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

A. Potanin, E. Bashkirov, Y. Pogozhev, D. Kovalev, N. Kochetov, P. Loginov, E. Levashov
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引用次数: 1

Abstract

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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基于mab相的MoAlB硼化陶瓷自蔓延高温合成
本研究重点研究了Mo-Al-B三元体系中反应混合物的燃烧动力学和机理,从而形成MoAlB - MAB相。研究了初始温度对关键燃烧参数的影响。反应混合物预热对最高燃烧温度的影响较小。计算了自传播高温合成(SHS)的有效活化能。Mo-Al-B系统的相图是使用AFLOW和Materials Project数据库构建的。研究了以厚度为0.4 μm、长度为~2 ~ 10 μm的MoAlB片层状晶粒为主要成分的合成陶瓷的相组成和结构。对总含量≤3%的MoB和Mo2B5中间硼化物的DXRD谱线进行了鉴定。扫描电镜和能谱分析表明,Al2O3相存在于晶间孔隙中。研究了燃烧波中的一系列化学转变,并提出了结构形成机理的假设。在SHS过程中,MoO2和Al2O3是初始相,MoAlB相是由含硼铝钼熔体形成的。燃烧后区形成亚微米量级的MoB相,这是由于铝在弥散强化机制下的部分氧化所致。
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