Self-propagating High Temperature Synthesis Mechanism of Mg-B2O3-TiO2 System

doi:10.11901/1005.3093.2014.228

Chinese Journal of Materials Research

2015, Vol. 29

Issue (1): 32-38 DOI: 10.11901/1005.3093.2014.228

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Self-propagating High Temperature Synthesis Mechanism of Mg-B₂O₃-TiO₂ System

Mingyuan WANG,Junshou LI(

),Xiaojuan WU,Su LI,Fang ZHAO

Institute of Advanced Materials, Ordnance Engineering College, Shijiazhuang 050003, China

Cite this article:

Mingyuan WANG,Junshou LI,Xiaojuan WU,Su LI,Fang ZHAO. Self-propagating High Temperature Synthesis Mechanism of Mg-B₂O₃-TiO₂ System. Chinese Journal of Materials Research, 2015, 29(1): 32-38.

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Abstract

The order of reactions for Mg-B₂O₃-TiO₂ system was determined by thermodynamic calculation. Then the composition and morphology evolution of the product prepared by self-propagating high temperature synthesis were analyzed in terms of reaction zones of the process by Cu wedge combustion wave quenching method. The formation and growth mechanism of the TiB₂ crystal grains was investigated as well. The results of thermodynamic calculation show that in the process of SHS reaction B and MgO were firstly obtained by reduction reaction between Mg and B₂O₃, then Ti and MgO was obtained by reduction reaction between Mg and TiO₂; finally B reacts with Ti to form TiB_2. In this process, the formation possibility of the intermediate products decreases corresponding to the following order: Ti₃O₅、Ti₂O₃ and TiO. The experimental results show that no intermediate products may be detected in the combustion center, where the reaction was entirely complete; however in zones near the center or at the edge there existed a small amount of Ti₂O₃ and TiO, where temperature was not high enough for completing the reaction; at the bottom zone of the combustion there existed a little Ti₃O₅, where temperature was too low for the reaction. Therefore, thermodynamic prediction coincides well with experimental results. It follows that during the reaction process of SHS, MgO firstly nucleates and grows up, while TiB₂ may form through tow ways, by one way TiB₂ nucleates on MgO crystals, and then grows into tiny particles as the rising temperature; by the other way TiB₂ independently nucleates and grows up into hexagonal crystal in between large MgO crystals. The growth of TiB₂ follows typical L-S mechanism; B and Ti alternatively gather and grow up to form hexagonal crystal.

Key words: inorganic non-metallic materials TiB₂ SHS combustion wave quenching rate method synthesis mechanism

Received: 06 May 2014

Fund: *Supported by National Natural Science Foundation of China No.51172281.

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https://www.cjmr.org/EN/10.11901/1005.3093.2014.228 OR https://www.cjmr.org/EN/Y2015/V29/I1/32

Fig.1 Gibbs free energy function curve of equations in Mg-B₂O₃-TiO₂ system

Fig.2 Schematic of Cu wedge combustion wave quenching cooling method

Fig.3 Schematic of Cu wedge combustion wave quenching cooling method

Fig.4 XRD patterns of combustion products in reaction zone

Fig.5 SEM of combustion product

Fig.6 SEM of combustion bottom, (a) TiB₂ particles grow up too late, (b) enlarged view of the area

Fig.7 SHS reaction mechanism of Mg-TiO₂-B₂O₃ system, (a) raw materials, (b) Mg and B₂O₃melted, (c) B and Ti replaced by Mg, (d) TiB₂ synthesized by B and Ti

Fig.8 SEM of combustion edge, (a) long strip TiB₂, (b) fine particles of TiB₂

Fig.9 SEM of the second combustion centre, (a) fine particles of TiB₂ (b) different patterns of TiB₂grains

Fig.10 SEM of combustion centre, (a) TiB₂ of different growing locations, (b) hexagonal columnar TiB₂

Fig.11 Schematic diagram of TiB₂ growing mechanism

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