Influence of the Bias Potential and the Pressure of the Nitrogen Atmosphere on the Structure and Properties of Vacuum-arc Coatings Based on the AlCrTiZrNbV High-entropy Alloy

V-Nb-Mo-Ta-W high-entropy alloy (HEA), one of the refractory HEAs, is considered as a next-generation structural material for ultra-high temperature uses. Refractory HEAs have low castability and machinability due to their high melting temperature and low thermal conductivity. Thus, powder metallurgy becomes a promising method for fabricating components with refractory HEAs. Therefore, in this study, we fabricated spherical V-Nb-Mo-Ta-W HEA powder using hydrogen embrittlement and spheroidization by thermal plasma. The HEA ingot was prepared by vacuum arc melting and revealed to have a single body-centered cubic phase. Hydrogen embrittlement which could be achieved by annealing in a hydrogen atmosphere was introduced to get the ingot pulverized easily to a fine powder having an angular shape. Then, the powder was annealed in a vacuum atmosphere to eliminate the hydrogen from the hydrogenated HEA, resulting in a decrease in the hydrogen concentration from 0.1033 wt% to 0.0003 wt%. The angular shape of the HEA powder was turned into a spherical one by inductively-coupled thermal plasma, allowing to fabricate spherical V-Nb-Mo-Ta-W HEA powder with a d50 value of 28.0 μm.

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Microstructure and Mechanical Properties of Co-Cr-Mo-Si-Y-Zr High Entropy Alloy

Metals ◽

10.3390/met10111456 ◽

2020 ◽

Vol 10 (11) ◽

pp. 1456

Author(s):

Karsten Glowka ◽

Maciej Zubko ◽

Paweł Świec ◽

Krystian Prusik ◽

Robert Albrecht ◽

...

Keyword(s):

Electron Microscopy ◽

Microstructure Analysis ◽

Vacuum Arc ◽

High Entropy Alloy ◽

High Entropy ◽

Arc Melting ◽

Vacuum Arc Melting ◽

Transmission Electron ◽

Multi Phase ◽

Principal Elements

Presented work was focused on obtaining new, up to our knowledge, non-described previously in the literature high entropy Co15Cr15Mo25Si15Y15Zr15 alloy to fill in the knowledge gap about the six-elemental alloys located in the adjacent to the center of phase diagrams. Material was obtained using vacuum arc melting. Phase analysis revealed the presence of a multi-phase structure. Scanning electron microscopy microstructure analysis revealed the existence of three different phases with partially dendritic structures. Chemical analysis showed that all phases consist of all six principal elements—however, with different proportions. Transmission electron microscopy microstructure analysis confirmed the presence of amorphous and nanocrystalline areas, as well as their mixture. For the studied alloy, any phase transformation and solid-state crystallization were not revealed in the temperature range from room temperature up to 1350 °C. Nanoindentation measurements revealed high nanohardness (13(2) GPa and 18(1) GPa for dendritic and interdendritic regions, respectively) and relatively low Young’s modulus (185(23) GPa and 194(9) GPa for dendritic and interdendritic regions, respectively) of the observed phases.

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Phase Evolution and Microstructure Analysis of CoCrFeNiMo High-Entropy Alloy for Electro-Spark-Deposited Coatings for Geothermal Environment

Coatings ◽

10.3390/coatings9060406 ◽

2019 ◽

Vol 9 (6) ◽

pp. 406 ◽

Cited By ~ 4

Author(s):

Sigrun N. Karlsdottir ◽

Laura E. Geambazu ◽

Ioana Csaki ◽

Andri I. Thorhallsson ◽

Radu Stefanoiu ◽

...

Keyword(s):

Bulk Material ◽

Microstructural Analysis ◽

Electrochemical Corrosion ◽

High Hardness ◽

Phase Evolution ◽

Vacuum Arc ◽

High Entropy Alloy ◽

Face Centered Cubic ◽

Σ Phase ◽

High Entropy

In this work, a CoCrFeNiMo high-entropy alloy (HEA) material was prepared by the vacuum arc melting (VAM) method and used for electro-spark deposition (ESD). The purpose of this study was to investigate the phase evolution and microstructure of the CoCrFeNiMo HEA as as-cast and electro-spark-deposited (ESD) coating to assess its suitability for corrosvie environments encountered in geothermal energy production. The composition, morphology, and structure of the bulk material and the coating were analyzed using scanning electron microscopy (SEM) coupled with energy-dispersive spectroscopy (EDS), and X-ray diffraction (XRD). The hardness of the bulk material was measured to access the mechanical properties when preselecting the composition to be pursued for the ESD coating technique. For the same purpose, electrochemical corrosion tests were performed in a 3.5 wt.% NaCl solution on the bulk material. The results showed the VAM CoCrFeNiMo HEA material had high hardness (593 HV) and low corrosion rates (0.0072 mm/year), which is promising for the high wear and corrosion resistance needed in the harsh geothermal environment. The results from the phase evolution, chemical composition, and microstructural analysis showed an adherent and dense coating with the ESD technique, but with some variance in the distribution of elements in the coating. The crystal structure of the as-cast electrode CoCrFeNiMo material was identified as face centered cubic with XRD, but additional BCC and potentially σ phase was formed for the CoCrFeNiMo coating.

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Effect of Mo Addition on The Microstructure and Mechanical Properties of CoCuFeNi High Entropy Alloy

Metals ◽

10.3390/met10081017 ◽

2020 ◽

Vol 10 (8) ◽

pp. 1017

Author(s):

Yang Shao ◽

Huan Ma ◽

Yibing Wang

Keyword(s):

Mechanical Properties ◽

Solution Structure ◽

Tensile Tests ◽

Atomic Ratio ◽

Vacuum Arc ◽

High Entropy Alloy ◽

High Entropy Alloys ◽

High Entropy ◽

Microstructure And Mechanical Properties ◽

Mo Content

In order to reveal the effect of Mo addition on the microstructure and mechanical properties, (CoCuFeNi)100-xMox (x = 0, 10, 15, 19, and 25, x values in atomic ratio) high entropy alloys were prepared by vacuum arc-melting. The results showed that with Mo addition, the μ phase formed and serious separation occurred in the high entropy alloys. The content of μ phase increased with the increase in Mo content. The microstructure of the alloys changed from an initial single-phase face-center-cubic (FCC) solid solution structure (x = 0) to a hypoeutectic microstructure (x = 15), then to a full eutectic microstructure (x = 19), and finally to a hypereutectic microstructure (x = 25). Coherent interface between μ phase and FCC phase was observed. The (CoCuFeNi)81Mo19 alloy with fully eutectic microstructures exhibited the highest yield strength of 557 MPa and fracture strength of 767 MPa in tensile tests at room temperature. The fracture surface revealed that the formation of great amounts of the μ phase resulted in the loss of ductility of (CoCuFeNi)100-xMox alloys.

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Annealing on the structure and properties evolution of the CoCrFeNiCuAl high-entropy alloy

Journal of Alloys and Compounds ◽

10.1016/j.jallcom.2009.11.104 ◽

2010 ◽

Vol 502 (2) ◽

pp. 295-299 ◽

Cited By ~ 123

Author(s):

K.B. Zhang ◽

Z.Y. Fu ◽

J.Y. Zhang ◽

J. Shi ◽

W.M. Wang ◽

...

Keyword(s):

High Entropy Alloy ◽

Structure And Properties ◽

High Entropy

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Structure and Properties of Coatings Made of High-Entropy Alloy with Martensitic Transformations Obtained by HVOF Method in a Protective Atmosphere

10.3390/ciwc2020-06805 ◽

2020 ◽

Author(s):

Petr Rusinov ◽

Zhesfina Blednova

Keyword(s):

Martensitic Transformations ◽

Protective Atmosphere ◽

High Entropy Alloy ◽

Structure And Properties ◽

Properties Of Coatings ◽

High Entropy

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High Temperature Chloride Corrosion Behavior of 904L:AlFeNiMoNb High-Entropy Alloy

Frontiers in Materials ◽

10.3389/fmats.2021.764928 ◽

2021 ◽

Vol 8 ◽

Author(s):

Lingyun Bai ◽

Wenyi Peng ◽

Dandan Men ◽

Jun Zhu ◽

Xuecheng Wu ◽

...

Keyword(s):

Weight Loss ◽

High Temperature ◽

Weight Change ◽

Cost Effective ◽

Melting Process ◽

Vacuum Arc ◽

High Entropy Alloy ◽

Coating Materials ◽

High Entropy ◽

Chloride Corrosion

In order to obtain high cost-effective coating materials working in chlorine-containing environment at high temperature, a 904L super austenitic alloy modified by an AlFeNiMoNb alloy (904L:AlFeNiMoNb) was obtained by vacuum arc melting process. The 904L:AlFeNiMoNb high-entropy alloy has a similar phase component with the AlFeNiMoNb alloy, but a more homogenous microstructure than that of the AlFeNiMoNb alloy. High-temperature chloride corrosion tests for 904L, AlFeNiMoNb, and 904L:AlFeNiMoNb high-entropy alloy were carried out under N2–2.6 vol.% CO2–1.3 vol.% O2–2,700 vppm HCl gaseous environment at 700°C and 800°C for 55 h, respectively. Due to the volatilization of FeCl2, weight change curves of the 904L alloy at 700°C and 800°C showed obvious weight loss. Especially at 800°C, the weight loss of the corroded 904L sample was 10 times that of the corroded sample at 700°C. Different from the weight loss situation of the 904L sample, both AlFeNiMoNb and 904L:AlFeNiMoNb high-entropy alloy showed small weight gains under the corrosion temperature of 700°C, while the latter gained half as much weight as the former. When the corrosion temperature was raised to 800°C, the AlFeNiMoNb and 904L:AlFeNiMoNb high-entropy alloy showed flat weight change curves with little weight loss. Weight loss for the AlFeNiMoNb and 904L:AlFeNiMoNb high-entropy alloy were 1.35138 and 0.0118 mg/cm2, respectively. The high temperature chloride corrosion resistance of 904L:AlFeNiMoNb high-entropy alloy is higher than that of 904L and AlFeNiMoNb at both 700°C and 800°C. Meanwhile, on the basis of the morphology and composition results of the corroded samples, combined with thermodynamic calculation, the high-temperature chloride corrosion mechanics of the tested alloys were discussed.

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