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研究生:黃柏喻
研究生(外文):Po-Yu Huang
論文名稱:大面積量測奈米粒子誘使液晶垂直配向之軟性顯示器
論文名稱(外文):Large-area measurement system for nanoparticles-induced vertical alignment in flexible liquid crystal display
指導教授:施宙聰施宙聰引用關係
指導教授(外文):Jow-Tsong Shy
學位類別:碩士
校院名稱:國立清華大學
系所名稱:光電工程研究所
學門:工程學門
學類:電資工程學類
論文種類:學術論文
論文出版年:2008
畢業學年度:96
語文別:中文
論文頁數:62
中文關鍵詞:一維陣列偵測器大面積量測奈米粒子垂直配向軟性顯示器錨定能
外文關鍵詞:photodiode arrayLarge-area measurement systemnanoparticlevertical alignmentflexible LC displaysanchoring energy
相關次數:
  • 被引用被引用:4
  • 點閱點閱:320
  • 評分評分:
  • 下載下載:53
  • 收藏至我的研究室書目清單書目收藏:1
本論文利用一定比例之奈米粒子POSS與正丁醇的混合物,旋轉塗佈於軟性基板,研究此液晶盒之光電特性,發現奈米粒子POSS可誘使液晶分子垂直配向,並利用表面自由能來佐證之。根據實驗結果、理論推導計算、模擬,我們發現其錨定能約為4.55×10-5 Jm-2,低於傳統之PI垂直配向膜。除此之外,因製程溫度僅約80°C且具有經濟效益,所以適用於軟性顯示器且可克服無法耐高溫製程的問題。
有鑑於軟性顯示器於撓曲時,易造成間隙的不均勻,所以我們架設了可信賴、快速、大面積之一維陣列偵測器的光電特性量測系統,由64個二極體所組成,一次可量得一維陣列的資訊,可有效檢測顯示器之大面積的光電特性,特別適用於軟性顯示器的檢測,我們也與商用機台 (Otsuka5100) 作比較,結果顯示VT-curve與反應時間均吻合,此套系統之時間解析度為1 msec,穩定度為2.7%。
In this thesis, we studied the electro-optical properties of a liquid crystal cell applied nanoparticles as an alignment material. It was decomposed on the substrate by spin coating the mixture, POSS and Butanol. Based on Fowkes’ theory, we indicated that the nanoparticle POSS can induce vertical alignment. According to the experimental results, theoretical prediction, and simulation, we found that the anchoring energy was about 4.55×10-5 Jm-2. It was lower than the traditional PI vertical alignment layer. Meanwhile, the process temperature is about 80°C, which is suitable to fabricate flexible LC displays.
Otherwise, the cell gap of flexible LC display was difficult to maintain under bending condition. So, we developed a reliable and rapid electro-optical measurement system for large area flexible liquid crystal displays. A 64-element photodiode array combined with simple bending mechanism was employed for 1D signal sampling. The system was also compared to another calibrated commercial system (Otuska5100). Both TV-curves and response time almost coincided with each other. The stability of the system was about 2.7 % and the time resolution was 1 msec.
中文摘要.................................................Ⅰ
英文摘要.................................................Ⅱ
誌謝.....................................................Ⅲ
目錄.....................................................Ⅳ
圖目錄...................................................Ⅶ
表目錄...................................................Ⅹ
第一章、導論.............................................1
1.1 前言.................................................1
1.2 研究目的.............................................2
第二章、液晶的配向機制與技術.............................3
2.1 顯示器的一般配向方法.................................3
2.1.1 接觸式.............................................3
2.1.2 非接觸式...........................................4
2.2 POSS對液晶產生之垂直配向.............................7
2.2.1 多面體矽氧烷寡聚物(POSS)之簡介.....................7
2.2.2 多面體矽氧烷寡聚物 (POSS) 對液晶產生之垂直配向.....9
2.2.3 表面張力與表面能..................................11
2.2.4 Fowkes’theory....................................13
2.3 錨定能對光電特性的影響..............................15
2.3.1 強錨定能..........................................16
2.3.2 弱錨定能..........................................17
第三章、一維陣列偵測器的量測系統........................20
3.1 量測系統裝置........................................20
3.1.1 一維陣列偵測器....................................21
3.1.2 程式設計流程圖與訊號擷取示意圖....................24
3.2 系統穩定度評估......................................27
3.2.1 光源之特性........................................27
3.2.2 量測系統之可靠性..................................28
3.2.3 系統穩定度評估....................................30
第四章、樣品製作及實驗裝置..............................31
4.1 液晶盒樣品製作......................................31
4.2 實驗裝置............................................33
第五章、實驗結果........................................34
5.1 表面能與表面張力....................................34
5.2 光電特性............................................35
5.3 不同撓曲曲率下之光電特性............................39
5.4 POSS和PI的比較......................................45
第六章、實驗結果討論....................................47
6.1 5.1和5.2的實驗結果討論..............................47
6.2 弱錨定能的光電特性討論..............................50
6.2.1 時間響應與錨定能的關係............................50
6.2.2 閥值電壓..........................................52
第七章、結論與展望......................................53
7.1 結論................................................53
7.2 展望................................................54
參考文獻................................................55
附錄....................................................57
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