Electrohydromechanical analysis based on conductivity gradient in microchannel 被引量：4

Electrohydromechanical analysis based on conductivity gradient in microchannel

在线阅读下载PDF

导出

摘要 Fluid manipulation is very important in any lab-on-a-chip system. This paper analyses phenomena which use the alternating current （AC） electric field to deflect and manipulate coflowing streams of two different electrolytes （with conductivity gradient） within a microfluidic channel. The basic theory of the electrohydrodynamics and simulation of the analytical model are used to explain the phenomena. The velocity induced for different voltages and conductivity gradient are computed. The results show that when the AC electrical signal is applied on the electrodes, the fluid with higher conductivity occupies a larger region of the channel and the interface of the two fluids is deflected. It will provide some basic reference for people who want to do more study in the control of different fluids with conductivity gradient in a microfluidic channel. Fluid manipulation is very important in any lab-on-a-chip system. This paper analyses phenomena which use the alternating current （AC） electric field to deflect and manipulate coflowing streams of two different electrolytes （with conductivity gradient） within a microfluidic channel. The basic theory of the electrohydrodynamics and simulation of the analytical model are used to explain the phenomena. The velocity induced for different voltages and conductivity gradient are computed. The results show that when the AC electrical signal is applied on the electrodes, the fluid with higher conductivity occupies a larger region of the channel and the interface of the two fluids is deflected. It will provide some basic reference for people who want to do more study in the control of different fluids with conductivity gradient in a microfluidic channel.

作者姜洪源任玉坤敖宏瑞 Antonio Ramos

机构地区 School of Mechatronics Engineering Department Electronica y Electromagnetismo

出处《Chinese Physics B》 SCIE EI CAS CSCD 2008年第12期4541-4546,共6页 中国物理B（英文版）

基金 Project supported by the 111 Project (Grant No B07018)

关键词 ELECTROHYDRODYNAMICS conductivity gradient theoretical analysis numerical simulation electrohydrodynamics, conductivity gradient, theoretical analysis, numerical simulation

分类号 TN401 [电子电信—微电子学与固体电子学]

作者简介 E-mail： xiaoyu2002-2001@ 163.com

引文网络
相关文献

参考文献12

1Stone H A, Stroock A D and Ajdari A 2004 Annual Review Fluid Mechanics 36 381
2Li B X, Ye M Y, Chu Q Y and Yu J 2007 Acta Phys. Sin. 56 3447
3Koch M, Evans A and Brunnschewiler A 2000 Microfluidie Technology and Applications (Herts: Research Studies Ltd)
4Ramos A, Morgan H, Green N G and Castellanos A 1998 J. Phys. D 31 2338
5Bazant M Z and Squires T M 2004 Phys. Rev. Lett. 92 066101
6Sasaki N, Kitamori T and Kim H B 2006 Lab Chip 6 550
7Zhao H and Bau H H 2007 Phys. Rev. E 75 066217
8Green1 N G, Ramos A, Gonzdlez A, Morgan H and Castel- lanos A 2000 Phys. Rev. E 61 4011
9Morgan H, Green N G and Ramos A 2007 Appl. Phys. Lett. 91 254107
10Stratton J A 1941 Electromagnetic Theory (New York: Mcgraw-Hill)

同被引文献35

1刘国君,程光明,杨志刚.一种压电式精密输液微泵的试验研究[J].光学精密工程,2006,14(4):612-616. 被引量：18
2姜洪源,闫宝森,杨胡坤,Ramos Antonio.交流电渗驱动机理及流速计算[J].中国机械工程,2007,18(14):1672-1675. 被引量：7
3STUDER V, PEPIN A, CHEN Yong, et al. Fabrication of microfluidic devices for AC electrokinetic fluid pum- ping[J}. Microelectronie Engineering, 2002, 61 (2) : 915 -920.
4STONE H, STROOCK A, AJDABI A. Microfluidic technologies for miniaturized analysis systems[ M]. New York : Springer-Verlag, 2007 : 1 - 3.
5WANG Xiayan, WANG Shili, GENDHAR B, et al. Electroosmotic pumps for microflow analysis[ J ]. Trends in Anylytical Chemistry, 2009, 28 ( 1 ) : 64 - 74.
6CAHILL B P, HEYDERMAN L J, GOBRECHT J, et al. Electro-osmotic streaming on application of traveling- wave electric fields [ J ]. Physical Review E, 2004, 70 (3) : 036 - 305.
7STUDER V, PEPIN A, CHEN Yong, et al. An integrat- ed AC electrokinetic pump in a microfluidic loop for fast and tunable flow control [ J]. The Analyst, 2004, 129 (10) : 944 - 949.
8NG W Y, LAM Y C, RODRIGUEZ I. Experimental verification of faradaic charging in ac electrokinetics [J]. Biomicrofluidics, 2009, 3(2) - 022 -405.
9GARCIA-SANCHEZ P, RAMOS A. Flow reversal in traveling-wave electrokinetics: an analysis of forces due to ionic concentration gradients [ J ]. Langmuir, 2009, 25(9) : 4988 -4997.
10LIAN Meng, ISLAM N, WU Jie. AC electrothermal ma- nipulation of conductive fluids and particles for lab - chip applications [ J ]. IET Nanobiotechnol, 2007, 1(3): 36 -43.

引证文献4

1姜洪原,任玉坤,A.Ramos.交流电场作用下具有导电率梯度的两相微流体驱动[J].哈尔滨工业大学学报,2011,43(2):109-113.
2姜洪源,任玉坤,于东,霍彦婷,陶冶,Antonio Ramos.点面电极系统高频流体驱动机理[J].哈尔滨工程大学学报,2011,32(3):350-354.
3姜洪源,霍彦婷,任玉坤,李姗姗,陶冶,Antonio Ramos.点面电极系统低频流体驱动机理[J].哈尔滨工业大学学报,2011,43(5):56-60.
4REN Yukun,WU Hongchi,FENG Guojing,HOU Likai,JIANG Hongyuan.Effects of Chip Geometries on Dielectrophoresis and Electrorotation Investigation[J].Chinese Journal of Mechanical Engineering,2014,27(1):103-110. 被引量：4

二级引证文献4

1顾雯雯,温志渝.介电电泳细胞分析芯片结构设计及富集效率优化[J].仪器仪表学报,2015,36(1):174-180. 被引量：1
2TAO Ye,REN Yukun,YAN Hui,JIANG Hongyuan.Continuous Separation of Multiple Size Microparticles using Alternating Current Dielectrophoresis in Microfluidic Device with Acupuncture Needle Electrodes[J].Chinese Journal of Mechanical Engineering,2016,29(2):325-331. 被引量：3
3白国花,谭秋林.基于微流控芯片的细胞排列和迁移的实验研究[J].中北大学学报（自然科学版）,2017,38(1):87-92.
4顾雯雯.介电电泳细胞分析芯片结构设计及实验研究[J].西南大学学报（自然科学版）,2015,37(4):158-163. 被引量：1

1彭晓峰,胡杭英,王补宣.Bubble formation of liquid boiling in microchannels[J].Science China(Technological Sciences),1998,41(4):404-410.
2Khaled S.Mekheimer,Soliman R.Komy,Sara I.Abdelsalam.Simultaneous effects of magnetic field and space porosity on compressible Maxwell fluid transport induced by a surface acoustic wave in a microchannel[J].Chinese Physics B,2013,22(12):323-332. 被引量：9
3龚磊,吴健康.RESISTANCE EFFECT OF ELECTRIC DOUBLE LAYER ON LIQUID FLOW IN MICROCHANNEL[J].Applied Mathematics and Mechanics(English Edition),2006,27(10):1391-1398. 被引量：1
4谭臻,齐海涛,蒋晓云.Electroosmotic flow of Eyring fluid in slit microchannel with slip boundary condition[J].Applied Mathematics and Mechanics(English Edition),2014,35(6):689-696. 被引量：1
5任玉坤,闫辉,姜洪源,顾建忠,Antonio Ramos.Force criterion of different electrolytes in microchannel[J].Chinese Physics B,2009,18(10):4349-4352.
6马友光,付涛涛,朱春英,季喜燕,LI Huaizhi.Formation Mechanism and Size Prediction of Bubble in Opposite-Flowing T-Shaped Microchannel[J].Transactions of Tianjin University,2010,16(4):251-255. 被引量：3
7包丽平,菅永军,长龙,苏洁,张海燕,刘全生.Time Periodic Electroosmotic Flow of The Generalized Maxwell Fluids in a Semicircular Microchannel[J].Communications in Theoretical Physics,2013,59(5):615-622. 被引量：1
8Cheng, JX,Yang, CB,Wen, TS,Wen, SH,Tang, DY,Zheng, ZJ,Shan, B,Liu, JY,Chang, ZH,Liu, XQ,Gao, SC.Twelve-frame camera for soft X-ray[J].Chinese Science Bulletin,1997,42(14):1215-1217.
9Yan Pang,Zhaomiao Liu,Fuwang Zhao.Downstream pressure and elastic wall reflection of droplet flow in a T-junction microchannel[J].Acta Mechanica Sinica,2016,32(4):579-587. 被引量：1
10晁侃,吴健康,陈波.Joule heating effect of electroosmosis in a finite-length microchannel made of different materials[J].Applied Mathematics and Mechanics(English Edition),2010,31(1):109-118.

Chinese Physics B

2008年第12期

浏览历史

内容加载中请稍等...

Electrohydromechanical analysis based on conductivity gradient in microchannel 被引量：4

参考文献12

同被引文献35

引证文献4

二级引证文献4

相关作者

相关机构

相关主题

浏览历史