藉由silane偶極劑來接枝二氧化矽或有機改質蒙特納黏土，以增加其添加劑與苯乙烯/不飽和聚酯(或乙烯基酯)之相容性，並利用傅立葉紅外線光譜儀量測silane接枝二氧化矽與silane改質蒙特納黏土之表面特性。
吾人亦利用廣角度X光散射儀(Wide-angle X-ray scattering,WAXS)，測定不同氧化反應時間處理後，其石墨粉、氧化石墨烯、熱還原氧化石墨烯三者之整體層間距離變化。
本研究的目的主要為探討三種特用添加劑，分別為:(1)奈米級核殼型顆粒(core-shell Particle，CSP) (2)有機改質蒙特納黏土(Montmorillonite caly，MMT) 及(3)熱還原氧化石墨烯(Thermal reduction of graphene oxide，TRGO)，其對苯乙烯/不飽和聚酯(或乙烯基酯)/特殊添加劑之三成份系統之反應前相容性、微觀型態結構、抗體積收縮特性及機械性質等之影響研究。

The synthesis of silane-grafted silica nanoparticles size (d = 15 nm) and montmorillonite clay (MMT) with the subsequent characterization of the grafting efficiency, grafting density, as well as the surface silanol groups conversion have been carried out. The silane coupling agents used for the treatment are γ-methacryloxy propyl trimethoxy silane (MPS). The number of silane coupling agents grafted on the MMT or silica surface and their silanol groups conversion were characterized by Fourier Transform Infrared Spectroscopy (FTIR).
The synthesis of graphite oxide(GO) and thermal reduction of graphene oxide(TRGO) with different reaction time have been carried out. The interplanar spacing of graphite oxide(GO) and thermal reduction of graphene oxide(TRGO) with different reaction time was measurement by Wide-angle X-ray scattering.
The effects of three additives, including (1) nano-scale core-shell particle additive, (2) organo- montmorillonite clay, (3) Thermal reduction of graphene oxide, on the cured sample morphology, volume shrinkage characteristics and mechanical properties of the Styrene(St)/Unsaturated polyester (or Vinyl ester resin)/additives ternary systems after the cure have been investigated.

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