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以作者查詢圖書館館藏 、以作者查詢臺灣博碩士 、以作者查詢全國書目 、勘誤回報 、線上人數:150 、訪客IP:18.216.34.146
姓名 吳冠逸(Kuan-Yi Wu) 查詢紙本館藏 畢業系所 化學學系 論文名稱 合成與鑑定不同側鏈取代基(烷基、醚烷基、硫醚烷基)在苯并二噻吩以及噻吩與噻吩并噻吩取代丙烯腈為基礎的共聚高分子並應用於有機光伏電池
(Synthesis and Characterization of Benzodithiophene (BDT) and (Thienothiophene-2,5-diyl)bis(thiophenyl)acrylonitrile (TTDCN) based Copolymers with Varying Side-Chain Substituent (Alkyl, Alkoxy, Alkylthio) for Polymer Solar Cells.)相關論文 檔案 [Endnote RIS 格式]
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摘要(中) 本研究延伸自pBCN[34]結構,合成且鑑定不同側鏈取代基(烷基、醚烷基、硫醚烷基)在苯并二噻吩以及噻吩與噻吩并噻吩取代丙烯腈的共聚高分子,一系列是腈基 (Cyano group) 靠近噻吩并噻吩 (Thienothiophene) 的pBIC、pBIO與pBIS (pBIX),另一系列是Cyano group 遠離Thienothiophene的pBOC、pBOO與pBOS (pBOX)。
熱性質的探討中,熱裂解溫度 (Td) 與玻璃轉換溫度 (Tg) 的差異是由於烷基、醚烷基、硫醚烷基的鍵能強度不同,使其較容易或不易振動或轉動。
在 UV-vis 吸收光譜圖中,取代基相同的情況下,pBOX都較pBIX為紅位移,推測是Cyano group位置的差異造成有效共軛長度差異。Cyano group位置相同的情況下,UV-vis 吸收光譜圖中紅位移程度皆是:醚烷基 > 硫醚烷基 > 烷基;能隙大小為:醚烷基 < 硫醚烷基 < 烷基,三種不同側鏈取代基影響分子能階較明顯的是在HOMO能階,以醚烷基高分子的最高,烷基高分子的最低,推測是高分子的推電子能力差異,以及單體π共軛共平面性不同造成的。每個高分子在薄膜狀態下吸收與其在溶液狀態下的吸收較為紅位移,高分子間的排列在少了溶劑的阻隔後,使其堆疊較緊密。
元件結構為ITO/ZnO/Polymer : PC61BM (w:w = 1:1)/MnO3/Ag之反式單層異質接面的有機光伏電池,其中pBOC的光電轉換效率可達到5.03 %、開路電壓為0.97 V、短路電流為9.26 mA/cm2、填充因子為55.94 %。而我們實驗室使用pBCN以相同元件結構的有機光伏電池的光電轉換效率為4.44 %、開路電壓為0.86 V、短路電流為8.17 mA/cm2、填充因子為63.28 %。摘要(英) We have Synthesis and Characterization of Benzodithiophene (BDT) and (Thienothiophene-2,5-diyl)bis(thiophenyl)acrylonitrile (TTDCN) based Copolymers with Varying Side-Chain Substituent (Alky, Alkoxyl, Alkylthio). A series is pBIC, pBIO and pBIS (pBIX) that cyano group close to thienothiophene, another series is pBOC, pBOO and pBOS (pBOX) that far from thienothiophene cyano group.
About the thermal properties, the difference of thermal decomposition temperature (Td) and glass transition temperature (Tg) are due to the banding energy would make the polymers to vibration.
In the case of UV-vis absorption spectra, pBOX are red shift than pBIX. It may cause by the location of cyano group in the polymers. When the cyano group under same location of the polymers, the degree of red shift is Alkoxyl > Alkylthio > Alky; the degree of band gap (Eg) is Alkoxyl < Alkylthio < Alky ; Alkylthio polymers (pBIO, pBOO) have highest HOMO energy level, and Alky polymers (pBIC, pBOC) have lowest HOMO energy level. It is due to the difference of electron-donating ability and planarity. Absorption of film are red shift than absorption of solution is impacted by intermolecule π-π stacking.
Devices of inverted bulk heterojunction organic photovoltaics are based on ITO/ZnO/Polymer : PC61BM (w:w = 1:1)/MnO3/Ag. The best power conversion effciency of pBOC is 5.03 %, open circuit voltage of 0.97 V, short circuit current of 9.26 mA/cm2, fill factor of 55.94 %. pBCN is 4.44 %, open circuit voltage of 0.86 V, short circuit current of 8.17 mA/cm2, fill factor of 63.28 %.關鍵字(中) ★ 太陽能電池
★ 有機光伏電池
★ 高分子
★ 側鏈關鍵字(英) ★ solar cell
★ Organic Photovoltaics
★ polymer
★ side chains論文目次 中文摘要 I
英文摘要 II
謝誌 III
目錄 IV
圖目錄 VII
表目錄 IX
第一章 緒論 - 1 -
1.1前言 - 1 -
1.2太陽能電池 - 1 -
1.2.1太陽能電池定義 - 1 -
1.2.2太陽能電池發展歷史 - 2 -
1.2.3有機太陽能電池與無機太陽能電池 - 3 -
1.3有機太陽能電池的分類 - 5 -
1.3.1染料敏化太陽能電池 (Dye Sensitized Solar Cells, DSSCs) - 5 -
1.3.2有機光伏電池 (Organic Photovoltaics, OPV) - 6 -
1.4高分子太陽能電池工作原理[16] [17] - 8 -
1.5高分子太陽能電池元件結構[18] - 12 -
1.4.1單層結構 (Single Layer Structure) - 12 -
1.4.2雙層異質接面結構 (Bilayer Heterojunction Structure) - 13 -
1.4.3單層異質接面結構 (Bulk Heterojunction Structure, BHJ) - 13 -
1.4.4規則異質接面結構 (Ordered Heterojunction Structure, OHJ) - 14 -
1.5太陽光模擬 - 15 -
1.6元件的基本參數 - 17 -
第二章 文獻回顧與研究動機 - 21 -
2.1側鏈 (Side Chains) 對於共軛高分子的影響 - 21 -
2.1.1碳鏈的長度 - 21 -
2.1.2碳鏈的位置 - 22 -
2.1.3側鏈的非共價鍵作用力 - 23 -
2.1.4具共軛結構的側鏈 - 24 -
2.1.5具有推電子或拉電子特性的側鏈 - 26 -
2.2醚烷基與硫醚烷基 - 27 -
2-3研究動機 - 29 -
第三章 實驗內容 - 33 -
3.1使用藥品與溶劑 - 33 -
3.2使用儀器 - 38 -
3.3實驗流程 - 41 -
3.4合成步驟 - 42 -
3.4.1共同起始物之合成步驟: - 42 -
3.4.2單體TTIDCN與TTODCN之合成步驟 - 49 -
3.4.3單體TTIDCNO與TTODCNO之合成步驟 - 58 -
3.4.4單體TTIDCNS與TTODCNS之合成步驟 - 68 -
3.4.5單體BDT之合成步驟 - 80 -
3.4.6共軛高分子pBIC之聚合 - 85 -
3.4.7共軛高分子pBIO之聚合 - 86 -
3.4.8共軛高分子pBIS之聚合 - 87 -
3.4.9共軛高分子pBOC之聚合 - 88 -
3.4.10共軛高分子pBOO之聚合 - 89 -
3.4.11共軛高分子pBOS之聚合 - 90 -
第四章 結果與討論 - 91 -
4.1高分子分子量 - 91 -
4.2熱性質 - 92 -
4.2.1 TGA - 92 -
4.2.2 DSC - 93 -
4.3光學性質 - 94 -
4.4材料能階 - 98 -
4.4.1 CV - 98 -
4.4.2 AC-2 - 100 -
4.4.3 理論計算 - 103 -
4.5有機光伏電池元件 - 107 -
第五章 結論 - 111 -
第六章 參考資料 - 113 -
附錄 1HNMR圖、13CNMR圖與MS圖 - 117 -參考文獻 [1] M. Z. Jacobson and G. M. Masters, Sci., 2001, 293, 1438.
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