Investigation of Formation Process of the Chrome-free Passivation Film of Electrodeposited Zinc

Chinese Journal of Aeronautics 20(2007) 129-133 Chinese Journal of Aeronautics www.elsevier.com/locate/cja Investigation of Formation Process of the Chrome-free Passivation Film of Electrodeposited Zinc ZHU Li-qun*, YANG Fei, HUANG Hui-jie School of Materials Science and Engineering, Beijing University of Aeronautics and Astronautics, Beijing, 100083, China Received 10 August 2006; accepted 19 December 2006 Abstract The feasibility was investigated to substitute chrome-free passivation treatment of electrodeposited zinc in a titanium bath for chromate passivation treatment. The formation mechanism of the chrome-free passivation film was further analyzed. The surface morphologies and the elemental compositions of the treated samples with varied immersion times were observed by scanning electron microscopy (SEM) and determined by energy dispersion spectrometry (EDS), respectively. The electrode potential of the sample surface was recorded in the film formation process. The changes of the electrode potential are in accordance with that of SEM and EDS of the sample surface. The results of X-ray photoelectron spectroscopy (XPS) show the chrome-free passivation film composed of ZnO, SiO 2, TiO 2, Zn 4 Si 2 O 7 (OH) 2, and SrF 2. The anode zinc dissolution and the local ph value increase due to the cathode hydrogen ion reduction process result in the formation of the chrome-free passivation film. The macro-images of the chrome-free passivation films formed on electrodeposited zinc show that the color of the film changes from blue to iridescence with the increase of the immersion times. Keywords: electrodeposited zinc; chrome-free pasivation film; film formation process 1 Introduction * Zinc is widely used as a coat material in steel coating to reduce corrosion. In this case the zinc acts as a sacrificial anode providing high corrosion resistance. However, a corrosion product, Zn(OH) 2, rapidly forms when the zinc coat is exposed to atmosphere or immersed in an aqueous solution. To avoid this, chromates are utilized as an efficient inhibitor to hinder corrosion of zinc. So far, the chromate passivation still remains one of the most efficient surface treatments for electrodeposited zinc. However, the wide use of noxious solutions always presents troublesome effluent disposal problems. The ever-increasing public concerns about the noxious and carcinogenic industrial wastes largely limit the future applications of the chromate passivation technology. In response to the appeals for an eco-friendly coating technology, new non-toxic passivation films together with high corrosion resistance have been unceasingly developed. Chrome-free processes like zirconium, titanium and hafnium compounds with an addition of fluorides have found their first applications in the container industry [1-3]. Recently, new types of passivation films have been produced by immersion in solutions containing cerium chloride [4-7] or other rare earth metal chlorides such as lanthanum [8]. In this paper, in the course of successful preparation of a titanium-based passivation film of electrodeposited zinc, a kind of chromate-free passivation films, special attentions was paid to the formation process of the film. *Corresponding author. Tel.: +86-10-82317113. E-mail address:zhulq@buaa.edu.cn

130 ZHU Li-qun et al. / Chinese Journal of Aeronautics 20(2007) 129-133 2 Experimental Procedure On the plate-substrates each measured 20 mm 40 mm 1 mm were electrodeposited to form a 9-12 μm thick zinc layers. The samples were immersed in 3 wt.% HNO3 at 20 for 3-6 s followed by a thorough rinse in distilled water. After activation and rinsing by water, the samples were again immersed in the titanium bath for 1-300 s with agitation. The chrome-free passivation films thus produced on the electrodeposited zinc were finally dried up by blowing air. The surface morphologies were observed by scanning electron microscopy (SEM, S-530). The elemental compositions of the samples were determined by energy dispersion spectrometry (LINK ISIS EDS). The X-ray photoelectron spectroscopy of the passivation films was recorded using an X-ray photo-electro-spectrometer (PHI Quantera SXM) with Al-Kα radiation as the X-ray source. The surface macro-images were taken by a Canon DIGI-TAL IXUS 30. The electrode potential of the surface of the samples was recorded in the film formation process. A saturated calomel electrode (SCE) was used as reference electrode. result shows that the composition of the sample is Zn 81.29, O 16.25, Ti 0.35, Si 0.48, Sr 0.20, F 0.53 (at.%). According to the previous research[9], the elements of Ti, Si, Sr and F are the composition of the chrome-free passivation film. This indicates that compounds of the film have formed on the surface of the sample. 3 Results and Discussion 3.1 Morphology and composition of the film in the film formation process SEM micrograph in Fig.1(a) shows the bare electrodeposited zinc. The sample surface is not smooth and zones of different depths (concave convex) exist. The chemical composition of the bare electrodeposited zinc by EDS analysis is Zn 92.67, O 7.33 (at.%). The element oxygen comes from the zinc oxide caused by the zinc exposed to open air. Fig.1(b) shows the sample treated in the titanium bath for 5 s. The sample surface is smooth and the composition of the sample is Zn 92.25, O 7.75 (at.%). This indicates that the zinc dissolves and there are not any film forming elements deposition. Fig.1(c) shows the zinc treated for 15 s and there are some granules on the surface of the sample. EDS Fig.1 SEM micrograph of electrodeposited zinc. (a) bare sample; (b-h) treated in bath for 5, 15, 45, 60, 90, 180 and 300 s respectively. SEM micrograph in Fig.1(d) shows the electrodeposited zinc treated in the passivation bath for 45 s. The whole surface of the sample is deposited as the granule structure. When the sample treated for 60 s, the granules become small (Fig.1(e)). For the sample treated longer, the granule structure dis-

ZHU Li-qun et al. / Chinese Journal of Aeronautics 20(2007) 129-133 131 appears and the surface becomes very smooth (Fig.1(f)). When the sample treated in the bath up to 300 s, the morphology of the sample becomes highly smooth, which was observed from SEM micrograph (Fig.1(h)). As shown in Table 1, the contents of Ti, Si, Sr and F increase with the immersion times in the titanium bath from 15 to 300 s. The results of the EDS indicate that the film becomes more integrated and thick. Table 1 EDS results of the sample with varied immersion times Immersion Element content / (at.%) time / s O F Si Ti Zn Sr 0 7.33 92.67 5 7.75 92.25 15 16.25 0.53 0.48 0.35 81.29 0.20 45 29.65 0.93 0.63 0.55 67.85 0.40 60 35.82 1.20 0.73 0.65 61.05 0.54 90 41.65 1.18 1.89 0.72 53.90 0.67 180 33.08 1.69 4.23 0.97 59.14 0.89 300 36.20 1.82 3.47 0.94 56.82 0.76 3.2 Electrode potential of the film in the film formation process Fig.2 shows the surface electrode potential of the sample with varied immersion times. The electrode potential reflects the surface state of the sample. For the immersion times from 1 to 5 s, the electrode potential of the sample decreases. It is in accordance with the corrosion state of surface (Fig.1(b)). Then the electrode potential of the sample increases fast up to 45 s and increases slow from 45 to 90 s. As shown in Fig.1(d), (e), (f), the sample surface becomes more intact and uniformly. The electrode potential of the sample is steady when the immersion time up to 100 s. As shown in Fig.1(g), (h), the sample surface changes a little. Fig.2 Electrode potential of the sample with varied immersion times. 3.3 XPS analysis and formation process of the film XPS was used to analyze the chemical composition of the passivation film. The XPS for the sample after sputtered with Ar + at a rate of 0.13 nm/s for 2 min are shown in Fig.3. Fig.3 The whole XPS of the chrome-free passivation film. The whole XPS of the chrome-free passivation film (the sample treated in the titanium bath for 45 s) is shown in Fig.3. The binding energies of the Zn 2p 1/2 and Zn 2p 3/2 peaks are 1 045.0 ev and 1 021.7 ev. The spectrum of Si 2p peaks at 101.6 ev. For the Ti 2p 1/2 and Ti 2p 3/2 peaks, the spectrum of Ti exhibits peaks at 464.3 ev and 458.4 ev. The binding energy of the O 1s peak is 530.1 ev. The binding energies of the Sr 3d 3/2 and Sr 3d 5/2 peaks are 131.3 ev and 133.8 ev. In the spectra for F 1s, peak for F appears at 684.5 ev. As shown in Table 1, the atomic ratio of Sr:F is about 1:2. According to the binding energies of pure compounds and previous research [10,11], the passivation film is mainly composed of ZnO, SiO 2, TiO 2, Zn 4 Si 2 O 7 (OH) 2, and SrF 2. In the titanium bath, Ti 3+ is oxidized into Ti 4+ and Ti 4+ exists in the form of [Ti(OH) 2 (H 2 O) 4 ] 2+. The anodic reaction is of zinc dissolution and the cathodic reaction is of hydrogen evolution. The increases of local ph value near the surface lead to the precipitation of titanium hydroxide, zinc hydroxide, and silicon hydroxide on the zinc surface. Then the dehydration of the hydroxides may react and the chrome-free passivation film forms on the electrodeposited zinc.

132 ZHU Li-qun et al. / Chinese Journal of Aeronautics 20(2007) 129-133 3.4 Macro-images of the passivation film in the film formation process Fig.4 shows the macro-images of the film with varied immersion times. 4 Conclusions The possibility of producing protective chrome-free paasivation films on electrodeposited zinc for anti-corrosion is explored. The film is composed of ZnO, SiO2, TiO2, Zn4Si2O7(OH)2, and SrF2. The film formation process is investigated. The anodic zinc dissolution and the local ph value increase due to the catholic hydrogen ion reduction process, thus resulting in the formation of the passivation film. The passivation film grows fast initially and following by slow growth. The further studies are still needed to be done in the investigation of the anti-corrosion behavior of the chrome-free passivation film obtained from the titanium bath. References [1] Wilcox G D, Wharton J A. A review of chromate-free passivation treatments for zinc and zinc alloys. J Trans IMF 1997; 75(6): 141-142. [2] Tang P T Bech-Nielsen G, Molker P M. Molybdate based alternatives to chromating as a passivation treatment for zinc. Plat & Surf Fin 1994; 81(11): 20-21. [3] Hara M, Ichino R. Corrosion protection property of colloidal silicate film on galvanized steel. Surface & Coating Technology 2003; 169-170: 679-681. [4] Aramaki K. Preparation of chromate-free, self-healing polymer films containing sodium silicate on zinc pretreated in a cerium (III) nitrate bath for preventing zinc corrosion at scratches in 0.5 M NaCl. Corrosion Science 2002; 44(6): 1375-1389. [5] Aramaki K. Cerium (III) chloride and sodium octylthiopropionate as an effective inhibitor mixture for zinc corrosion in 0.5 M NaCl. Corrosion Science 2002; 44(6): 1361-1374. [6] Aramaki K. Treatment of zinc surface with cerium (III) nitrate to prevent zinc corrosion in aerated 0.5 M NaCl. Corrosion Science 2001; 43(11): 2201-2215. [7] Aramaki K. Self-healing mechanism of an organosiloxane polymer film containing sodium silicate and cerium (III) nitrate for corrosion of scratched zinc surface in 0.5 M NaCl. Corrosion Science 2002; 44(7): 1621-1632. [8] Aballe A, Behtencourt M, Botana F J, et al. Electrochemical noise applied to the study of the inhibition effect of CeCl3 on the corrosion behaviour of Al-Mg alloy AA5083 in seawater. Electrochim. Fig.4 Macro-images of the films formed on electrodeposited zinc with varied immersion times. Acta 2002; 47(9): 1415-1422. [9] Yang F. Study on passivation technology on electrodeposited zinc

ZHU Li-qun et al. / Chinese Journal of Aeronautics 20(2007) 129-133 133 in titanium bath and performance of this film. Master thesis, Beijing: Beijing University of Aeronautics and Astronautics, 2007. [in Chinese]. [10] Wanger C D, Riggs W M, Davis L E, et al. Handbook of X-Ray photoelectro spectroscopy. Eden Prairie: Perkin Elmer Corp, 1979. [11] Zhu L Q, Yang F, Huang H J, et al. Blue passivation on electrodeposited zinc in titanium solution. Journal of Jiangsu University (Natural Science Edition) 2007; 28(2): 127-130. [in Chinese]. Biography: ZHU Li-qun Born in 1955, he received a B.S. degree from Beijing University of Aeronautics and Astronautics in 1977, a M.S. degree in 1986 and a Ph.D. in 1998. He is now working as a professor and a doctoral supervisor at the School of Materials Science and Engineering of Beijing University of Aeronautics and Astronautics. From 2002 to 2003, he did cooperative research work in the University of Queensland in Australia. His current research interest focuses on new technology of protective coatings and platings, chemical and electrochemical polishing, anodization of light alloys, electronic plating and test technology for accelerated corrosion. E-mail: zhulq@buaa.edu.cn YANG Fei Born in 1981, he received a B.S. degree from Beijing University of Aeronautics and Astronautics in 2004. Now he is a graduate student at the School of Materials Science and Engineering of Beijing University of Aeronautics and Astronautics. His current research focuses on chrome-free passivation technology for protective coatings and platings. E-mail: feiyang81@126.com