In Figure 3(a), is the uncompensated solution resistance; and are the interface resistance and the interface constant phase element, respectively. The mathematical expression of the impedance of the electrode system in this model is The impedance of the constant phase element is presented by and are two parameters of . When , it means that is equivalent to a pure capacitor and .

Model B
It is believed that the impedance of the passive films of metals comes from the migration of metal and oxygen vacancies within the film. Macdonald and coworkers propose the point defect model about the growth and destruction of the passive film. According to this model, the process of migration of metal vacancies and oxygen vacancies within the passive film has the form of Warburg impedance. When the oxygen vacancies are dominant in the passive film, the impedance of the film . Figure 3(b) shows the equivalent circuit of this model; here is the charge transfer resistance [27]. The mathematic expression of the impedance of this electrode system is

Model C
A constant phase element () is used to represent the transfer of the charged particles within the passive film, shown in Figure 3(c). It is believed that the passive film has capacitive characters. Jamnik et al. think that, in the impedance complex plane diagram, the diffusion activities of the charged particles in a solid are not reflected as a 45° sloped straight line but as a line that approximates 90° which reflects the capacitive characters of the electrode [28]. The mathematic expression of the impedance of the electrode system is

Model D
Two parallel circuits are used, to represent the electrochemical activities of the passive film and the film/solution interface, respectively, (Figure 3(d)) [29]. In this figure, and are the charge transfer resistance and the double layer capacitance, respectively. and are the film resistance and the film capacitance, or the resistance and capacitance of the space charge layer, respectively. The mathematical expression of the impedance of the electrode system in this model is

Model E
Figure 3(e) shows a graphical representation of the electrochemical system and the equivalent circuit [30]. and represent the capacitive and resistive contributions of the passive film/metal interface, and represent the bulk passive film, and represent the solution/passive film interface, and is the uncompensated solution resistance. The mathematical expression of the impedance of the electrode system in this model is

Model F
Figure 3(f) shows a graphical representation of the electrochemical system and the equivalent circuit [31]. The equivalent circuit is a combination of three branches, including the uncompensated solution resistance, and are the charge-transfer resistance of the interfacial reaction and the double-layer capacitance. and are related to the electronic charging in the passive oxide film. represents the impedance diffusion, which can be related to ionic defect transport through the passive film. and indicate the contribution of surface states. According to Cahan et al. [30], in some passivation conditions an excess proton creates a corresponding Fe2+ and a deficient proton causes an equivalent Fe3+ in the film, and these ions play the role of surface states. The mathematical expression of the impedance of the electrode system in this model is The impedance of diffusion is given by where is the diffusion resistance, is the effective diffusion thickness, is the effective diffusion coefficient, and is the generalized finite Warburg exponent.

3.3. The Fitting Results

Figure 4 shows that the fitting results of typical Nyquist plots for passive films on AISI 304 electrodes were formed potentiostatically at 0.2 V using the five models. It is found that the fitting errors of Models A, B, C, and D are relatively high. In Model A, the EIS is corresponding to a capacitive loop. When fitting the data, the fitting error increases remarkably. In Model B, diffusion process occurs at low frequency and has a form of Warburg impedance. When fitting with this model, large errors occur in the low-frequency region. Therefore, Models A and B are not suitable for this system.

In Model C, is the charge transfer resistance. and , respectively, reflect the double-layer capacitance and the substance transfer processes in the passive film. From the physical point of view, it is not reasonable to represent the substance transfer within the passive film simply by a capacitor. Model D consists of two (R-Q) parallel circuits, which represent the contribution of the interfacial reaction and a passivating film. When fitting with this model, large errors occur in the low-frequency region and no significant variations of the different electrical-circuit element were found. Therefore, Models C and D are not suitable for this system either. When fitting with Model E, small errors occur in the low-frequency region.

The above six models were used to fit the impedance data obtained; it was found that the fitting results of model F are suitable to the actual passivation process. When fitting our theoretical electrical-equivalent circuit, a value of chi-quadrate () of approximately 10−4 was found and the fitting errors were quite small. Figure 5 shows in all cases that the correlation between experimental data and simulated data is very good.

The Bode plots and admittance plots (not shown) also displayed an acceptable agreement between experimental and simulated data, thereby validating the selected equivalent circuit model. Table 1 summarizes the values of the circuit parameters obtained from the best fit with the experimental impedance diagrams.

Contrary to charge-transfer resistance (), which does not vary significantly with film formation potential, film resistance () varies with film formation potential. increases considerably with film formation potential. This increase of is accompanied by a decrease of at every electrode potential, reflecting the growth and the thickening of the passive film or the decrease in the amount of charge carriers in the film. One can notice the continuous decrease of when the film formation potential increases and its highest value at films formed at 0.6 V. These results may be related to the presence and the competition of two kinds of oxides, chromium and iron. At low potentials (potentials lower than the transpassive potential of chromium), passive films are more enriched with chromium, making the films more protective. At high potential in the passive range, chromium decreases continuously and iron increases progressively and hence the protective effect reduces.

The values of the exponent obtained by fitting our EIS data were between 0.85 and 0.95, which points to a considerable passive film surface homogeneity; therefore, the constant phase element can be assumed to correspond to capacitive behavior, while the values of and obtained can be associated with a distribution of the relaxation times as a result of heterogeneities present at the interfaces and static disorders such as porosity [32].

The impedance of diffusion is independent of film formation potential. Defect transport is primarily due to migration under the influence of the electric field, and because the field strength is postulated to be independent of the applied potential in the point defect model, the impedance should be insensitive to the film formation potential [33].

The significant variation of with the film formation potential is characteristic for uniform distribution of surface-states. The values of initially increased with film formation potential in the region I. At a sufficiently high potential ( V), which is close to the onset of the transpassive state (Region II), is observed to decrease with increasing formation potential. Moreover, the change of shows a similar tendency. The surface-state capacitance decreases with increasing film formation potential. This decrease can be correlated either with a decrease of surface-state concentration or with a decrease of the active area available for their interaction.

The polarization resistance was taken to be the sum of , , , and . Figure 6 shows the variation of polarization resistance with the film formation potential. The polarization resistance () initially increased with film formation potential in the region I. This is due to the establishment of the passive oxide layer. At a sufficiently high potential ( V), which is close to the onset of the transpassive state (Region II), the polarization resistance is observed to decrease with increasing potential. It has been reported that this is due to the oxidative ejection of Cr (VI) from the passive film.

4. Conclusion

(1)The impedance data obtained for AISI 304 in sulphuric aid solution were adequately represented by an equivalent electrical circuit model, comprising two elements in series with a and an uncompensated solution resistance.(2)The interfacial impedance and polarization resistance initially increased with applied potential. At a sufficiently high potential ( V), which is close to the initiation of the transpassive state, the interfacial impedance and polarization resistance were observed to decrease with increasing potential. The polarization resistance of AISI 304 stainless steel is of the order of 103 kΩcm2, commensurate with its high corrosion resistance.