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研究生: 林彥勳
Lin, Yen-Hsun
論文名稱: 引入喹喔啉吡唑配位基之二價鉑金屬磷光材料的製備及光物理性質探討
Synthesis and Characterization of Pt(II) Complexes with Quinoxalinyl Pyrazolate Chelates
指導教授: 季昀
Chi, Yun
口試委員: 蔡易州
Tsai, Yi-Chou
陳建添
Chen, Chien-Tien
洪文誼
Hung, Wen-Yi
學位類別: 碩士
Master
系所名稱: 理學院 - 化學系
Department of Chemistry
論文出版年: 2021
畢業學年度: 109
語文別: 中文
論文頁數: 136
中文關鍵詞: 有機發光二極體磷光發光材料MMLCT躍遷近紅外光發光材料鉑金屬錯合物平面四邊形錯合物
外文關鍵詞: Orgaic light emitting diode, phosphor materials, metal-metal to ligand charge transfer, near-infrared emitting materials, square planar complexes
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    • 近紅外光有機發光二極體(near-IR OLED)因為其在醫療、軍事、生物技術上的潛力而受到重視。實驗室在2017年發表的Pt(fprpz)2結構,其最大放射波長(λmax)達到740nm,製作成元件後的最大外部量子效率(EQE)可以達到24%。
      在本論文中,我們將Pt(fprpz)2中的配位基fprpz共軛延長為fqxpz。並引入picolinic acid (pic)作為ancillary ligand,期望能使放光紅移。
      合成了一系列具這樣骨架的錯合物後,我們從液態UV-Vis光譜推測錯合物單分子時的發色團位於fqxpz上,且不容易受到pic上的取代基影響。但昇華粉末PL及mechanochormism現象則顯示錯合物在固態時為MMLCT放光,且pic上的取代基可以影響堆疊,進而影響錯合物在固態時放光的光色。
      最後,蒸鍍薄膜的分析顯示,儘管蒸鍍薄膜的吸收光譜沒有明顯的MMLCT吸收,但放射光譜卻有明顯的MMLCT放光。這是一個有趣且值得探討的現象,但因此而導致的大Stokes shift使的本系列錯合物無法於OLED上有應用。

    Near-infrared organic light-emitting diodes (near-IR OLEDs)have attracted much attention for its various applications in many fields such as medical, military, biotechnology, etc. In 2017, our group developed Pt(fprpz)2, a near IR phosphorescent emitting material with an emission peak weavelength (λmax) at 740 nm, and shows 24% EQE after being fabricated into device.
      To pursue emitters showing longer emission wavelength, we extend the aromatic system of fprpz in Pt(fprpz)2 to fqxpz and synthetized a series of complexes with a framework of Pt(fqxpz)(pic).
      Analysis of liquid UV-Vis spectrum shows that the chromophores are mainly located at fqxpz and not affected by ancillary ligand when complexs are in monomer state. On the other hand, analysis of solid-state PL spectrum shows MMLCT emission, which indicated a Pt-Pt interaction in solid state.
      Finally, analysis of vacuum deposition thin film of complexes shows that the complexes show no MMLCT in absorption but show MMLCT in emission. This is an interesting phenomena, but the resulting large stokes shift hinders those complexes in any OLED applications.

    摘要 i Abstract ii 誌謝 iii 目錄 iv 圖目錄 v 表目錄 viii 第一章: 序論 1 第一節: OLED的歷史及運作原理 1 第二節:螢光與磷光之發光原理 2 第三節:TTA(Triplet-triplet annihilation)現象及解決方案 4 第四節:鉑金屬磷光發光材料及其在OLED上的應用 10 第五節:研究動機與分子設計 17 第二章: 實驗與合成 19 第一節:試藥 19 第二節:儀器 19 第三節:配位基之合成 21 第四節:錯合物之合成 25 第三章: 結果與討論 32 第一節:Pt(II) Complex with quinoline/quinoxaline and picolinate 32 第二節:Pt(II) Complex with quinoxaline and 4-substitue picolinate 41 第四章: 結論 54 附錄一:未收錄於正文中之錯合物 55 附錄二:光譜資料 73 附錄三:參考文獻 135

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