Thermal transport property correlated with microstructure transformation and structure evolution of Fe-based amorphous coating

The correlation between the thermal transport properties and microstructure features of amorphous coatings is crucial for reliable thermal insulation applications. In this work, an Fe48Cr15Mo14C15B6Y2 amorphous coating prepared by high-velocity oxygen-fuel spraying (HVOF) was employed to reveal this relationship under long-term heating. From the combined effects of the amorphous phase and unique coating structure, the proposed coating exhibits an extremely low thermal conductivity of 1.92 W/(m center dot K), granting a significant potential for being as metal-based thermal barrier coatings. Isothermal annealing experiments below the glass transition temperature demonstrate that the thermal insulation property can maintain stability with prolonged annealing time, despite a slight degradation relative to the as-sprayed coating which is ascribed to structural relaxation. Although nearly full crystallization can be slowly induced by annealing at the critical temperature of 600 degrees C, the thermal conductivity displays a distinct two-stage variation with annealing time, which is primarily attributed to the sluggish sintering of the coating structure. Moreover, grain growth and rapid structural sintering result in a drastic degradation of thermal insulation in the early stage of annealing at 850 degrees C, whereas grain growth upon prolonged annealing governs further variation of thermal conductivity. The results of this study not only provide important insights into the degeneration mechanism of thermal insulation of Fe-based amorphous coating, but also present an inspiration for exploring the degeneration mechanism of the most metallic coatings serving at high temperatures.

Automated summary

The correlation between thermal transport properties and microstructure features of amorphous coatings was investigated in this study. The Fe48Cr15Mo14C15B6Y2 amorphous coating prepared by HVOF exhibited low thermal conductivity and potential for use in metal-based thermal barrier coatings. Isothermal annealing experiments showed that the thermal insulation property remained stable with prolonged annealing time, despite some degradation due to structural relaxation. The thermal conductivity exhibited a distinct two-stage variation with annealing time, primarily attributed to sluggish sintering of the coating structure.