Structural–Phase States of an Al–Fe–Co–Cr–Ni HEA Coating Formed on 5083 Alloy

An Al–Fe–Cr–Co–Ni high-entropy alloy (HEA) coating is deposited on a substrate made of 5083 alloy using the cold metal transfer (CMT) technology (wire-arc additive manufacturing (WAAM) in combination with welding surfacing). The HEA alloy has a nonequiatomic composition. The modern physical material...

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Published inPhysics of the solid state Vol. 65; no. 1; pp. 36 - 42
Main Authors Ivanov, Yu. F., Gromov, V. E., Konovalov, S. V., Efimov, M. O., Shlyarova, Yu. A., Panchenko, I. A., Starostenkov, M. D.
Format Journal Article
LanguageEnglish
Published Moscow Pleiades Publishing 2023
Springer
Springer Nature B.V
Subjects
Alloys
Aluminum oxide
Analysis
Chemical elements
Chromium
Coating
Coatings
Cobalt
Crystal defects
Grain boundaries
Grain sub boundaries
High entropy alloys
Inclusions
Iron
Nickel
Phase composition
Physics
Physics and Astronomy
Solid State Physics
Specialty metals industry
Substrates
Thickness
Wire industry
elemental and phase compositions
aluminum alloy 5083
cold metal transfer method
high-entropy alloy
defect substructure
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Summary:An Al–Fe–Cr–Co–Ni high-entropy alloy (HEA) coating is deposited on a substrate made of 5083 alloy using the cold metal transfer (CMT) technology (wire-arc additive manufacturing (WAAM) in combination with welding surfacing). The HEA alloy has a nonequiatomic composition. The modern physical materials science methods are used to analyze the structure, phase and elemental compositions, defect substructure of the coating–substrate system. It is shown that he elemental and phase compositions, the defect substructure of the coating are dependent on the distance from the zone of contacting the coating and the substrate. The layer with a thickness to 200 µm adjacent to the contact zone contains includes a second phase at the HEA grain boundaries rich in chromium and iron atoms. The microdiffraction analysis shows that these inclusions are Al 8 Cr 5 . It is revealed that nanocrystalline phases Al 2 O 3 and MgAlO with sizes 10–20 nm and a subgrained structure (subgrain size 140–170 nm) form in the zone of mixing the coating and substrate. The structure of the I type is characterized by inhomogeneous distribution of chemical elements in HEA; there are regions of lammelar shape enriched in Cr atoms and the regions of spherical shape enriched Ni, Fe, and Co atoms. Nanosized (NiCo) 3 , Al 4 , and Al 13 Fe 4 particles are arranged along the subgrain boundaries of the system. The physical mechanisms of increasing the material hardness in the coating-substrate contact are discussed.
ISSN:1063-7834
1090-6460
DOI:10.1134/S1063783423700063