纳米 KTi<SUB>6</SUB>O<SUB>13w</SUB>合成中的形态演化和生长机理

无机材料学报, 2006, 21(6): 1325-1332. doi: 10.3724/SP.J.1077.2006.01325

纳米 KTi₆O_13w合成中的形态演化和生长机理

徐艳姬 , 徐明霞 , 申玉田 , 崔春翔

(1. 天津大学材料学院, 天津 300072

3. 3. 河北工业大学材料学院, 天津 300130)

(1. School of Materials Science and Engineering, Tianjin University, Tianjin 300072, China

2. 2. Department of Materials Science and Engineering, Tsinghua University, Beijing 100084, China

3. 3. School of Materials Science and Engineering, Hebei University of Technology, Tianjin 300130, China)

关键词： KTi6O13晶须 , growth mechanism

Morphologic Evolution and Growth Mechanism Involved in the Synthesis of Nanometer KTi₆O_13w

XU Yan-Ji , XU Ming-Xia , SHEN Yu-Tian , CUI Chun-Xiang

Keywords： KTi6O13 whisker , 生长机理

以纳米TiO₂为原料, 通过煅烧反应制备了纳米KTi₆O₁₃晶须, 对晶须合成中温度和时间诱导的相变、形态演化和生长机理等进行了原位研究. 结果表明: 纳米TiO₂作原料可显著降低晶须合成温度, 适宜的煅烧温度为900~1100℃. 形态演化观察和高温XRD分析表明: KTi₆O₁₃晶须的相变及生长对温度极为敏感, 形态演化是基于初期爆发式的相变和随后串并联式的长大. KTi₆O₁₃晶须的生长遵守本研究提出的串并联机制, 晶须轴向的生长台阶是串并联生长的直接结果.

The present work was aimed at in-situ studies of temperature and time induced phase transition, morphologic evolution, growth mechanism, and microstructure of KTi₆O₁₃ nano-whiskers synthesized by calcination reaction using nanometer TiO₂ as the starting material. The experimental results indicate that the use of nanometer TiO greatly reduces calcination temperature with a suitable calcination temperature range of 900~1100℃. Observation of morphologic evolution and dynamic HTXRD analysis show that the phase transition and growth of KTi₆O₁₃ whiskers are quite sensitive to calcination temperature, and the morphologic evolution of KTi₆O₁₃ whiskers is mainly based on the fulminous phase transition at the initial stage and subsequent concatenation-parallel growth in length and diameter. The growth of KTi₆O₁₃ whiskers follows the concatenation-parallel growth mechansim developed in this study, which directly results in the formation of growth steps along the axis of the whiskers.

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材料期刊网

纳米 KTi6O13w合成中的形态演化和生长机理

Morphologic Evolution and Growth Mechanism Involved in the Synthesis of Nanometer KTi6O13w

参考文献

纳米 KTi₆O_13w合成中的形态演化和生长机理

Morphologic Evolution and Growth Mechanism Involved in the Synthesis of Nanometer KTi₆O_13w