Self-Propagating High-Temperature Synthesis of Boron-Containing MAX-Phase

Амосов, А. П.; Latukhin, E. I.; Petrov, P.; Amosov, Evgeniy; Новиков, В. А.; Illarionov, A Yu

doi:10.4028/www.scientific.net/kem.746.207

Cited by 5 publications

(2 citation statements)

References 16 publications

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“…Furthermore replacing the M, A, or X atoms have gone beyond the state-of-the-art providing boundless platforms of exploration. The preparation of boron containing the MAX phase by replacing half of the carbon atoms by boron in Ti 3 AlC 2 allowed for the production of a partially modified boron-containing MAX phase, where the interplanar distances of the crystal lattice in the Ti 3 AlC 2 phases (shifting to lower angles) increase as more carbon atoms are replaced by boron in the charge; TiB, TiB 2 , and Al 3 Ti become the main phases in the product obtained [32]. M-site solid solutions of (Ti 1−x Nb x ) 2 AlC (with a trivial amount of TiC) have been prepared using Ti, Nb, Al, and carbon (x = 0.2-0.8) under conditions of mild combustion.…”

Section: Shs From Elementsmentioning

confidence: 99%

Combustion Synthesis of MAX Phases: Microstructure and Properties Inherited from the Processing Pathway

Aydinyan

2023

Crystals

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The MAX phases exhibit outstanding combination of strength and ductility which are unique features of both metals and ceramics. The preparation of pure MAX phases has been challenging due to the thermodynamic auspiciousness of intermetallic formation in the ternary systems. This review demonstrates the power of the self-propagating, high-temperature synthesis method, delivers the main findings of the combustion synthesis optimization of the MAX phases, and reveals the influence of the combustion wave on the microstructure features thereof. The possibility of using elements and binary compounds as precursors, oxidizers, and diluents to control the exothermicity was comparatively analyzed from the point of view of the final composition and microstructure in the following systems: Ti-Al-C, Ti-V-Al-C, Cr-V-Al-C, Ti-Cr-Al-C, Ti-Nb-Al-C, Ti-Al-Si-C, Ti-Al-Sn-C, Ti-Al-N, Ti-Al-C-N, Ti-Al-B, Ti-Si-B, Ti-Si-C, Nb-Al-C, Cr-Al-C, Cr-Mn-Al-C, V-Al-C, Cr-V-Al-C, Ta-Al-C, Zr-S-C, Cr-Ga-C, Zr-Al-C, and Mo-Al-C, respectively. The influence of sample preparation (including the processes of preheating, mechanical activation, and microwave heating, sample geometry, porosity, and cold pressing) accompanied with the heating and cooling rates and the ambient gas pressure on the combustion parameters was deduced. The combustion preparation of the MAX phases was then summarized in chronological order. Further improvements of the synthesis conditions, along with recommendations for the products quality and microstructure control were given. The comparison of the mechanical properties of the MAX phases prepared by different approaches was illustrated wherever relevant.

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Section: Shs From Elementsmentioning

confidence: 99%

Combustion Synthesis of MAX Phases: Microstructure and Properties Inherited from the Processing Pathway

Aydinyan

2023

Crystals

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“…Опубликованы статьи, связанные с изучением механизмов и кинетики процессов горения, стадийности фазо-и структурообразования при синтезе MAX-фаз [21][22][23][24][25]. Авторами [26] получена борсодержащая МАХ-фаза состава Ti 3 Al(C 1-x B x ) 2 с частичной заменой атомов углерода на бор. Рентгеноструктурный фазовый анализ показал, что такая замена до половины их содержания не меняет фазовый состав продукта синтеза.…”

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Self-propagating high-temperature synthesis of MoAlB boride ceramics based on MAB-phase

Potanin

Bashkirov

Pogozhev

et al. 2022

Izv. VUZ. Poroshk. Met.

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This study focuses on the combustion kinetics and mechanisms of reaction mixtures in the Mo–Al–B ternary system taken so that the MoAlB MAB phase was formed. The effect of the initial temperature on the key combustion parameters was demonstrated. Reaction mixture preheating was found to weakly affect the maximum combustion temperature. The effective activation energy of self-propagating high-temperature synthesis (SHS) was calculated. Phase diagrams in the Mo–Al–B system were built using the AFLOW and Materials Project databases. The phase composition and structure of the synthesized ceramics with MoAlB lamellar grains 0.4 μm thick and ~2–10 μm long as a main component were studied. The DXRD lines of MoB and Mo2B5 intermediate borides with their total content of ≤3 % were also identified. Scanning electron microscopy and energy dispersive spectroscopy studies revealed that the Al2O3 phase was present in the intergranular pores. A sequence of chemical transformations in the combustion wave was studied, and a hypothesis about the structure formation mechanism was put forward. MoO2 and Al2O3 can be the primary phases during SHS, and the MoAlB phase is formed from the boron-containing aluminum–molybdenum melt. Submicron-sized MoB precipitates are formed in the post-combustion zone due to the partial oxidation of aluminum by the dispersion strengthening mechanism.

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Synthesis, structure and properties of MAB phase MoAlB ceramics produced by combination of SHS and HP techniques

Potanin¹,

Bashkirov²,

Pogozhev³

et al. 2022

Journal of the European Ceramic Society

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Self-Propagating High-Temperature Synthesis of Boron-Containing MAX-Phase

Cited by 5 publications

References 16 publications

Combustion Synthesis of MAX Phases: Microstructure and Properties Inherited from the Processing Pathway

Combustion Synthesis of MAX Phases: Microstructure and Properties Inherited from the Processing Pathway

Self-propagating high-temperature synthesis of MoAlB boride ceramics based on MAB-phase

Synthesis, structure and properties of MAB phase MoAlB ceramics produced by combination of SHS and HP techniques

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