Insights into protective performance of CoCrNi medium entropy alloy coating subjected to supersonic micro-ballistic impact

• Published in: International journal of impact engineering Vol. 180; p. 104714
• Main Authors: Dong, J.L., Li, F.C., Wu, X.Q., Wang, G.J., Zhang, X.P., Luo, B.Q., Chen, X.M., Tan, F.L., Liu, Y.H., Jiang, M.Q., Zhao, J.H., Huang, C.G., Sun, C.W.
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 01.10.2023
• Subjects: Impact-mode ratio; Medium entropy alloy; Protective coating; Protective performance; Supersonic microparticle impact; Impact-mode ratio; Medium entropy alloy; Protective coating; Protective performance; Supersonic microparticle impact
• ISSN: 0734-743X; 1879-3509
• DOI: 10.1016/j.ijimpeng.2023.104714

•High-quality amorphous CoCrNi MEA coatings were fabricated through IBAD method.•Impact mode of CoCrNi MEA coating were obtained under microparticles impact.•MEA coating shows high impact resistance under supersonic impact of microparticles. Medium- and high-entropy alloys (MEAs and HEAs) coatings have attracted increasing attention owing to their exceptional mechanical properties and potential applications in structures protective from supersonic microparticle impact. However, there are no experimental insights into their protective performance. In this study, we fabricated high-quality amorphous CoCrNi MEA coatings with a thickness of 4.5 μm on the rigid and flexible substrates through ion beam-assisted deposition. Based on nanoindentation and laser-induced supersonic microparticle impact experiments, the mechanical properties and protective performance of the CoCrNi MEA coating were characterized and compared with those of the aluminum and copper coating. The results show that the CoCrNi MEA coating exhibits a high hardness of 9.7 GPa and an elastic modulus of 146.8 GPa. Under the supersonic impact, the CoCrNi MEA coating shows high coefficient of restitution, low rebound-to-fracture transition velocity, and small impact-mode ratios. The impact-mode ratios of the CoCrNi MEA coating subjected to microparticles of different materials further indicate that the CoCrNi MEA coating can efficiently withstand the high-velocity impact of most metallic particles except tungsten ones. Our work provides direct experimental insights into the excellent impact resistance of CoCrNi MEA coatings, which holds a great promise for improving the reliability and durability of equipment subjected to high-speed collisions of solid particles entrained within the air such as ice and sand dust. [Display omitted]