electroosmotic flow

The velocity of the electroosmotic flow is determined by the electric potential difference per unit length ( Electric Field Strength ) that applied on the microchannels .

电渗流的速度取决于微通道上单位长度的电势差（电场强度）。

Methods for controlling electroosmotic flow ( EOF ) in electroosmotic pump are the same as those in CE and EC , and are reviewed from the papers on EC and CE .

电渗泵中电渗流（EOF）控制方法与EC和CE等文献中盼电渗流控制方法是相同的。

Numerical simulation on Influence Factors of electroosmotic flow in rectangular microchannel

矩形微流道内电渗流影响因素的数值模拟

Control for Electroosmotic Flow in High Performance Capillary Electrophoresis

高效毛细管电泳中的电渗流及控制

Numerical Simulation of Surface Roughness Effect on Electroosmotic Flow in Microchannels

微流道壁面粗糙度影响的电渗流数值模拟

Analysis of Electroosmotic Flow with Linear Variable Zeta Potential

基于线性变化边界条件的电渗流仿真分析

Effect of Surface Roughness on Electroosmotic Flow in Microchannels by Finite Element Simulating

微通道内壁面粗糙度对电渗流影响有限元模拟

Enhanced Resolution Achieved With Electroosmotic Flow Control in Capillary Isoelectric Focusing With Dynamic Coatings

在动态涂层毛细管等电聚焦中通过控制电渗流提高分辨率

Molecular Dynamics Simulation of Electroosmotic Flow in Nanotubes

纳米管道中电渗流的分子动力学仿真

Research on the Separation Behavior of Acidic Drugs in Capillary Electrophoresis with Reversed Direction of Electroosmotic Flow

酸性药物的反向电渗流高效毛细管电泳分离分析研究

Separation of Aromatic Amines by Capillary Zone Electro-phoresis with Lower Electroosmotic Flow

低电渗流毛细管区带电泳分离芳香胺

Effect of Composition of Mobile Phase on Electrophoresis Osmotic Flow in Monolithic Capillary Columns with Low Electroosmotic Flow

微电渗流毛细管原位柱中流动相组成对电渗流的影响

Application of liquid - driving intelligent electrical instrument in the measurement of electroosmotic flow of PMMA microfluidic chip

流体驱动智能电动控制仪用于PMMA微流控芯片电渗流的测量

Electroosmotic flow and process characteristics of hydroxylapatite electrochromatography

羟基磷灰石电色谱中电渗流动与分离过程特性

Manipulation of Electroosmotic Flow in Capillary Electrophoresis for Iodide and Iodate

毛细管电泳分离I~-和IO3~-中的电渗流的控制与调节

Transient thermal effect on electroosmotic flow in mini-tube

微细管内电渗流动的瞬态热效应

Hydrodynamic analysis of electroosmotic flow in micropump

毛细管电渗流微泵的流体动力学的数值仿真

Electroosmotic Flow in Capillary Zone Electrophoresis

毛细管区带电泳的电渗流

CFD simulation and experimental study of electroosmotic flow in porous media (ⅰ) CFD simulation of electroosmotic flow in porous media

多孔介质电渗流动计算流体力学模拟与实验研究（Ⅰ）多孔介质电渗流动的CFD模拟

It is also found that the electroosmotic flow is in the opposite direction to that predicted by the classical continuum theory .

约占整个通道的三分之二内的区域内，溶液朝着与连续性理论预测的相反方向流动，出现了反转电渗流。

Controlling Electroosmotic Flow in Electroosmotic Pump

电渗泵中电渗流的控制微流量输液泵

The results demonstrated the coated columns were good enough to repress the electroosmotic flow and the adsorption of the proteins on t.

通过物理吸附方法将其涂布在熔融石英毛细管内表面，测定了涂层柱的电渗流及其对碱性蛋白质的分离能力。

The influences of pH , separation voltage , and concentrations of electroosmotic flow modifier , CTAB and background electrolyte were investigated .

通过研究分离电压、背景电解质和电渗流改性剂的浓度、pH的影响优化了分析条件。

The electroosmotic flow and voltage-ampere curves of the PMMA chips corresponded to those reported in the literature .

测定了PMMA芯片的伏安曲线和电渗流，其电渗流值与文献报道值基本一致。

Imidazole ionic liquids can be absorbed into capillary wall affecting the quantity and direction of electroosmotic flow ( EOF ) .

咪唑型离子液体因其独特结构，能吸附在毛细管壁，影响毛细管电泳电渗流大小和方向。

In order to solve the problem of different solutions from different channels mixing slowly , an electroosmotic flow mixer is designed , and then simulation experiment is done .

为解决来自多通道不同溶液混合缓慢的问题，设计了微电渗流混合器，并做了仿真实验。

The coated column prepared by this method was good enough to repress the electroosmotic flow and the adsorption of the proteins on the capillary wall .

该方法制备的涂层柱能有效地抑制电渗流和蛋白质在毛细管壁的吸附作用；

The electroosmotic flow can be produced without any buffer salts by the carefully controlled bonding degree . It is convenient and saves a lot of time .

仔细地控制该板的键合度可以不使用缓冲液而产生电渗流，这为实验带来了极大的方便，节省了时间，并且在此基础上可以发展出一些新的展开方法和使用技巧。

RESULTS : The phosphate buffer of pH 4.0 could deactivate the capillary wall effectively , so that the best resolution was obtained because of the reduced electroosmotic flow .

结果：pH4.0的磷酸盐缓冲液可有效地涂渍毛细管壁，减少电渗流，提高分辨率。在优化的测定条件下共分出了6种糖基化形式。

The effects of grafting density , electric field strength and solvent quality on electroosmotic flow velocity , counterion distribution and conformational characteristics of grafted chains have been studied .

阐述了接枝度、电场强度和溶剂效应对电渗速度、反离子分布和聚合物链构象特征的影响。