Abstract
The effect of thermal spraying on the electrochemical activity of an anti-corrosion superalloy was studied quantitatively using scanning electrochemical microscopy (SECM). The superalloy used was Inconel 625 (a Ni base superalloy) and thin coatings of the alloy were formed on mild steel using high velocity oxy-fuel (HVOF) thermal spraying. The kinetics of electron transfer (ET) across the Inconel 625 coating/electrolyte interface were studied using SECM using ferrocenemethanol as the redox mediator. For comparison, the kinetics of ET across stainless steel/electrolyte and bulk wrought Inconel 625/electrolyte interfaces were also studied using SECM. The standard heterogeneous ET rate constant, k°, for ferrocenemethanol reduction at stainless steel was 1.0 ± 0.5 × 10 −3 cm s −1, compared to 2.6 ± 1.8 × 10 −2 cm s −1 at the wrought Inconel 625 surface. However, at the HVOF-sprayed Inconel 625 surface, the kinetics of ET varied across the surface and k° for ferrocenemethanol reduction ranged between ∼2.2 × 10 −4 cm s −1 and ∼2.6 × 10 −3 cm s −1. These results clearly demonstrate that SECM can be used to quantify the effect of thermal spraying on the electrochemical properties of Inconel 625 and that thermal spraying results in an electrochemically-heterogeneous surface.
Highlights
Thermal-sprayed corrosion resistant coatings are used in a wide variety of industries to enhance the lifetime of engineering components [1]
scanning electrochemical microscopy (SECM) has been used to measure the rate of electron transfer across the interface between a thermal sprayed anti-corrosion superalloy (Inconel 625) coating and an aqueous electrolyte
The rate of electron transfer from the coating to a redox species in solution was measured at discrete locations on the sprayed surface and the rate varied across the surface
Summary
Thermal-sprayed corrosion resistant coatings are used in a wide variety of industries to enhance the lifetime of engineering components [1]. One of the drawbacks of thermally sprayed coatings including HVOF coatings is that they do not offer the same level of corrosion resistance as the corresponding bulk alloys. SECM was recently used to visualise the electrochemical activity of thin coatings of Inconel 625, a Ni base superalloy that is used as a corrosion-resistant material [23]. SECM feedback approach curve experiments, in which ferrocenemethanol was used as a redox mediator, were used to determine the rate of ET across the interface between each substrate and an aqueous electrolyte. This analysis reveals that, in general, Inconel 625 is more electrochemically active than stainless steel. The HVOF process introduces heterogeneity to the surface of Inconel 625, which can be quantified by variations in the heterogeneous ET rate constant, k0, when measured at different locations on the coating surface
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