Series of Nanocrystalline NiCoAlFe(Cr, Cu, Mo, Ti) High-Entropy Alloys produced by Mechanical Alloying

Gómez-Esparza, C.D.; Baldenebro-López, F.J.; Gonzalez-Rodelas, L.; Baldenebro-López, Jesús; Martínez-Sánchez, R.

doi:10.1590/1980-5373-mr-2015-0668

Cited by 24 publications

(5 citation statements)

References 20 publications

(22 reference statements)

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“…The powders were generally smooth in texture with no agglomeration and they had particle sizes from about 45 to 106 μm, which resulted in good flowability during deposition. There were different morphologies observed; flake irregular shapes were Cr, Fe, and Ti particles while rounded or fairly spherical shapes were Al, Cu, Ni, and Co particles 49,50 . A gray and white two‐phase contrast in the powder particles of both alloys were observed, which was also reported by Mohanty, et al 51 The white contrast corresponds with the Al, Co, Fe, Ni with a low concentration of Cr and the gray contrast corresponds with the Ti and Cu contents.…”

Section: Resultssupporting

confidence: 62%

Process optimization of high entropy alloys by laser additive manufacturing

Dada

Popoola

Mathe

et al. 2020

Engineering Reports

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Aerospace components and their coatings are required to possess excellent surface properties over a wide temperature range. Stainless steels, titanium, nickel superalloy, and more recently high entropy alloys (HEAs) have been used to improve the exterior properties of these components. In this study, AlTiCrFe-CoNi and AlCoCrFeNiCu HEAs were successfully fabricated using laser additive manufacturing to produce coatings on an A301 steel base plate. The influence of the laser parameters (laser power and scan speed) on the microstructure and hardness properties were also investigated. The results revealed that coatings homogeneously adhered to the baseplate. The optimum processing parameters for both alloys with defect-free structures at a preheat temperature of 400 • C, were at 1200-1600 W at 8-12 mm/s with the layers composed of both face centred-cubic (FCC) and body centred-cubic (BCC) phases. The laser parameters affected the quality and hardness properties of the alloys. The results showed that optimizing the laser parameters achieved by preheating temperature invariably improved the performance of the alloys with potential coatings and structural applications.

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Section: Resultssupporting

confidence: 62%

Process optimization of high entropy alloys by laser additive manufacturing

Dada

Popoola

Mathe

et al. 2020

Engineering Reports

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“…Accordingly, similar to the FeNiMnCuCo alloy, in FeNiMnCuTi alloy, the FCC phase is more dominant, causing a large powder size after milling. Ti addition has also been reported to increase particle size in NiCoAlFeCuCr alloy [63]. The competition between the welding and fracturing and the hardening rate of initial powders can also affect the final particle size [61].…”

Section: Resultsmentioning

confidence: 99%

“…A ductile phase and a brittle phase can influence the fracturing and rewelding rates in such a way that particle size is reduced. The mean particle size decreases when hard and brittle elements, such as Mo and Cr, are added [63].…”

Section: Resultsmentioning

confidence: 99%

Alloying, phases and magnetic behaviour of mechanically alloyed FeNiMnCu-based high entropy alloys

Jahani

Reihanian

Gheisari

2023

Materials Science and Technology

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In the present work, FeNiMnCuX (X: Co, Cr, Mo, Ti, W) high entropy alloys are successfully fabricated by mechanical alloying. After 15 h of milling, FeNiMnCu and FeNiMnCuCo alloys form a single FCC structure, while other alloys formed an FCC + BCC mixture structure. All alloys contained homogeneous distributions of Fe and Ni, while Cu was segregated. Alloys FeNiMnCuTi and FeNiMnCuW exhibited homogeneous distributions of Mn, whereas others exhibited Mn-rich islands. Except for the FeNiMnCuTi alloy, all alloys exhibited a soft magnetic behaviour. The saturation magnetisation of the base FeNiMnCu alloy was increased by adding Co and decreased by adding Cr, Mo, Ti, and W.

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“…Similarly, mechanical alloying (MA), a solid-state powder process, is widely used for producing solid solution structures at the nanoscale with unusual properties, 13 being an alternate route instead of arc melting and casting for producing HEAs. 14 Gómez-Esparza et al 15 prepared the FeCoNiAlCr high-entropy alloy powder (HEAP) by MA, and thereafter, 10 h of milling the same has shown a mixture of solid solution phases of FCC and BCC.…”

Section: Introductionmentioning

confidence: 99%

Effect of Cr-Doping on the Structural and Magnetic Properties of Mechanically Alloyed FeCoNiAlMn_1–xCr_x High-Entropy Alloy Powder

et al. 2023

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In this work, the new compositions of FeCoNiAlMn 1−x Cr x , (0.0 ≤ x ≤ 1.0), a high-entropy alloy powder (HEAP), are prepared by mechanical alloying (MA). The influence of Cr doping on the phase structure, microstructure, and magnetic properties is thoroughly investigated through X-ray diffraction (XRD), scanning electron microscopy (SEM), and vibrating sample magnetometry. It is found that this alloy has formed a simple body-centered cubic structure with a minute facecentered cubic structure for Mn to Cr replacement with heat treatment. The lattice parameter, average crystallite size, and grain size decrease by replacing Cr with Mn. The SEM analysis of FeCoNiAlMn showed no grain boundary formation, depicting a single-phase microstructure after MA, similar to XRD. The saturation magnetization first increases (68 emu/g) up to x = 0.6 and then decreases with complete substitution of Cr. Magnetic properties are related to crystallite size. FeCoNiAlMn 0.4 Cr 0.6 HEAP has shown optimum results with better saturation magnetization and coercivity as a soft magnet.

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Series of Nanocrystalline NiCoAlFe(Cr, Cu, Mo, Ti) High-Entropy Alloys produced by Mechanical Alloying

Cited by 24 publications

References 20 publications

Process optimization of high entropy alloys by laser additive manufacturing

Process optimization of high entropy alloys by laser additive manufacturing

Alloying, phases and magnetic behaviour of mechanically alloyed FeNiMnCu-based high entropy alloys

Effect of Cr-Doping on the Structural and Magnetic Properties of Mechanically Alloyed FeCoNiAlMn_1–xCr_x High-Entropy Alloy Powder

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Series of Nanocrystalline NiCoAlFe(Cr, Cu, Mo, Ti) High-Entropy Alloys produced by Mechanical Alloying

Cited by 24 publications

References 20 publications

Process optimization of high entropy alloys by laser additive manufacturing

Process optimization of high entropy alloys by laser additive manufacturing

Alloying, phases and magnetic behaviour of mechanically alloyed FeNiMnCu-based high entropy alloys

Effect of Cr-Doping on the Structural and Magnetic Properties of Mechanically Alloyed FeCoNiAlMn1–xCrx High-Entropy Alloy Powder

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Effect of Cr-Doping on the Structural and Magnetic Properties of Mechanically Alloyed FeCoNiAlMn_1–xCr_x High-Entropy Alloy Powder