CLC number: TN27
On-line Access: 2019-10-08
Received: 2018-03-19
Revision Accepted: 2018-05-13
Crosschecked: 2019-09-04
Cited: 0
Clicked: 4646
Han Zhang, Xue-lei Liang. Bistable electrowetting device with non-planar designed controlling electrodes for display applications[J]. Frontiers of Information Technology & Electronic Engineering,in press.https://doi.org/10.1631/FITEE.1800167 @article{title="Bistable electrowetting device with non-planar designed controlling electrodes for display applications", %0 Journal Article TY - JOUR
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Reference[1]Bitman A, Bartels F, Rawert J, et al., 2012. Production considerations for bistable droplet driven electrowetting displays. Society for Information Display Int Symp, p.1-4. [2]Blankenbach K, Schmoll A, Bitman A, et al., 2008. Novel highly reflective and bistable electrowetting displays. J Soc Inform Disp, 16(2):237-244. [3]Blankenbach K, Jentsch M, Rawert J, et al., 2011. Sunlight readable bistable electrowetting displays for indicators and billboards. Society for Information Display Int Symp, p.1-4. [4]Brinker CJ, 2013. Dip coating. In: Schneller T, Waser R, Kosec M, et al. (Eds.), Chemical Solution Deposition of Functional Oxide Thin Films. Springer, Vienna, p.233- 261. [5]Charipar KM, Charipar NA, Bellemare JV, et al., 2015. Electrowetting displays utilizing bistable, multi-color pixels via laser processing. J Disp Technol, 11(2):175- 182. [6]Chen CY, Wang CY, Wang WC, et al., 2011. A 3.5-inch bendable active matrix electrowetting display. Society for Information Display Int Symp, p.1-4. [7]Cho SK, Moon H, Kim CJ, 2003. Creating, transporting, cutting, and merging liquid droplets by electrowetting- based actuation for digital microfluidic circuits. J Microelectromech Syst, 12(1):70-80. [8]Comiskey B, Albert JD, Yoshizawa H, et al., 1998. An electrophoretic ink for all-printed reflective electronic displays. Nature, 394(6690):253-255. [9]Dai YX, 2008. Design and Operation of TFT LCD Panels. Tsinghua University Press, Beijing, China (in Chinese). [10]Deng Y, Tang B, Henzen AV, et al., 2017. Recent progress in video electronic paper displays based on electro-fluidic technology. Society for Information Display Int Symp, p.1-4. [11]Hayes RA, Feenstra BJ, 2003. Video-speed electronic paper based on electrowetting. Nature, 425(6956):383-385. [12]Heikenfeld J, Zhou K, Kreit E, et al., 2009. Electrofluidic displays using Young-Laplace transposition of brilliant pigment dispersions. Nat Photon, 3(5):292-296. [13]Hou L, Smith NR, Heikenfeld J, 2007. Electrowetting manipulation of any optical film. Appl Phys Lett, 90(25): 1-3. [14]Huh D, Tkaczyk AH, Bahng JH, et al., 2003. Reversible switching of high-speed air-liquid two-phase flows using electrowetting-assisted flow-pattern change. J Am Chem Soc, 125(48):14678-14679. [15]Jones TB, 2005. An electromechanical interpretation of electrowetting. J Micromech Microeng, 15(6):1184-1187. [16]Jung HY, Choi UC, Park SH, et al., 2012. Development of driver IC with novel driving method for the electrowetting display. Society for Information Display Int Symp, p.1-4. [17]Kuiper S, Hendriks BHW, 2004. Variable-focus liquid lens for miniature cameras. Appl Phys Lett, 85(7):1128-1130. [18]Lao Y, 2008. Ultra-High Transmission Electrowetting Displays. MS Thesis, University of Cincinnati, Cincinnati, USA. [19]Mugele F, Baret JC, 2005. Electrowetting: from basics to applications. J Phys Condens Matter, 17(28):705-774. [20]Pollack MG, Shenderov AD, Fair RB, 2002. Electrowetting- based actuation of droplets for integrated microfluidics. Lab Chip, 2(2):96-101. [21]Rawert J, Jerosch D, Blankenbach K, et al., 2010. Bistable D3 electrowetting display products and applications. Society for Information Display Int Symp, p.1-4. [22]Shui LL, Hayes RA, Jin ML, et al., 2014. Microfluidics for electronic paper-like displays. Lab Chip, 14(14):2374- 2384. [23]Smith NR, Abeysinghe DC, Haus JW, et al., 2006. Agile wide-angle beam steering with electrowetting microprisms. Opt Expr, 14(14):6557-6563. [24]Verheijen HJJ, Prins MWJ, 1999. Reversible electrowetting and trapping of charge: model and experiments. Langmuir, 15(20):6616-6620. [25]Yang S, Zhou K, Kreit E, et al., 2010. High reflectivity electrofluidic pixels with zero-power grayscale operation. Appl Phys Lett, 97(14):1-3. [26]You H, Steckl AJ, 2010. Three-color electrowetting display device for electronic paper. Appl Phys Lett, 97(2):1-3. [27]Zhang H, Yan QP, Xu QY, et al., 2017. A sacrificial layer strategy for photolithography on highly hydrophobic surface and its application for electrowetting devices. Sci Rep, 7(1):1-7. [28]Zhou K, Heikenfeld J, Dean KA, et al., 2009. A full description of a simple and scalable fabrication process for electrowetting displays. J Micromech Microeng, 19(6):1-12. Journal of Zhejiang University-SCIENCE, 38 Zheda Road, Hangzhou
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