Effects of W and Mo Additions on Wet-dry Acid Corrosion Behavior of Low-Alloy Steels Under Different O2 Concentrations

doi:10.1007/s40195-016-0475-1

Abstract

Abstract:

Effects of W and Mo additions on wet-dry acid corrosion behavior of low-alloy steels under different O₂ concentrations were investigated. The results showed that W and Mo-containing steels presented excellent wet-dry corrosion resistance under O₂ concentrations of both 1 and 5%. The roles of W and Mo played in increasing corrosion resistance of the steels were different. W could improve the thermodynamic stability of the steel substrate, while Mo could promote the formation of protective rust. Interaction between W, Mo and O₂ concentration greatly influenced wet-dry acid corrosion of low-alloy steels. W addition was more effective for depressing charge transfer process at the rust/substrate interface and presented higher enhanced effect on increasing corrosion resistance than Mo under O₂ concentration of 1%. Mo was more effective on increasing rust compactness and showed higher enhanced effect on increasing corrosion resistance than W under O₂ concentration of 5%.

Key words: Wet-dry acid corrosion, SteelCorrosion resistance, Electrochemical impedance spectroscopy (EIS), Rust

Qing-He Zhao,Wei Liu,Shuan-Zhu Li,Bin-Li Zhang,Yi-Chun Zhu,Min-Xu Lu. Effects of W and Mo Additions on Wet-dry Acid Corrosion Behavior of Low-Alloy Steels Under Different O₂ Concentrations[J]. Acta Metallurgica Sinica (English Letters), 2016, 29(10): 951-962.

Figures/Tables 19

Fig. 1 Schematic of wet-dry acid corrosion test device

Fig. 2 SEM micrographs of the bare steels: a blank steel; b W steel; c Mo steel

Fig. 3 Corrosion loss of the steels in wet-dry acid corrosion environments with different O2 concentrations of a 1%; b 5%

Fig. 4 Potentiodynamic polarization curves of the bare steels in 0.01 M Na2SO4 solution with pH 3.0 and at temperature of 25 °C

Fig. 5 EIS plots of the bare steels tested in 0.01 M Na2SO4 solution with pH 3.0 and at temperature of 25 °C

Fig. 6 Equivalent circuit for fitting EIS plots of the bare steels tested

Fig. 7 EIS plots of rusted steels in 1% O2 wet-dry acid corrosion: a, b 14 CCT; c, d 28 CCT; e, f 42 CCT

Fig. 8 Equivalent circuit for fitting EIS plots of rusted steels

Fig. 9 EIS plots of the rusted steels in 5% O2 wet-dry acid corrosion: a, b 14 CCT; c, d 28 CCT; e,f 42 CCT

Fig. 10 SSA of the rust at 42 CCT in wet-dry acid corrosion with O2 concentrations of a 1%; b 5%

Fig. 11 Cross-sectional morphologies of the rusts at 42 CCT in wet-dry acid corrosion: a-c for the blank steel, W steel, and Mo steel under O2 concentration of 1%; d-f for the blank steel, W steel, and Mo steel under O2 concentration of 5%

Fig. 12 Distribution of the elements W and Mo in the rust at 42 CCT in wet-dry acid corrosion: a W 1% O2; b Mo 1% O2; c W 1% O2; d Mo 5% O2

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Effects of W and Mo Additions on Wet-dry Acid Corrosion Behavior of Low-Alloy Steels Under Different O₂ Concentrations

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