Repassivation Behaviour of UNS S32101 and UNS S30403 Stainless Steels after Cathodic Stripping of the Native Passive Film in a CO2-Saturated Oilfield Brine ()
1. Introduction
The behavior of stainless steels in aqueous solution has been widely studied. It is widely agreed that the alloying elements help in the formation of the protective passive film [1] [2] . This film is stable, invisible, thin durable and extremely adherent and self-repairing. The stability of the film depends on the nature of the corroding metal and ions present in the solution [3] . In order to prevent corrosion, it is important that stainless steels have stable passive film with rapid passivation in severe environments [4] . It is believed that the stability of passive film and their repassivation kinetics are dependent on the metallurgy, applied passivation potentials, pH and chloride ion concentration in the aqueous solution [1] [5] [6] . Therefore, it is necessary to know the kinetics at which the passive film is formed on the stainless steels.
Reasons for the choice of UNS S32101 and UNS S30403 for this research are because these two alloys have been found to be competitors for applications in marine and oilfield environments [7] -[11] . Moreover, very few literatures exist on the repassivation kinetics of passive film in a CO2-saturated oilfield environment replicating service conditions where these two alloys find applications.
2. Materials and Method
Potentiostatic polarization tests were performed using EG & G 263A model potentiostat/galvanostat and a three-electrode electrochemical set up consisting of an Ag/AgCl reference electrode and a platinum counter electrode in order to obtain the current decay at constant applied potentials. The working electrode was polarized to a potential of −850 mVAg/AgCl for 1800 s to thin/remove the passive film formed in air [12] -[14] . The potential was then stepped to −200, −100, 0, 100, and 200 mVAg/AgCl. The chosen passive potential was then applied for 5 minutes and the potentiostatic current density was recorded. The data acquisition was 50 points/s in order to record higher number of points.
Meanwhile, in this study, oilfield brine (Table 1) was adopted. The oilfield brine was initially sparged with CO2 gas for 8hrs and stored in an air tight container. Before each experiment, the oilfield brine was sparged for one hour resulting in a pH of approximately 5.0 and the oxygen level less than 50 ppb. Moreover, CO2 was continuously fed into the solution throughout the duration of the experiment. Table 2 shows the composition of the alloys used for this research.
3. Results and Discussion
Figure 1 and Figure 2 show the anodic current transient for both alloys. It can be observed that for both alloys, the passive film repassivates at potentials of 0, −100 and −200 mV. This is shown by the steady decrease of current with time. The steady current decrease indicates anodic film growth [15] . A steady increase of current with time is however observed for both alloys at potentials of 100 mV and 200 mV. A steady increase in current indicates corrosion as a result of anodic film dissolution. This indicates that the passive film is not protective at these potentials. Park et al. [16] , also described such steady current increase to be as a result of metastable or stable corrosion pits.
Table 1. Oilfield brine adopted for the research.
Table 2. Composition of the alloys in solution annealed condition.
Figure 1. Anodic current transient for UNS S32101 after cathodic stripping at 50˚C.
Figure 2. Anodic current transient for UNS S30403 after cathodic stripping at 50˚C.
During the current decrease (repassivation stage at lower potentials), three stages can be described. The stage of adsorption of metal-hydroxide species on the bare metal surface exposed to the medium, the stage of transformation of the adsorb layer to passive film and the stage of growth of passive film [17] .
At higher potential, local anodic dissolution are promoted with the formation of pit nuclei [17] . However, at lower applied potential range that falls within the Tafel region, adsorbed metal-hydroxide species on bare surfaces of metals seems to be sufficiently stable to hinder metal dissolution [18] . This can be related to the behavior of the alloys at potentials of −200 mV, −100 mV and 0 mV as shown in Figure 1 and Figure 2. As the applied anodic potential increased from the Tafel region to the active region, the rate of the dissolution of the passive film into solution increased. Hence the behavior of the alloys at potentials of 100 and 200 mV as showed in Figure 1 and Figure 2.
Figure 3 and Figure 4 show the anodic current transients in logarithm scale for UNS S32101 and UNS S30403 in a CO2-saturated oilfield brine at 50˚C. Both figures show three stages [16] [19] corresponding to constant current stage, transition stage and a stage where the current either decreases or increases with time. The first stage (constant current) seems to be similar for both alloys at all potentials. Stage two also looks similar showing the start of current decay at potentials of −200 mV, −100 mV and 0 mV and the start of increasing current at potentials of 100 mV and 200 mV. The third stage also shows similarity for both alloys with a steep increase or decrease in current. There is a general decrease in current with time in logarithm scale for both alloys
Figure 3. Anodic current transients in logarithm scale for UNS S30403 after cathodic stripping at 50˚C.
Figure 4. Anodic current transients in logarithm scale for UNS S32101 after cathodic stripping at 50˚C.
at potentials of −200 mV, −100 mV and V0 mV. The current, however increases with time for potentials of 100 mV and 200 mV at stage III.
The current density recorded corresponds to the total current density resulting from the film formation and dissolution of the alloys in the solution [5] . The three stages (Figure 3 and Figure 4) described above can be explained thus: Stage I is the constant current stage where the rate of oxide formation and dissolution is equal [16] [19] . At this stage oxide film hardly grows. Stage II corresponds to the transition zone where the current density either starts to decrease or increase, depending on whether the passive film is protective or non-protec- tive. Stage III is the region where the anodic current density either decreases or increases linearly in logarithm scale depending on whether the passive film is passivating or dissolving/depassivating. If the current decreases it means that the passive film is repassivating and hence it is protective. The converse is the case when the current increases.
It can also be observed that at potentials of −200 mV, −100 mV and 0 mV, the rate of passivation dominates the rate of dissolution. This implies that the alloy may not be susceptible to pitting corrosion at these potentials. However, at potentials of 100 mV and above, the rate of dissolution is higher than the rate of passivation as indicated by a steady rise in the current density in logarithm scale in Figure 3 and Figure 4. This implies that the passive film may not be protective at potentials above this value.
4. Conclusions
1) The passive film formed on both UNS S32101 and UNS S30403 after an initial cathodic stripping repassivates at potentials of −200 mV, −100 mV and 0 mV at 50˚C. This is shown by the continuous steady anodic current decrease for both alloys at these test potentials.
2) The passive film formed on both UNS S32101 and UNS S30403 does not repassivate at potentials of 100 mV and 200 mV the test temperature of 50˚C. This is shown by the continuous steady anodic current increase for both alloys at these test potentials, both alloys are therefore susceptible to pitting corrosion at these potentials.
3) UNS S32101 and UNS S30403 behaved similarly in the oilfield brine used for this research. Both alloys are therefore likely to have similar resistance to localized corrosion and stress corrosion cracking. This is because both pitting corrosion and stress corrosion cracking depend on the repassivation behavior of passive film.