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標題: 電濕潤顯示器之封裝製程與研究
The Investigation of Electrowetting Display Assembly Process
作者: 林黃譽
Lin, Hung-Yu
關鍵字: 電濕潤顯示器;electrowetting display;油墨;奈米粒子;OD值;封裝製程;oil;nanocrystal;optical density;assembly process
出版社: 精密工程學系所
引用: [1] 友達光電『技術研發 TFT-LCD簡介』。 [2] “Introduction to OLED Displays-Design Guide for Active Matrix OLED(AMOLED) Displays”,, 2008. [3] C.-L. Lin, Y.-C. Chen, “A Novel LTPS-TFT Pixel Circuit Compensating for TFT Threshold-Voltage Shift and OLED Degradation for AMOLED”, IEEE Electron Device Letters, Vol.28, pp.129-131, 2007. [4] 聶建名『有機發光二極體採用非晶態薄膜電晶體之驅動補償電 路研究:Enchancement of OLED compensation pixel circuit using Amorphous TFTs』,碩士論文,國立交通大學光電工程研 究所,2009 [5] G. Beni and S. Hackwood, “Electro-wetting display,” Applied Physics Letters, Vol.38, pp.207-209, 1981. [6] R. A. Hayes and B. J. Feenstra, “ Video-speed electronic paper based on electrowetting,” Nature, Vol.425, pp.383-385, 2003. [7] 李英彰『電濕潤顯示器畫素擋牆高度對反應時間的影響』,碩 士論文,國立中興大學精密工程研究所,2010。 [8] 游國豐『奈米粒在電濕潤顯示器的研究』,碩士論文,國立中 興大學精密工程研究所,2011。 [9] T. A. Mcmahon and J. T. Bonner, “On Size and Life,” Scientific American Books, 1983. [10] B. J. Feenstra, R. A. Hayes, R. Van Dijk, R. G. H. Boom, M. M. H. Wageman, I. G. J. Camps, A. Giraldo and B. v. d. Heijden, “Electrowetting-based displays: bringing microfluidics alive on-screen,” IEEE International Conference on Micro Electro Mechanical Systems, Vol.2006, pp.48-53, 2006. [11] R. A. Hayes and B. J. Feentra, “Video-speed electronic paper based on electrowetting,” Nature, Vol.425, pp.383-385, 2003. [12] G. M. Podojil, D. J. Davis, X. Y. Huang, N. Miller and J. W. Doane, “Plastic VGA Reflective Cholesteric LCDS with Dynamic Drive,”SID98 Digest,Vol.29, pp.51- 54, 1998. [13] J. C. Heikenfeld and A. J. Steckl, “Liquid Light,” Information Display, pp.26, 2004. [14] J. Park, K. An, Y. Hwang, J.-G. Park, H.-J. Noh, J.- Y. Kim, J.-H. Park, N.-M. Hwang and Taeghwan Hyeon, “Ultra-large-scale synthesis of monodisperse Nanocrystals,” Nature Materials, Vol. 3, pp. 891-895, 2004. [15] G. Gao, X. Liu, R. Shi, K. Zhou, Y. Shi, R. Ma, T.-M. Eiji, and G. Qiu, “Shape-Controlled Synthesis and Magnetic Properties of Monodisperse Fe3O4 Nanocubes, ” Crystal Growth and Design, Vol. 10, pp. 2888-2891, 2010. [16] 馮榮豐、陳錫添編著『奈米工程概論第四版』全華圖書股份有 限公司,2010。 [17] 范光照、黃漢邦、陳炳煇、張所鋐、顏家鈺編著『奈米工程概 論』普林斯頓國際有限公司,2003。 [18] 葉瑞銘編著『奈米科技第二版』高立圖書有限公司,2009。 [19] 郭柏佑,磷化鐵奈米柱與奈米花的合成,國立成功大學化學工 程系碩士論文,2009。 [20] J. Park, J. Joo, S. G. Kwon, Y. Jang, and T. Hyeon, “Synthesis of Monodisperse Spherical Nanocrystals,” Angewandte Chemie Int. Ed., Vol.46, pp.4630-4660, 2007. [21] Q. A. Pankhurst, J. Connolly, S. K. Jones and J. Dobson “Applications of magnetic nanoparticles in biomedicine,” Journal of Physics D: Applied Physics, Vol.36, pp.167-181, 2003. [22] 程孝龍,電濕潤顯示器製程與反應時間之影響,國立中興大學 精密工程研究所碩士論文,2008。 [23] H. Wang, P. Hu, D. Pan, J. Tian, S. Zhang, A. A. Volinsky, “Carbothermal reduction method for Fe3O4 powder synthesis,” Journal of Alloys and Compounds , Vol.502, pp.338-340, 2010. [24] 鍾文定『凝聚態物理學叢書鐵磁學中冊』科學出版社出版, 1998。 [25] 紀國鐘『液晶顯示器技術手冊』,2001。
近年大尺寸TFTLCD面板的封裝方式主要為ODF(One Drop Fill)製程,而本論文是利用TFTLCD封裝方式中的ODF製程,應用在我們的電濕潤顯示器光閥封裝製程中:經由噴墨系統噴印至畫素中再貼合封裝。先將奈米粒子分散於載液中來調配成油墨,基於此油墨其特有的性質,經過噴印系統噴墨至畫素中後,加上毛細力可控制油墨吸附在畫素底層,再加水於畫素中後,油墨不會被沖刷出來。
整個油墨製備過程中我們採用不同的參數:奈米粒製成加熱過程中通入氬氣與否、通入氬氣時的樣品的溫度,會產生不同粒徑大小的黑色奈米粒子最後再以不同比例(奈米粒子與作為溶劑的油之體積比)溶入載液中調配不同OD值(Optical Density)、黏稠度不同的黑色油墨。

In recent years, the mainly assembly process for large size TFTLCD panel is used by using the ODF (One Drop Fill) technology. For cutting into TFTLCD manufacturing process, the investigation of ODF process is implemented for the electrowetting display assembly in this thesis:printing the ink into the pixel and then making the display assembly. With the properties of nano-crystal and capillary phenomenon of the ink formed by the nano-crystal , the printing ink can be sit in pixel and not flush out of the pixel by water that is printing into the pixel after ink printing.
This ink formation is focused on different parameters, such as whether the addition of argon flow in the nanocrystals solution formation process, what is the temperature when argon flow into the formation process during elevating temperature in process, and the effect of the starting temperature when the argon flow into formation process. Finally, different mixing ratios (volume ration : nano-crystal solution to oil) produce black inks with different optical densities and viscosities.
其他識別: U0005-2208201214282700
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