合成電極應用於牆型及三維六角形結構之藍相液晶研究

張耕綸; Keng-Lun Chang

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/99607

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	蔡永傑	zh_TW
dc.contributor.advisor	Wing-Kit Choi	en
dc.contributor.author	張耕綸	zh_TW
dc.contributor.author	Keng-Lun Chang	en
dc.date.accessioned	2025-09-17T16:07:33Z	-
dc.date.available	2025-09-18	-
dc.date.copyright	2025-09-17	-
dc.date.issued	2025	-
dc.date.submitted	2025-08-08	-
dc.identifier.citation	[1] Reinitzer, F. (1888). “Beiträge zur kenntniss des cholesterins. Monatshefte für Chemie/”Chemical Monthly. 9: 421-441. [2] Yang, D. K., & Wu, S. T. (2014). “Fundamentals of Liquid Crystal Devices(2nd ed.). Wiley.” [3] Wu, S.-T. (1986). “Birefringence dispersions of liquid crystals.” Physical Review A. 33: 1270. [4] Coles, H. J., & Morris, S. M. (2010). “Liquid-crystal blue phases: Physics and applications.”Nature Photonics, 4(10), 676–685. [5] Bahr, C., & Kitzerow, H. S. (2001). “Chirality in liquid crystals.” Heidelberg: Springer. [6] Kikuchi, H., Yokota, M., Hisakado, Y., Yang, H., & Kajiyama, T. (2002). “Polymer-stabilized liquid crystal blue phases.”Nature Materials, 1(1), 64–68. [7] Yan, J., Cheng, H. C., Gauza, S., Li, Y., Jiao, M., Rao, L., & Wu, S. T. (2010). “Extended Kerr effect of polymer-stabilized blue-phase liquid crystals.” Applied Physics Letters,96(7), 071105. [8] Schadt, M., & Helfrich, W. (1971). “Voltage‐dependent optical activity of a twisted nematic liquid crystal.” Applied Physics Letters,18(4), 127-128. [9] Chigrinov, V. G. (1999). “Liquid crystal devices: physics and applications.” [10] Klauk, H., Zschieschang, U., Pflaum, J., & Halik, M. (2009). “Organic thin-film transistors with high mobility based on a new molecular semiconductor.Advanced Materials,”21(14-15), 1449–1473. [11] Oh‐e, M. and Kondo, K. (1995). “Electro‐optical characteristics and switching behavior of the in‐plane switching mode.” Applied physics letters. 67: 3895-3897. [12] Oh‐e, M. and Kondo, K. (1996). “Response mechanism of nematic liquid crystals using the in‐plane switching mode.” Applied physics letters. 69: 623-625. [13] Kumar, P., Jaggi, C., Sharma, V., & Raina, K. K. (2016). “Advancements of vertically aligned liquid crystal displays.” Micron, 81, 34–47. [14] Ting, C.L. and Huang, W.F. (2005). “Multi-domain vertical alignment liquid crystal display and driving method thereof,” U.S. Patents. US 6922183 B2 [15] Kim, K.H., et al. (1998). “Domain divided vertical alignment mode with optimized fringe field effect.” Proceedings of Asia Display. 98: 383-386. [16] Kim, S.G., et al. (2007). “Stabilization of the liquid crystal director in the patterned vertical alignment mode through formation of pretilt angle by reactive mesogen.” Applied physics letters. 90: 261910. [17] Lee, Y.J., et al. (2009). “Surface-controlled patterned vertical alignment mode with reactive mesogen.” Optics express. 17: 10298-10303. [18] Lee, S., et al. (1998). “Electro-optic characteristics and switching principle of a nematic liquid crystal cell controlled by fringe-field switching.” Applied physics letters. 73: 2881-2883. [19] Hong, S.H., et al. (2000). “Electro-optic characteristic of fringe-field switching mode depending on rubbing direction.” Japanese Journal of Applied Physics. 39: L527 [20] Kikuchi, H., & Haseba, Y. (2012). “Blue phase liquid crystal displays: Advances and challenges.Journal of the Society for Information Display,” 20(9), 483–489. [21] Kim, M., Kim, M. S., Kang, B. G., Kim, M.-K., Yoon, S., Lee, S. H., … Wu, S.-T. (2009). “Wall-shaped electrodes for reducing the operation voltage of polymer-stabilized blue phase liquid crystal displays.” Journal of Physics D: Applied Physics, 42(23), 235502. [22] Chen, H., Lan, Y.-F., Tsai, C.-Y., & Wu, S.-T. (2016). “Low-voltage blue-phase liquid crystal display with diamond-shape electrodes.” Liquid Crystals, 44(7), 1124–1130. [23] Zhu, X., Ge, Z., & Wu, S. T. (2006). “Analytical solutions for uniaxial-film-compensated wide-view liquid crystal displays.” Journal of Display Technology,2(1), 2-20. [24] Chen Yanqing,Sun Yubao &Yang Guoqiang(2011) “Low voltage and high transmittance blue-phase LCDs with double-side in-plane switching electrodes,” Liquid Crystals, 38:5, 555-559. [25] Yamada, N., Kohzaki, S., Funada, F., & Awane, K. (1995). “Axially symmetric aligned microcell (ASM) mode: Electro-optical characteristics of new display mode with excellent wide viewing angle.” Journal of the Society for Information Display, 3(4), 155. [26] Goldberg, H. D., Brown, R. B., Liu, D. P., & Meyerhoff, M. E. (1994). “Screen printing: a technology for the batch fabrication of integrated chemical-sensor arrays. Sensors and Actuators B: Chemical,” 21(3), 171–183. [27] Zhao, X., Evans, J. R. G., Edirisinghe, M. J., & Song, J.-H. (2002). “Direct Ink-Jet Printing of Vertical Walls. Journal of the American Ceramic Society,” 85(8), 2113–211	-
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/99607	-
dc.description.abstract	隨著科技日益的進步，液晶顯示器成為生活中相當重要的電子產品，其中藍相液晶被視為具有潛力的材料之一，藍相液晶因自組裝三維晶格結構，展現出高速響應、寬視角與製程簡化等優勢，但同時面臨高操作電壓與低穿透率等瓶頸。研究中利用TechWiz 3D專業模擬軟體，建立多種電極結構模型，系統性分析傳統雙面藍相IPS結構、牆型電極、半牆型電極，以及三維多重中空六角形電極在穿透率與操作電壓上的表現，本論文透過三個部分探討合成電極於牆型及三維六角形結構之應用。第一部分，說明如何從雙邊IPS為基礎，透過改善操作電壓以及穿透率，調整電極排列結構形成合成電極結構。第二部分，改良傳統牆型電極結構高操作電壓及不透光區域問題，提出半牆型結構並結合合成電極設計，有效改善原本不透光區域的電場分布，顯著提升穿透率並大幅降低操作電壓。第三部分在三維六角形結構部分，研究證實多重中空六角形排列能兼顧高穿透率與低操作電壓，並進一步結合合成電極與結構優化，最終於六重中空六角形基礎上實現96.3%的高穿透率與較傳統設計降低52.5%的操作電壓。整體而言，本論文透過合成電極結構改善原有之牆型及三維六角形結構，使結果兼具製程可行性與性能優勢，為藍相液晶顯示技術的實用化與未來發展提供了具體的創新路徑與理論依據。	zh_TW
dc.description.abstract	With the rapid advancement of technology, liquid crystal displays have become indispensable in daily life, and blue phase liquid crystals are regarded as one of the most promising materials for next-generation displays. BPLCs, characterized by their self-assembled three-dimensional lattice structures, offer advantages such as ultra-fast response, wide viewing angles, and simplified fabrication processes. However, they still face challenges including high operating voltage and low transmittance. In this study, TechWiz 3D professional simulation software was utilized to construct and systematically analyze various electrode structure models—including traditional double-sided blue phase IPS structures, wall-shaped electrodes, half-wall electrodes, and three-dimensional multi-hollow hexagonal electrodes—in terms of their transmittance and operating voltage. This thesis explores the application of composite electrodes in wall-shaped and three-dimensional hexagonal structures by first improving the double-sided IPS structure through optimized electrode arrangement to enhance operating voltage and transmittance, then addressing the high operating voltage and non-transparent regions of traditional wall-shaped electrodes by introducing a half-wall structure combined with composite electrode design, which significantly improves the electric field distribution and overall transmittance while reducing operating voltage. Furthermore, for three-dimensional hexagonal structures, the study demonstrates that multi-hollow hexagonal arrangements can achieve both high transmittance and low operating voltage; by further integrating composite electrodes and optimizing the structure, a six-layer hollow hexagonal design achieves a high transmittance of 96.3% and a 52.5% reduction in operating voltage compared to traditional designs. Overall, this thesis demonstrates that the composite electrode structure effectively improves both the process feasibility and performance of wall-shaped and three-dimensional hexagonal structures, providing concrete innovative pathways and theoretical foundations for the practical application and future development of blue phase liquid crystal display technology.	en
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dc.description.tableofcontents	審定書 i 誌謝 ii 中文摘要 iii ABSTRACT iv 目次 vi 圖次 viii 表次 x Chapter 1 液晶簡介 1 1.1 液晶的定義 1 1.2 液晶的相態及分類 2 1.2.1 熱致液晶和濃度致液晶 2 1.2.2 向列型液晶 3 1.2.3 層列型液晶 4 1.2.4 膽固醇型液晶 5 1.3 液晶的特性 6 1.3.1 光學異相性 6 1.3.2 電光效應 7 1.3.3 熱學性質與連續彈性體理論 8 1.4 藍相液晶介紹 9 1.4.1 結構類型 9 1.4.2 物理與光學性質 10 1.4.3 穩定性改良及克爾效應 10 Chapter 2 顯示器介紹及研究動機 12 2.1 液晶顯示器 12 2.1.1 液晶顯示器的歷史 12 2.1.2 液晶顯示器的介紹 12 2.2 藍相液晶顯示器優劣勢 13 2.3 液晶顯示器重要參數 14 2.3.1 響應時間(Response Time) 14 2.3.2 對比度(Contrast Ratio,CR) 15 2.3.3 灰階(Gray Scale) 15 2.3.4 可視角度(Viewing Angle) 15 2.3.5 操作電壓及穿透率 15 2.4 研究動機 15 Chapter 3 TechWiz 3D模擬軟體 17 3.1 模擬軟體(TechWiz 3D)介紹 17 3.2 Material Database(材料庫模組) 17 3.3 Mesh Generation(網格化切割) 19 3.4 LC Analysis(液晶分析) 19 3.5 Optical Analysis(光學分析) 20 Chapter 4 模擬結果與討論 22 4.1 合成電極(Composite electrodes)結構分析 22 4.1.1 Double-side BP IPS 22 4.1.2 調整上下電極間距 23 4.1.3 調整電極排列方式 26 4.2 牆型電極(Wall-shaped electrodes)結構分析及討論 30 4.2.1 不同間距之傳統牆型電極結構比較 30 4.2.2 不同牆體寬度之傳統牆型電極結構比較 32 4.2.3 半牆型(Half wall)電極結構發想 34 4.2.4 結合合成電極之優化模擬結果分析 36 4.2.5 調整上下牆體寬度 40 4.3 三維六角形電極(Hexagonal electrodes)結構分析及討論 43 4.3.1 中空六角形電極結構 43 4.3.2 多重六角形結構討論 44 4.3.3 結合合成電極之優化模擬結果分析 45 Chapter 5 結論與未來目標 52 Reference 53	-
dc.language.iso	zh_TW	-
dc.subject	藍相液晶顯示器	zh_TW
dc.subject	TechWiz LCD	zh_TW
dc.subject	雙邊IPS結構	zh_TW
dc.subject	合成電極結構	zh_TW
dc.subject	牆型電極結構	zh_TW
dc.subject	多重中空六角形電極結構	zh_TW
dc.subject	double-sided IPS structure	en
dc.subject	Blue phase liquid crystal display	en
dc.subject	multi-hollow hexagonal electrode structure	en
dc.subject	wall-shaped electrode structure	en
dc.subject	composite electrode structure	en
dc.subject	TechWiz LCD	en
dc.title	合成電極應用於牆型及三維六角形結構之藍相液晶研究	zh_TW
dc.title	Application of Composite Electrode to Blue Phase Liquid Crystals in Wall-Shaped and Three-Dimensional Hexagonal Design	en
dc.type	Thesis	-
dc.date.schoolyear	113-2	-
dc.description.degree	碩士	-
dc.contributor.oralexamcommittee	林晃巖;黃定洧;黃念祖	zh_TW
dc.contributor.oralexamcommittee	Hoang-Yan Lin;Ding-Wei Huang;Nien-Tsu Huang	en
dc.subject.keyword	藍相液晶顯示器,TechWiz LCD,雙邊IPS結構,合成電極結構,牆型電極結構,多重中空六角形電極結構,	zh_TW
dc.subject.keyword	Blue phase liquid crystal display,TechWiz LCD,double-sided IPS structure,composite electrode structure,wall-shaped electrode structure,multi-hollow hexagonal electrode structure,	en
dc.relation.page	55	-
dc.identifier.doi	10.6342/NTU202504216	-
dc.rights.note	同意授權(限校園內公開)	-
dc.date.accepted	2025-08-13	-
dc.contributor.author-college	電機資訊學院	-
dc.contributor.author-dept	光電工程學研究所	-
dc.date.embargo-lift	2030-08-07	-
顯示於系所單位：	光電工程學研究所

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