開發可應用於太陽能電池並具新型鍵聯結構之有機染料

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姓名

林雅芬(Ya-Fen Lin) 查詢紙本館藏

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化學學系

論文名稱

開發可應用於太陽能電池並具新型鍵聯結構之有機染料
(The Development of an Organic Dye with a New Anchoring Group for Solar Cell applications)

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摘要(中)

染料敏化太陽能電池由於製作過程簡易及便宜，目前為新一代太陽能電池研究的熱門課題。在染料敏化太陽能電池中，光敏染料是否可鍵聯並將電子有效傳至二氧化鈦為影響其效率之重要因素之一。本研究首先設計並合成一個具新型的電子予體 (donor) 的染料CS106。利用常被使用之Carbazol為主要結構，再將?吩 (thiophene) 導入形成新的電子予體，希望藉此強化其共振體及送電子之能力。本研究分別製備電子予體(Donor) 與電子受體(acceptor) 之中間物，再將其耦合反應獲得產物CS106，以提供效率量測。同時，為改良鍵聯到二氧化鈦的能力，本研究亦設計具另一新型電子受體含硫醯基結構 (–SO2–) 之染料CS101與CS106做比較及判斷各自之優缺點，以做為提升染敏電池之效率之參考。

摘要(英)

Dye-sensitized solar cell is showing advantage on its simple fabrication process and low cost and is currently a popular topic for the research of new-generation solar cells. One of the important factors for the efficiency is the dyes can be anchoring and transferred electron to TiO2 for dye-sensitized solar cells. In this study, we designed and synthesized a specific novel electron donor dye, CS106. Carbazol is the main structure that is often used, and thiophene is introduced to form a new electron precursor, and expect to strengthen its ability of resonate and donor. In this study, an intermediate of an electron precursor and an electron acceptor was separately prepared, and then coupled to obtain the product CS106 to provide an efficiency measurement. In order to improve the ability of the bond to titanium dioxide, this study also designed a dye with another novel electron acceptor with sulfonyl group (–SO2–), CS101, for future comparison purposes, and wish improve the efficiency of the dye-sensitized battery.

關鍵字(中)

★ 太陽能電池
★ 鍵聯結構
★ 有機染料

關鍵字(英)

論文目次

目錄
摘要------------i
Abstract----------ii
誌謝----------------iii
目錄----------iv
圖目錄----------vii
表目錄----------ix
一緒論--------1
　1-1 前言-------------1
　1-2 太陽能電池----------3
　1-3 太陽能電池簡介-----------5
　　　1-3-1 含矽太陽能電池---------6
　　　1-3-2 半導體化合物-----------7
　　　1-3-3 有機化合物------------8
　　　　1-3-3-1 有機光伏電池----8
　　　　1-3-3-2 染料敏化太陽能電池------9
　　　1-3-4 鈣鈦礦---------10
　1-4 染料敏化太陽能電池-----------12
1-4-1 基本構造及原理--------12
1-4-2 染料---------14
　1-5 文獻回顧及探討-------17
二染料結構設計概念--------23
　2-1 染料結構基本概念--------23
　2-2 染料結構設計動機-------28
三實驗藥品、儀器及步驟------------29
　3-1 染料之逆合成分析-------29
　3-2 染料合成步驟------------32
　3-3 實驗藥品------------34
　3-4 實驗儀器------------35
3-4-1 核磁共振光譜儀（Nuclear magnetic resonance spectroscopy）--------------35
3-4-2 紫外線-可見光光譜儀（UV-vis spectrophotometer）---------35
3-4-3 高解析質譜儀（High Resolution Mass）------36
3-4-4 單晶x光結構繞射儀(X-ray Diffractometer)---------36
　3-5 實驗步驟------------37
四結果與討論--------43
　4-1 光物理性質探討-----------43
4-2電池之光電效能分析--------45
結論與未來展望-----------47
參考文獻----------------48
附錄--------------52
　NMR------------53
　x-ray------------68

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指導教授

李文仁(Wen-Ren Li)

審核日期

2018-8-20

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