功能绝缘材料加工工艺对电润湿显示器性能的影响

Process Influence on Electro-Wetting Display Insulator Material Property

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摘要以通过蒸汽溶解法(Vapor redissolve method)代替高温回流法来恢复氟树脂层的疏水性能,使用氟碳溶剂(HFE7100)蒸汽溶解氟树脂层粗糙表面使其形成溶胶状态,加热蒸发溶剂后使表面恢复疏水性质.对溶解法溶解时间、干燥温度和干燥时间等条件进行了探究,对比了高温回流法和蒸汽溶解法对电润湿显示器产生的物理和光电的影响.蒸汽溶解法在不影响电润湿显示器其他功能的前提下,可以替代高温回流方法恢复氟树脂层的疏水功能并且工艺更简单. Instead of high temperature reflow method, vapor redissolve method is suggested to recover hydrophobicity, using a fluorocarbon solvent （HFE7100） steam to dissolve fluororesin layer surface roughened sol state. After heating, the solvent is evaporated to restore the hydrophobic nature of its surface. Focus on the dissolving time, drying temperature and drying time, deep research is done. Comparison on physical effects and photoelectric effects to electrowetting display devices are made between these two methods. Under the premise that does not affect the performance of electrowetting display devices, vapor redissolve method can be used to recover the hydrophobicity of fluororesin layer with simple process.

作者郭媛媛蒋洪伟吴昊周国富 Robert A.Hayes

机构地区华南师范大学华南先进光电子研究院深圳国华光电科技有限公司

出处《华南师范大学学报（自然科学版）》 CAS 北大核心 2015年第6期42-47,共6页 Journal of South China Normal University(Natural Science Edition)

基金国家自然科学基金项目(21303060) 广东省自然科学基金项目(S2013010014418) 教育部引进创新科研团队项目(IRT13064) 广东省创新科研团队项目(2011D039)

关键词电润湿显示器疏水层性能恢复高温回流法蒸汽溶解法性能 electro-wetting display hydrophobicity recovery high temperature reflow method vapor redissolve method property

分类号 TN27 [电子电信—物理电子学]

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参考文献14

1David Q. Wetting and roughness [ J ]. Annual Review of Materials Research, 2008, 38( 1 ):71 -99.
2Kang K H. How electrostatic fields change contact angle in electrowetting[ J ]. Langmuir, 2002, 18 (26) : 10318 - 10322.
3Verheijen H J J, Prins M W J. Reversible electrowetting and trapping of charge: Model and experiments [ J ]. Langmuir, 1999, 15(20) : 6616-6620.
4Hendriks B H W, Kuiper S, Van As M A J, et al. Elec- trowetting based variable focus lens for miniature systems [J]. Optical Review, 2005, 12(3) : 255 -259.
5Paik P, Vamsee K P, Michael G P, et al. Electrowet- ting-based droplet mixers for microfluidic systems [ J ]. Lab on a Chip, 2003, 3(1) :28 -33.
6Hayes R A, Feenstra B J. Video-speed electronic paper based on electrowetting[ J ]. Nature, 2003, 425 (6956) : 383 - 385.
7Lee G, Moon H, Fowler J, et al. Electrowetting and electrowetting on dielectric for microscale liquid handling [ J ]. Sensors and Actuators A : Physical, 2002, 95 (2) : 259 - 268.
8Chang H C, Chang J K. Large slip of aqueous liquid flow over a nanoengineered superhydrophobic surface [ J 1. Vir- tual Journal of Nanoscale Science and Technology, 2006, 13(8) : 066001.
9Datta A, Eom I A, Dhar A, et al. Microfabrication and characterization of Teflon AF-coated liquid core waveguide channels in silicon[ J]. IEEE Sensors Journal, 2003, 3 (6) : 788 -795.
10Anamelechi C C, Truskey G A, Reichert W M. Mylar (TM) and Teflon-AF (TM) as cell culture substrates for studying endothelial cell adhesion [ J ]. Biomaterials, 2005, 26 (34) : 6887 - 6896.

二级参考文献13

1Comiskey B, Albert J D, Yoshizawa H, et al. An elec- trophoretic ink for all-printed reflective electronic displays [J]. Nature, 1998, 394:253-255.
2Hayes R A, Feenstra B J. Video-speed electronic paper based on electrowetting [ J ]. Nature, 2003, 425 : 383 - 385.
3Hayes R A, Feenstra B J, Camps I G J, et al. A video- speed reflective display based on eleetrowetting: Principle and properties[J]. Journal of the Society for Information Display, 2004, 312:293-299.
4You H, Steckl A J. Three-color electrowetting display de- vice for electronic paper [ J ]. Applied Physics Letters, 2010, 97(2) :023514.
5Heikenfeld J, Zhou K, Kreit E, et al. Electrufluidic dis- plays using Young-Laplace transposition of brilliant pig- ment dispersions [ J ]. Nature Photonics, 2009, 3 (5) : 292 - 296.
6Yang S, Zhou K, Kreit E, et al. High reflectivity elec- trofluidic pixels with zero-power grayscale operation [ J ]. Applied Physics Letters, 2010, 97(14) :143501.
7Zhou K, Heikenfeld J, Dean K A, et ah A full descrip- tion of a simple and scalable fabrication process for'elec- trowetting displays [ J ]. Journal of Micromechanics and Microengineering, 2009, 19 (6) : 065029.
8Roques-Carmes T, Hayes R A, Feenstra B J, et al. Liq- uid behavior inside a reflective display pixel based on electrowetting[ J]. Journal of Applied Physics, 2004, 95 (8) :4389 - 4396.
9Roques-Carmes T, Palmier S, Hayes R A, et al. The effect of the oil-water interfacial tension on electrowetting driven fluid motion[ Jl. Colloids and Surfaces A: Physico- chem. Eng. Aspects. 2005, 267:56 -63.
10Sureshkumar P, Kim M,Song E G, et al. Effect of sur- face roughness on the fabrication of electrowetting display cells and its electro-optic switching behavior[ J].Surface Review and Letters, 2009, 16:23 - 28.

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2金杏林.氟碳溶剂脱水技术[J].机械工艺师,1989(7):23-24.
3金林.氟碳溶剂清洗在电子元件生产中的应用[J].电子工艺简讯,1991(8):2-4.
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10G.W.Gale,H.Ohno,H.Namba,T.Orii,Y.Takagi,M.Yamasaka.晶圆干燥缺陷的机理与控制[J].电子工业专用设备,2005,34(7):29-33. 被引量：1

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功能绝缘材料加工工艺对电润湿显示器性能的影响

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