Preparation and corrosion resistance of titanium–zirconium–cerium based conversion coating on 6061 aluminum alloy

Wang, Zhan; Qian, Xuzheng; Gui, Boyi; Liu, Xiaohui; Li, Zhipeng; Hu, Li‐Xin

doi:10.1002/maco.201911193

Cited by 16 publications

(12 citation statements)

References 23 publications

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“…Chlorine ions are known as a major element causing pitting corrosion by chemical attack of the passive film on the aluminum surface. [18][19][20][21] Particularly, corrosion of aluminum may be further promoted in summer due to the hot and humid environment. [22] Also, Cl − ions on the surface of the heat exchanger may be concentrated, leading to a serious corrosion phenomenon.…”

Section: Introductionmentioning

confidence: 99%

Effects of environmental factors on corrosion behavior of aluminum

Jung

Kwon

2020

Materials & Corrosion

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Aluminum, used as a material for heat exchangers in air conditioners, often has problems of leakage of refrigerant on the Al surface due to corrosion. The problems originate from pitting corrosion of the Al in an external environment. To understand corrosion problems, it is necessary to study the corrosion behavior of Al in various environments. In this study, the effects of environmental factors on the corrosion behavior of Al were studied by the surface analysis and electrochemical testing in 3.5 wt% NaCl solutions, with changes of dissolved oxygen, temperature, and concentration of Cl− and S ions. Among the external environmental factors, the presence of oxygen and the increase of Cl− ion concentration do not significantly affect the corrosion potential of Al, leading to an increase of only 1.1 and 6 times, respectively. There was a significant decrease in the corrosion resistance of Al, approximately 40 and 800 times, respectively, with the increase of concentration of S and temperature.

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Section: Introductionmentioning

confidence: 99%

Effects of environmental factors on corrosion behavior of aluminum

Jung

Kwon

2020

Materials & Corrosion

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“…Figure 4 exhibits the potentiodynamic polarization curves of Al alloy matrix, CoTiCC (Co 2 SO 4 : 2.0 g/L and H 2 TiF 6 : 1.5 ml/L) and CoTiMoCC (Co 2 SO 4 : 2.0 g/L, H 2 TiF 6 : 1.5 ml/L, and Na 2 MoO 4 : 1.0 g/L) in a neutral 3.5 wt% NaCl solution. The shape of polarization curves is similar to each other, and the relevant values of corrosion potential (E corr ) and corrosion current density (i corr ) are displayed in the inset [22]. Generally speaking, E corr is a thermodynamic parameter to characterize corrosion susceptibility.…”

mentioning

confidence: 58%

“…However, the distinction of the dropping time between the Na 2 MoO 4 content of 1.0 and 2.5 g/L is insignificant, and only 7 s. As a result, based on the economic benefits and the improvement of corrosion resistance, the most appropriate addition amount is 1.0 g/L. [22] Generally speaking, E corr is a thermodynamic parameter to characterize corrosion susceptibility. Obviously, CoTiMoCC demonstrates a nobler E corr value than the Al alloy matrix and CoTiCC and thus has a more thermodynamically steady system than the other.…”

Section: T a B L E 2 Superior Formula Of The Chemical Conversion Solu...mentioning

confidence: 99%

“…LY12 aluminum alloy contains an Al-rich matrix and a certain amount of intermetallic compounds, such as Mg 2 Si and Al 2 CuMg. [22,23] Owing to the chemical potential difference, the Al-rich matrix is used as the micro anode, while the intermetallic compounds are used as the micro cathode. Usually, in an electrochemical corrosion system, the metal dissolution reaction occurs in the micro anode, whereas the H evolution reaction together with the oxygen absorption reaction occurs in the micro cathode, as shown in Figure 10b.…”

Section: Formation Process Of Cotimoccmentioning

confidence: 99%

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Formation and corrosion resistance of a novel Co–Ti–Mo composite chromium‐free chemical conversion coating on LY12 aluminum alloy

Qian

Zhao

Wang

et al. 2022

Materials & Corrosion

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A novel type of Co–Ti–Mo conversion coating (CoTiMoCC) was prepared on LY12 aluminum alloy, furthermore the optimal formula and the effect of conversion time (CTI) were studied in detail. The micromorphology and phase compositions were systematically investigated by scanning electron microscopy and X‐ray photoelectron spectroscopy, and the corrosion resistance was determined by dropping test, electrochemical tests, and immersion test. Results reveal that the best formula of CoTiMoCC is Co2SO4: 2.0 g/L, H2TiF6: 1.5 ml/L, and Na2MoO4: 1.0 g/L and the corresponding optimal CTI is 16 min. Significantly, the micromorphology of CoTiMoCC under the best conversion condition is relatively smooth, continuous, and dense, and the major elements on the surface are Co, Ti, Mo, Al, O, and F. The phase compositions mainly consist of CoO, Co3O4, MoO3, Mo2O5, TiO2, and Al2O3, as well as a small quantity of AlF3·3H2O and Na3AlF6. Compared with the Al alloy matrix, CoTiMoCC acquires an order of magnitude lower Icorr and thus significantly reduces its corrosion rate, which is also confirmed by electrochemical impedance spectroscopy results. Further study of immersion test exhibits that the corrosion resistance of CoTiMoCC is approximately five times that of Al alloy matrix, and no obvious corrosion spots are generated on its surface.

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“…8 Thus, a variety of chromate-free and environmentally friendly conversion coatings have been developed, such as phosphate/permanganate conversion coating, 9 molybdate conversion coating, 10 silicate conversion coating, 6 zirconium/titanium conversion coating, [11][12][13] and cerium (Ce) conversion coating. [14][15][16][17][18] Among these coatings, Ce conversion coating is a promising alternative to Cr (VI) conversion coating due to its unique properties such as environmental friendliness, high adhesive strength to the substrate, and excellent corrosion resistance. 19,20 In recent years, considerable efforts have been devoted to improving the corrosion resistance of Ce-based coatings on metal substrates.…”

Section: Introductionmentioning

confidence: 99%

Surface treatment and adhesion strength of aluminum foil for lithium‐ion battery package

Chen

Shen

Xia

et al. 2021

Surface & Interface Analysis

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In this study, an environmentally friendly cerium (Ce) conversion coating was deposited onto the surface of aluminum (Al) foil for preparing the packaging material of lithium‐ion batteries, and its morphology, composition, and formation mechanisms were investigated using scanning electron microscopy (SEM), atomic force microscopy (AFM), energy‐dispersive spectroscopy (EDS), and X‐ray photoelectron spectroscopy (XPS). The packaging material consisting of six layers was prepared by hot pressing using casting polypropylene (CPP) as the inner layer and maleic anhydride (MAH) grafted polypropylene (mPP) as the inner adhesive. The adhesion properties of untreated and Ce‐treated Al foils were characterized by T‐peeling test. The results show that Ce conversion coating is mainly composed of cerium dioxide (CeO2) and cerium sesquioxide (Ce2O3), and Ce treatment leads to a significant increase in the adhesive strength between Al foil and mPP.

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Preparation and corrosion resistance of titanium–zirconium–cerium based conversion coating on 6061 aluminum alloy

Cited by 16 publications

References 23 publications

Effects of environmental factors on corrosion behavior of aluminum

Effects of environmental factors on corrosion behavior of aluminum

Formation and corrosion resistance of a novel Co–Ti–Mo composite chromium‐free chemical conversion coating on LY12 aluminum alloy

Surface treatment and adhesion strength of aluminum foil for lithium‐ion battery package

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