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  • 學位論文

應用田口方法於製備氧化鋅奈米材料及導電玻璃之研究

Studies on Preparation of ZnO Nanomaterials and Conductive Glass by Taguchi Method

指導教授 : 宮大川
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摘要


資源短缺促使企業將環境保護視為核心目標;相較於傳統的資源回收技術,「綠色化學」以無毒、對生物無害及對能源與物質的高使用效率,成為環境保護的顯學,因此無論業界或學界,近年均熱衷將「綠色化學」導入各種產品的研發及生產製程。 由於奈米結構氧化鋅引人注目的特性、無毒、對生物無害、可透明導電,使其成為符合「綠色化學」概念,深具發展潛力的多功能材料,被廣泛應用在各領域中,如:化妝品、太陽能電池、化學感測器、光電材料、壓電材料、紫外光雷射、透明薄膜電晶體、液晶顯示器、、、等。 在本研究中,我們發展出新且更環保的製程以製備氧化鋅奈米材料,並以氧化鋅薄膜取代氧化銦錫薄膜以製備導電玻璃,而且使用田口方法進行實驗設計,分析製程參數對產物特性之影響,以獲得最佳且更接近「綠色化學」的製程條件。

並列摘要


The depletion of natural resources has led most industries to treat the protection of the environment as a core business goal. In contrast with traditional waste recycling techniques、「Green Chemistry」 makes a significant contribution to the protection of the environment through its promotion of non-toxicity、biosafety、and consumption efficiency in energy and materials. Academics and practitioners alike are enthusiastic about the introduction of green chemistry to the processes of production as well as research and development. Nanostructural zinc oxide (ZnO) is one of the most promising functional materials due to its novel characteristics of non-toxicity、biosafety、and transparent conductivity. It has already found its way into many products used in our daily life、such as cosmetics、solar cells、chemical sensors、photoelectric materials、piezoelectric materials、ultraviolet lasers、transparent thin film transistors、and liquid crystal displays. This study developed a new process to prepare ZnO nanomaterial、substituting ZnO thin film for the ITO (indium-tin oxide) in the preparation of conductive glass. Taguchi method was employed to attain optimal、「Greener」 conditions in the design of the experiments、the synthesis of the materials、and our analysis of the characteristics related to the resulting ZnO products.

並列關鍵字

Nanomaterials ZnO Taguchi Method Conductive Glass

參考文獻


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