Wear, corrosion and oxidation characteristics of consolidated and laser remelted high entropy alloys manufactured via powder metallurgy

Wear, corrosion and oxidation characteristics of consolidated and laser remelted high entropy alloys manufactured via powder metallurgy

High entropy alloys have promising wear, oxidation, and corrosion properties compared to conventional alloys and superalloys. In the present study, CrCuFeNiAl0.5 and CrCuFeNiAl0.5Si0.5 alloys were prepared using a traditional powder metallurgy process and then remelted the surfaces via laser. The la...

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Bibliographic Details
Published in:Surface & coatings technology Vol. 467; p. 129704
Main Authors: Kafali, Mertcan, Doleker, Kadir Mert, Erdogan, Azmi, Sunbul, Sefa Emre, Icin, Kursat, Yildiz, Ataberk, Gok, Mustafa Sabri
Format: Journal Article
Language:English
Published: Elsevier B.V 25-08-2023
Subjects:
Corrosion
High entropy alloy
Laser remelting
Oxidation
Powder metallurgy
Wear
Oxidation
Corrosion
High entropy alloy
Powder metallurgy
Wear
Laser remelting
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Summary:High entropy alloys have promising wear, oxidation, and corrosion properties compared to conventional alloys and superalloys. In the present study, CrCuFeNiAl0.5 and CrCuFeNiAl0.5Si0.5 alloys were prepared using a traditional powder metallurgy process and then remelted the surfaces via laser. The laser remelting (LR) process gains a denser and more homogeneous surface to alloys. Pressureless consolidated and laser-remelted specimens were subjected to wear, corrosion, and oxidation tests. In the wear tests, it was observed that the wear resistance of Si-containing samples was better due to higher hardness. However, the laser remelting process has mostly increased rather than reduced wear losses. The less volume loss of laser-melted samples was attributed to the almost pure Cu in its content. There is little difference among all samples in electrochemical corrosion measurements. The formation of a fragile passivation layer was observed in potentiodynamic polarization curves of CrCuFeNiAl0.5Si0.5 and LR-CrCuFeNiAl0.5Si0.5 alloys. The alloy with the best corrosion resistance is CrCuFeNiAl0.5Si0.5, whose icorr value is 0.936 × 10−6 A/cm2. After high-temperature oxidation tests, the CrCuFeNiAl0.5 alloy exhibited the worst oxidation performance due to not forming a protective oxide layer on the surface, while LR enabled the protective oxide scale in a short oxidation time. The presence of Si in this alloy relatively enhances the oxidation resistance. The best oxidation performance was observed in LR-CrCuFeNiAl0.5Si0.5 due to the forming of a protective Al2O3 layer during the oxidation tests. •Laser remelting significantly enhanced the microstructure and phase distribution.•Si addition increased hardness, wear, corrosion and oxidation resistance.•Cu-rich regions caused wear losses to be different than expected.•The addition of Si affects the electrochemical properties and passive film formation•The laser remelting process and Si addition provide alumina scale after oxidation.
ISSN:0257-8972
1879-3347
DOI:10.1016/j.surfcoat.2023.129704