Effect of Sub-T g Annealing on the Corrosion Resistance of the Cu-Zr Amorphous Alloys

doi:10.1007/s40195-017-0637-9

Abstract

Abstract:

Despite the economy of material cost and excellent toughness of Cu-based amorphous alloys, especially Cu₅₀Zr₅₀, their poor corrosion resistance to a chloride medium limits their widespread applications. In this study, corrosion tests were performed on the Cu₅₀Zr₅₀ amorphous alloy with different degrees of short-range order, which were prepared by annealing below the glass transition temperature (T _g). It was found that the corrosion resistance of amorphous alloys is improved to a significant level when the alloys were heated below T _g. Calorimetric studies showed that thermally activated relaxation process of created disorder, which occurs during sub-T _g annealing, is responsible for the improvement in the corrosion resistance. Molecular dynamics simulations performed on the Cu-Zr amorphous alloys demonstrated that the relaxation process of the alloys is associated with the formation of energetically stable icosahedra and icosahedron-like structures. Our study highlights the effects of sub-T _g annealing on the improvement in the corrosion resistance of the amorphous alloys from the viewpoint the relaxation process of the short-range orders.

Key words: Amorphous alloys, Corrosion, Annealing, Molecular dynamics, Electrochemical performance

Sang-Soo Shin, Hong-Kyu Kim, Jae-Chul Lee, Ik-Min Park. Effect of Sub-T _g Annealing on the Corrosion Resistance of the Cu-Zr Amorphous Alloys[J]. Acta Metallurgica Sinica (English Letters), 2018, 31(3): 273-280.

Figures/Tables 7

Fig. 1 a XRD patterns of the as-spun and the 20-min-annealed Cu50Zr50 samples, b HRTEM image and corresponding diffraction pattern of the 20-min-annealed Cu50Zr50 sample

Fig. 2 a DSC thermograms recorded from the as-spun and the 20-min-annealed samples, b magnified view of regions in the vicinity of the glass transition temperature, showing that annealing of the samples for different time changes the exothermic heat corresponding to α-relaxation

Fig. 3 Corrosion rates measured from the as-spun and the 20-min-annealed samples using immersion tests

Fig. 4 Surface morphologies of the samples immersed in 1 N NaCl aqueous solution for 4 h at the room temperature, showing the formation of pits in a the as-spun sample, b the 20-min-annealed sample

Fig. 5 a Potentiodynamic polarization curves, b Nyquist plots of the as-spun and the 20-min-annealed samples in a 0.1 N NaCl solution at room temperature

Fig. 6 Snapshots showing changes in the population of icosahedra and other polyhedra in the Cu50Zr50 amorphous alloy during the annealing process. The distribution of icosahedra in a the as-spun and b the annealed alloy shows that the population of icosahedra is increased after annealing, whereas the population of loosely packed polyhedra is decreased in c the as-spun, d the annealed alloy

Fig. 7 Variations of a the population of icosahedra, b the potential energy of the Cu50Zr50 amorphous alloy calculated as function of annealing time

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