Browsing by Author "Katsuda, Yuji"

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    Reinforcement of precursor-derived Si-(B-)C-N ceramics with carbon nanotubes
    (2005) Katsuda, Yuji; Aldinger, Fritz (Prof. Dr.)
    Incorporation of carbon nanotubes (CNTs) into the precursor-derived Si-(B-)C-N ceramics has been investigated for the reinforcement of the materials. Different types of CNTs consisting of multi-wall (MW) and single-wall (SW) were examined as the reinforcement of the Si-(B-)C-N ceramics to make a comparison of the effect. Mechanical properties demonstrated in the Si-(B-)C-N/CNT nanocomposites have been discussed in connection with their microstructural features characterized by scanning electron (SEM) and transmission electron microscope (TEM). Other material properties of the nanocomposites as revealed on the thermal stability and the crystallization behavior have been also considered in relation to the microstructural characteristics of the nanocomposites. Dense Si-C-N/CNT nanocomposites containing different types of MWCNTs were successfully prepared by casting of a mixture of MWCNTs and a liquid precursor polymer followed by cross-linking and thermolysis. In these processes, the sonication for deagglomeration and dispersion of CNTs in the precursor polymer as well as the thermolysis condition for ceramization of the cross-linked precursor/CNT nanocomposites was examined to obtain homogeneously CNT distributed Si-C-N ceramics. Fracture toughness behavior of the Si-C-N/CNT nanocomposites has been evaluated by a thermal loading technique on the disc shaped materials. The results reveal a dependence of the fracture toughness on the type of the MWCNTs. The MWCNTs showing high integrity in the tube structure exhibit a remarkable increase in the fracture toughness at the CNT content of 1 – 2 mass %, whereas the other ones possessing amorphous nature exhibits no effect. The microstructural analyses at the fracture surfaces have demonstrated different features of CNTs between both nanocomposites, where pulling out and breaking of CNTs are considered to be reasons for the observed fracture toughness increase. No significant influences observed on the material properties of the Si-C-N/CNT nanocomposites besides the toughening indicates that CNTs can simply work as the reinforcement for the Si-C-N ceramics. SWCNTs incorporation into the Si-C-N materials has revealed toughening effect with similar microstructural features to the MWCNT reinforced Si-C-N nanocomposites. In this system, it was found that the deagglomeration and debundle of the SWCNTs are major issues to make the best use of SWCNTs as the reinforcements. Concerning the Si-B-C-N/CNT nanocomposites, preparation processes via a casting and a warm pressing from different types of boron-containing precursors have been investigated to produce rigid MWCNT nanocomposites. The observed pulling out and breaking CNTs structure at the fracture surfaces of the Si-B-C-N/CNT nanocomposites indicate the toughening effect of CNTs similar to Si-C-N/CNT ceramics. Moreover, the interaction between CNTs and the matrix has appeared to be changed with increasing thermolysis temperature. However, the crystallization of the Si-B-C-N matrix and the deterioration of thermal stability have been disclosed in the Si-B-C-N/CNT nanocomposites. It is revealed that embedded CNTs have an effect to accelerate or to generate nucleation sites for the crystallization of Si-B-C-N matrix.