Contact angle hysteresis in electrowetting on dielectric 被引量：1

Contact angle hysteresis in electrowetting on dielectric

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摘要 Contact angle hysteresis(CAH) is one of the significant physical phenomena in electrowetting on dielectric(EWOD).In this work, a theoretical model is proposed to characterize electrowetting evolution on substrates with CAH, and the relationship among apparent contact angle, potential, and some other parameters is quantified. And this theory is also validated experimentally. The results indicate that our theory and equation based on energy balance succeed in describing the electrowetting response of potential with significant contact angle hysteresis. The CAH in EWOD, ranging from 0° to about 20° in electrowetting cycle, increases with the increase of voltage and climbs up to about 20° when voltage is increased to about 38 V, and then decreases to zero with the further increase of voltage. Contact angle hysteresis(CAH) is one of the significant physical phenomena in electrowetting on dielectric(EWOD).In this work, a theoretical model is proposed to characterize electrowetting evolution on substrates with CAH, and the relationship among apparent contact angle, potential, and some other parameters is quantified. And this theory is also validated experimentally. The results indicate that our theory and equation based on energy balance succeed in describing the electrowetting response of potential with significant contact angle hysteresis. The CAH in EWOD, ranging from 0° to about 20° in electrowetting cycle, increases with the increase of voltage and climbs up to about 20° when voltage is increased to about 38 V, and then decreases to zero with the further increase of voltage.

作者赵瑞刘启超王评梁忠诚

机构地区 Center of Optofluidic Technology

出处《Chinese Physics B》 SCIE EI CAS CSCD 2015年第8期492-496,共5页 中国物理B（英文版）

基金 supported by the Natural Science Foundation of Jiangsu Province,China(Grant No.BK2011752)

关键词 contact angle hysteresis ELECTROWETTING energy balance contact angle hysteresis,electrowetting,energy balance

分类号 O441.1 [理学—电磁学]

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参考文献36

1Walker, Shawn W.,Shapiro, Benjamin,Nochetto, Ricardo H.Electrowetting with contact line pinning: Computational modeling and comparisons with experiments. The Physics of Fluids . 2009
2Lippmann G. Ann.Chim.Phys . 1875
3Li F,Mugele F. Applied Physics Letters . 2008
4Zeng Xue-Feng,Yue Rui-Feng,Wu Jian-Gang,Dong Liang,Liu Li-Tian.Actuation and Control of Droplets by Using Electrowetting-on-Dielectric. Chinese Physics . 2004
5Gras S L,Mahmud T,Rosengarten G,Mitchell A,Kalantar-zadeh K. Chem.Phys.Chem . 2007
6Zhao Y P,Wang Y. Rev.Adhesion Adhesives . 2013
7Chen L Q,Bonaccurso E. Advances in Colloid and Interface Science . 2014
8Cheng J,Chen C L. Applied Physics Letters . 2011
9Wang D Z,Peng R L,Chen J B,Zhuang S L. Acta Opt.Sin . 2011
10Zhao R,Tian Z Q,Liu Q C,Wang P,Liang Z C. Acta Opt.Sin . 2014

二级参考文献14

1KAVEHVASH Z, MEHRANY K, BAGHERI K. Optimization of lens-array structure for performance improvement of integral imaging [J]. Opt. Lett. , 2011, 36(20): 3993-3995.
2CHEN J, WANG W S, FANG J. Variable-focusing microlens with microfluidic chip [J]. Journal of Micromechanics and Microengineering , 2004, 14 (5) : 675-680.
3MORAN P M, DHARMATILLEKE S, KHAW A H. Fluidic lenses with variable focal length [J]. Applied Physics Letters, 2006, 88(041120) : 1-3.
4HU X, ZHANG S, LIU Y, et al: Electrowetting based infrared lens using ionic liquids [J]. Applied Physics Letters, 2011, 99:2135-2140.
5JORGE F F, SALVADOR C, LUIS C, et al: Test and evaluation of a variable focus liquid lens for curvature wavefront sensors in astronomy [J]. Ap- plied Optics, 2013, 52(30) :7256-7264.
6JULIET T G, VICTOR M B, CAROL C C, etal: Simulation of electrowetting lens and prism arrays for wavefront compensation [J]. Applied Optics, 2012, 51(27): 6618-6623.
7KUIPER S, HENDRIKS B H W. Variable-focus liquid lens for miniature cameras [J]. Applied Physics Letters, 2004, 85 :1128-1130.
8BERGE B, PESEUX J. Variable focal lens con- trolled by an external voltage: an application of electrowetting [J]. The European Physical Jour-hal E, 2000, 3: 158-163.
9CHEVALLIOT S, KUIPER S, HEIKENFELD J, et al: Experimental validation of the invariance of electrowetting contact angle saturation [J]. Journal of Adhesion Science and Technology, 2012, 26:1909-1930.
10WYATT C, NELSON C J. Droplet actuation by electrowetting-on-dielectric [J]. Journal of Ad- hesion Science and Technology, 2012, 26:1747- 1771.

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2吴雯婷,梁忠诚,仉乐,赵瑞,孔梅梅.微流控双稳振荡器光开关[J].光子学报,2016,45(7):176-181.
3王亮,段俊萍,王万军,张斌珍.介电材料在介电润湿器件中的应用进展[J].材料导报,2016,30(19):70-76. 被引量：3
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6陈博伟,吴之舟,王正强.电润湿双液体透镜的建模仿真[J].电脑知识与技术,2018,14(5X):192-195. 被引量：1
7刘肖尧,梁忠诚,郝未倩,赵瑞,孔梅梅,陈陶,张月.辐射状多子镜阵列结构的成像特性[J].光学学报,2019,39(8):150-158. 被引量：4
8吴雯婷,梁忠诚,仉乐.可调微流控光学变焦透镜[J].发光学报,2015,36(6):718-723. 被引量：15
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10陈航宇,朱惺璐,李昕,刘泽宇.基于电润湿透镜的手机镜头设计[J].电脑知识与技术,2020,16(29):208-209. 被引量：1

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1公茂刚,刘远越,许小亮.A new model for the formation of contact angle and contact angle hysteresis[J].Chinese Physics B,2010,19(10):390-395.
2王飞,何枫.微管道内两相流数值算法及在电浸润液滴控制中的应用[J].物理学报,2006,55(3):1005-1010. 被引量：10
3LI XiaoLiang,HE GuoWei,ZHANG Xing.Numerical simulation of drop oscillation in AC electrowetting[J].Science China(Physics,Mechanics & Astronomy),2013,56(2):383-394. 被引量：1
4John Poulsen.Second Chance： If at First You Do Not Succeed, Set up a Plan and Try, Try Again[J].US-China Education Review(A),2012,2(3):365-373.
5徐梅,令狐荣锋,汪荣凯,杨向东.CaH,CaD分子的结构及其基态(X^2∑^+)势能函数的理论研究[J].原子与分子物理学报,2007,24(B08):45-47. 被引量：1
6SUN Jincai,WANG Chong and SUN Zhaohui (Institute of Acoustic Engineering Northwestern Polytechnical University Xi’an, 710072).Modification of energy balance equations in Statistical Energy Analysis[J].Chinese Journal of Acoustics,1996,15(1):1-7. 被引量：7
7ZHANG Ren-liang,DI Qin-feng,WANG Xin-liang,DING Wei-peng,GONG Wei.NUMERICAL STUDY OF THE RELATIONSHIP BETWEEN APPARENT SLIP LENGTH AND CONTACT ANGLE BY LATTICE BOLTZMANN METHOD[J].Journal of Hydrodynamics,2012,24(4):535-540. 被引量：11
8赵凌琪,白凤兰.拟谱方法及其收敛性[J].内蒙古民族大学学报（自然科学版）,2002,17(5):387-389.
9汪磊,许常悦.EFFECT OF CONTACT ANGLE HYSTERESIS ON DROPLET BEHAVIORS:TWO-PHASE LATTICE BOLTZMANN SIMULATION[J].Transactions of Nanjing University of Aeronautics and Astronautics,2013,30(3):270-275. 被引量：1
10王守田,王碧祥.Cahn－Hiliard方程的近似惯性流形[J].纯粹数学与应用数学,1996,12(2):37-42.

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