消除毛细管电泳槽道中弯道导致的扩散效应的新方法被引量：7

New Approach to Minimize Dispersion Induced by Turn in the Capillary Electrophoresis Channel Flows

下载PDF

导出

摘要　首先分析了毛细管通道中流动的弯道效应及其产生的原因,接着在建立电渗流场数学模型的基础上,用有限差分法对弯道处内外壁面上不同电荷分布时的扩散进行了数值模拟·　根据计算结果,提出了一种基于改变弯道处内外壁面上电荷分布的新方法,以此使流场的弯道效应最弱·　同时还建立了分析和确定弯道处最佳电荷分布的优化方法·　结果表明。 The mechanism of dispersion induced by turn in the capillary electrophoresis channel flows was analyzed firstly. Then the mathematical model of electroosmotic flow is built, and the dispersion of the flow, with different distribution of charge at inner and outer wall in the turns, was simulated numerically using the finite differential method. A new approach of altering the distribution of charge at inner and outer wall in the turns was presented, based on the computational results, to minimize the dispersion induced by turn. Meanwhile, an optimization algorithm to analyze the numerical results and determine the optimal distribution of charge in the turns was also developed. It is found that the dispersion induced by turn in the capillary electrophoresis channel flows could be significantly suppressed by this approach.

作者李志华林建忠聂德明

机构地区浙江大学力学系流体传动及控制国家重点实验室

出处《应用数学和力学》 CSCD 北大核心 2005年第6期631-636,共6页 Applied Mathematics and Mechanics

基金国家自然科学基金(重大)资助项目(20299030)

关键词微流动电泳电渗扩散弯道 micro-flow electrophoresis electroosmotic dispersion turn

分类号 O363.2 [理学—流体力学] O357 [理学—流体力学]

引文网络
相关文献

参考文献8

1Culbertson C T, Jacobson S C, Ramsey J M. Dispersion sources for compact geometries on microchip[ J]. Analytical Chemistry, 1998,70(18) :3781-3789.
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.
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.
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.
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.
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.
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.
8Hayes M A. Extension of external voltage control of electroosmosis to high-pH buffers[ J]. Analytical Chemistry, 1990,71(17) :3793-3798.

同被引文献44

1聂德明,林建忠,石兴.弯管电渗流场的数值模拟及研究[J].分析化学,2004,32(8):988-992. 被引量：6
2李志华,林建忠,聂德明.NEW APPROACH TO MINIMIZE DISPERSION INDUCED BY TURN IN CAPILLARY ELECTROPHORESIS CHANNEL FLOWS[J].Applied Mathematics and Mechanics(English Edition),2005,26(6):685-690. 被引量：3
3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
4张凯,林建忠,李志华.RESEARCH ON DIFFUSION IN MICRO-CHANNEL FLOW DRIVEN BY ELECTROOSMOSIS[J].Applied Mathematics and Mechanics(English Edition),2006,27(5):575-582. 被引量：1
5吴健康,王贤明.生物芯片微通道周期性电渗流特性[J].力学学报,2006,38(3):309-315. 被引量：14
6龚磊,吴健康.微通道液体流动双电层阻力效应[J].应用数学和力学,2006,27(10):1219-1225. 被引量：14
7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
8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
9Culbertson C T, Jacobson S C, Ramsey J M. Dispersion sources for compact geometries on microchips[JJ. Analytical Chemistry, 1998, 70(18): 3781-3789.
10Brian M. Paegel, Lester D. Hutt, Peter C. Simpson, and Richard A. Mathies. Turn Geometry for Minimizing Band Broadening in Microfabricated Capillary Electrophoresis Channels. Anal. Chem., 2000, 72: 3030-3037.

引证文献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
7A. A. SIDDIQUI,A. LAKHTAKIA.Debye-Hckel solution for steady electro-osmotic flow of micropolar fluid in cylindrical microcapillary[J].Applied Mathematics and Mechanics(English Edition),2013,34(11):1305-1326.

二级引证文献14

1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
2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
3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
4谭德坤,刘莹.双电层效应对压力驱动微流体流动及传热的影响[J].机械工程学报,2012,48(18):144-151. 被引量：3
5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
6于华,关继腾,陈辉,郑海霞,房文静.储层岩石流动电位频散特性的数学模拟[J].地球物理学报,2013,56(2):676-687. 被引量：10
7杜新龙,康毅力,游利军,俞杨烽,刘雪芬,杨建.低渗透储层微流动机理及应用进展综述[J].地质科技情报,2013,32(2):91-96. 被引量：9
8刘莹,谭德坤.压力驱动微流道内流动电势及壁面滑移效应[J].化工学报,2013,64(5):1743-1749. 被引量：3
9邢靖楠,菅永军.矩形纳米管道中的电动能量转换效率[J].应用数学和力学,2016,37(4):363-372. 被引量：2
10金军斌,董晓强.高温老化对黏土/降滤失剂体系滤失作用研究[J].科学技术与工程,2018,18(3):15-20. 被引量：4

应用数学和力学

2005年第6期

浏览历史

内容加载中请稍等...

消除毛细管电泳槽道中弯道导致的扩散效应的新方法被引量：7

参考文献8

同被引文献44

引证文献7

二级引证文献14

相关作者

相关机构

相关主题

浏览历史

消除毛细管电泳槽道中弯道导致的扩散效应的新方法 被引量：7

参考文献8

同被引文献44

引证文献7

二级引证文献14

相关作者

相关机构

相关主题

浏览历史

消除毛细管电泳槽道中弯道导致的扩散效应的新方法被引量：7