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研究生: 祝子翔
Tzu-Hsiang Chu
論文名稱: 具氧化磷或二氮螺旋雙芴或四苯基苯噁二唑結構的熱延遲活化藍色螢光材料
The blue thermally activated delay fluorescence materiels which contain phosphine oxide, diazaspirobifluorene, tetraphenyl oxadiazole stucture
指導教授: 陳錦地
Chin-Ti Chen
陳銘洲
Ming-Chou Chen
口試委員:
學位類別: 碩士
Master
系所名稱: 理學院 - 化學學系
Department of Chemistry
論文出版年: 2018
畢業學年度: 106
語文別: 中文
論文頁數: 260
中文關鍵詞: 有機電激發光二極體熱延遲活化螢光材料藍光氧化磷二氮螺旋雙芴四苯基苯噁二具氧化磷或二氮螺旋雙芴或四苯基苯噁二唑結構的熱延遲活化藍色螢光材料
外文關鍵詞: OLED, TADF, Blue, Phosphine oxide, Diaza spirobifluorene, Tetraphenylbenzyl oxadiazole
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    • OLED產業發展至今已進入商業化時代,對於三原色所需求的材料條件更是越加嚴苛,在藍光材料所產生的困境也被彰顯出來,而由Chihaya Adachi教授所提出的Metal-Free之熱延遲活化螢光材料的分子設計正好替藍光材料帶來一線曙光。本篇論文使用氧化磷、二氮螺旋雙芴、四苯基苯噁二唑等五個結構為電子受體,並與五個Acridan的衍生物之電子予體做配合,共計提出21種化合物。我們將根據量測結果探討各個電子予體與電子受體之特性,並將其中較有潛力的組合製成參雜型有機電激發光二極體元件,討論這類化合物在元件的表現。

    OLED, Organic light Emitting Diode has now become more and more commercialized. Therefore, the urgent and distrcit need of three types of color - green, red, blue has drawn everybody to this search area. Aspecially the blue color, which has been a problem to catch up the efficiency of the other two colors to forn white light. Since professor Chihaya adachi brought a brand new metal free design of TADF, we had discovered a chance for blue light materials.
    In this thesis, we choose phosphine oxide, diaza spirofluorene, tetraphenyl phenyl oxadiazole, totally five accepter to conbine with five acridan derivatives, which are donors, and come up with 21 compound as blue emitter candidates.
    We will discuss the properties we can get and choose few compound which has potential to make the devices to check the device properties.

    目錄 中文摘要 I Abstract II 謝誌 III 目錄 IV 圖目錄 VI 表目錄 IX 第一章 緒論 1 1.1 前言 1 1.2 致光原理 3 1.2.1 激發 3 1.2.2 緩解 5 1.2.3 元件電激發光 6 1.2.4 主客體參雜系統放光機制 7 1.3 有機電激發光二極體材料 8 1.3.1 陽極材料 (anode materials) 8 1.3.2 陰極材料 (cathode materials) 9 1.3.3 電洞注入材料 (hole injection materials) 9 1.3.4 電洞傳輸材料 (hole transporting materials) 10 1.3.5 電洞阻擋材料 (hole blocking materials) 12 1.3.6 電子注入材料 (electron injection materials) 12 1.3.7 電子傳輸材料 (electron transporting materials) 13 1.3.8 螢光發光材料 (fluorescent emitting materials) 14 1.3.9 磷光發光材料 (phosphorescent emitting materials) 15 1.4 有機電激發光二極體材料之載子移動率 18 1.5 有機電激發光二極體之光色 20 1.6 有機電激發光二極體之效率 21 1.6.1 螢光 (磷光) 量子產率 21 1.6.2 發光效率及電流效率 23 1.7 熱延遲活化螢光材料 24 1.7.1 熱延遲活化螢光材料發展進程 24 1.7.2 本篇論文相關文獻回顧 29 1.7.3 研究動機 31 第二章 具氧化磷或二氮螺旋雙芴或四苯基苯噁二唑結構的熱延遲活化藍色螢光材料 34 2.1實驗藥品 34 2.2溶劑與溶劑前處理 35 2.3分析儀器 36 2.4光電元件製備及量測 40 2.5 分子設計、合成及結構解析 42 2.6 熱、理論計算、光物理、電化學性質之探討 74 2.6.1 熱性質 74 2.6.2 理論計算 80 2.6.3 光物理性質 92 2.7 元件結果與討論 110 第三章 結論與未來展望 117 3.1 結論 117 3.2 未來展望 117 參考文獻 118 附錄、核磁共振光譜圖 122

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