In-situ Formation of Spinel Fibers in MgO-C Refractory Matrixes

In-situ Formation of Spinel Fibers in MgO-C Refractory Matrixes

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摘要 In-situ magnesia-rich spinel fiber was formed resulting from the addition of ferrocene into MgO-C refractory matrixes. The formation of in-situ spinel fiber was detected to start at 1300 ℃. The amount, diameter and length of the fibers increased with rising temperature. Ferrocene may have catalytic effects on the growth of the fibers in two aspects. First, the reaction between MgO and C and the decomposition of Al4C3 may be catalyzed at high temperature. Suitable concentration gaseous phase is then created for vapor-vapor reaction which could result in the in-situ formation of fibers. Second, Fe nanoparticle produced from ferrocene can act as catalytic droplets and catalyze the growth of the fibers. The fibers are formed via the vapor-liquid-solid and vapor-solid mechanisms. In terms of chemical thermodynamics, the partial pressure of CO and Mg（g） are found to play an important role in the in-situ fibers formation. Different concentration of vapors affects the size, amount and composition of the fibers at different temperatures. The mechanical properties of MgO-C brick was found to be improved by ferrocene addition. In-situ magnesia-rich spinel fiber was formed resulting from the addition of ferrocene into MgO-C refractory matrixes. The formation of in-situ spinel fiber was detected to start at 1300 ℃. The amount, diameter and length of the fibers increased with rising temperature. Ferrocene may have catalytic effects on the growth of the fibers in two aspects. First, the reaction between MgO and C and the decomposition of Al4C3 may be catalyzed at high temperature. Suitable concentration gaseous phase is then created for vapor-vapor reaction which could result in the in-situ formation of fibers. Second, Fe nanoparticle produced from ferrocene can act as catalytic droplets and catalyze the growth of the fibers. The fibers are formed via the vapor-liquid-solid and vapor-solid mechanisms. In terms of chemical thermodynamics, the partial pressure of CO and Mg（g） are found to play an important role in the in-situ fibers formation. Different concentration of vapors affects the size, amount and composition of the fibers at different temperatures. The mechanical properties of MgO-C brick was found to be improved by ferrocene addition.

作者谢朝晖

机构地区 High Temperature Ceramics Institute

出处《Journal of Wuhan University of Technology(Materials Science)》 SCIE EI CAS 2009年第6期896-902,共7页 武汉理工大学学报（材料科学英文版）

基金 Funded by the National Natural Science Foundation of China (No.50872125)

关键词 spinel fiber in-situ formation FERROCENE MgO-C brick refractory. spinel fiber in-situ formation ferrocene MgO-C brick refractory.

分类号 TQ175.1 [化学工程—硅酸盐工业]

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Journal of Wuhan University of Technology(Materials Science)

2009年第6期

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In-situ Formation of Spinel Fibers in MgO-C Refractory Matrixes

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