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研究生: 周永晟
Jou, Yung-Cheng
論文名稱: 具有載子注入平衡共主體結構之黃光有機發光二極體
High Efficiency Yellow Organic Light-Emitting Diodes with a Balanced Carrier Injection Co-host Structure
指導教授: 周卓煇
Jou, Jwo-Huei
口試委員: 吳茂昆
Wu, Maw-Kuen
薛景中
Shyue, Jing-Jong
陳建添
Chen, Chieh-Tien
岑尚仁
Chen, Sun-Zen
學位類別: 碩士
Master
系所名稱: 工學院 - 材料科學工程學系
Materials Science and Engineering
論文出版年: 2012
畢業學年度: 100
語文別: 中文
論文頁數: 73
中文關鍵詞: 黃光有機發光二極體高效率共主體載子注入平衡
外文關鍵詞: yellow OLED, high efficiency, cohost, balanced carrier injection
相關次數: 點閱:3下載:0
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    • 本研究利用一無電子注入能障之主體材料,搭配利於電洞注入之共主體 tris(2-phenylpyridine)iridium(III) [Ir(ppy)3],並使用高發光效率之磷光黃光染料 iridium(III)bis(4-phenylthieno[3,2-c]pyridinato-N,C 2')acetylacetonate (PO-01),有效使元件於高亮度下仍能保持高效率,並製備一突破世界紀錄之高效率黃光磷光有機發光二極體。元件效率表現,在亮度為 100 cd/m2 下,能量效率為79 lm/W,電流效率為77 cd/A,外部量子效率為25%,在亮度為1,000 cd/m2下,則分別為59 lm/W,71 cd/A,以及23%。元件高效率的原因為:(1)使用薄發光層以及無電子注入能障主體,有效降低元件驅動電壓而達高效率;(2)使用共主體結構,使載子更易注入至發光層;於低電壓下,激子主要於共主體上產生,高電壓下則主要於主體上產生,使元件不論在低或高電壓下,皆能夠有良好的主客體能量傳遞,並於高亮度下仍能維持高效率。另外,選用不同性質之主體材料 (具電洞傳輸性或同時具電子電洞傳輸性),搭配此共主體材料,於高亮度下,元件效率皆能獲得改善。

    We demonstrate herein the design and fabrication of a highly efficient yellow organic light-emitting diode (OLED) with a balanced carrier injection device architecture having a zero electron-injection-barrier host blended with a hole-injection aiding co-host. The resultant yellow OLED showed, at 1,000 cd m-2 for example, an efficacy of 59 lm W-1, current efficiency of 71 cd A-1 and external quantum efficiency (EQE) of 23%, while 42 lm W-1, 47 cd A-1 and 15% EQE without co-host. The co-host effect that resulted in a much balanced carrier injection was also valid for other yellow OLED devices and their efficiency improvement was also very marked. With the use of a micro-lens, the device efficiency is further improved to 79 lm W-1, 96 cd A-1 and 30% EQE.

    目錄 摘要 I 英文摘要 II 誌謝 I 目錄 III 圖目錄 VI 表目錄 VIII 壹、 緒論 1 貳、 文獻回顧 4 2-1 有機發光二極體的歷史發展 4 2-2 有機發光二極體的發光原理 15 2-2-1 有機電激發光原理 15 2-2-2 載子再結合機制 21 2-2-3能量傳遞機制 23 2-2-4元件效率 25 2-3 有機發光二極體材料發展 27 2-3-1、陽極材料 27 2-3-2、電洞注入材料 27 2-3-3、電洞傳輸材料 27 2-3-4、發光材料 29 2-3-5、電子傳輸材料 29 2-3-6、電子注入材料 30 2-3-7、陰極材料 31 2-4黃光有機發光二極體之發展 32 參、實驗方法 36 3-1、材料 36 3-1-1 材料之全名、簡稱及來源一覽 36 3-1-2 本研究所使用有機材料之化學結構式 39 3-1-3 材料性質之量測 41 3-2 元件設計及製備 43 3-2-1 元件電路設計 43 3-2-2 ITO基材前處理 44 3-2-3 旋轉塗佈電洞傳輸層 45 3-2-4 蒸鍍裝置 45 3-2-5 蒸鍍電子阻擋層 46 3-2-6 發光層蒸鍍源之製備與蒸鍍 47 3-2-7 電子傳輸層之製備 47 3-2-8 無機層之製備 48 3-3 元件之量測 49 元件電流、電壓與亮度特性之量測 49 肆、 結果與討論 51 4-1、主體效應 51 4-1-1 元件能階結構與元件名稱對照表 51 4-1-2 濃度對效率的影響 53 4-1-3 主體對效率的影響 54 4-2、共主體效應 56 4-2-1 元件能階結構與元件名稱對照表 56 4-2-2 共主體摻雜濃度的影響 58 4-2-3有無共主體對不同主體黃光元件的影響 61 4-3 所有元件的效率表現 64 伍、結論 65 陸、參考文獻 66 附錄、個人著作目錄 73 (A) 期刊論文 73 (B) 研討會論文 73 圖目錄 圖一、柯達公司於1987年首創異質接面之雙層OLED元件結構圖28 7 圖二、CALVENDISH實驗室,所發表(A)溶液塗佈方式之示意圖及(B)單層PLED元件結構圖32 9 圖三、KIDO教授團隊,在電洞傳輸層及電子傳輸層之間,加入一電洞阻擋層之OLED元件結構示意圖35 10 圖四、SHIROTA等人,使用雙層電洞傳輸層之OLED元件結構圖37 11 圖五、LEO教授團隊,發表之P-I-N結構示意圖41 12 圖六、溶劑預混法之示意圖64 13 圖七、OLED元件結構之示意圖 16 圖八、OLED元件的發光機制三步驟48 16 圖九、JABLONSKI能階圖48 22 圖十、FÖRSTER ENERGY TRNASFER54和DEXTER ENERGY TRANSFER55之示意圖 24 圖十一、本實驗所使用微透鏡 (MICROLENS)的SEM圖86 37 圖十二、本研究所使用有機材料之化學結構式87 41 圖十三、OLED元件之電路設計圖95 43 圖十四、本研究所使用之真空蒸鍍系統示意圖89 46 圖十五、OLED元件之電流-電壓-亮度(I-V-L)及CIE色座標量測示意圖90 49 圖十六、單層發光層黃光磷光OLED元件結構 52 圖十七、濃度效應對元件效率(元件I~III)的影響 53 圖十八、主體效應對元件效率的影響(A) 亮度及電流效率對電壓關係圖(B)能量效率對電壓關係圖 55 圖十九、摻雜共主體IR(PPY)3的能階結構圖 57 圖二十、共主體摻雜濃度對以TPBI為主體的元件之電激發光光譜關係圖 60 圖二十一、有無摻雜共主體對元件電流密度的影響 60 圖二十二、有無摻雜共主體對元件表現的影響 62 圖二十三、在皆有摻雜共主體下,CBP為主體的元件有些微藍位移 63 表目錄 表一、為有機發光二極體發展史的重要時間點及其團隊重大發現 4 表二、各光色波長相對應之HOMO-LUMO能階差及CIE座標49 17 表三、為黃光有機發光二極體發展史的時間點及其團隊發現 32 表四、本研究所使用之材料的主要功能、系統命名、俗稱及來源 38 表五、單層黃光磷光發光層的元件名稱與黃光摻雜濃度對照表 52 表六、元件名稱與共主體和黃光染料摻雜濃度對照表 57 表七、所有元件的效率表現 64

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