Development of Slippery Liquid-Infused Porous Surface on AZ31 Mg Alloys for Corrosion Protection

doi:10.1007/s40195-022-01459-7

Abstract

Abstract:

The relatively poor corrosion resistance remarkably limits the wide applications of Mg alloys in practice, although they possess many attractive properties, like low density, high specific strength, and good biocompatibility. The formation of a protective coating can effectively suppress the corrosion. In this work, a slippery liquid-infused porous surface (SLIPS), with good surface hydrophobicity, stability, and self-healing property, was formed on AZ31 Mg alloys. The development of SLIPS requires suitable porous micro/nanostructures. Layered double hydroxide (LDH), with effective corrosion resistance for Mg alloys, was a good candidate to accommodate the liquid lubricant. Especially, different temperatures were applied to in situ form MgAl-LDH on AZ31 Mg alloys. The results showed that the temperature of 120 °C was the best condition for the SLIPS to provide good corrosion protection for Mg alloys, with the lowest corrosion current density of 3.19 × 10^-9 A cm⁻². In addition, the SLIPS performed well in the long-term immersion test and abrasion test. The AZ31 Mg alloys with superior corrosion resistance and good mechanical and chemical stability can be extensively applied in areas of automotive, electronics, and aerospace.

Key words: Mg alloy, Hydrothermal temperature, Corrosion protection, Slippery liquid-infused porous surface, Hydrophobicity, Surface stability

Wenhui Yao, Yonghua Chen, Yanning Chen, Liang Wu, Bin Jiang, Fusheng Pan. Development of Slippery Liquid-Infused Porous Surface on AZ31 Mg Alloys for Corrosion Protection[J]. Acta Metallurgica Sinica (English Letters), 2023, 36(2): 229-236.

Figures/Tables 12

Fig. 1 Schematically illustrating a superhydrophobic surface, b SLIPS

Fig. 2 Schematic diagram illustrating the abrasion test

Fig. 3 SEM images of surface morphology of MgAl-LDH synthesized at a 60 °C, b 90 °C, c 120 °C, d 150 °C, e 180 °C, f SLIPS developed by MgAl-LDH synthesized at 120 °C. The inset in e is the optical image of MgAl-LDH synthesized at 180 °C

Fig. 4 XRD patterns of MgAl-LDH synthesized at different temperatures

Fig. 5 Variation of the weight of silicone oil in MgAl-LDH with hydrothermal temperature

Fig. 6 Water contact angle and sliding angle of AZ31, MgAl-LDH, superhydrophobic surface, and SLIPS

Fig. 7 Tafel polarization curves of AZ31 alloy, MgAl-LDH, superhydrophobic surface, and SLIPS

Fig. 8 Bode plots of a impedance modulus |Z|, b phase angle versus frequency of MgAl-LDH, superhydrophobic surface, and SLIPS

Fig. 9 Equivalent circuit model of a MgAl-LDH, b superhydrophobic surface and SLIPS

Fig. 10 Variation of hydrogen evolution volume of superhydrophobic surface and SLIPS with immersion time in 3.5 wt% NaCl solution

Fig. 11 Tafel polarization curve of SLIPS after abrasion test

Fig. 12 Optical image of MgAl-LDH surface after crosshatch adhesion test

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