Combustion synthesis of TiC-based ceramic-metal composites with high entropy alloy binder

Рогачев, А. С.; Вадченко, С. Г.; Кочетов, Н. А.; Kovalev, D. Yu.; Ковалев, И. Д.; Щукин, А. С.; Gryadunov, A. N.; Baras, F.; Politano, O.

doi:10.1016/j.jeurceramsoc.2019.11.059

Cited by 39 publications

(9 citation statements)

References 31 publications

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“…-WC-CoCrFeNiMn [10], -SiC-CoCrFeMnNi [11], -TiC-FeCrNiCoAlCu [12; 13], -TiC-FeMnCrNiCo [14], -TiCN-AlCoCrFeNi [15], -TiCN-CoCrFeNiCu [16], -Ti(C,N)-ВЭС на основе (Co, Fe, Ni) [17], -TiCN-CrMnFeCoNi [18], -TiC-CoCrFeNiMe (Me = Mn, Ti, Al) [19].…”

Section: введение введениеmentioning

confidence: 99%

“…Ранее [19] была исследована возможность получения кермета на основе высокоэнтропийного связующего (CoCrFeNiMn, CoCrFeNiTi и CoCrFeNiAl) и добавки смеси Ti + C методом самораспространяющегося высокотемпературного синтеза (СВС), который реализуется за счет тепла, выделяющегося при экзотермической реакции титана с углеродом. В волне горения происходит плавление 5 элементов с образованием многокомпонентного расплава CoCrFeNiMe (Me = Mn, Ti, Al), который кристаллизуется в ВЭС в качестве связующей фазы.…”

Section: введение введениеunclassified

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Formation of products upon ignition, combustion and melting of mixtures of high-entropy alloy FeNiCoCrCu with titanium and carbon

Вадченко

Vergunova

Рогачев

et al. 2023

Izv. VUZ. Poroshk. Met.

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The dependence of the ignition temperature, combustion rate and composition of the resulting products on the concentration of Ti + C in mixtures with powder of a high-entropy alloy (HEA) FeNiCoCrCu and the initial mixture of metals forming it (MIX) has been studied. HEA was obtained by mechanical activation (MA) of a mixture of metal powders in argon. At the melting temperature, the high-entropy FeNiCoCrCu alloy decomposes into several phases, but the basis of the HEA alloy, as well as the alloy obtained by melting and crystallizing MIX, is a 5-component phase with an average formula Cu1.2Fe1.4Ni1.4Co1.4Cr. In addition, 5, 4, and 3-component phases with averaged formulas Cu2Ni2Co2Fe2Cr, Cu3Ni3Co2.9Fe2.5Cr, Cu4.8Ni4.5Co4.6Fe4.2Cr, Cu40Fe2Ni4Co2C, Cr12.5Fe3.2Co2.6Ni and Co3.2 Fe3,5 Cr are present in small amounts in the binder. Experiments on the ignition and combustion of mixtures of MIX and HEA with Ti + C were carried out in argon at atmospheric pressure. The combustion rate, ignition temperature, and maximum temperature reached in the thermal explosion of MIX and HEA mixtures with Ti + C increase with increasing Ti + C concentration. Due to the low exothermicity of the mixtures, the experiments were carried out at an initial temperature of 500 °С. At this initial temperature, the combustion limit of the samples occurs when the Ti + C concentration in the HEA and MIX mixtures is less than 30 %. Based on the results of scanning electron microscopy, the volume concentration of the number of titanium carbide (TiC) particles in molten samples was calculated. In an alloy with a HEA binder, the number of TiC particles per unit volume is 1.5-3.0 times greater than in an alloy with a MIX binder, and their size is correspondingly smaller. With an increase in the concentration of Ti + C from 30 to 40 % in a mixture with HEA, the number of TiC particles per unit volume decreases. In a mixture with MIX, the number of TiC particles per unit volume passes through a minimum. This is due to two opposite processes: on the one hand, the probability of the generation of TiC particles increases, on the other hand, their coagulation occurs.

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Section: введение введениеmentioning

confidence: 99%

Section: введение введениеunclassified

Formation of products upon ignition, combustion and melting of mixtures of high-entropy alloy FeNiCoCrCu with titanium and carbon

Вадченко

Vergunova

Рогачев

et al. 2023

Izv. VUZ. Poroshk. Met.

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“…Therefore, a thermite-type reaction or a thermally coupled reaction accompanied by a large release of heat sufficient to melt metal components and form HEA can be used [ 22 ]. However, the latter approach is mainly suitable for the production of cermets, in which HEA is used as a metallic binder for ceramic grains [ 23 , 24 ].…”

Section: Introductionmentioning

confidence: 99%

Combustion Synthesis and Reactive Spark Plasma Sintering of Non-Equiatomic CoAl-Based High Entropy Intermetallics

et al. 2023

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The present work reports the direct production of a high-entropy (HE) intermetallic CoNi0.3Fe0.3Cr0.15Al material with a B2 structure from mechanically activated elemental powder mixtures. Fast and efficient combustion synthesis (CS), spark plasma sintering (SPS), and reactive SPS (RSPS) methods were used to synthesize the HE powders and bulks. The formation of the main B2 phase along with some amounts of secondary BCC and FCC phases are reported, and L12 intermetallic (CS scheme) and BCC based on Cr (CS + SPS and RSPS schemes at 1000 °C) were observed in all samples. The interaction between the components during heating to 1600 °C of the mechanically activated mixtures and CS powders has been studied. It has been shown that the formation of the CoNi0.3Fe0.3Cr0.15Al phase occurs at 1370 °C through the formation of intermediate intermetallic phases (Al9Me2, AlCo, AlNi3) and their solid solutions, which coincidences well with thermodynamic calculations and solubility diagrams. Compression tests at room and elevated temperatures showed that the alloy obtained by the RSPS method has enhanced mechanical properties (σp = 2.79 GPa, σ0.2 = 1.82 GPa, ε = 11.5% at 400 °C) that surpass many known alloys in this system. High mechanical properties at elevated temperatures are provided by the B2 ordered phase due to the presence of impurity atoms and defects in the lattice.

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“…Among nanomaterials, the use of magnetic nanoparticles provides a good way to separate pollutions by an external magnetic field that is cost‐effective in terms of reuse and recycling [19] . Combustion is an auspicious technique to synthesize different substances such as intermetallics, composites, and ceramics [20–22] . It is also utilized for synthesizing various nanomaterials.…”

Section: Introductionmentioning

confidence: 99%

Magnetic‐Nanoparticle‐Based Dispersive Micro‐Solid Phase Extraction for the Determination of Crystal Violet in Environmental Water Samples

et al. 2021

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In present study, a rapid and simple method based on ultrasonic‐assisted magnetic dispersive micro‐solid phase extraction (MD‐μ‐SPE) using magnetic ZnFe2O4‐ZnS nanocomposites has been proposed for the determination of crystal violet (CV) in environmental water samples. To increase the extraction efficiency, the affecting factors on the ultrasonic‐assisted magnetic dispersive micro‐solid phase extraction method were investigated and optimized by Taguchi method, artificial neural network (ANN), and response surface methodology (RSM). For proposed method, the crystal violet was selected as target dye. Under optimal conditions, the limits of detection were obtained 25 ng mL−1 and the calibration curve showed linearity in the range of 100–600 ng mL−1. The good extraction efficiency obtained indicates that the proposed MD‐μ‐SPE possesses a good potential for the determination of CV in environmental water samples.

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Combustion synthesis of TiC-based ceramic-metal composites with high entropy alloy binder

Cited by 39 publications

References 31 publications

Formation of products upon ignition, combustion and melting of mixtures of high-entropy alloy FeNiCoCrCu with titanium and carbon

Formation of products upon ignition, combustion and melting of mixtures of high-entropy alloy FeNiCoCrCu with titanium and carbon

Combustion Synthesis and Reactive Spark Plasma Sintering of Non-Equiatomic CoAl-Based High Entropy Intermetallics

Magnetic‐Nanoparticle‐Based Dispersive Micro‐Solid Phase Extraction for the Determination of Crystal Violet in Environmental Water Samples

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