Structure and oxidation behavior of CoCrFeNiX (where X is Al, Cu, or Mn) coatings obtained by electron beam cladding in air atmosphere

High-entropy alloys (HEAs) are currently considered as promising materials for a wide range of applications, including high-temperature use. Since HEAs contain a large number of expensive elements, producing HEA-based coatings seems to be a reasonable approach from an economic point of view. In this...

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Bibliographic Details
Published in:Surface & coatings technology 2022-10, Vol.448, p.128921, Article 128921
Main Authors: Ruktuev, Alexey A., Lazurenko, Daria V., Ogneva, Tatiana S., Kuzmin, Ruslan I., Golkovski, Mikhail G., Bataev, Ivan A.
Format: Article
Language:English
Subjects:
Electron beam cladding
High-entropy alloy
High-temperature oxidation
Microstructure
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Summary:High-entropy alloys (HEAs) are currently considered as promising materials for a wide range of applications, including high-temperature use. Since HEAs contain a large number of expensive elements, producing HEA-based coatings seems to be a reasonable approach from an economic point of view. In this study, non-vacuum electron beam cladding was used for the first time to produce CoCrFeNiX layers (where X = Al, Cu or Mn) on a surface of low-carbon steel. As-received coatings had a columnar grain structure with a 〈100〉 fiber texture. The CoCrFeNiCu cladding layer consisted of two fcc phases: Cu-enriched phase was observed in the interdendritic regions, and the Cu-depleted phase was found in dendrites. The CoCrFeNiMn coating had a single-phase fcc structure. CoCrFeNiAl alloy consisted of bcc and B2 phases. The hardness of the Cu and Mn-containing coatings was 190 and 186 HV, respectively. The hardness of the CoCrFeNiAl coating was 570 HV, which is 3.4 times higher compared to the material of the substrate. High-temperature oxidation tests carried out at 850 °C for 45 h revealed that oxide layers formed on the tested samples had a gradient structure that consisted of several different sublayers. The total mass gain due to high temperature oxidation was 2.29 mg/cm2, 2.04 mg/cm2, and 0.60 mg/cm2 for the CoCrFeNiCu, CoCrFeNiMn, and CoCrFeNiAl samples, respectively. The mass gain of the base material over the same period of time was 41.01 mg/cm2. The CoCrFeNiAl coating had the best oxidation resistance due to the formation of a dense Al2O3 scale. We show that non-vacuum electron beam cladding can be used to produce an HEA-based coating with a different chemical composition. The thickness of coatings in a single pass cladding can be as high as 1.8 mm. CoCrFeNiAl is a suitable coating for low-carbon steel in applications where high hardness and oxidation resistance are required. •HEA-based coatings were fabricated by non-vacuum electron beam cladding.•Coatings were produced from Co + Cr + Ni + X (X = Al, Cu, Mn) powders on Fe-based substrate.•Coatings possessed the columnar grain structure with a  fiber texture.•Gradient oxide layers were formed on the coatings during oxidation at 850 °C.•CoCrFeNiAl coating possessed the best oxidation resistance compared to other samples.
ISSN:0257-8972
1879-3347
DOI:10.1016/j.surfcoat.2022.128921