Debye-Hckel solution for steady electro-osmotic flow of micropolar fluid in cylindrical microcapillary

Debye-Hckel solution for steady electro-osmotic flow of micropolar fluid in cylindrical microcapillary

下载PDF

导出

摘要 Analytic expressions for speed, flux, microrotation, stress, and couple stress in a micropolar fluid exhibiting a steady, symmetric, and one-dimensional electro-osmotic flow in a uniform cylindrical microcapillary were derived under the constraint of the Debye-Hiickel approximation, which is applicable when the cross-sectional radius of the microcapillary exceeds the Debye length, provided that the zeta potential is sufficiently small in magnitude. Since the aciculate particles in a micropolar fluid can rotate without translation, micropolarity affects the fluid speed, fluid flux, and one of the two non-zero components of the stress tensor. The axial speed in a micropolar fluid intensifies when the radius increases. The stress tensor is confined to the region near the wall of the mi- crocapillary, while the couple stress tensor is uniform across the cross-section. Analytic expressions for speed, flux, microrotation, stress, and couple stress in a micropolar fluid exhibiting a steady, symmetric, and one-dimensional electro-osmotic flow in a uniform cylindrical microcapillary were derived under the constraint of the Debye-Hiickel approximation, which is applicable when the cross-sectional radius of the microcapillary exceeds the Debye length, provided that the zeta potential is sufficiently small in magnitude. Since the aciculate particles in a micropolar fluid can rotate without translation, micropolarity affects the fluid speed, fluid flux, and one of the two non-zero components of the stress tensor. The axial speed in a micropolar fluid intensifies when the radius increases. The stress tensor is confined to the region near the wall of the mi- crocapillary, while the couple stress tensor is uniform across the cross-section.

作者 A. A. SIDDIQUI A. LAKHTAKIA

机构地区 Department of Basic Sciences Nanoengineered Metamaterials Group

出处《Applied Mathematics and Mechanics(English Edition)》 SCIE EI 2013年第11期1305-1326,共22页 应用数学和力学（英文版）

关键词 couple stress ELECTRO-OSMOSIS MICROCAPILLARY micropolar fluid microrota-tion steady flow couple stress, electro-osmosis, microcapillary, micropolar fluid, microrota-tion, steady flow

分类号 O363.2 [理学—流体力学]

引文网络
相关文献

参考文献2

1李志华,林建忠,聂德明.消除毛细管电泳槽道中弯道导致的扩散效应的新方法[J].应用数学和力学,2005,26(6):631-636. 被引量：8
2林建忠,张凯,李惠君.Study on the mixing of fluid in curved microchannels with heterogeneous surface potentials[J].Chinese Physics B,2006,15(11):2688-2696. 被引量：1

二级参考文献24

1Culbertson C T, Jacobson S C, Ramsey J M. Dispersion sources for compact geometries on microchip[ J]. Analytical Chemistry, 1998,70(18) :3781-3789. 被引量：1
2Paegel B M, Lester D H, Simpson P C, et al. Turn geometry for minimizing band broadening in microfabricated capillary electrophoresis channels[ J]. Analytical Chemistry, 2000,72(14): 3030-3037. 被引量：1
3Molho J I, Herr A E, Mosier B P, et al. Optimization of turn geometries for microchip electrophoresis[J]. Analytical Chemistry ,2001,73(7): 1350-1360. 被引量：1
4Qiao R, Aluru N R. Dispersion control in nano-channel systems by localized zeta-potential variations[ J ]. Sensors and Actuators A: Physical, 2003,104(3) :268-274. 被引量：1
5Schwer C, Kenndler E. Electrophoresis in fused-silica capillaries-the influence of organic-solvents on the electroosmotic velocity and the zeta-potential[ J]. Analytical Chemistry, 1991,63( 17):1801-1807. 被引量：1
6Moseley M A, Deterding L J, Tomer K B, et al. Determination of bioactive peptides using capillary zone electrophoresis mass-spectrometry[ J]. Analytical Chemistry, 1991,63(2): 114-120. 被引量：1
7Johnson T J, Ross D, Gaitan M, et al. Laser modification of performed polymer microchannels: ap-plication to reduced band broadening around turns subject to electrokinetic flow[J ]. Analytical Chemistry, 2001,73(15): 3656-3661. 被引量：1
8Hayes M A. Extension of external voltage control of electroosmosis to high-pH buffers[ J]. Analytical Chemistry, 1990,71(17) :3793-3798. 被引量：1
9Chang C C and Yang R J 2004 J. Micromech. Microeng.14 550 被引量：1
10Liu Y Z, Byoung J K and Hyung J S 2004 Inter. J. Heat and Fluid Flow 25 986 被引量：1

共引文献7

1张凯,林建忠,李志华.电渗驱动微通道流中的扩散[J].应用数学和力学,2006,27(5):512-518. 被引量：4
2龚磊,吴健康,王蕾,晁侃.微通道周期流动电位势及电粘性效应[J].应用数学和力学,2008,29(6):649-656. 被引量：8
3龚磊,吴健康,王蕾,晁侃.Periodical streaming potential and electro-viscous effects in microchannel flow[J].Applied Mathematics and Mechanics(English Edition),2008,29(6):715-724. 被引量：1
4高晓冲,高轻,王震,高瑞昶.消除芯片毛细管电泳弯道效应的新方法[J].化学工程与装备,2011(10):29-33.
5陈辉,关继腾,房文静.Microscopic mechanism of periodical electroosmosis in reservoir rocks[J].Applied Mathematics and Mechanics(English Edition),2012,33(10):1275-1286. 被引量：1
6陈辉,关继腾,房文静.储层岩石周期性电渗流特性的微观机制[J].应用数学和力学,2012,33(10):1189-1198. 被引量：1
7李江涛,李风娟,赵群喜,刘泽锋,于佳佳,马保建.基于BOBYQA算法毛细管电泳弯管效应的优化[J].传感器与微系统,2024,43(8):114-117.

1M. S. Faltas,H. H. Sherief,E. A. Ashmawy,M. G. Nashwan.Unsteady unidirectional micropolar fluid flow[J].Theoretical & Applied Mechanics Letters,2011,1(6):36-40.
2Zhang Chonghong,Chen Keqin,Wang Yinshu and Sun Jiguang(General Research Institute of Nonferrous Metals ,Beijing.).Cross－sectional　TEM　Study　of　Helium　Bubble　Nucleation　in　316L　SS　Implanted　at　400℃　and　550℃[J].IMP & HIRFL Annual Report,1994(0):175-175.
3H.H. Sherief,M.S. Faltas,E.A. Ashmawy.Exact solution for the unsteady flow of a semi-infinite micropolar fluid[J].Acta Mechanica Sinica,2011,27(3):354-359. 被引量：1
4陈明涛.GLOBAL WELL-POSEDNESS OF THE 2D INCOMPRESSIBLE MICROPOLAR FLUID FLOWS WITH PARTIAL VISCOSITY AND ANGULAR VISCOSITY[J].Acta Mathematica Scientia,2013,33(4):929-935. 被引量：2
5D.SRINIVASACHARYA,D.SRIKANTH.FLOW OF MICROPOLAR FLUID THROUGH CATHETERIZED ARTERY -- A MATHEMATICAL MODEL[J].International Journal of Biomathematics,2012,5(2):61-72. 被引量：1
6胡业民,胡希伟.Properties and Structure of a Plasma Non-Neutral Shock[J].Chinese Physics Letters,2004,21(1):133-136. 被引量：1
7DAI,Tian-min(戴天民).RESTUDY OF COUPLED FIELD THEORIES FOR MICROPOLAR CONTINUA (Ⅰ)──MICROPOLAR THERMOELASTICITY[J].Applied Mathematics and Mechanics(English Edition),2002,23(2):119-126. 被引量：1
8MISRA J. C.,CHANDRA S..Electro-osmotic flow of a second-grade fluid in a porous microchannel subject to an AC electric field[J].Journal of Hydrodynamics,2013,25(2):309-316. 被引量：3
9M.ASHRAF,M.M.ASHRAF.MHD stagnation point flow of a micropolar fluid towards a heated surface[J].Applied Mathematics and Mechanics(English Edition),2011,32(1):45-54.
10Bin Ji,Wanji Chen,Jie Zhao.Measurement of length-scale and solution of cantilever beam in couple stress elasto-plasticity[J].Acta Mechanica Sinica,2009,25(3):381-387. 被引量：2

Applied Mathematics and Mechanics(English Edition)

2013年第11期

浏览历史

内容加载中请稍等...

Debye-Hckel solution for steady electro-osmotic flow of micropolar fluid in cylindrical microcapillary

参考文献2

二级参考文献24

共引文献7

相关作者

相关机构

相关主题

浏览历史