Passivation of T2 Cu and QCr0.5 Cu-alloy with Chromate-free Solutions of Molybdate Compound

doi:10.11902/1005.4537.2017.017

Journal of Chinese Society for Corrosion and protection

2018, Vol. 38

Issue (2): 210-218 DOI: 10.11902/1005.4537.2017.017

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Passivation of T2 Cu and QCr0.5 Cu-alloy with Chromate-free Solutions of Molybdate Compound

Jiulong SONG, Wenge CHEN(

), Nannan LEI

School of Materials Science and Engineering, Xi'an University of Technology, Xi'an 710048, China

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Abstract

T2 Cu and QCr0.5 Cu-alloy were passivated in chromate-free solutions with single molybdate and complex molybdate respectively. The formed passivation films were then characterized by electrochemical method, nitric acid drop test, neutral salt spray test, SEM and XRD etc., taking the passivation film prepared with conventional chromate containing solution as comparison. Results show that the addition of polyaspartic acid (PASP) and H₂O₂ could improve the passivation effect of molybdate, especially the addition of the both simultaneously, which promoted the formation of passive film, the decrease of dissolution of Cu-alloy, and thereby the formation of a passivation film of copper oxide-based, significantly improved the corrosion resistance of T2 Cu and QCr0.5 Cu-alloy. After salt spray test, the surface of passivation treated samples presents metallic lustrousness to certain extent, while with less corrosion pits. In particular, the free-corrosion current density for T2 Cu passivated in molybdate solution with PASP+H₂O₂ is only 3.10×10^-6 A/cm², which is close to that for the chromate passivation film i.e. 9.06×10^-7 A/cm².

Key words: T2 Cu QCr0.5 Cu-alloy passivation molybdate polyaspartic acid

Received: 04 February 2017

Fund: Supported by Xi'an Science and Technology Project (2017080CG/RC043)

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Jiulong SONG, Wenge CHEN, Nannan LEI. Passivation of T2 Cu and QCr0.5 Cu-alloy with Chromate-free Solutions of Molybdate Compound. Journal of Chinese Society for Corrosion and protection, 2018, 38(2): 210-218.

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https://www.jcscp.org/EN/10.11902/1005.4537.2017.017 OR https://www.jcscp.org/EN/Y2018/V38/I2/210

Table 1 Chemical compositions of T2 Cu and QCr0.5 Cu-alloy
(mass fraction / %)

Table 2 Passivating solution components and process conditions of T2 Cu and QCr0.5 Cu-alloy

Table 3 Nitric acid-testing results of T2 Cu and QCr0.5 with different passivation treatments

Fig.1 Morphologies of T2 Cu and QCr0.5 Cu-alloy samples without (a1~a6) and with passivation treatments in Na₂MoO₄ (b1~b6), Na₂MoO₄+H₂O₂ (c1~c6), Na₂MoO₄+PASP (d1~d6), Na₂MoO₄+H₂O₂+PASP (e1~e6) and CrO₃+H₂SO₄+NaCl (f1~f6) solutions after salt spray test for different time

Fig.2 Weight gain curves of T2 Cu (a) and QCr0.5 Cu-alloy (b) samples without and with passivation treatments in different solutions during salt spray tests for 100 h

Fig.3 XRD spectra of T2 Cu (a) and QCr0.5 Cu-alloy (b) samples before and after passivation treatments

Fig.4 SEM images of T2 Cu (a1~f1) and QCr0.5 Cu-alloy (a2~f2) samples without (a1, a2) and with passivation treatments in Na₂MoO₄ (b1, b2), Na₂MoO₄+H₂O₂ (c1, c2), Na₂MoO₄+PASP (d1, d2), Na₂MoO₄+H₂O₂+PASP (e1, e2) and CrO₃+ H₂SO₄+ NaCl (f1, f2) soulutions after exposure in atmosphere for 7 d

Fig.5 SEM images of T2 Cu (a1~f1) and QCr0.5 Cu-alloy (a2~f2) samples without (a1, a2) and with passivation treatments in Na₂MoO₄ (b1, b2), Na₂MoO₄+H₂O₂ (c1, c2), Na₂MoO₄+PASP (d1, d2), Na₂MoO₄+H₂O₂+PASP (e1, e2) and CrO₃+ H₂SO₄+NaCl (f1, f2) solutions after salt spray test and then exposure in atmosphere for 7 d

Fig.6 Electrochemical polarization curves of T2 Cu (a) and QCr0.5 Cu-alloy (b) samples with passivation treatments after immersion in 3.5%NaCl solution for 1.5 h

Table 4 Fitting results of electrochemical polarization curves of T2 Cu and QCr0.5 Cu-alloy samples with various passivation treatments

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