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Journal of Coatings Technology and Research

Erschienen in:

06.07.2016

Electrochemical and morphological properties of zirconium conversion coating in the presence of nickel ions on galvanized steel

verfasst von: H. R. Asemani, A. A. Sarabi, H. Eivaz Mohammadloo, M. Sarayloo

Erschienen in: Journal of Coatings Technology and Research | Ausgabe 5/2016

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Abstract

A hexafluorozirconic acid-based conversion coating was applied on a galvanized steel substrate and the influence of nickel ion from nickel sulfate solution (in zirconium solution and in a separate solution) on the corrosion resistance behavior and morphology of zirconium conversion coating was investigated. Electrochemical impedance spectroscopy and DC polarization were conducted in 3.5 wt% NaCl solution in order to optimize practical conditions of zirconium conversion coating and NiSO₄ solution on the galvanized steel substrate. Field emission scanning electron microscopy and X-ray photoelectron spectroscopy were employed to study the morphology and composition of the coated surfaces. Results revealed that the conversion coating obtained from solution containing zirconium and nickel ions (Zr + Ni) did not improve corrosion resistance and uniformity of the coating in comparison with Zr conversion coating in optimized condition. However, a positive effect was obtained from samples coated with separate solutions of zirconium and nickel (Zr–Ni). Improved corrosion resistance and morphology of Zr-based conversion coating were observed in Ni²⁺ concentration, pH, and immersion time of 10 g/L, 6 and 300 s, respectively. Morphology and surface composition analysis proved that two separate layers of conversion coating containing zirconium, zinc, and nickel oxide/hydroxide compounds were formed in the case samples that were treated by separate solutions. This led to better uniformity and higher thickness of the coating. Finally, adhesion strength of epoxy organic coating on galvanized steel with and without conversion coating was investigated by pull-off measurement. Zr–Ni conversion coating in optimum conditions had a positive effect on adhesion of organic coating in comparison with blank sample and samples pretreated with Zr and Zr + Ni conversion coatings through increased surface roughness and physical interlocking.

Vorheriger Artikel Colorimetric analysis of black coated fabrics

Nächster Artikel Electrochemical impedance study for modeling the anticorrosive performance of coatings based on accelerated tests and outdoor exposures

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Dillard, JI, Inorganic Chemistry: With the Elements of Physical and Theoretical Chemistry, 2nd ed. Wiley, New York (1908)

Graedel, TE, “Corrosion Mechanisms for Zinc Exposed to the Atmosphere.” J. Electrochem. Soc., 136 193c–203c (1989)CrossRef

John, S, The Useful Metals and Their Alloys. Houlston and Wright, London (1861)

Frank, P, Corrosion Resistance of Zinc and Zinc Alloys. CRC Press, Boca Raton (1994)

Yi, AH, Li, WF, Du, J, Mu, SL, “Preparation and Properties of Chrome-Free Colored Ti/Zr Based Conversion Coating on Aluminum Alloy.” Appl. Surf. Sci., 258 5960–5964 (2012)CrossRef

Adhikari, S, Unocic, KA, Zhai, Y, Frankel, GS, Zimmerman, J, Fristad, W, “Hexafluorozirconic Acid Based Surface Pretreatments: Characterization and Performance Assessment.” Electrochim. Acta, 56 1912–1924 (2011)CrossRef

Twite, RL, Bierwagen, GP, “Review of Alternatives to Chromate for Corrosion Protection of Aluminum Aerospace Alloys.” Prog. Org. Coat., 33 91–100 (1998)CrossRef

Eppensteiner, FW, Jenkins, MR, “Chromate Conversion Coatings.” Met. Finish., 105 413–424 (2007)CrossRef

Barrera-Diaz, C, Palomar-Pardave, M, Romero-Romo, M, Martinez, S, “Chemical and Electrochemical Considerations on the Removal Process of Hexavalent Chromium from Aqueous Media.” J. Appl. Electrochem., 33 61–71 (2003)CrossRef

10.

Sankara Narayanan TSN, “Surface Pretreatment by Phosphate Conversion Coatings.” Rev. Adv. Mater. Sci., 9 130–177 (2005)

11.

Jegannathan, S, Sankara Narayanan, TSN, Ravichandran, K, Rajeswari, S, “Formation of Zinc Phosphate Coating by Anodic Electrochemical Treatment.” Surf. Coat. Technol., 200 6014–6021 (2006)CrossRef

12.

Wang, C, Jiang, F, Wang, F, “The Characterization and Corrosion Resistance of Cerium Chemical Conversion Coatings for 304 Stainless Steel.” Corros. Sci., 46 75–89 (2004)CrossRef

13.

Lee, YL, Chu, YR, Chen, FJ, Lin, CS, “Mechanism of the Formation of Stannate and Cerium Conversion Coatings on AZ91D Magnesium Alloys.” Appl. Surf. Sci., 276 578–585 (2013)CrossRef

14.

Gang, K, Lingyan, L, Jintang, L, Chunshan, C, Zheng, Z, “Corrosion Behavior of Lanthanum-Based Conversion Coating Modified with Citric Acid on Hot Dip Galvanized Steel in Aerated 1 M NaCl Solution.” Corros. Sci., 53 1621–1626 (2011)CrossRef

15.

Hamdy, AS, Doench, I, Möhwald, H, “Vanadia-Based Coatings of Self-repairing Functionality for Advanced Magnesium Elektron ZE41 Mg–Zn–Rare Earth Alloy.” Surf. Coat. Technol., 206 3686–3692 (2012)CrossRef

16.

Yu-Te, T, Kung-Hsu, H, Ching-Yuan, B, Jeou-Long, L, Ming-Der, G, “The Influence on Immersion Time of Titanium Conversion Coatings on Electrogalvanized Steel.” Thin Solid Films, 518 7541–7544 (2010)CrossRef

17.

Eivaz Mohammadloo, H, Sarabi, AA, “Ti-Based Conversion Coatings on Cold Rolled Steel Substrate: The Effect of Practical Parameters and Ti Source on Surface and Electrochemical Properties.” Corrosion (2016). doi:http://dx.doi.org/10.5006/1936

18.

Tiwari, SK, Tripathi, M, Singh, R, “Electrochemical Behavior of Zirconia Based Coatings on Mild Steel Prepared by Sol–Gel Method.” Corros. Sci., 63 334–341 (2012)CrossRef

19.

Puomi, P, Fagerholm, HM, Rosenholm, JB, Sipila, R, “Optimization of Commercial Zirconic Acid Based Pretreatment on Hot-Dip Galvanized and Galfan Coated Steel.” Sur. Coat. Technol., 115 79–86 (1999)CrossRef

20.

Taheri, P, Lill, K, De Wit, JHW, Mol, JMC, Terryn, H, “Effects of Zinc Surface Acid-Based Properties on Formation Mechanisms and Interfacial Bonding Properties of Zirconium-Based Conversion Layers.” J. Phys. Chem., 116 8426–8436 (2012)

21.

Eivaz Mohammadloo, H, Sarabi, AA, Sabbagh Alvani, AA, Sameie, H, Salimi, R, “Nano-ceramic Hexafluorozirconic Acid Based Conversion Thin Film: Surface Characterization and Electrochemical Study.” Surf. Coat. Technol., 206 4132–4139 (2012)CrossRef

22.

Eivaz Mohammadloo, H, Sarabi, AA, Mohammad Hosseini, R, Sarayloo, M, Sameie, H, Salimi, R, “A Comprehensive Study of the Green Hexafluorozirconic Acid-Based Conversion Coating.” Prog. Org. Coat., 77 322–330 (2014)CrossRef

23.

Guan, Yong, “Novel Ti/Zr Based Non-chromium Chemical Conversion Coating for the Corrosion Protection of Electrogalvanized Steel.” Int. J. Electrochem. Sci., 6 4853–4867 (2011)

24.

Da Fonte, B, Mich, MC, Jr, “Trivalent Chromium Passivate Solution and Process.” US Patent 4,359,345 (1982)

25.

Bi-ian, LIN, Jin-tang, LU, Gang, KONG, Jun, LIU, “Growth and Corrosion Resistance of Molybdate Modified Zinc Phosphate Conversion Coatings on Hot-Dip Galvanized Steel.” Trans. Nonferrous Met. Soc. China, 17 755–761 (2007)CrossRef

26.

Ishizuka, K, Hayashi, K, Shindo, H, Nishimura, K, “The Effect of Mg Addition to the Phosphate Film on the Properties of Prephosphated Electrogalvanized Steel Sheets.” Galvanotechnik 219–223 (2007)

27.

Su, H-Y, Lin, C-S, “Effect of Additives on the Properties of Phosphate Conversion Coating on Electrogalvanized Steel Sheet.” Corros. Sci., 83 137–146 (2014)CrossRef

28.

Cheng-Yang, T, Jen-Shou, L, Pei-Li, C, Chao-Sung, L, “Effect of Mg²⁺ on the Microstructure and Corrosion Resistance of the Phosphate Conversion Coating on Hot-Dip Galvanized Sheet Steel.” Corros. Sci., 52 3907–3916 (2010)CrossRef

29.

Ramezanzadeh, B, Attar, MM, Farzam, M, “Corrosion Performance of a Hot-Dip Galvanized Steel Treated by Different Kinds of Conversion Coatings.” Surf. Coat. Technol., 205 874–884 (2010)CrossRef

30.

Mohammad Hosseini, R, Sarabi, AA, Eivaz Mohammadloo, H, Sarayloo, M, “The Performance Improvement of Zr Conversion Coating Through Mn Incorporation: With and Without Organic Coating.” Surf. Coat. Technol., 258 437–446 (2014)CrossRef

31.

Zhang, X, Van den Bos, C, Sloof, WG, Hovestad, A, Terryn, H, De Wit, JHW, “Comparison of the Morphology and Corrosion Performance of Cr(VI)- and Cr(III)-Based Conversion Coatings on Zinc.” Surf. Coat. Technol., 199 92–104 (2005)CrossRef

32.

Fedrizzi, L, Ciaghi, L, Bonora, PL, Fratesi, R, Roventi, G, “Corrosion Behaviour of Electrogalvanized Steel in Sodium Chloride and Ammonium Sulphate Solutions: A Study by E.I.S.” J. Appl. Electrochem., 22 247–254 (1992)CrossRef

33.

Akhtar, AS, Wong, KC, Mitchell, KAR, “The Effect of pH and Role of Ni²⁺ in Zinc Phosphating of 2024-Al alloy. Part I: Macroscopic Studies with XPS and SEM.” Appl. Surf. Sci., 253 493–501 (2006)CrossRef

34.

Zimmermann, D, Munoz, AG, Schultze, JW, “Microscopic Local Elements in the Phosphating Process.” Electrochim. Acta, 48 3267–3277 (2003)CrossRef

35.

Pourbaix, M, Atlas of Electrochemical Equilibria in Aqueous Solutions. Pergamon Press, New York (1966)

36.

Li, L, Desouzac, AL, Swain, GM, “In Situ pH Measurement During the Formation of Conversion Coatings on an Aluminum Alloy (AA2024).” J. Analyst., 138 4398–4402 (2013)CrossRef

37.

Ramezanzadeh, B, Attar, MM, “Effects of Co(II) and Ni(II) on the Surface Morphology and Anticorrosion Performance of the Steel Samples Pretreated by Cr(III) Conversion Coating.” Corrosion, 68 015008-1–015008-11 (2012)CrossRef

38.

Bass, JL, Turner, GL, “Anion Distributions in Sodium Silicate Solutions. Characterization by 29 SI NMR and Infrared Spectroscopies and Vapor Phase Osmometry.” J. Phys. Chem. B, 101 10638–10644 (1997)CrossRef

39.

Lu, YP, Qu, ZY, “Low-Chromium Passivation Film Zinc Coating Modification and Corrosion Resistance.” J. Mater. Prot., 36 35–37 (2003)

40.

Mahdavian, M, Attar, MM, “Electrochemical Behaviour of Some Transition Metal Acetylacetonate Complexes as Corrosion Inhibitors for Mild Steel.” Corros. Sci., 51 409–414 (2009)CrossRef

41.

Wang, W, Guo, HT, Gao, JP, Dong, XH, Qin, QX, “XPS, UPS and ESR Studies on the Interfacial Interaction in Ni-ZrO₂ Composite Plating.” Mater. Sci., 35 1495–1499 (2000)CrossRef

42.

Espinoza-González, RA, Diaz-Droguett, DE, Avila, JI, Gonzalez-Fuentes, CA, Fuenzalida, VM, “Hydrothermal Growth of Zirconia Nanobars on Zirconium Oxide.” Mater. Lett., 65 2121–2123 (2011)CrossRef

43.

Verdier, S, Delalande, S, van der Laak, N, Metson, J, Dalard, F, “Monochromatized X-ray Photoelectron Spectroscopy of the AM60 Magnesium Alloy Surface After Treatments in Fluoride-Based Ti and Zr Solutions.” Surf. Interface Anal., 37 509–516 (2005)CrossRef

44.

Jimenez, I, Palomares, FJ, Sacedón, JL, “SiO₂ Growth on GaAs by Reduction of GaAs Oxides: Separation of Stoichiometric Changes from SiO2/GaAs Band-Lineup Effects.” Phys. Rev. B., 49 11117–11126 (1994)CrossRef

45.

Lin, J, Chen, HY, Chen, L, Tan, KL, Zeng, HC, “NO₂ Decomposition over ZrO₂—An In-Situ DRIFT, TPR, TPD and XPS Study.” Appl. Surf. Sci., 103 307–314 (1996)CrossRef

46.

Dupin, JC, Gonbeau, D, Vinatier, P, Levasseur, A, “Systematic XPS Studies of Metal Oxides, Hydroxides and Peroxides.” Phys. Chem. Chem. Phys., 2 1319–1324 (2000)CrossRef

47.

Cornell, M, Schwertmann, U, The Iron Oxides: Structure, Properties, Reactions, Occurrences and Uses, 2nd ed. Wiley-VCH, Weinheim (2003)CrossRef

48.

Müller, U, Hauert, R, “XPS Investigation of TiO₂ Containing Diamond-Like Carbon Films.” Thin Solid Films, 290 323–327 (1996)CrossRef

49.

Venezia, AM, Bertoncello, R, Deganello, G, “X-ray Photoelectron Spectroscopy Investigation of Pumice-Supported Nickel Catalysts.” Surf. Interface Anal., 23 239 (1995)CrossRef

50.

Lorenz, P, Finster, J, Wendt, G, Salyn, JV, Zumadilov, EK, Nefedov, VI, “Esca Investigations of Some NiO/SiO₂ and NiO—Al₂O₃/SiO₂ Catalysts.” J. Electron Spectrosc. Relat. Phenom., 16 267–276 (1979)CrossRef

51.

Shalvoy, RB, Davis, BH, Reucroft, PJ, “Studies of the Metal–Support Interaction in Coprecipitated Nickel on Alumina Methanation Catalysts Using X-ray Photoelectron Spectroscopy (XPS).” Surf. Interface Anal., 2 11–16 (1980)CrossRef

52.

Casella, IG, Guascito, MR, Sannazzaro, MG, “Voltammetric and XPS Investigations of Nickel Hydroxide Electrochemically Dispersed on Gold Surface Electrodes.” J. Electroanal. Chem., 462 202–210 (1999)CrossRef

53.

Luo, PF, Kuwana, T, Paul, DK, Sherwood, PMA, “Electrochemical and XPS Study of the Nickel-Titanium Electrode Surface.” Anal. Chem., 68 3330–3337 (1996)CrossRef

54.

Kim, KS, Baitinger, WE, Amy, JW, Winograd, N, “ESCA Studies of Metal-Oxygen Surfaces Using Argon and Oxygen Ion-Bombardment.” J. Electron Spectrosc. Relat. Phenom., 5 351–367 (1974)CrossRef

55.

Rahme, R, Avril, F, Cassagnau, P, Sage, D, Verch, D, Doux, M, “New Polymer/Steel Solution for Automotive Application.” Int. J. Adhes. Adhes., 31 725–734 (2011)CrossRef

56.

Asemani, HR, Ahmadi, P, Sarabi, AA, Eivaz-Mohammadloo, H, “Effect of Zirconium Conversion Coating: Adhesion and Anti-corrosion Properties of Epoxy Organic Coating Containing Zinc Aluminum Polyphosphate (ZAPP) Pigment on Carbon Mild Steel.” Prog. Org. Coat., 94 18–27 (2016)CrossRef

Titel: Electrochemical and morphological properties of zirconium conversion coating in the presence of nickel ions on galvanized steel
verfasst von: H. R. Asemani
A. A. Sarabi
H. Eivaz Mohammadloo
M. Sarayloo
Publikationsdatum: 06.07.2016
Verlag: Springer US
Erschienen in: Journal of Coatings Technology and Research / Ausgabe 5/2016
Print ISSN: 1547-0091
Elektronische ISSN: 1935-3804
DOI: https://doi.org/10.1007/s11998-016-9800-x

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