具有高粱微观结构多孔SiC的制备与表征

无机材料学报, 2008, 23(3): 602-606. doi: 10.3724/SP.J.1077.2008.00602

具有高粱微观结构多孔SiC的制备与表征

王庆 , 王冬华 , 靳国强 , 郭向云

1.1. 中国科学院山西煤炭化学研究所煤转化国家重点实验室, 太原 030001

2. 2. 中国科学院研究生院, 北京 100049

1.1. Key Laboratory of Coal Conversion, Institute of Coal Chemistry, Taiyuan 030001, China

2. 2. Graduate University of the Chinese Academy of Sciences, Beijing 100049, China

关键词：高粱 , microstructure , infiltration of liquid Si , null

Preparation and Characterization of Biomorphic Silicon Carbide from Durra

WANG Qing , WANG Dong-Hua , JIN Guo-Qiang , GUO Xiang-Yun

Keywords： biomorphic silicon carbide , 生物形态碳化硅 , 微观结构 , 液相渗硅

高粱经高温热解转化为碳模板, 再经液相渗透技术与熔融硅反应, 生成具有高粱微观结构的多孔SiC材料. 采用XRD、SEM和压汞技术对样品的物相、微观结构以及孔分布进行了研究. 结果表明, 最终的产物主要由β-SiC组成, 且很好地复制了碳模板的微观结构. SiC的平均孔径和孔隙率分别为91.4μm和76.6%, 与碳模板的88.5μm和71.2%相似. SiC的比表面积为33.7m²/g, 与碳模板的比表面积59.4m²/g相比明显降低. 二者相近的表面分维数(SiC为2.73, 碳模板为2.70)也表明SiC很好地保持了碳模板的微观结构. 高粱转化的SiC具有颗粒直径大、孔隙率高等特点.

Durra was firstly transformed into carbon template by high-temperature pyrolysis and then converted into biomorphic SiC by infiltration of liquid Si in Ar atmosphere at 1600℃. The purified SiC sample was characterized by X-ray diffraction, scanning electron microscope and mercury intrusion. The results suggest that the sample mainly consist of β-SiC and perfectly replicate the microstructure and morphology of the carbon template. The durra-derived SiC has a mean pore diameter of 91.4μm and porosity of 76.6%, and both of them are similar to those of the carbon template, 88.5 μm and 71.2%, respectively. The specific surface area of SiC is 33.7m²/g, which is less than that of the carbon template, 59.4m²/g. The surface fractal dimension is 2.73 for the SiC sample and 2.70 for the template by analyzing the mercury intrusion data. The durra-derived SiC has characteristics of large grain size and high porosity.

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