Kinetic measurements during transient film growth on zinc

Chen, Yun; Lobo, Rui F. M.; Santos, Diogo M. F.; Sequeira, César A. C.

doi:10.1590/S0100-40422009000200022

Abstract

The electrochemical behaviour of zinc has been extensively studied in alkaline and acid media, but only a few studies have been reported in neutral solutions, particularly in deaerated media. Zinc passivation in neutral medium and the effect of the ClO4- ion on the nucleation and growth of the passive layer is studied in this paper by a transient technique at different electrolyte concentrations and applied potentials. ZnO growth rate was shown to decrease with increasing electrolyte concentration. Moreover, passive layer growth occurred followed by pitting nucleation and growth. Film growth and pit nucleation are explained by means of the Macdonald and Engell-Stolica models.

zinc; passivation; pitting

ARTIGO

Kinetic measurements during transient film growth on zinc

Yun Chen^I; Rui F. M. Lobo^II; Diogo M. F. Santos^III; César A. C. Sequeira^III,^* * e-mail: cesarsequeira@ist.utl.pt

^IDepartment of Engineering Physics, University of Wisconsin-Madison, Wisconsin 53706, USA

^IIInstitute of Materials and Surfaces Science and Engineering, Faculty of Science and Technology, New University of Lisbon, 2829-516 Caparica, Portugal

^IIIInstitute of Materials and Surfaces Science and Engineering, Department of Chemical and Biological Engineering, Instituto Superior Técnico, Technical University of Lisbon, Av. Rovisco Pais, 1049-001 Lisboa, Portugal

ABSTRACT

The electrochemical behaviour of zinc has been extensively studied in alkaline and acid media, but only a few studies have been reported in neutral solutions, particularly in deaerated media. Zinc passivation in neutral medium and the effect of the ClO₄^- ion on the nucleation and growth of the passive layer is studied in this paper by a transient technique at different electrolyte concentrations and applied potentials. ZnO growth rate was shown to decrease with increasing electrolyte concentration. Moreover, passive layer growth occurred followed by pitting nucleation and growth. Film growth and pit nucleation are explained by means of the Macdonald and Engell-Stolica models.

Keywords: zinc; passivation; pitting.

INTRODUCTION

Zinc, one of the most widely used metals, cannot be worn in applications under applied stress due to its low creep resistance. It recrystallises rapidly after deformation at room temperature and, thus, cannot be work-hardened at room temperature. Creep resistance and recrystallisation temperature may be increased through alloying.¹ In the past decades, research on various aspects of corrosion of zinc has generated much technical information. Most of this wealth of information has been systematically and critically reviewed.²

The electrochemical properties of zinc are of most importance in its production and applications. For instance, electrowinning in zinc refining, electroplating in the production of zinc coatings, zinc batteries for energy storage, and zinc anodes for corrosion protection are all based essentially on zinc electrochemical properties. These properties include the relatively active position in the electromotive force series, fast and reversible dissolution/deposition kinetics, high overpotential for hydrogen evolution, and formation of passive film in slightly alkaline solutions.²

The electrochemical behaviour of zinc has been studied in alkaline media³ due to the need of developing primary cells with high dissolution electrode activity and without passivation; it has also been studied in acid media⁴ and slightly acid solutions⁵ due to its applications in the Cl₂/Zn and Leclanché's batteries. Despite its extensive use in galvanised steels,⁶ few studies have been reported in neutral solutions, particularly in deaerated media.^{5, 7} In neutral solutions, with chemical agents that are not electrochemically reactive and that do not form insoluble salts or complex ions with zinc, the corrosion rate of zinc is not very different from that in distilled water. However, there are several species (e.g. certain anions) that greatly influence the corrosion processes of zinc in solutions. Láng and Horányi^8,9 demonstrated that the reduction of ClO₄^- ions takes place during the spontaneous dissolution of Zn in HClO₄. They furnished unambiguous evidence that such reduction leads to the formation of aggressive chloride ions

which play an important role in the passive layer formation as well as in the pitting process. In the absence of oxygen, the perchlorate ion adsorbs on the electrode surface and enhances the chemical dissolution of the interior ZnO layer to form Zn²⁺ (aq).^10,11 Moreover, its reduction promotes the formation of the less protective exterior passive layer as a result of the high amount of OH^- produced from reaction (1). The formation of a thicker less protective exterior layer and a thinner interior one in absence of O₂ is consistent with the nucleation and growth of pitting corrosion products.¹² The aggressiveness of the ClO₄^- ion towards the passivated Zn electrode in a neutral medium is studied in this paper by potentiostatic current-time transients at different electrolyte concentrations and applied potentials. Kinetic parameters were derived for passive layer growth, pit nucleation and its growth. The phenomenon of passivity, the electrochemistry of passivation, the models for pit initiation leading to passive film breakdown, and the kinetics of pit growth can be found in a number of sources.^13-15 In the present study, the nucleation rate increases with increasing electrolyte concentration and anodic applied potential. Film growth and pit nucleation are explained by means of the Macdonald and Engell-Stolica models.^{16, 17}

EXPERIMENTAL

The working electrode was a disk made from a zinc rod (Aldrich, 99.999 %), with a geometric useful area of 0.243 cm², embedded in an epoxy resin. At the beginning of each electrochemical experiment, the electrode was polished with 800 grade emery paper under running water conditions and then thoroughly rinsed with purified water and dried with absorbent paper. A platinum sheet of 2 cm² geometric area was used as counter electrode and a saturated calomel electrode as reference, to which all potentials are referred. To avoid contamination with Cl^- ions, the reference electrode was connected to the working electrode through a bridge filled with the solution under test, the top of the bridge being pressed against the electrode surface to minimise the IR drop of the solution. The electrolyte solutions (0.001 - 0.1 M KClO₄ neutral solutions) were prepared from purified water (Milli-Q system) and KClO₄ (SIGMA, ACS Reagent, 99%). The solutions were deaerated with N₂ before each experiment, and during the experiments N₂ was passed over the non-stirred solutions. Tests for Cl^- ions in the ClO₄^- solutions revealed the absence of chloride ions after each experimental run.

The potentiostatic current-time transients were recorded by polarising potentiodynamically the working electrode from the starting potential of -1800 mV vs. SCE in the positive direction with the scan rate of 50 mVs^-1 to a potential limit E_a (< -500 mV vs. SCE) at which the current transients were recorded for 2 min. The selection of the -1800/-500 mV potential window was dictated by previous cyclic voltammetry measurements that showed an active/passive transition within that anodic span (Figure 1). A potentiostat/galvanostat (EG&G model 273) and a personal computer were used. Each experiment was performed with a freshly prepared solution and a newly polished set of electrodes. All measurements were carried out at room temperature (25 ± 0.5 ºC).

Figure 1

RESULTS AND DISCUSSION

SEM observations (Figure 2) confirmed the different nature of the zinc surface, from its pretreated situation (A) to its anodic polarisation showing passivity (B), starting of pit nucleation (C), and growth of pits (D).

The potentiostatic current-time transients for Zn in KClO₄ solutions with concentrations ranging from 0.001 to 0.1 M at various potential limits E_a (within the passive region) were recorded. Figure 3 represents some of these transients at E_a = -950 mV vs. SCE.

Inspection of the recorded results reveals that at low electrolyte concentration (< 0.01 M), the current decreases very rapidly with time to attain a steady state current value. The decrease in the transient current, i, is related to the growth of a ZnO layer on the electrode surface.^18-20 The film growth kinetics fits the model proposed by Macdonald et al.^{16, 21} which is given by:

where A and n are constants depending upon the potential limit E_a and the electrolyte concentration. The value of n represents the ZnO growth rate²² and is given by the slope of the descending part of the log i - log t relationship (Figure 3B). The data given in Table 1 show that the values of n decrease with increasing electrolyte concentration [KClO₄]. This means that as the KClO₄ concentration increases, the growth rate of ZnO decreases. This aggressiveness of the ClO₄^- species, already discussed in the Introduction section, is well reported in the literature.^23-26 Favouring reaction (1), weakens the passive layer, which breaks and promotes pit initiation and growth. Considering that chemical analysis did not detect any traces of Cl^- after each experimental run, it can be assumed that reaction (1), although very aggressive towards the ZnO passive layer, is kinetically hindered. At concentrations higher than about 0.005 M, the current transient initially decreases to a minimum value i_m at a characteristic pitting time parameter t_i (incubation time). In other words, at low concentrations (~ 0.001 - 0.005 M) the passive layer grows very quickly and pitting corrosion is not induced. At moderate and higher concentrations passive layer growth occurs followed by a current increase that indicates pitting nucleation and growth.^27-29 The reciprocal of the incubation time (t_i^-1) is taken as the rate of pit nucleation. After t_i, the current transient exhibits two straight lines with two different slopes. The time at the inflection point is denoted as the induction time (τ). The first straight line may be considered to correspond to the period of pit nucleation, while the second line to that of pit growth.³⁰ The increase of current transient after t_i can be represented by the Engell-Stolica equation for pitting corrosion:¹⁷

where B and b are constants depending upon the applied potential and the concentration of KClO₄. The slopes of the log i - log t curves after t_i (b₁ for the first line and b₂ for the second line) as well as the pit nucleation rate (t_i^-1) and i_m for various KClO₄ concentrations are given in Table 1.

The values of b₁ are nearly constant, while those of b₂, t_i^-1 and i_m increase with increasing perchlorate concentration. Moreover, current-time transient curves were recorded at various potential limits E_a for a given electrolyte concentration. Figure 4 represents some transients on linear (a) and logarithmic (b) scales for Zn in 0.1 M KClO₄ solution at E_a potentials ranging from -1100 mV to -950 mV (vs. SCE).

For anodic potentials in the lower limits of the passive region, the rapid decrease of i to a steady value means that only the ZnO film is formed. For anodic potentials higher than about -1000 mV vs. SCE, ZnO growth as well as pit nucleation and growth occur. Table 2 lists the values of n, b₁, b₂, t_i^-1 and i_m for the different anodic potentials used to obtain the results given in Figure 4. The values of n decrease with increasing applied potential, the values of b₁ are nearly constant, while those of b₂, t_i^-1 and i_m enhance with the potential limit E_a.

CONCLUSIONS

The corrosion behaviour of Zn in KClO₄ solutions was studied by current-time transient measurements. Previous potentiodynamic curves exhibited active/passive transitions. Zinc passivation is due to the formation of a ZnO layer on the electrode surface. Higher concentrations of ClO₄^- ions (>0.005 M) break down the passive layer and cause pitting corrosion at a certain anodic potential. The rate of pit nucleation increases with increasing both ClO₄^- concentration and applied anodic potential.

ACKNOWLEDGEMENTS

The authors would like to thank José A. D. Condeço for his help with the SEM measurements.

Recebido em 10/4/08; aceito em 6/10/08; publicado na web em 26/1/09

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2. Zhang, X. G.; Corrosion and Electrochemistry of Zinc, Plenum: New York, 1996.
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4. Kim, J. T.; Jorné, J.; J. Electrochem. Soc 1980, 127, 7.
5. Baugh, L. M.; Electrochim. Acta 1979, 24, 657.
6. Deslouis, C.; Duprat, M.; Tulet-Tournillon, C.; Corros. Sci 1989, 29, 13.
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9. Láng, G.; Horányi, G.; J. Electroanal. Chem 2003, 552, 197.
10. Sziráki, L.; Szöcs, E.; Philbáth, Zs.; Papp, K.; Kálmán, E.; Electrochim. Acta 2001, 46, 3743.
11. Justo, M. J.; Ferreira, M. G. S.; Corros. Sci 1993, 34, 533.
12. Szklarska-Smialowska, Z.; Pitting Corrosion of Metals, NACE: Houston, 1986.
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14. Kaesche, H.; Die Korrosion der Metalle, 3^rd ed., Springer-Verlag: Berlin, 1990.
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16. Macdonald, D. D.; Urquidi-Macdonald, M.; J. Electrochem. Soc 1990, 137, 2395.
17. Engell, H. J.; Stolica, D. N.; Z. Phys. Chem. Unterr 1959, 20, 113.
18. Sziráki, L.; Cziráki, A.; Geröcs, I.; Vértesy, Z.; Kiss, L.; Electrochim. Acta 1998, 43, 175.
19. Triboulet, R.; Perrière, J.; Prog. Crystal Growth Char. Mat 2003, 47, 65.
20. Chen, X. L.; Geng, X. H.; Xue, J. M.; Li, L. N.; J. Crystal Growth 2007, 299, 77.
21. Chao, C. Y., Lin, L. F.; Macdonald, D. D.; J. Electrochem. Soc 1981, 128, 1187.
22. Kim, J.; Pyun, S.; Electrochim. Acta 1995, 40, 1863.
23. Ujvári, M.; Láng, G.; Horányi, G.; J. Appl. Electrochem 2002, 32, 581.
24. Cachet, C.; Wiart, R.; J. Electroanal. Chem 1981, 129, 103.
25. Cachet, C.; Ganne, F.; Maurin, G.; Petitjean, J.; Vivier, V.; Wiart, R.; Electrochim. Acta 2001, 47, 509.
26. Cachet, C.; Ganne, F.; Joiret, S.; Maurin, G.; Petitjean, J.; Vivier, V.; Wiart, R.; Electrochim. Acta 2002, 47, 3409.
27. Amin, M. A.; Electrochim. Acta 2005, 50, 1265.
28. Abd El Aal, E. E.; Corros. Sci 2002, 44, 2041.
29. Assaf, F. H.; Abd El-Rehiem, S. S.; Zaky, A. M.; Mat. Chem. Phys 1999, 58, 58.
30. Milosev, I.; Metikos-Hukovic, M.; J. Electrochem. Soc 1991, 138, 61.

*

e-mail:

cesarsequeira@ist.utl.pt

Publication Dates

Publication in this collection
23 Apr 2009
Date of issue
2009

History

Received
10 Apr 2008
Accepted
06 Oct 2008

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] 1. Morgan, S. W. K.; Zinc and its Alloys and Compounds, Wiley: New York, 1985.

[2] 2. Zhang, X. G.; Corrosion and Electrochemistry of Zinc, Plenum: New York, 1996.

[3] 3. McKrube, M. C. H.; Macdonald, D. D.; J. Electrochem. Soc 1981, 128, 524.

[4] 4. Kim, J. T.; Jorné, J.; J. Electrochem. Soc 1980, 127, 7.

[5] 5. Baugh, L. M.; Electrochim. Acta 1979, 24, 657.

[6] 6. Deslouis, C.; Duprat, M.; Tulet-Tournillon, C.; Corros. Sci 1989, 29, 13.

[7] 7. Hamnett, H.; Mortimer, R. J.; J. Electroanal. Chem 1987, 234, 185.

[8] 8. Láng, G.; Inzelt, G.; Vrabecz, A.; Horányi, G.; J. Electroanal. Chem 2005, 582, 249.

[9] 9. Láng, G.; Horányi, G.; J. Electroanal. Chem 2003, 552, 197.

[10] 10. Sziráki, L.; Szöcs, E.; Philbáth, Zs.; Papp, K.; Kálmán, E.; Electrochim. Acta 2001, 46, 3743.

[11] 11. Justo, M. J.; Ferreira, M. G. S.; Corros. Sci 1993, 34, 533.

[12] 12. Szklarska-Smialowska, Z.; Pitting Corrosion of Metals, NACE: Houston, 1986.

[13] 13. Sato, N.; Hashimoto, K., eds.; Passivity of Metals and Semiconductors, Pergamon: Oxford, 1990, part 1.

[14] 14. Kaesche, H.; Die Korrosion der Metalle, 3^rd ed., Springer-Verlag: Berlin, 1990.

[15] 15. Frankel, G. S.; Scully, J. R.; Jahnes, C. V.; J. Electrochem. Soc 1996, 143, 1834.

[16] 16. Macdonald, D. D.; Urquidi-Macdonald, M.; J. Electrochem. Soc 1990, 137, 2395.

[17] 17. Engell, H. J.; Stolica, D. N.; Z. Phys. Chem. Unterr 1959, 20, 113.

[18] 18. Sziráki, L.; Cziráki, A.; Geröcs, I.; Vértesy, Z.; Kiss, L.; Electrochim. Acta 1998, 43, 175.

[19] 19. Triboulet, R.; Perrière, J.; Prog. Crystal Growth Char. Mat 2003, 47, 65.

[20] 20. Chen, X. L.; Geng, X. H.; Xue, J. M.; Li, L. N.; J. Crystal Growth 2007, 299, 77.

[21] 21. Chao, C. Y., Lin, L. F.; Macdonald, D. D.; J. Electrochem. Soc 1981, 128, 1187.

[22] 22. Kim, J.; Pyun, S.; Electrochim. Acta 1995, 40, 1863.

[23] 23. Ujvári, M.; Láng, G.; Horányi, G.; J. Appl. Electrochem 2002, 32, 581.

[24] 24. Cachet, C.; Wiart, R.; J. Electroanal. Chem 1981, 129, 103.

[25] 25. Cachet, C.; Ganne, F.; Maurin, G.; Petitjean, J.; Vivier, V.; Wiart, R.; Electrochim. Acta 2001, 47, 509.

[26] 26. Cachet, C.; Ganne, F.; Joiret, S.; Maurin, G.; Petitjean, J.; Vivier, V.; Wiart, R.; Electrochim. Acta 2002, 47, 3409.

[27] 27. Amin, M. A.; Electrochim. Acta 2005, 50, 1265.

[28] 28. Abd El Aal, E. E.; Corros. Sci 2002, 44, 2041.

[29] 29. Assaf, F. H.; Abd El-Rehiem, S. S.; Zaky, A. M.; Mat. Chem. Phys 1999, 58, 58.

[30] 30. Milosev, I.; Metikos-Hukovic, M.; J. Electrochem. Soc 1991, 138, 61.

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Kinetic measurements during transient film growth on zinc

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